Eurocode 3 - Design of steel structures - Part 1-8: Design of joints [2005 ed.]


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UNIedil Strutture 2005.2
Indice generale file://../INDICI/INDICEG.PDF Norme ordinate file://../INDICI/INDICEN.PDF per numero file://../INDICI/NUMERO.PDF#page=1 UNI EU 54:1981 file://../SB/AA007284.PDF UNI EN 74:1990 file://../SB/AA008388.PDF UNI EN 101:1992 file://../SB/AA007396.PDF UNI EN 107:1983 file://../SB/AA007402.PDF UNI EN 124:1995 file://../SB/AA008329.PDF UNI ISO 128-23:2005 file://../SB/AA022461.PDF UNI EN 131-1:1994 file://../SB/AA010102.PDF UNI EN 131-2:1994 file://../SB/AA010101.PDF UNI EN ISO 140-1:1999 file://../SB/AA014298.PDF UNI EN ISO 140-3:1997 file://../SB/AA012460.PDF UNI EN ISO 140-4:2000 file://../SB/AA015564.PDF UNI EN ISO 140-5:2000 file://../SB/AA015436.PDF UNI EN ISO 140-6:2000 file://../SB/AA015541.PDF UNI EN ISO 140-7:2000 file://../SB/AA015565.PDF UNI EN ISO 140-8:1999 file://../SB/AA014490.PDF UNI EN ISO 140-11:2005 file://../SB/AA022851.PDF UNI EN ISO 140-12:2001 file://../SB/AA016141.PDF UNI EN ISO 140-14:2004 file://../SB/AA021181.PDF UNI EN 149:2003 file://../SB/AA018875.PDF UNI EN 166:2004 file://../SB/AA020519.PDF UNI EN 175:1999 file://../SB/AA014116.PDF UNI EN 179:2002 file://../SB/AA018152.PDF UNI EN 196-1:2005 file://../SB/AA022508.PDF UNI EN 196-2:2005 file://../SB/AA022509.PDF UNI EN 196-3:2005 file://../SB/AA022510.PDF UNI ENV SPERIMENTALE 196-4:1994 file://../SB/AA008536.PDF UNI EN 196-5:2005 file://../SB/AA022511.PDF UNI EN 196-6:1991 file://../SB/AA008538.PDF UNI EN 196-7:1991 file://../SB/AA008539.PDF UNI EN 196-8:2004 file://../SB/AA021396.PDF UNI EN 196-9:2004 file://../SB/AA021368.PDF UNI EN 197-1:2001 file://../SB/AA016370.PDF UNI EN 197-2:2001 file://../SB/AA016371.PDF UNI EN 197-4:2005 file://../SB/AA021543.PDF UNI EN 206-1:2001 file://../SB/AA016760.PDF UNI EN 233:2001 file://../SB/AA016722.PDF UNI EN 234:1990 + A1:1999 file://../SB/AA018737.PDF UNI EN 235:2004 file://../SB/AA020401.PDF UNI EN 259-1:2003 file://../SB/AA018994.PDF UNI EN 259-2:2003 file://../SB/AA019067.PDF UNI EN 266:1993 file://../SB/AA009128.PDF UNI EN 280:2005 file://../SB/AA022453.PDF UNI EN 287-1:2004 file://../SB/AA020683.PDF UNI EN 287-2:1993 + A1:1999 file://../SB/AA018755.PDF UNI EN 288-2:1993 + A1:1999 file://../SB/AA018757.PDF UNI EN 288-4:1993 + A1:1999 file://../SB/AA018763.PDF UNI EN 288-7:1997 file://../SB/AA011951.PDF UNI EN 288-8:1997 file://../SB/AA011952.PDF UNI EN 288-9:2001 file://../SB/AA015990.PDF UNI EN 301:1993 file://../SB/AA009172.PDF UNI EN 302-1:2005 file://../SB/AA022089.PDF UNI EN 302-2:2005 file://../SB/AA022182.PDF UNI EN 302-3:2005 file://../SB/AA022090.PDF UNI EN 302-4:2005 file://../SB/AA022091.PDF UNI ENV 302-5:2005 file://../SB/AA021761.PDF UNI EN 302-6:2005 file://../SB/AA022183.PDF UNI EN 302-7:2005 file://../SB/AA022964.PDF UNI EN 336:2004 file://../SB/AA021356.PDF UNI EN 338:2004 file://../SB/AA021308.PDF UNI EN 341:1993 + A1:1998 file://../SB/AA018766.PDF UNI EN 352-1:2004 file://../SB/AA020565.PDF UNI EN 352-3:2004 file://../SB/AA020575.PDF UNI EN 352-4:2002 file://../SB/AA018029.PDF UNI EN 352-5:2004 file://../SB/AA020541.PDF UNI EN 352-6:2004 file://../SB/AA020542.PDF UNI EN 353-1:2003 file://../SB/AA019625.PDF UNI EN 353-2:2003 file://../SB/AA019627.PDF UNI EN 354:2003 file://../SB/AA019777.PDF UNI EN 355:2003 file://../SB/AA019778.PDF UNI EN 356:2002 file://../SB/AA017150.PDF UNI EN 357:2005 file://../SB/AA022093.PDF UNI EN 360:2003 file://../SB/AA019779.PDF UNI EN 361:2003 file://../SB/AA019780.PDF UNI EN 363:2003 file://../SB/AA019781.PDF UNI EN 364:1993 file://../SB/AA009856.PDF UNI EN 365:2005 file://../SB/AA021572.PDF UNI EN 380:1994 file://../SB/AA010241.PDF UNI EN 383:1994 file://../SB/AA010329.PDF UNI EN 384:2005 file://../SB/AA022253.PDF UNI EN 385:2003 file://../SB/AA018933.PDF UNI EN 386:2003 file://../SB/AA019274.PDF UNI EN 387:2003 file://../SB/AA019176.PDF UNI EN 390:1997 file://../SB/AA011988.PDF UNI EN 391:2003 file://../SB/AA019273.PDF UNI EN 392:1997 file://../SB/AA011984.PDF UNI EN 397:2001 file://../SB/AA016754.PDF UNI EN 408:2004 file://../SB/AA021223.PDF UNI EN 409:1994 file://../SB/AA010240.PDF UNI EN 410:2000 file://../SB/AA014815.PDF UNI EN 413-1:2004 file://../SB/AA021261.PDF UNI EN 413-2:2005 file://../SB/AA022924.PDF UNI EN 420:2004 file://../SB/AA020836.PDF UNI EN 423:2002 file://../SB/AA018047.PDF UNI EN 424:2003 file://../SB/AA018466.PDF UNI EN 425:1995 file://../SB/AA011149.PDF UNI EN 426:1994 file://../SB/AA010297.PDF UNI EN 427:1995 file://../SB/AA011148.PDF UNI EN 428:1994 file://../SB/AA010298.PDF UNI EN 429:1994 file://../SB/AA010299.PDF UNI EN 430:1995 file://../SB/AA011147.PDF UNI EN 431:1995 file://../SB/AA011146.PDF UNI EN 432:1995 file://../SB/AA011145.PDF UNI EN 433:1995 file://../SB/AA011144.PDF UNI EN 434:1997 file://../SB/AA012176.PDF UNI EN 435:1997 file://../SB/AA012177.PDF UNI EN 436:1997 file://../SB/AA011923.PDF UNI EN 438-1:2005 file://../SB/AA022547.PDF UNI EN 438-2:2005 file://../SB/AA022548.PDF UNI EN 438-3:2005 file://../SB/AA022571.PDF UNI EN 438-4:2005 file://../SB/AA022572.PDF UNI EN 438-5:2005 file://../SB/AA022549.PDF UNI EN 438-6:2005 file://../SB/AA022550.PDF UNI EN 438-7:2005 file://../SB/AA022551.PDF UNI EN 445:1997 file://../SB/AA012271.PDF UNI EN ISO 445:2001 file://../SB/AA016226.PDF UNI EN 446:1997 file://../SB/AA012270.PDF UNI EN 447:1997 file://../SB/AA012274.PDF UNI EN 450-1:2005 file://../SB/AA022376.PDF UNI EN 450-2:2005 file://../SB/AA022377.PDF UNI EN 451-1:2004 file://../SB/AA021206.PDF UNI EN 451-2:1996 file://../SB/AA011221.PDF UNI EN 458:2005 file://../SB/AA022324.PDF UNI EN 459-1:2002 file://../SB/AA018043.PDF UNI EN 459-2:2002 file://../SB/AA018157.PDF UNI EN 459-3:2002 file://../SB/AA018041.PDF UNI EN 460:1996 file://../SB/AA011419.PDF UNI EN 471:2004 file://../SB/AA020977.PDF UNI EN 474-1:1997 + A1:2000 file://../SB/AA018782.PDF UNI EN 474-7:2000 file://../SB/AA014826.PDF UNI EN 474-8:2000 file://../SB/AA014827.PDF UNI EN 474-9:2000 file://../SB/AA014828.PDF UNI EN 474-10:2000 file://../SB/AA014829.PDF UNI EN 474-11:2000 file://../SB/AA014830.PDF UNI EN 477:1997 file://../SB/AA012169.PDF UNI EN 478:1997 file://../SB/AA012141.PDF UNI EN 479:1997 file://../SB/AA012166.PDF UNI EN 480-1:1999 file://../SB/AA014204.PDF UNI EN 480-2:1998 file://../SB/AA012677.PDF UNI EN 480-4:1998 file://../SB/AA012676.PDF UNI EN 480-5:1998 file://../SB/AA012687.PDF UNI EN 480-6:1998 file://../SB/AA012686.PDF UNI EN 480-8:1998 file://../SB/AA012685.PDF UNI EN 480-10:1998 file://../SB/AA012684.PDF UNI EN 480-11:2000 file://../SB/AA015163.PDF UNI EN 480-12:1999 file://../SB/AA014297.PDF UNI EN 480-13:2003 file://../SB/AA019108.PDF UNI EN 490:2005 file://../SB/AA021793.PDF UNI EN 491:2005 file://../SB/AA021701.PDF UNI EN 492:2005 file://../SB/AA021866.PDF UNI EN 494:2005 file://../SB/AA021867.PDF UNI EN 495-5:2002 file://../SB/AA017517.PDF UNI EN 500-1:1997 file://../SB/AA011882.PDF UNI EN 500-2:1997 file://../SB/AA011881.PDF UNI EN 500-3:1997 file://../SB/AA011880.PDF UNI EN 500-4:1997 file://../SB/AA011879.PDF UNI ENV 500-6:1997 file://../SB/AA011877.PDF UNI EN 501:1996 file://../SB/AA011634.PDF UNI EN 502:2001 file://../SB/AA015913.PDF UNI EN 505:2001 file://../SB/AA015914.PDF UNI EN 506:2002 file://../SB/AA018097.PDF UNI EN 507:2002 file://../SB/AA017086.PDF UNI EN 508-1:2002 file://../SB/AA018205.PDF UNI EN 508-2:2002 file://../SB/AA018204.PDF UNI EN 508-3:2002 file://../SB/AA018203.PDF UNI EN 510:1994 file://../SB/AA009915.PDF UNI EN 512:2003 file://../SB/AA019154.PDF UNI EN 513:2001 file://../SB/AA016471.PDF UNI EN 514:2001 file://../SB/AA016712.PDF UNI EN 516:1998 file://../SB/AA013269.PDF UNI EN 517:1998 file://../SB/AA013270.PDF UNI EN 518:1997 file://../SB/AA011966.PDF UNI EN 519:1997 file://../SB/AA011997.PDF UNI EN 520:2005 file://../SB/AA022184.PDF UNI EN 523:2005 file://../SB/AA022393.PDF UNI EN 524-1:1998 file://../SB/AA013491.PDF UNI EN 524-2:1998 file://../SB/AA013492.PDF UNI EN 524-3:1998 file://../SB/AA013493.PDF UNI EN 524-4:1998 file://../SB/AA013494.PDF UNI EN 524-5:1998 file://../SB/AA013495.PDF UNI EN 524-6:1998 file://../SB/AA013496.PDF UNI EN 534:2000 file://../SB/AA014966.PDF UNI EN 536:2001 file://../SB/AA016229.PDF UNI EN 538:1997 file://../SB/AA012175.PDF UNI EN 539-1:1997 file://../SB/AA012174.PDF UNI EN 539-2:2000 file://../SB/AA014856.PDF UNI EN 544:1999 file://../SB/AA014440.PDF UNI EN 548:2004 file://../SB/AA021301.PDF UNI EN 572-1:2004 file://../SB/AA021184.PDF UNI EN 572-2:2004 file://../SB/AA021128.PDF UNI EN 572-3:2004 file://../SB/AA021151.PDF UNI EN 572-4:2004 file://../SB/AA021129.PDF UNI EN 572-5:2004 file://../SB/AA021127.PDF UNI EN 572-6:2004 file://../SB/AA021152.PDF UNI EN 572-7:2004 file://../SB/AA021130.PDF UNI EN 572-8:2004 file://../SB/AA020771.PDF UNI EN 572-9:2005 file://../SB/AA021628.PDF UNI EN 580:2004 file://../SB/AA020228.PDF UNI EN 594:1997 file://../SB/AA012035.PDF UNI EN 595:1997 file://../SB/AA011979.PDF UNI EN 596:1997 file://../SB/AA012468.PDF UNI EN 639:1996 file://../SB/AA011465.PDF UNI EN 640:1996 file://../SB/AA011415.PDF UNI EN 641:1996 file://../SB/AA011414.PDF UNI EN 642:1996 file://../SB/AA011413.PDF UNI EN 649:1998 file://../SB/AA013505.PDF UNI EN 650:1998 file://../SB/AA013488.PDF UNI EN 651:1998 file://../SB/AA013475.PDF UNI EN 652:1998 file://../SB/AA013474.PDF UNI EN 653:1998 file://../SB/AA013489.PDF UNI EN 654:1998 file://../SB/AA013490.PDF UNI EN 655:1998 file://../SB/AA013473.PDF UNI EN 660-1-2004 file://../SB/AA020303.PDF UNI EN 661:1997 file://../SB/AA011920.PDF UNI EN 662:1997 file://../SB/AA012167.PDF UNI EN 663:1997 file://../SB/AA011914.PDF UNI EN 664:1997 file://../SB/AA012168.PDF UNI EN 665:1995 file://../SB/AA011272.PDF UNI EN 666:1995 file://../SB/AA011043.PDF UNI EN 669:1999 file://../SB/AA014043.PDF UNI EN 670:1999 file://../SB/AA014041.PDF UNI EN 672:1999 file://../SB/AA013707.PDF UNI EN 673:2005 file://../SB/AA023015.PDF UNI EN 674:1999 file://../SB/AA014107.PDF UNI EN 675:1999 file://../SB/AA014106.PDF UNI EN 678:1994 file://../SB/AA010458.PDF UNI EN 679:2005 file://../SB/AA023016.PDF UNI EN 680:1994 file://../SB/AA010460.PDF UNI EN 684:1997 file://../SB/AA012022.PDF UNI EN 685:2005 file://../SB/AA022852.PDF UNI EN 686:1998 file://../SB/AA013528.PDF UNI EN 687:1998 file://../SB/AA013529.PDF UNI EN 688:1998 file://../SB/AA013530.PDF UNI EN 713:1995 file://../SB/AA010756.PDF UNI EN ISO 717-1:1997 file://../SB/AA012619.PDF UNI EN ISO 717-2:1997 file://../SB/AA012618.PDF UNI EN 718:1997 file://../SB/AA012020.PDF UNI EN 719:1996 file://../SB/AA011558.PDF UNI EN 771-6:2002 file://../SB/AA017483.PDF UNI EN 772-1:2002 file://../SB/AA018090.PDF UNI EN 772-2:2001 file://../SB/AA016151.PDF UNI EN 772-3:2000 file://../SB/AA015562.PDF UNI EN 772-4:2001 file://../SB/AA016223.PDF UNI EN 772-5:2003 file://../SB/AA018458.PDF UNI EN 772-6:2002 file://../SB/AA017499.PDF UNI EN 772-7:2000 file://../SB/AA015563.PDF UNI EN 772-9:2001 file://../SB/AA016152.PDF UNI EN 772-10:2001 file://../SB/AA016199.PDF UNI EN 772-11:2001 file://../SB/AA016613.PDF UNI EN 772-13:2002 file://../SB/AA018092.PDF UNI EN 772-14:2003 file://../SB/AA018438.PDF UNI EN 772-15:2001 file://../SB/AA016660.PDF UNI EN 772-16:2005 file://../SB/AA022926.PDF UNI EN 772-18:2001 file://../SB/AA016614.PDF UNI EN 772-19:2003 file://../SB/AA018460.PDF UNI EN 772-20:2005 file://../SB/AA022552.PDF UNI EN 789:2005 file://../SB/AA022095.PDF UNI EN 791:1997 file://../SB/AA012155.PDF UNI EN 795:2002 file://../SB/AA018313.PDF UNI EN 812:2003 file://../SB/AA019401.PDF UNI EN 813:1998 file://../SB/AA013525.PDF UNI EN 815:1997 file://../SB/AA012164.PDF UNI EN 822:1995 file://../SB/AA011273.PDF UNI EN 823:1995 file://../SB/AA011274.PDF UNI EN 824:1995 file://../SB/AA011275.PDF UNI EN 825:1995 file://../SB/AA011276.PDF UNI EN 826:1998 file://../SB/AA012781.PDF UNI EN 832:2001 file://../SB/AA016379.PDF UNI EN 845-1:2004 file://../SB/AA020244.PDF UNI EN 845-2:2004 file://../SB/AA020208.PDF UNI EN 845-3:2004 file://../SB/AA020266.PDF UNI EN 846-2:2002 file://../SB/AA018083.PDF UNI EN 846-3:2002 file://../SB/AA017972.PDF UNI EN 846-4:2003 file://../SB/AA019563.PDF UNI EN 846-5:2002 file://../SB/AA017973.PDF UNI EN 846-6:2002 file://../SB/AA018195.PDF UNI EN 846-7:2002 file://../SB/AA018196.PDF UNI EN 846-8:2002 file://../SB/AA018197.PDF UNI EN 846-9:2002 file://../SB/AA017974.PDF UNI EN 846-10:2002 file://../SB/AA018198.PDF UNI EN 846-11:2002 file://../SB/AA017975.PDF UNI EN 846-13:2003 file://../SB/AA019268.PDF UNI EN 912:2002 file://../SB/AA017637.PDF UNI EN 918:1999 file://../SB/AA013854.PDF UNI ENV 927-2:2003 file://../SB/AA018991.PDF UNI EN 927-3:2003 file://../SB/AA019058.PDF UNI EN 927-5:2003 file://../SB/AA019060.PDF UNI EN 932-1:1998 file://../SB/AA012745.PDF UNI EN 932-2:2000 file://../SB/AA015401.PDF UNI EN 932-3:2004 file://../SB/AA020417.PDF UNI EN 932-5:2001 file://../SB/AA016006.PDF UNI EN 932-6:2001 file://../SB/AA015987.PDF UNI EN 933-1:1999 file://../SB/AA013955.PDF UNI EN 933-2:1997 file://../SB/AA012362.PDF UNI EN 933-3:2004 file://../SB/AA020418.PDF UNI EN 933-4:2001 file://../SB/AA016057.PDF UNI EN 933-5:2000 file://../SB/AA014634.PDF UNI EN 933-6:2003 file://../SB/AA018439.PDF UNI EN 933-7:2000 file://../SB/AA014647.PDF UNI EN 933-8:2000 file://../SB/AA015262.PDF UNI EN 933-9:2000 file://../SB/AA015220.PDF UNI EN 933-10:2002 file://../SB/AA017560.PDF UNI EN 934-2:2002 file://../SB/AA017630.PDF UNI EN 934-3:2004 file://../SB/AA020641.PDF UNI EN 934-4:2002 file://../SB/AA017445.PDF UNI EN 934-6:2002 file://../SB/AA017446.PDF UNI EN 947:2000 file://../SB/AA015221.PDF UNI EN 948:2000 file://../SB/AA015229.PDF UNI EN 949:2000 file://../SB/AA015146.PDF UNI EN 950:2000 file://../SB/AA015230.PDF UNI EN 951:2000 file://../SB/AA015147.PDF UNI EN 952:2000 file://../SB/AA015231.PDF UNI EN 984:2002 file://../SB/AA017953.PDF UNI EN 985:2003 file://../SB/AA018437.PDF UNI EN 986:1997 file://../SB/AA012244.PDF UNI EN 988:1998 file://../SB/AA013035.PDF UNI EN 989:1997 file://../SB/AA011980.PDF UNI EN 990:2003 file://../SB/AA018463.PDF UNI EN 991:1997 file://../SB/AA011981.PDF UNI EN 992:1997 file://../SB/AA011974.PDF UNI EN 994:1997 file://../SB/AA012372.PDF UNI EN 995:1997 file://../SB/AA012415.PDF UNI EN 996:2005 file://../SB/AA022035.PDF UNI EN 998-1:2004 file://../SB/AA020229.PDF UNI EN 998-2:2004 file://../SB/AA020230.PDF UNI EN 1004:2005 file://../SB/AA022517.PDF UNI EN 1008:2003 file://../SB/AA019242.PDF UNI EN 1011-1:2005 file://../SB/AA021876.PDF UNI EN 1011-2:2005 file://../SB/AA021797.PDF UNI EN 1011-3:2005 file://../SB/AA021877.PDF UNI EN 1011-4:2005 file://../SB/AA021798.PDF UNI EN 1011-5:2004 file://../SB/AA020496.PDF UNI EN 1013-1:1999 file://../SB/AA014228.PDF UNI EN 1013-2:2000 file://../SB/AA015094.PDF UNI EN 1013-3:1999 file://../SB/AA014229.PDF UNI EN 1013-4:2002 file://../SB/AA017112.PDF UNI EN 1013-5:2002 file://../SB/AA017252.PDF UNI EN 1015-1:2000 file://../SB/AA015109.PDF UNI EN 1015-2:2000 file://../SB/AA015110.PDF UNI EN 1015-3:2000 file://../SB/AA015117.PDF UNI EN 1015-4:2000 file://../SB/AA015111.PDF UNI EN 1015-6:2000 file://../SB/AA015112.PDF UNI EN 1015-7:2000 file://../SB/AA015113.PDF UNI EN 1015-9:2001 file://../SB/AA016163.PDF UNI EN 1015-10:2001 file://../SB/AA016164.PDF UNI EN 1015-11:2001 file://../SB/AA016327.PDF UNI EN 1015-12:2002 file://../SB/AA017646.PDF UNI EN 1015-17:2002 file://../SB/AA017188.PDF UNI EN 1015-18:2004 file://../SB/AA020114.PDF UNI EN 1015-19:2000 file://../SB/AA015107.PDF UNI EN 1015-21:2004 file://../SB/AA020052.PDF UNI EN 1024:1998 file://../SB/AA013549.PDF UNI EN 1026:2001 file://../SB/AA016384.PDF UNI EN 1027:2001 file://../SB/AA016383.PDF UNI EN 1036:2001 file://../SB/AA015612.PDF UNI EN 1050:1998 file://../SB/AA013574.PDF UNI EN 1051-1:2005 file://../SB/AA021651.PDF UNI EN 1052-1:2001 file://../SB/AA015632.PDF UNI EN 1052-2:2001 file://../SB/AA016667.PDF UNI EN 1052-3:2003 file://../SB/AA019573.PDF UNI EN 1052-4:2001 file://../SB/AA016715.PDF UNI EN 1056:1998 file://../SB/AA012985.PDF UNI EN 1062-1:2005 file://../SB/AA022380.PDF UNI EN 1062-3:2001 file://../SB/AA015926.PDF UNI EN 1062-6:2003 file://../SB/AA019901.PDF UNI EN 1062-7:2005 file://../SB/AA022381.PDF UNI EN 1062-11:2003 file://../SB/AA019902.PDF UNI EN 1063:2001 file://../SB/AA016950.PDF UNI EN 1065:1999 file://../SB/AA014581.PDF UNI EN 1075:2002 file://../SB/AA017081.PDF UNI EN 1081:2001 file://../SB/AA015946.PDF UNI ENV 1090-1:2001 file://../SB/AA016590.PDF UNI ENV 1090-2:2001 file://../SB/AA016432.PDF UNI ENV 1090-3:2001 file://../SB/AA016214.PDF UNI ENV 1090-4:2001 file://../SB/AA016259.PDF UNI ENV 1090-5:2001 file://../SB/AA016494.PDF UNI ENV 1090-6:2003 file://../SB/AA019823.PDF UNI EN 1096-1:2000 file://../SB/AA015115.PDF UNI EN 1096-2:2002 file://../SB/AA018207.PDF UNI EN 1096-3:2003 file://../SB/AA018859.PDF UNI EN 1096-4:2005 file://../SB/AA021611.PDF UNI EN 1097-1:2004 file://../SB/AA020419.PDF UNI EN 1097-2:1999 file://../SB/AA014484.PDF UNI EN 1097-3:1999 file://../SB/AA014479.PDF UNI EN 1097-4:2001 file://../SB/AA016055.PDF UNI EN 1097-5:2000 file://../SB/AA015451.PDF UNI EN 1097-6:2002 file://../SB/AA017201.PDF UNI EN 1097-7:2000 file://../SB/AA015452.PDF UNI EN 1097-8:2001 file://../SB/AA016067.PDF UNI EN 1097-9:2000 file://../SB/AA014807.PDF UNI EN 1097-10:2004 file://../SB/AA020132.PDF UNI EN 1107-1:2002 file://../SB/AA018189.PDF UNI EN 1107-2:2002 file://../SB/AA018218.PDF UNI EN 1109:2002 file://../SB/AA017523.PDF UNI EN 1121:2002 file://../SB/AA018093.PDF UNI EN 1125:2002 file://../SB/AA018151.PDF UNI EN ISO 1127:1998 file://../SB/AA013295.PDF UNI EN 1128:1997 file://../SB/AA012101.PDF UNI EN 1143-1:2003 file://../SB/AA019613.PDF UNI EN 1143-2:2003 file://../SB/AA019229.PDF UNI EN 1154:2003 file://../SB/AA019838.PDF UNI EN 1155:2003 file://../SB/AA019839.PDF UNI EN 1158:2003 file://../SB/AA019840.PDF UNI EN 1168:2005 file://../SB/AA022916.PDF UNI EN 1169:2001 file://../SB/AA016600.PDF UNI EN 1170-1:2001 file://../SB/AA016299.PDF UNI EN 1170-2:2001 file://../SB/AA016300.PDF UNI EN 1170-3:2001 file://../SB/AA016399.PDF UNI EN 1170-4:2001 file://../SB/AA016301.PDF UNI EN 1170-5:2001 file://../SB/AA016304.PDF UNI EN 1170-6:2001 file://../SB/AA016302.PDF UNI EN 1170-7:2001 file://../SB/AA016303.PDF UNI ENV 1170-8:1998 file://../SB/AA012811.PDF UNI EN 1172:1998 file://../SB/AA013154.PDF UNI EN 1177:2003 file://../SB/AA019561.PDF UNI EN ISO 1182:2005 file://../SB/AA021886.PDF UNI ENV 1187:2004 file://../SB/AA020440.PDF UNI EN 1191:2002 file://../SB/AA018108.PDF UNI EN 1192:2000 file://../SB/AA015232.PDF UNI EN 1194:2000 file://../SB/AA015405.PDF UNI EN 1195:1999 file://../SB/AA014319.PDF UNI EN 1263-1:2003 file://../SB/AA019130.PDF UNI EN 1263-2:2003 file://../SB/AA019131.PDF UNI EN 1269:1999 file://../SB/AA013942.PDF UNI EN 1279-1:2004 file://../SB/AA020859.PDF UNI EN 1279-2:2004 file://../SB/AA020702.PDF UNI EN 1279-3:2004 file://../SB/AA020707.PDF UNI EN 1279-4:2004 file://../SB/AA020726.PDF UNI EN 1279-5:2005 file://../SB/AA022853.PDF UNI EN 1279-6:2004 file://../SB/AA020708.PDF UNI SPERIMENTALE 1284:1971 file://../SB/AA000405.PDF UNI SPERIMENTALE 1285:1968 file://../SB/AA000406.PDF UNI 1288:1974 file://../SB/AA000407.PDF UNI EN 1288-1:2001 file://../SB/AA016960.PDF UNI EN 1288-2:2001 file://../SB/AA016961.PDF UNI EN 1288-3:2001 file://../SB/AA016962.PDF UNI EN 1288-4:2001 file://../SB/AA016963.PDF UNI EN 1288-5:2001 file://../SB/AA016964.PDF UNI 1289:1974 file://../SB/AA000408.PDF UNI EN 1289:2003 file://../SB/AA019872.PDF UNI EN 1290:2003 file://../SB/AA019752.PDF UNI EN 1291:2003 file://../SB/AA019873.PDF UNI EN 1294:2001 file://../SB/AA016708.PDF UNI EN 1296:2002 file://../SB/AA017541.PDF UNI EN 1297:2005 file://../SB/AA021483.PDF UNI EN 1298:1998 file://../SB/AA012711.PDF UNI EN 1303:2005 file://../SB/AA022482.PDF UNI EN 1304:2005 file://../SB/AA022848.PDF UNI EN 1307:2005 file://../SB/AA022726.PDF UNI EN 1308:2000 file://../SB/AA015022.PDF UNI EN 1317-1:2000 file://../SB/AA015000.PDF UNI EN 1317-2:2000 file://../SB/AA014962.PDF UNI EN 1317-3:2002 file://../SB/AA017100.PDF UNI ENV 1317-4:2003 file://../SB/AA019324.PDF UNI EN 1318:1999 file://../SB/AA013615.PDF UNI EN 1323:2000 file://../SB/AA015023.PDF UNI EN 1324:2000 file://../SB/AA015024.PDF UNI EN 1325-1:1998 file://../SB/AA013113.PDF UNI EN 1325-2:2005 file://../SB/AA021606.PDF UNI EN 1328:1997 file://../SB/AA012363.PDF UNI EN 1337-1:2001 file://../SB/AA016934.PDF UNI EN 1337-2:2004 file://../SB/AA020664.PDF UNI EN 1337-3:2005 file://../SB/AA022532.PDF UNI EN 1337-4:2004 file://../SB/AA020747.PDF UNI EN 1337-5:2005 file://../SB/AA022533.PDF UNI EN 1337-6:2004 file://../SB/AA020748.PDF UNI EN 1337-7:2004 file://../SB/AA020665.PDF UNI EN 1337-9:1999 file://../SB/AA014206.PDF UNI EN 1337-10:2004 file://../SB/AA021414.PDF UNI EN 1337-11:1999 file://../SB/AA014263.PDF UNI EN 1338:2004 file://../SB/AA021097.PDF UNI EN 1339:2005 file://../SB/AA021582.PDF UNI EN 1340:2004 file://../SB/AA020411.PDF UNI EN 1341:2003 file://../SB/AA019179.PDF UNI EN 1342:2003 file://../SB/AA019180.PDF UNI EN 1343:2003 file://../SB/AA019181.PDF UNI EN 1344:2003 file://../SB/AA019727.PDF UNI EN 1346:2000 file://../SB/AA015025.PDF UNI EN 1347:2000 file://../SB/AA015026.PDF UNI EN 1348:2000 file://../SB/AA015028.PDF UNI EN 1351:1998 file://../SB/AA013523.PDF UNI EN 1352:1998 file://../SB/AA013472.PDF UNI EN 1353:1999 file://../SB/AA013614.PDF UNI EN 1354:2005 file://../SB/AA023068.PDF UNI EN 1355:1998 file://../SB/AA013487.PDF UNI EN 1356:1998 file://../SB/AA013486.PDF UNI EN 1363-1:2001 file://../SB/AA016516.PDF UNI EN 1363-2:2001 file://../SB/AA016517.PDF UNI ENV 1363-3:2000 file://../SB/AA015150.PDF UNI EN 1364-1:2002 file://../SB/AA017475.PDF UNI EN 1364-2:2002 file://../SB/AA017859.PDF UNI EN 1365-1:2002 file://../SB/AA017084.PDF UNI EN 1365-2:2002 file://../SB/AA017080.PDF UNI EN 1365-3:2002 file://../SB/AA017088.PDF UNI EN 1365-4:2002 file://../SB/AA017642.PDF UNI EN 1365-5:2005 file://../SB/AA021897.PDF UNI EN 1365-6:2005 file://../SB/AA021898.PDF UNI EN 1366-1:2001 file://../SB/AA016795.PDF UNI EN 1366-2:2001 file://../SB/AA016796.PDF UNI EN 1366-3:2005 file://../SB/AA022327.PDF UNI EN 1366-5:2005 file://../SB/AA021526.PDF UNI EN 1366-6:2005 file://../SB/AA022062.PDF UNI EN 1366-7:2005 file://../SB/AA021670.PDF UNI EN 1366-8:2005 file://../SB/AA021626.PDF UNI EN 1367-1:2001 file://../SB/AA016465.PDF UNI EN 1367-2:2000 file://../SB/AA014676.PDF UNI EN 1367-3:2002 file://../SB/AA017822.PDF UNI EN 1367-4:2000 file://../SB/AA014641.PDF UNI EN 1367-5:2003 file://../SB/AA019205.PDF UNI EN 1373:2001 file://../SB/AA015663.PDF UNI EN 1380:2001 file://../SB/AA016971.PDF UNI EN 1381:2001 file://../SB/AA016972.PDF UNI EN 1382:2002 file://../SB/AA017796.PDF UNI EN 1383:2002 file://../SB/AA017855.PDF UNI EN 1386:1999 file://../SB/AA013717.PDF UNI EN 1399:1999 file://../SB/AA014059.PDF UNI EN 1412:1998 file://../SB/AA012678.PDF UNI EN 1423:2004 file://../SB/AA020256.PDF UNI EN 1424:2004 file://../SB/AA020300.PDF UNI EN 1433:2004 file://../SB/AA020308.PDF UNI EN 1435:2004 file://../SB/AA020480.PDF UNI EN 1436:2004 file://../SB/AA020272.PDF UNI EN 1446:1998 file://../SB/AA012992.PDF UNI EN 1448:1998 file://../SB/AA013322.PDF UNI EN 1449:1998 file://../SB/AA013262.PDF UNI EN ISO 1461:1999 file://../SB/AA014390.PDF UNI EN 1463-1:2004 file://../SB/AA020315.PDF UNI EN 1463-2:2001 file://../SB/AA016138.PDF UNI EN 1469:2005 file://../SB/AA022189.PDF UNI EN 1470:1999 file://../SB/AA014442.PDF UNI EN 1471:1999 file://../SB/AA013616.PDF UNI EN 1492-4:2004 file://../SB/AA021005.PDF UNI EN 1495:2005 file://../SB/AA022454.PDF UNI EN 1504-1:2005 file://../SB/AA023018.PDF UNI EN 1504-2:2005 file://../SB/AA021591.PDF UNI EN 1504-4:2005 file://../SB/AA022009.PDF UNI EN 1504-5:2005 file://../SB/AA022328.PDF UNI EN 1504-8:2005 file://../SB/AA021899.PDF UNI ENV 1504-9:1999 file://../SB/AA014184.PDF UNI EN 1504-10:2005 file://../SB/AA022064.PDF UNI EN 1516:2001 file://../SB/AA015911.PDF UNI EN 1517:2001 file://../SB/AA016365.PDF UNI EN 1520:2004 file://../SB/AA020017.PDF UNI EN 1521:1999 file://../SB/AA013708.PDF UNI EN 1522:2000 file://../SB/AA015462.PDF UNI EN 1523:2000 file://../SB/AA015463.PDF UNI EN 1527:2000 file://../SB/AA015459.PDF UNI EN 1529:2000 file://../SB/AA015233.PDF UNI EN 1530:2000 file://../SB/AA015234.PDF UNI EN 1533:2002 file://../SB/AA017871.PDF UNI EN 1534:2002 file://../SB/AA017416.PDF UNI EN 1536:2003 file://../SB/AA018424.PDF UNI EN 1537:2002 file://../SB/AA017745.PDF UNI EN 1538:2002 file://../SB/AA017645.PDF UNI EN 1540:2001 file://../SB/AA016156.PDF UNI EN 1542:2000 file://../SB/AA015555.PDF UNI EN 1543:2000 file://../SB/AA014635.PDF UNI EN 1569:2001 file://../SB/AA015912.PDF UNI EN 1570:2001 file://../SB/AA015979.PDF UNI EN 1602:1999 file://../SB/AA013903.PDF UNI EN 1603:1999 file://../SB/AA013904.PDF UNI EN 1604:1999 file://../SB/AA013905.PDF UNI EN 1605:1999 file://../SB/AA013906.PDF UNI EN 1606:1999 file://../SB/AA013907.PDF UNI EN 1607:1999 file://../SB/AA013908.PDF UNI EN 1608:1999 file://../SB/AA013909.PDF UNI EN 1609:1999 file://../SB/AA013910.PDF UNI ENV 1627:2000 file://../SB/AA014747.PDF UNI ENV 1628:2000 file://../SB/AA014783.PDF UNI ENV 1629:2000 file://../SB/AA014784.PDF UNI ENV 1630:2000 file://../SB/AA014785.PDF UNI ENV 1631:1998 file://../SB/AA012999.PDF UNI EN 1634-1:2001 file://../SB/AA016800.PDF UNI EN 1634-3:2005 file://../SB/AA021715.PDF UNI EN 1670:2000 file://../SB/AA015381.PDF UNI EN 1708-1:2005 file://../SB/AA022036.PDF UNI EN ISO 1716:2005 file://../SB/AA021508.PDF UNI EN 1731:2000 file://../SB/AA015538.PDF UNI EN 1737:2000 file://../SB/AA015345.PDF UNI EN 1738:2000 file://../SB/AA015346.PDF UNI EN 1739:2000 file://../SB/AA015347.PDF UNI EN 1740:2000 file://../SB/AA015348.PDF UNI EN 1741:2001 file://../SB/AA015602.PDF UNI EN 1742:2000 file://../SB/AA015349.PDF UNI EN 1744-1:1999 file://../SB/AA014483.PDF UNI EN 1744-3:2003 file://../SB/AA019206.PDF UNI EN 1745:2005 file://../SB/AA021905.PDF UNI EN 1748-1-1:2005 file://../SB/AA021455.PDF UNI EN 1748-1-2:2005 file://../SB/AA021462.PDF UNI EN 1748-2-1:2005 file://../SB/AA021454.PDF UNI EN 1748-2-2:2005 file://../SB/AA021428.PDF UNI EN 1766:2001 file://../SB/AA016140.PDF UNI EN 1767:2001 file://../SB/AA015991.PDF UNI EN 1770:2000 file://../SB/AA014716.PDF UNI EN 1771:2005 file://../SB/AA021498.PDF UNI EN 1790:2000 file://../SB/AA015327.PDF UNI EN 1793-1:1999 file://../SB/AA014201.PDF UNI EN 1793-2:1999 file://../SB/AA014202.PDF UNI EN 1793-3:1999 file://../SB/AA014203.PDF UNI CEN/TS 1793-4:2004 file://../SB/AA020603.PDF UNI EN 1794-1:2004 file://../SB/AA020654.PDF UNI EN 1794-2:2004 file://../SB/AA020655.PDF UNI EN 1799:2000 file://../SB/AA015095.PDF UNI EN 1804-1:2004 file://../SB/AA020832.PDF UNI EN 1808:2002 file://../SB/AA017341.PDF UNI EN 1813:1999 file://../SB/AA014443.PDF UNI EN 1814:1999 file://../SB/AA014528.PDF UNI EN 1815:1999 file://../SB/AA014230.PDF UNI EN 1816:2001 file://../SB/AA015963.PDF UNI EN 1817:2001 file://../SB/AA015964.PDF UNI EN 1818:2000 file://../SB/AA015419.PDF UNI EN 1824:2000 file://../SB/AA014959.PDF UNI EN 1827:2002 file://../SB/AA017225.PDF UNI EN 1837:2001 file://../SB/AA016435.PDF UNI EN 1838:2000 file://../SB/AA014811.PDF UNI EN 1841:2000 file://../SB/AA015116.PDF UNI EN 1844:2002 file://../SB/AA017374.PDF UNI EN 1847:2002 file://../SB/AA017438.PDF UNI EN 1848-1:2002 file://../SB/AA018187.PDF UNI EN 1848-2:2002 file://../SB/AA018215.PDF UNI EN 1849-1:2002 file://../SB/AA018234.PDF UNI EN 1849-2:2002 file://../SB/AA018245.PDF UNI EN 1850-1:2001 file://../SB/AA016925.PDF UNI EN 1850-2:2001 file://../SB/AA016926.PDF UNI EN 1863-1:2002 file://../SB/AA017183.PDF UNI EN 1863-2:2005 file://../SB/AA021629.PDF UNI EN 1871:2002 file://../SB/AA018080.PDF UNI EN 1877-1:2001 file://../SB/AA016430.PDF UNI EN 1877-2:2001 file://../SB/AA016346.PDF UNI EN 1889-1:2004 file://../SB/AA020833.PDF UNI EN 1889-2:2004 file://../SB/AA020834.PDF UNI EN 1891:2001 file://../SB/AA015628.PDF UNI EN 1897:2003 file://../SB/AA019320.PDF UNI EN 1902:2001 file://../SB/AA015774.PDF UNI EN 1903:2001 file://../SB/AA015775.PDF UNI EN 1910:2001 file://../SB/AA016073.PDF UNI EN 1912:2005 file://../SB/AA022191.PDF UNI EN 1925:2000 file://../SB/AA015574.PDF UNI EN 1926:2000 file://../SB/AA015575.PDF UNI EN 1928:2002 file://../SB/AA017351.PDF UNI EN 1931:2002 file://../SB/AA018003.PDF UNI EN 1932:2002 file://../SB/AA018146.PDF UNI EN 1933:2000 file://../SB/AA015489.PDF UNI EN 1934:2000 file://../SB/AA014999.PDF UNI EN 1935:2004 file://../SB/AA020019.PDF UNI EN 1936:2001 file://../SB/AA015608.PDF UNI EN 1937:2001 file://../SB/AA015776.PDF UNI EN 1946-1:2001 file://../SB/AA015986.PDF UNI EN 1946-2:2001 file://../SB/AA016158.PDF UNI EN 1946-3:2004 file://../SB/AA020020.PDF UNI EN 1946-4:2005 file://../SB/AA022192.PDF UNI EN 1946-5:2005 file://../SB/AA022097.PDF UNI EN 1963:1999 file://../SB/AA014472.PDF UNI EN 1969:2001 file://../SB/AA016139.PDF UNI EN 1990:2004 file://../SB/AA020435.PDF UNI EN 1991-2:2005 file://../SB/AA021705.PDF UNI ENV 1991-4:1997 file://../SB/AA011793.PDF UNI ENV 1991-5:2002 file://../SB/AA017729.PDF UNI EN 1991-1-1:2004 file://../SB/AA020648.PDF UNI EN 1991-1-2:2004 file://../SB/AA020840.PDF UNI EN 1991-1-3:2004 file://../SB/AA020839.PDF UNI EN 1991-1-4:2005 file://../SB/AA022574.PDF UNI EN 1991-1-5:2004 file://../SB/AA020841.PDF UNI EN 1991-1-6:2005 file://../SB/AA022917.PDF UNI ENV 1991-2-7:2000 file://../SB/AA015352.PDF UNI ENV 1992-1-1:1993 file://../SB/AA009140.PDF UNI EN 1992-1-2:2005 file://../SB/AA021908.PDF UNI ENV 1992-1-3:1995 file://../SB/AA011076.PDF UNI ENV 1992-1-4:1995 file://../SB/AA011071.PDF UNI ENV 1992-1-5:1995 file://../SB/AA011278.PDF UNI ENV 1992-1-6:1995 file://../SB/AA011072.PDF UNI ENV 1992-2:2000 file://../SB/AA015323.PDF UNI ENV 1992-3:2000 file://../SB/AA015398.PDF UNI ENV 1992-4:2001 file://../SB/AA015796.PDF UNI EN 1993-1-1:2005 file://../SB/AA022680.PDF UNI EN 1993-1-2:2005 file://../SB/AA022534.PDF UNI ENV 1993-1-3:2000 file://../SB/AA014657.PDF UNI ENV 1993-1-4:1999 file://../SB/AA014451.PDF UNI ENV 1993-1-5:2001 file://../SB/AA016508.PDF UNI ENV 1993-1-6:2002 file://../SB/AA018112.PDF UNI ENV 1993-1-7:2002 file://../SB/AA018178.PDF UNI EN 1993-1-8:2005 file://../SB/AA022731.PDF UNI EN 1993-1-9:2005 file://../SB/AA022681.PDF UNI EN 1993-1-10:2005 file://../SB/AA022732.PDF UNI ENV 1993-2:2002 file://../SB/AA017632.PDF UNI ENV 1993-4-1:2002 file://../SB/AA018175.PDF UNI ENV 1993-4-2:2002 file://../SB/AA018176.PDF UNI ENV 1993-4-3:2002 file://../SB/AA018177.PDF UNI EN 1994-1-1:2005 file://../SB/AA021864.PDF UNI EN 1994-1-2:2005 file://../SB/AA023105.PDF UNI ENV 1994-2:2002 file://../SB/AA018396.PDF UNI ENV 1993-5:2002 file://../SB/AA017085.PDF UNI ENV 1993-6:2002 file://../SB/AA017126.PDF UNI EN 1995-2:2005 file://../SB/AA021530.PDF UNI EN 1995-1-1:2005 file://../SB/AA021616.PDF UNI EN 1995-1-2:2005 file://../SB/AA021531.PDF UNI ENV 1996-2:2001 file://../SB/AA016122.PDF UNI ENV 1996-3:2001 file://../SB/AA016989.PDF UNI ENV 1996-1-1:1998 file://../SB/AA012947.PDF UNI EN 1996-1-2:2005 file://../SB/AA022786.PDF UNI ENV 1996-1-3:2002 file://../SB/AA017275.PDF UNI EN 1997-1:2005 file://../SB/AA021693.PDF UNI ENV 1997-2:2002 file://../SB/AA017733.PDF UNI ENV 1997-3:2002 file://../SB/AA017962.PDF UNI EN 1998-1:2005 file://../SB/AA021704.PDF UNI ENV 1998-2:1998 file://../SB/AA012852.PDF UNI EN 1998-3:2005 file://../SB/AA022733.PDF UNI ENV 1998-4:2000 file://../SB/AA015344.PDF UNI EN 1998-5:2005 file://../SB/AA021517.PDF UNI EN 1998-6:2005 file://../SB/AA022915.PDF UNI ENV 1999-1-2:2001 file://../SB/AA016783.PDF UNI ENV 1999-2:2002 file://../SB/AA018182.PDF UNI ENV 1999-1-1:2002 file://../SB/AA017340.PDF UNI ISO 2017:1992 file://../SB/AA000053.PDF UNI 2331-2:1980 file://../SB/AA004593.PDF UNI 2332-1:1979 file://../SB/AA004594.PDF UNI 2333-1:1983 + FA 189:1985 file://../SB/AA018509.PDF UNI SPERIMENTALE 2334:1943 file://../SB/AA000562.PDF UNI ISO 2374:1987 file://../SB/AA007513.PDF UNI ISO 2509:1993 file://../SB/AA009142.PDF UNI ISO 2510:1993 file://../SB/AA009143.PDF UNI 2623:1944 file://../SB/AA000710.PDF UNI 2624:1944 file://../SB/AA000711.PDF UNI 2625:1944 file://../SB/AA000712.PDF UNI 2626:1944 file://../SB/AA000713.PDF UNI 2627:1944 file://../SB/AA000714.PDF UNI 2628:1944 file://../SB/AA000715.PDF UNI 2629:1944 file://../SB/AA000716.PDF UNI EN ISO 2810:2005 file://../SB/AA022382.PDF UNI 3151:1982 file://../SB/AA000912.PDF UNI EN ISO 3382:2001 file://../SB/AA016931.PDF UNI EN ISO 3766:2005 file://../SB/AA021698.PDF UNI ISO 3810:1990 file://../SB/AA008180.PDF UNI ISO 3813:1990 file://../SB/AA008181.PDF UNI EN ISO 3822-1:2000 file://../SB/AA015450.PDF UNI EN ISO 3822-2:1998 file://../SB/AA013188.PDF UNI EN ISO 3822-3:1998 file://../SB/AA013207.PDF UNI EN ISO 3822-4:1998 file://../SB/AA013208.PDF UNI 3952:1998 file://../SB/AA013377.PDF UNI EN ISO 4063:2001 file://../SB/AA016745.PDF UNI ISO 4068:1989 file://../SB/AA007962.PDF UNI 4096:1958 file://../SB/AA001370.PDF UNI 4097:1958 file://../SB/AA001371.PDF UNI 4157:1987 file://../SB/AA001408.PDF UNI EN ISO 4157-1:2003 file://../SB/AA019156.PDF UNI EN ISO 4157-2:2003 file://../SB/AA019218.PDF UNI EN ISO 4157-3:2003 file://../SB/AA019157.PDF UNI SPERIMENTALE 4163:1959 file://../SB/AA001409.PDF UNI EN ISO 4172:2004 file://../SB/AA020573.PDF UNI ISO 4301-1:1988 file://../SB/AA010149.PDF UNI ISO 4301-2:1988 file://../SB/AA007845.PDF UNI ISO 4301-3:1995 file://../SB/AA010844.PDF UNI ISO 4301-4:1991 file://../SB/AA008631.PDF UNI ISO 4301-5:1992 file://../SB/AA009044.PDF UNI ISO 4305:1989 file://../SB/AA007965.PDF UNI ISO 4306-1:1990 file://../SB/AA008184.PDF UNI ISO 4306-2:1989 file://../SB/AA007966.PDF UNI ISO 4306-3:1993 file://../SB/AA009186.PDF UNI ISO 4310:1988 file://../SB/AA007848.PDF UNI 4377:1959 + FA 233:1987 file://../SB/AA018556.PDF UNI 4378:1959 + FA 234:1987 file://../SB/AA018558.PDF UNI 4379:1959 + FA 235:1987 file://../SB/AA018559.PDF UNI 4380:1959 + FA 236:1987 file://../SB/AA018482.PDF UNI 4381:1959 + FA 237:1987 file://../SB/AA018487.PDF UNI 4382:1959 + FA 237:1987 file://../SB/AA018490.PDF UNI 4383:1959 + FA 239-87:1987 file://../SB/AA018492.PDF UNI 4384:1959 + FA 240:1987 file://../SB/AA018497.PDF UNI 4385:1959 + FA 241:1987 file://../SB/AA018501.PDF UNI EN ISO 4618-3:2001 file://../SB/AA016654.PDF UNI 4630:1982 file://../SB/AA006511.PDF UNI 4633:1960 file://../SB/AA001615.PDF UNI 4634:1960 file://../SB/AA001616.PDF UNI 4712:1961 file://../SB/AA001664.PDF UNI ISO 4736:1982 file://../SB/AA007663.PDF UNI 4873:1961 file://../SB/AA001757.PDF UNI 4874:1961 file://../SB/AA001758.PDF UNI 4875:1961 file://../SB/AA001759.PDF UNI EN ISO 5135:2003 file://../SB/AA019885.PDF UNI EN ISO 5136:2005 file://../SB/AA022266.PDF UNI ISO 5251:1982 file://../SB/AA007680.PDF UNI ISO 5256:1987 file://../SB/AA008273.PDF UNI ISO 5329:1987 file://../SB/AA007681.PDF UNI EN ISO 5353:2000 file://../SB/AA014656.PDF UNI 5365:2000 file://../SB/AA015055.PDF UNI 5368:2000 file://../SB/AA015073.PDF UNI 5371:1984 file://../SB/AA002026.PDF UNI 5397:1978 file://../SB/AA002036.PDF UNI 5398:1978 file://../SB/AA002037.PDF UNI 5573:1972 file://../SB/AA002154.PDF UNI 5574:1972 file://../SB/AA002155.PDF UNI 5646:2003 file://../SB/AA019052.PDF UNI 5654:1965 + FA 191-87:1987 file://../SB/AA018608.PDF UNI 5655:1965 + A192:1987 file://../SB/AA018526.PDF UNI 5656:1965 + A193:1987 file://../SB/AA018529.PDF UNI 5657:1965 + A224:1987 file://../SB/AA018533.PDF UNI 5658:1965 + A225:1987 file://../SB/AA018542.PDF UNI 5659:1965 + A226:1987 file://../SB/AA018547.PDF UNI 5660:1965 + A227:1987 file://../SB/AA018550.PDF UNI 5661:1965 + A228:1987 file://../SB/AA018552.PDF UNI 5662:1965 + A229:1987 file://../SB/AA018553.PDF UNI 5663:1965 + A230:1987 file://../SB/AA018557.PDF UNI 5664:1965 + A231:1987 file://../SB/AA018561.PDF UNI 5665:1965 + A232:1987 file://../SB/AA018565.PDF UNI 5679:1973 file://../SB/AA002237.PDF UNI 5681:1973 file://../SB/AA002239.PDF UNI 5712:1975 file://../SB/AA002264.PDF UNI EN ISO 5817:2004 file://../SB/AA020969.PDF UNI 5958:1985 file://../SB/AA002440.PDF UNI 6028:1999 file://../SB/AA014421.PDF UNI 6128:1972 file://../SB/AA002532.PDF UNI 6131:2002 file://../SB/AA017520.PDF UNI 6134:1972 file://../SB/AA002536.PDF UNI EN ISO 6165:2004 file://../SB/AA020046.PDF UNI EN ISO 6259-1:2002 file://../SB/AA018334.PDF UNI 6262:1968 file://../SB/AA002613.PDF UNI 6263:1968 file://../SB/AA002614.PDF UNI 6264:1968 file://../SB/AA002615.PDF UNI 6265:1968 file://../SB/AA002616.PDF UNI 6266:1968 file://../SB/AA002617.PDF UNI 6267:1968 file://../SB/AA002618.PDF UNI EN ISO 6284:2002 file://../SB/AA017082.PDF UNI EN ISO 6385:2004 file://../SB/AA020517.PDF UNI 6393:1988 file://../SB/AA005886.PDF UNI EN ISO 6412-1:1996 file://../SB/AA011821.PDF UNI EN ISO 6412-2:1996 file://../SB/AA011823.PDF UNI EN ISO 6412-3:1996 file://../SB/AA011822.PDF UNI 6484:1969 file://../SB/AA002752.PDF UNI 6485:1969 file://../SB/AA002753.PDF UNI 6534:1974 file://../SB/AA002801.PDF UNI 6537:1969 file://../SB/AA002804.PDF UNI 6538:1969 file://../SB/AA002805.PDF UNI 6539:1969 file://../SB/AA002806.PDF UNI 6540:1969 file://../SB/AA002807.PDF UNI 6541:1969 file://../SB/AA002808.PDF UNI 6542:1969 file://../SB/AA002809.PDF UNI 6543:1969 file://../SB/AA002810.PDF UNI 6545:1969 file://../SB/AA002812.PDF UNI 6546:1969 file://../SB/AA002813.PDF UNI 6547:1985 file://../SB/AA002814.PDF UNI 6555:1973 file://../SB/AA002822.PDF UNI 6556:1976 file://../SB/AA002823.PDF UNI 6665:1988 file://../SB/AA005889.PDF UNI EN ISO 6683:2001 file://../SB/AA016653.PDF UNI 6687:1973 file://../SB/AA002923.PDF UNI 6718:1970 file://../SB/AA002943.PDF UNI 6762:1970 file://../SB/AA002976.PDF UNI 6763:1970 file://../SB/AA002977.PDF UNI 6774:1970 file://../SB/AA002988.PDF UNI 6775:1970 file://../SB/AA002989.PDF UNI 6792:1971 file://../SB/AA003000.PDF UNI 6823:1998 file://../SB/AA013100.PDF UNI 6824:1971 file://../SB/AA003027.PDF UNI EN ISO 6946:1999 file://../SB/AA014366.PDF UNI 7043:1972 file://../SB/AA003220.PDF UNI 7044:1972 file://../SB/AA003221.PDF UNI 7086:1972 file://../SB/AA003252.PDF UNI 7087:2002 file://../SB/AA017752.PDF UNI EN ISO 7096:2002 file://../SB/AA018155.PDF UNI 7110:1972 file://../SB/AA003276.PDF UNI 7121:1972 file://../SB/AA003286.PDF UNI 7122:1989 file://../SB/AA006202.PDF UNI 7123:1972 file://../SB/AA003287.PDF UNI 7143:1972 file://../SB/AA003300.PDF UNI 7144:1979 file://../SB/AA003301.PDF UNI EN ISO 7235:2005 file://../SB/AA021888.PDF UNI EN ISO 7250:2000 file://../SB/AA014765.PDF UNI SPERIMENTALE 7278:1974 file://../SB/AA003425.PDF UNI ISO 7296-2:2001 file://../SB/AA016406.PDF UNI 7310:1974 file://../SB/AA003441.PDF UNI EN ISO 7345:1999 file://../SB/AA014241.PDF UNI 7357:1974+A101:1983+A83:1979+A3:1989 file://../SB/AA018807.PDF UNI 7360:1974 + A1:1997 file://../SB/AA018626.PDF UNI ISO 7363:1988 file://../SB/AA007889.PDF UNI EN ISO 7369:2005 file://../SB/AA022479.PDF UNI EN ISO 7389:2004 file://../SB/AA020450.PDF UNI EN ISO 7390:2004 file://../SB/AA020344.PDF UNI EN ISO 7437:1999 file://../SB/AA014426.PDF UNI 7448:1975 file://../SB/AA003551.PDF UNI 7449:1975 file://../SB/AA003552.PDF UNI 7508:1996 file://../SB/AA011762.PDF UNI EN ISO 7518:2001 file://../SB/AA016165.PDF UNI EN ISO 7519:2001 file://../SB/AA015974.PDF UNI 7525:1976 file://../SB/AA003616.PDF UNI 7527-1:1976 file://../SB/AA003620.PDF UNI 7527-2:1976 file://../SB/AA003621.PDF UNI 7544-1:1976 file://../SB/AA003628.PDF UNI 7544-2:1985 file://../SB/AA003629.PDF UNI 7544-3:1978 file://../SB/AA003630.PDF UNI 7544-11:1994 file://../SB/AA010584.PDF UNI 7545-1:1976 file://../SB/AA003631.PDF UNI 7545-2:1976 file://../SB/AA003632.PDF UNI 7545-4:1976 file://../SB/AA003634.PDF UNI 7545-7:1976 file://../SB/AA003637.PDF UNI 7545-8:1976 file://../SB/AA003638.PDF UNI 7545-11:1978 file://../SB/AA003641.PDF UNI 7545-12:1978 file://../SB/AA003642.PDF UNI 7545-16:1983 file://../SB/AA003760.PDF UNI 7545-17:1983 file://../SB/AA003761.PDF UNI 7545-18:1986 file://../SB/AA005470.PDF UNI 7545-21:1991 file://../SB/AA007037.PDF UNI 7545-22:1993 file://../SB/AA009112.PDF UNI 7545-25:1994 file://../SB/AA010588.PDF UNI 7545-26:1994 file://../SB/AA010589.PDF UNI 7546-1:1976 file://../SB/AA003644.PDF UNI 7546-5:1994 file://../SB/AA003648.PDF UNI 7546-6:1978 file://../SB/AA003649.PDF UNI 7546-7:1985 file://../SB/AA004959.PDF UNI 7546-8:1986 file://../SB/AA005472.PDF UNI 7546-9:1994 file://../SB/AA005473.PDF UNI 7546-10:1994 file://../SB/AA010592.PDF UNI 7546-11:1994 file://../SB/AA010593.PDF UNI 7546-12:1994 file://../SB/AA010594.PDF UNI 7546-14:2001 file://../SB/AA015722.PDF UNI 7547-2:1976 file://../SB/AA003651.PDF UNI 7547-4:1976 file://../SB/AA003653.PDF UNI 7547-5:1976 file://../SB/AA003654.PDF UNI 7547-6:1976 file://../SB/AA003655.PDF UNI 7547-7:1994 file://../SB/AA005441.PDF UNI 7547-11:1995 file://../SB/AA011234.PDF UNI 7548-1:1992 file://../SB/AA009010.PDF UNI 7548-2:1992 file://../SB/AA009011.PDF UNI SPERIMENTALE 7549-8:1976 file://../SB/AA003665.PDF UNI 7570:1976 file://../SB/AA003690.PDF UNI 7571:1976 file://../SB/AA003691.PDF UNI 7615:1976 file://../SB/AA004672.PDF UNI 7616:1976 + A90:1979 file://../SB/AA018590.PDF UNI 7675:1977 file://../SB/AA003786.PDF UNI 7676:1977 file://../SB/AA003787.PDF UNI 7697:2002 file://../SB/AA017770.PDF UNI 7699:2005 file://../SB/AA023035.PDF UNI EN ISO 7726:2002 file://../SB/AA017164.PDF UNI EN ISO 7730:1997 file://../SB/AA012428.PDF UNI 7744:1998 file://../SB/AA013432.PDF UNI 7745:1977 + A112:1983 file://../SB/AA018597.PDF UNI EN ISO 7783-2:2001 file://../SB/AA015703.PDF UNI 7819:1988 + SS UNI E13.12.716.0:2001 file://../SB/AA018809.PDF UNI EN ISO 7823-1:2002 file://../SB/AA018308.PDF UNI EN ISO 7823-2:2004 file://../SB/AA021303.PDF UNI 7861:1978 file://../SB/AA003935.PDF UNI 7862:1978 file://../SB/AA003936.PDF UNI 7863:1978 file://../SB/AA003937.PDF UNI 7864:1978 file://../SB/AA003938.PDF UNI 7865:1978 file://../SB/AA003939.PDF UNI 7866:1978 file://../SB/AA003940.PDF UNI 7876:1978 file://../SB/AA003973.PDF UNI 7891:1978 + A113:1983 file://../SB/AA018633.PDF UNI ISO 7892:1990 file://../SB/AA008197.PDF UNI 7895:1978 file://../SB/AA003993.PDF UNI 7927:1978 file://../SB/AA004026.PDF UNI 7929:1979 file://../SB/AA004028.PDF UNI 7956:1979 file://../SB/AA004052.PDF UNI 7958:1979 file://../SB/AA004054.PDF UNI 7959:1988 file://../SB/AA005916.PDF UNI 7960:1979 file://../SB/AA004055.PDF UNI 7961:1987 file://../SB/AA004056.PDF UNI 7991:1979 file://../SB/AA004094.PDF UNI 7998:1979 file://../SB/AA005443.PDF UNI 7999:1979 file://../SB/AA004099.PDF UNI 8012:1979 file://../SB/AA004109.PDF UNI 8013-1:1979 file://../SB/AA004110.PDF UNI 8014-1:1979 file://../SB/AA004111.PDF UNI 8014-2:1979 file://../SB/AA004112.PDF UNI 8014-3:1979 file://../SB/AA004113.PDF UNI 8014-4:1979 file://../SB/AA004114.PDF UNI 8014-5:1981 file://../SB/AA004675.PDF UNI 8014-6:1981 file://../SB/AA004676.PDF UNI 8014-7:1981 file://../SB/AA004677.PDF UNI 8014-8:1981 file://../SB/AA004678.PDF UNI 8014-9:1981 file://../SB/AA004679.PDF UNI 8014-10:1981 file://../SB/AA004680.PDF UNI 8014-12:1987 file://../SB/AA003260.PDF UNI 8014-13:1987 file://../SB/AA005444.PDF UNI 8014-14:1987 file://../SB/AA005445.PDF UNI SPERIMENTALE 8014-15:1989 file://../SB/AA006223.PDF UNI 8014-16:1989 file://../SB/AA006224.PDF UNI EN ISO 8044:2001 file://../SB/AA016420.PDF UNI 8087:1980 file://../SB/AA004200.PDF UNI 8088:1980 file://../SB/AA004201.PDF UNI 8089:1980 file://../SB/AA004202.PDF UNI 8090:1980 file://../SB/AA004203.PDF UNI 8091:1980 file://../SB/AA004204.PDF UNI 8097:2004 file://../SB/AA020533.PDF UNI 8105:1980 file://../SB/AA004223.PDF UNI 8146:1980 + FA 125-83:1983 file://../SB/AA018674.PDF UNI 8147:1980 + FA 126-83:1983 file://../SB/AA018841.PDF UNI 8148:1980 + FA 127-83:1983 file://../SB/AA018681.PDF UNI 8149:1980 + FA 128-83:1983 file://../SB/AA018683.PDF UNI 8151:1980 file://../SB/AA004288.PDF UNI 8178:1980 file://../SB/AA004313.PDF UNI 8188:1981 file://../SB/AA004323.PDF UNI 8199:1998 file://../SB/AA013541.PDF UNI 8200:1981 file://../SB/AA004333.PDF UNI 8201:1981 file://../SB/AA004334.PDF UNI 8202-13:1988 file://../SB/AA005927.PDF UNI 8202-14:1981 file://../SB/AA004339.PDF UNI 8202-16:1984 file://../SB/AA004903.PDF UNI 8202-18:1984 file://../SB/AA004905.PDF UNI 8202-19:1988 file://../SB/AA005928.PDF UNI 8202-20:1987 file://../SB/AA004748.PDF UNI 8202-24:1988 file://../SB/AA005930.PDF UNI 8202-25:1984 file://../SB/AA004907.PDF UNI 8202-27:1982 file://../SB/AA004750.PDF UNI 8202-31:1988 file://../SB/AA005933.PDF UNI 8202-32:1988 file://../SB/AA005934.PDF UNI 8202-34:1988 file://../SB/AA005935.PDF UNI 8202-35:1988 file://../SB/AA005936.PDF UNI 8204:1981 file://../SB/AA004341.PDF UNI 8207:2003 file://../SB/AA019558.PDF UNI 8208-14:1981 file://../SB/AA004358.PDF UNI 8209:1981 + FA 155-84:1984 file://../SB/AA018844.PDF UNI 8219:1981 file://../SB/AA004369.PDF UNI ISO 8269:1987 file://../SB/AA007759.PDF UNI 8272-1:1981 file://../SB/AA004421.PDF UNI 8272-2:1982 file://../SB/AA004751.PDF UNI 8272-6:1981 file://../SB/AA004425.PDF UNI 8272-8:1982 file://../SB/AA004753.PDF UNI 8272-11:1987 file://../SB/AA005462.PDF UNI ISO 8275:1987 file://../SB/AA007761.PDF UNI 8289:1981 file://../SB/AA004439.PDF UNI 8290-1:1981 + A122:1983 file://../SB/AA018696.PDF UNI 8290-2:1983 file://../SB/AA004757.PDF UNI 8290-3:1987 file://../SB/AA005477.PDF UNI 8297:2004 file://../SB/AA020617.PDF UNI 8298-1:2000 file://../SB/AA015397.PDF UNI 8298-2:1987 file://../SB/AA005465.PDF UNI 8298-3:1986 file://../SB/AA005478.PDF UNI 8298-4:1986 file://../SB/AA005479.PDF UNI 8298-5:1986 file://../SB/AA005480.PDF UNI 8298-6:1986 file://../SB/AA005481.PDF UNI 8298-8:1986 file://../SB/AA005483.PDF UNI 8298-9:1989 file://../SB/AA006237.PDF UNI 8298-10:1989 file://../SB/AA006238.PDF UNI 8298-11:1987 file://../SB/AA005466.PDF UNI 8298-12:1989 file://../SB/AA006239.PDF UNI 8298-14:1989 file://../SB/AA006241.PDF UNI 8298-15:1989 file://../SB/AA006242.PDF UNI 8298-16:1989 file://../SB/AA006243.PDF UNI 8307:1981 file://../SB/AA004456.PDF UNI 8326:1981 file://../SB/AA004797.PDF UNI 8327:1981 file://../SB/AA004798.PDF UNI 8328:1981 file://../SB/AA004799.PDF UNI 8360:1982 file://../SB/AA004836.PDF UNI 8361:1982 file://../SB/AA004837.PDF UNI 8362:1982 file://../SB/AA004838.PDF UNI ISO 8369:1992 file://../SB/AA000286.PDF UNI 8369-1:1988 file://../SB/AA005939.PDF UNI 8369-2:1987 file://../SB/AA004844.PDF UNI 8369-4:1988 file://../SB/AA005941.PDF UNI 8369-5:1988 file://../SB/AA005942.PDF UNI 8370:1982 file://../SB/AA004845.PDF UNI 8376:1982 + FA 170-85:1985 file://../SB/AA018625.PDF UNI 8377:1982 file://../SB/AA004852.PDF UNI 8379:2000 file://../SB/AA014908.PDF UNI 8380:1982 file://../SB/AA004855.PDF UNI 8381:1982 file://../SB/AA004856.PDF UNI 8437:1983 file://../SB/AA004710.PDF UNI 8438:1983 file://../SB/AA004711.PDF UNI 8456:1987 file://../SB/AA004972.PDF UNI 8457:1987 + A1:1996 file://../SB/AA018632.PDF UNI 8470:1983 file://../SB/AA004986.PDF UNI EN ISO 8497:1999 file://../SB/AA013713.PDF UNI EN ISO 8502-8:2005 file://../SB/AA022297.PDF UNI EN ISO 8502-12:2005 file://../SB/AA022299.PDF UNI EN ISO 8503-5:2005 file://../SB/AA022845.PDF UNI EN ISO 8504-1:2001 file://../SB/AA016727.PDF UNI 8520-1:2005 file://../SB/AA022860.PDF UNI 8520-2:2005 file://../SB/AA022861.PDF UNI 8520-8:1999 file://../SB/AA014127.PDF UNI SPERIMENTALE 8520-17:1984 file://../SB/AA005066.PDF UNI 8520-21:1999 file://../SB/AA014123.PDF UNI 8520-22:2002 file://../SB/AA017743.PDF UNI EN ISO 8560:2002 file://../SB/AA017083.PDF UNI 8616:1984 file://../SB/AA005170.PDF UNI 8617:1984 file://../SB/AA005171.PDF UNI 8619:1984 file://../SB/AA005173.PDF UNI 8625-1:1984 + A1:1993 file://../SB/AA018811.PDF UNI 8626:1984 file://../SB/AA005178.PDF UNI 8627:1984 file://../SB/AA005179.PDF UNI 8629-1:1992 file://../SB/AA000006.PDF UNI 8629-2:1992 file://../SB/AA000218.PDF UNI 8629-3:1992 file://../SB/AA000219.PDF UNI 8629-4:1989 file://../SB/AA006472.PDF UNI 8629-5:1992 file://../SB/AA000220.PDF UNI 8629-6:1989 file://../SB/AA006473.PDF UNI 8629-7:1992 file://../SB/AA000221.PDF UNI 8629-8:1992 file://../SB/AA000222.PDF UNI 8634:1985 file://../SB/AA005185.PDF UNI 8635-1:1984 file://../SB/AA005186.PDF UNI 8635-2:1984 file://../SB/AA005187.PDF UNI 8635-3:1984 file://../SB/AA005188.PDF UNI EN 12864:2005
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Eurocode 3 - Design of steel structures - Part 1-8: Design of joints [2005 ed.]

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Filename filename2

NRIF AA022731 IDcompl

ITEM3

UNI EN 1993-1-8:2005 -

UNIN1993-1-8_2005_EEN.pdf UNIN1993-1-8

- Eurocodice 3 - Progettazione delle strutture di acciaio - Parte 1-8: Progettazione dei collegamenti

INGEGNERIA STRUTTURALE

NORMA TECNICA DATA

UNI EN 1993-1-8:2005 01/08/2005

AUTORI

INGEGNERIA STRUTTURALE

TITOLO

Eurocodice 3 - Progettazione delle strutture di acciaio - Parte 1-8: Progettazione dei collegamenti Eurocode 3 - Design of steel structures - Part 1-8: Design of joints

SOMMARIO

La presente norma è la versione ufficiale in lingua inglese della norma europea EN 1993-1-8 (edizione maggio 2005). La norma fornisce i metodi di progettazione dei collegamenti sottoposti a carico statico predominante. Si applica a collegamenti realizzati

TESTO DELLA NORMA CLASSIFICAZIONE ICS CLASSIFICAZIONE ARGOMENTO

91.010.30 91.080.10 AA10B0303

PARZIALMENTE SOSTITUITA GRADO DI COGENZA STATO DI VALIDITA' COLLEGAMENTI INTERNAZIONALI

In vigore EN 1993-1-8:2005

LINGUA

Inglese

PAGINE

129

PREZZO EURO

Non Soci

96,00 Euro - Soci 48,00 Euro

Documento contenuto nel prodotto UNIEDIL STRUTTURE edizione 2005.2 E' vietato l'uso in rete del singolo documento e la sua riproduzione. E' autorizzata la stampa per uso interno.

Eurocodice 3 NORMA EUROPEA

Progettazione delle strutture di acciaio Parte 1-8: Progettazione dei collegamenti

UNI EN 1993-1-8

AGOSTO 2005 Eurocode 3

Design of steel structures Part 1-8: Design of joints La norma fornisce i metodi di progettazione dei collegamenti sottoposti a carico statico predominante. Si applica a collegamenti realizzati con acciaio di classe S235, S275, S355 e S460.

TESTO INGLESE

La presente norma è la versione ufficiale in lingua inglese della norma europea EN 1993-1-8 (edizione maggio 2005). La presente norma, unitamente alle UNI EN 1993-1-1:2005, UNI EN 1993-1-9:2005 e UNI EN 1993-1-10:2005, sostituisce la UNI ENV 1993-1-1:2004. ICS UNI Ente Nazionale Italiano di Unificazione Via Battistotti Sassi, 11B 20133 Milano, Italia

91.080.10; 91.010.30

© UNI Riproduzione vietata. Tutti i diritti sono riservati. Nessuna parte del presente documento può essere riprodotta o diffusa con un mezzo qualsiasi, fotocopie, microfilm o altro, senza il consenso scritto dell’UNI. www.uni.com UNI EN 1993-1-8:2005

Pagina I

Documento contenuto nel prodotto UNIEDIL STRUTTURE edizione 2005.2 E' vietato l'uso in rete del singolo documento e la sua riproduzione. E' autorizzata la stampa per uso interno.

PREMESSA NAZIONALE La presente norma costituisce il recepimento, in lingua inglese, della norma europea EN 1993-1-8 (edizione maggio 2005), che assume così lo status di norma nazionale italiana. La presente norma è stata elaborata sotto la competenza della Commissione Tecnica UNI Ingegneria strutturale La presente norma è stata ratificata dal Presidente dell’UNI, con delibera del 19 luglio 2005.

Le norme UNI sono elaborate cercando di tenere conto dei punti di vista di tutte le parti interessate e di conciliare ogni aspetto conflittuale, per rappresentare il reale stato dell’arte della materia ed il necessario grado di consenso. Chiunque ritenesse, a seguito dell’applicazione di questa norma, di poter fornire suggerimenti per un suo miglioramento o per un suo adeguamento ad uno stato dell’arte in evoluzione è pregato di inviare i propri contributi all’UNI, Ente Nazionale Italiano di Unificazione, che li terrà in considerazione per l’eventuale revisione della norma stessa. Le norme UNI sono revisionate, quando necessario, con la pubblicazione di nuove edizioni o di aggiornamenti. È importante pertanto che gli utilizzatori delle stesse si accertino di essere in possesso dell’ultima edizione e degli eventuali aggiornamenti. Si invitano inoltre gli utilizzatori a verificare l’esistenza di norme UNI corrispondenti alle norme EN o ISO ove citate nei riferimenti normativi. UNI EN 1993-1-8:2005

© UNI

Pagina II

Documento contenuto nel prodotto UNIEDIL STRUTTURE edizione 2005.2 E' vietato l'uso in rete del singolo documento e la sua riproduzione. E' autorizzata la stampa per uso interno.

EN 1993-1-8

EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM

May 2005

ICS 91.010.30

Supersedes ENV 1993-1-1:1992

English version

Eurocode 3: Design of steel structures - Part 1-8: Design of joints Eurocode 3: Calcul des structures en acier - Partie 1-8: Calcul des assemblages

Eurocode 3: Bemessung und Konstruktion von Stahlbauten - Teil 1-8: Bemessung von Anschlüssen

This European Standard was approved by CEN on 16 April 2004. CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the Central Secretariat or to any CEN member. This European Standard exists in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN member into its own language and notified to the Central Secretariat has the same status as the official versions. CEN members are the national standards bodies of Austria, Belgium, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.

EUROPEAN COMMITTEE FOR STANDARDIZATION COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG

Management Centre: rue de Stassart, 36

© 2005 CEN

All rights of exploitation in any form and by any means reserved worldwide for CEN national Members.

B-1050 Brussels

Ref. No. EN 1993-1-8:2005: E

Documento contenuto nel prodotto UNIEDIL STRUTTURE edizione 2005.2 E' vietato l'uso in rete del singolo documento e la sua riproduzione. E' autorizzata la stampa per uso interno.

EN 1993-1-8 : 2005 (E)

Contents 1

Introduction ............................................................................................................................................. 8 1.1 1.2 1.3 1.4 1.5

2

Scope ................................................................................................................................................. 8 Normative references......................................................................................................................... 8 Distinction between Principles and Application Rules ....................................................................10 Terms and definitions .......................................................................................................................10 Symbols ............................................................................................................................................13

Basis of design .........................................................................................................................................18 2.1 2.2 2.3 2.4 2.5 2.6 2.7

3

Page

Assumptions .....................................................................................................................................18 General requirements........................................................................................................................18 Applied forces and moments ............................................................................................................18 Resistance of joints...........................................................................................................................18 Design assumptions ..........................................................................................................................19 Joints loaded in shear subject to impact, vibration and/or load reversal ..........................................19 Eccentricity at intersections..............................................................................................................19

Connections made with bolts, rivets or pins.........................................................................................20 3.1 Bolts, nuts and washers ....................................................................................................................20 3.1.1 General .....................................................................................................................................20 3.1.2 Preloaded bolts .........................................................................................................................20 3.2 Rivets................................................................................................................................................20 3.3 Anchor bolts .....................................................................................................................................21 3.4 Categories of bolted connections......................................................................................................21 3.4.1 Shear connections .....................................................................................................................21 3.4.2 Tension connections .................................................................................................................21 3.5 Positioning of holes for bolts and rivets ...........................................................................................23 3.6 Design resistance of individual fasteners .........................................................................................24 3.6.1 Bolts and rivets .........................................................................................................................24 3.6.2 Injection bolts ...........................................................................................................................28 3.7 Group of fasteners ............................................................................................................................29 3.8 Long joints........................................................................................................................................29 3.9 Slip-resistant connections using 8.8 or 10.9 bolts ............................................................................30 3.9.1 Design Slip resistance...............................................................................................................30 3.9.2 Combined tension and shear.....................................................................................................31 3.9.3 Hybrid connections...................................................................................................................31 3.10 Deductions for fastener holes ...........................................................................................................31 3.10.1 General .....................................................................................................................................31 3.10.2 Design for block tearing ...........................................................................................................32 3.10.3 Angles connected by one leg and other unsymmetrically connected members in tension .......33 3.10.4 Lug angles ................................................................................................................................34 3.11 Prying forces.....................................................................................................................................34 3.12 Distribution of forces between fasteners at the ultimate limit state..................................................34 3.13 Connections made with pins.............................................................................................................35 3.13.1 General .....................................................................................................................................35 3.13.2 Design of pins...........................................................................................................................35

4

Welded connections ................................................................................................................................38 4.1 General .............................................................................................................................................38 4.2 Welding consumables.......................................................................................................................38 4.3 Geometry and dimensions ................................................................................................................38 4.3.1 Type of weld.............................................................................................................................38 4.3.2 Fillet welds ...............................................................................................................................38 4.3.3 Fillet welds all round ................................................................................................................40 4.3.4 Butt welds.................................................................................................................................40 4.3.5 Plug welds ................................................................................................................................41

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EN 1993-1-8 : 2005 (E)

4.3.6 Flare groove welds....................................................................................................................41 4.4 Welds with packings.........................................................................................................................41 4.5 Design resistance of a fillet weld......................................................................................................42 4.5.1 Length of welds ........................................................................................................................42 4.5.2 Effective throat thickness .........................................................................................................42 4.5.3 Design Resistance of fillet welds..............................................................................................42 4.6 Design resistance of fillet welds all round........................................................................................44 4.7 Design resistance of butt welds ........................................................................................................45 4.7.1 Full penetration butt welds .......................................................................................................45 4.7.2 Partial penetration butt welds ...................................................................................................45 4.7.3 T-butt joints ..............................................................................................................................45 4.8 Design resistance of plug welds .......................................................................................................45 4.9 Distribution of forces........................................................................................................................46 4.10 Connections to unstiffened flanges...................................................................................................46 4.11 Long joints........................................................................................................................................48 4.12 Eccentrically loaded single fillet or single-sided partial penetration butt welds ..............................48 4.13 Angles connected by one leg ............................................................................................................48 4.14 Welding in cold-formed zones .........................................................................................................49 5

Analysis, classification and modelling ..................................................................................................50 5.1 Global analysis .................................................................................................................................50 5.1.1 General .....................................................................................................................................50 5.1.2 Elastic global analysis ..............................................................................................................50 5.1.3 Rigid-plastic global analysis.....................................................................................................51 5.1.4 Elastic- plastic global analysis..................................................................................................51 5.1.5 Global analysis of lattice girders ..............................................................................................52 5.2 Classification of joints ......................................................................................................................54 5.2.1 General .....................................................................................................................................54 5.2.2 Classification by stiffness.........................................................................................................54 5.2.3 Classification by strength .........................................................................................................55 5.3 Modelling of beam-to-column joints ................................................................................................56

6

Structural joints connecting H or I sections.........................................................................................60 6.1 General .............................................................................................................................................60 6.1.1 Basis .........................................................................................................................................60 6.1.2 Structural properties .................................................................................................................60 6.1.3 Basic components of a joint......................................................................................................61 6.2 Design Resistance.............................................................................................................................65 6.2.1 Internal forces ...........................................................................................................................65 6.2.2 Shear forces ..............................................................................................................................65 6.2.3 Bending moments .....................................................................................................................66 6.2.4 Equivalent T-stub in tension.....................................................................................................67 6.2.5 Equivalent T-stub in compression ............................................................................................70 6.2.6 Design Resistance of basic components ...................................................................................71 6.2.7 Design moment resistance of beam-to-column joints and splices ............................................84 6.2.8 Design resistance of column bases with base plates.................................................................89 6.3 Rotational stiffness ...........................................................................................................................92 6.3.1 Basic model ..............................................................................................................................92 6.3.2 Stiffness coefficients for basic joint components .....................................................................94 6.3.3 End-plate joints with two or more bolt-rows in tension ...........................................................97 6.3.4 Column bases............................................................................................................................98 6.4 Rotation capacity ..............................................................................................................................99 6.4.1 General .....................................................................................................................................99 6.4.2 Bolted joints............................................................................................................................100 6.4.3 Welded Joints .........................................................................................................................100

7

Hollow section joints.............................................................................................................................101 7.1

General ...........................................................................................................................................101 3

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7.1.1 Scope ......................................................................................................................................101 7.1.2 Field of application.................................................................................................................101 7.2 Design.............................................................................................................................................103 7.2.1 General ...................................................................................................................................103 7.2.2 Failure modes for hollow section joints..................................................................................103 7.3 Welds..............................................................................................................................................107 7.3.1 Design resistance ....................................................................................................................107 7.4 Welded joints between CHS members ...........................................................................................108 7.4.1 General ...................................................................................................................................108 7.4.2 Uniplanar joints ......................................................................................................................108 7.4.3 Multiplanar joints ...................................................................................................................115 7.5 Welded joints between CHS or RHS brace members and RHS chord members ...........................116 7.5.1 General ...................................................................................................................................116 7.5.2 Uniplanar joints ......................................................................................................................117 7.5.3 Multiplanar joints ...................................................................................................................128 7.6 Welded joints between CHS or RHS brace members and I or H section chords ...........................129 7.7 Welded joints between CHS or RHS brace members and channel section chord members ..........132

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EN 1993-1-8 : 2005 (E)

Foreword This European Standard EN 1993, Eurocode 3: Design of steel structures, has been prepared by Technical Committee CEN/TC250 « Structural Eurocodes », the Secretariat of which is held by BSI. CEN/TC250 is responsible for all Structural Eurocodes. This European Standard shall be given the status of a National Standard, either by publication of an identical text or by endorsement, at the latest by November 2005, and conflicting National Standards shall be withdrawn at latest by March 2010. This Eurocode supersedes ENV 1993-1-1. According to the CEN-CENELEC Internal Regulations, the National Standard Organizations of the following countries are bound to implement these European Standard: Austria, Belgium, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Slovakia, Slovenia, Spain, Sweden, Switzerland and United Kingdom.

Background to the Eurocode programme In 1975, the Commission of the European Community decided on an action programme in the field of construction, based on article 95 of the Treaty. The objective of the programme was the elimination of technical obstacles to trade and the harmonization of technical specifications. Within this action programme, the Commission took the initiative to establish a set of harmonized technical rules for the design of construction works which, in a first stage, would serve as an alternative to the national rules in force in the Member States and, ultimately, would replace them. For fifteen years, the Commission, with the help of a Steering Committee with Representatives of Member States, conducted the development of the Eurocodes programme, which led to the first generation of European codes in the 1980s. In 1989, the Commission and the Member States of the EU and EFTA decided, on the basis of an agreement1 between the Commission and CEN, to transfer the preparation and the publication of the Eurocodes to CEN through a series of Mandates, in order to provide them with a future status of European Standard (EN). This links de facto the Eurocodes with the provisions of all the Council’s Directives and/or Commission’s Decisions dealing with European standards (e.g. the Council Directive 89/106/EEC on construction products - CPD - and Council Directives 93/37/EEC, 92/50/EEC and 89/440/EEC on public works and services and equivalent EFTA Directives initiated in pursuit of setting up the internal market). The Structural Eurocode programme comprises the following standards generally consisting of a number of Parts: EN 1990 EN 1991 EN 1992 EN 1993 EN 1994 EN 1995 EN 1996 EN 1997 EN 1998 EN 1999

1

Eurocode 0: Eurocode 1: Eurocode 2: Eurocode 3: Eurocode 4: Eurocode 5: Eurocode 6: Eurocode 7: Eurocode 8: Eurocode 9:

Basis of Structural Design Actions on structures Design of concrete structures Design of steel structures Design of composite steel and concrete structures Design of timber structures Design of masonry structures Geotechnical design Design of structures for earthquake resistance Design of aluminium structures

Agreement between the Commission of the European Communities and the European Committee for Standardisation (CEN) concerning the work on EUROCODES for the design of building and civil engineering works (BC/CEN/03/89).

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EN 1993-1-8 : 2005 (E)

Eurocode standards recognize the responsibility of regulatory authorities in each Member State and have safeguarded their right to determine values related to regulatory safety matters at national level where these continue to vary from State to State.

Status and field of application of eurocodes The Member States of the EU and EFTA recognize that Eurocodes serve as reference documents for the following purposes : – as a means to prove compliance of building and civil engineering works with the essential requirements of Council Directive 89/106/EEC, particularly Essential Requirement N°1 – Mechanical resistance and stability – and Essential Requirement N°2 – Safety in case of fire; – as a basis for specifying contracts for construction works and related engineering services; – as a framework for drawing up harmonized technical specifications for construction products (ENs and ETAs) The Eurocodes, as far as they concern the construction works themselves, have a direct relationship with the Interpretative Documents2 referred to in Article 12 of the CPD, although they are of a different nature from harmonized product standards3. Therefore, technical aspects arising from the Eurocodes work need to be adequately considered by CEN Technical Committees and/or EOTA Working Groups working on product standards with a view to achieving full compatibility of these technical specifications with the Eurocodes. The Eurocode standards provide common structural design rules for everyday use for the design of whole structures and component products of both a traditional and an innovative nature. Unusual forms of construction or design conditions are not specifically covered and additional expert consideration will be required by the designer in such cases.

National Standards implementing Eurocodes The National Standards implementing Eurocodes will comprise the full text of the Eurocode (including any annexes), as published by CEN, which may be preceded by a National title page and National foreword, and may be followed by a National annex. The National annex may only contain information on those parameters which are left open in the Eurocode for national choice, known as Nationally Determined Parameters, to be used for the design of buildings and civil engineering works to be constructed in the country concerned, i.e. : – values and/or classes where alternatives are given in the Eurocode, – values to be used where a symbol only is given in the Eurocode, – country specific data (geographical, climatic, etc.), e.g. snow map, – the procedure to be used where alternative procedures are given in the Eurocode. It may contain – decisions on the application of informative annexes, – references to non-contradictory complementary information to assist the user to apply the Eurocode.

Links between Eurocodes and harmonized technical specifications (ENs and ETAs) for products

2

3

According to Art. 3.3 of the CPD, the essential requirements (ERs) shall be given concrete form in interpretative documents for the creation of the necessary links between the essential requirements and the mandates for harmonized ENs and ETAGs/ETAs.

According to Art. 12 of the CPD the interpretative documents shall : give concrete form to the essential requirements by harmonizing the terminology and the technical bases and indicating classes or levels for each requirement where necessary ; b) indicate methods of correlating these classes or levels of requirement with the technical specifications, e.g. methods of calculation and of proof, technical rules for project design, etc. ; c) serve as a reference for the establishment of harmonized standards and guidelines for European technical approvals. a)

The Eurocodes, de facto, play a similar role in the field of the ER 1 and a part of ER 2.

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EN 1993-1-8 : 2005 (E)

There is a need for consistency between the harmonized technical specifications for construction products and the technical rules for works4. Furthermore, all the information accompanying the CE Marking of the construction products which refer to Eurocodes should clearly mention which Nationally Determined Parameters have been taken into account.

National annex for EN 1993-1-8 This standard gives alternative procedures, values and recommendations with notes indicating where national choices may have to be made. The National Standard implementing EN 1993-1-8 should have a National Annex containing all Nationally Determined Parameters for the design of steel structures to be constructed in the relevant country. National choice is allowed in EN 1993-1-8 through: –

2.2(2)



1.2.6 (Group 6: Rivets)



3.1.1(3)



3.4.2(1)



5.2.1(2)



6.2.7.2(9)

4

see Art.3.3 and Art.12 of the CPD, as well as clauses 4.2, 4.3.1, 4.3.2 and 5.2 of ID 1.

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EN 1993-1-8 : 2005 (E)

1 Introduction 1.1 Scope (1)

This part of EN 1993 gives design methods for the design of joints subject to predominantly static loading using steel grades S235, S275, S355 and S460.

1.2 Normative references This European Standard incorporates by dated or undated reference, provisions from other publications. These normative references are cited at the appropriate places in the text and the publications are listed hereafter. For dated references, subsequent amendments to or revisions of any of these publications apply to this European Standard, only when incorporated in it by amendment or revision. For undated references the latest edition of the publication referred to applies (including amendments). 1.2.1

Reference Standards, Group 1: Weldable structural steels

EN 10025-1:2004

Hot rolled products of structural steels. General technical delivery conditions

EN 10025-2:2004

Hot rolled products of structural steels. Technical delivery conditions for non-alloy structural steels

EN 10025-3:2004

Hot rolled products of structural steels. Technical delivery conditions for normalized/normalized rolled weldable fine grain structural steels

EN 10025-4:2004

Hot rolled products of structural steels. Technical delivery conditions for thermomechanical rolled weldable fine grain structural steels

EN 10025-5:2004

Hot rolled products of structural steels. Technical delivery conditions for structural steels with improved atmospheric corrosion resistance

EN 10025-6:2004

Hot rolled products of structural steels. Technical delivery conditions for flat products of high yield strength structural steels in quenched and tempered condition

1.2.2

Reference Standards, Group 2: Tolerances, dimensions and technical delivery conditions

EN 10029:1991

Hot rolled steel plates 3 mm thick or above - Tolerances on dimensions, shape and mass

EN 10034:1993

Structural steel I- and H-sections - Tolerances on shape and dimensions

EN 10051:1991

Continuously hot-rolled uncoated plate, sheet and strip of non-alloy and alloy steels Tolerances on dimensions and shape

EN 10055:1995

Hot rolled steel equal flange tees with radiused root and toes - Dimensions and tolerances on shape and dimensions

EN 10056-1:1995

Structural steel equal and unequal leg angles - Part 1: Dimensions

EN 10056-2:1993

Structural steel equal and unequal leg angles - Part 2: Tolerances on shape and dimensions

EN 10164:1993

Steel products with improved deformation properties perpendicular to the surface of the product - Technical delivery conditions

1.2.3

Reference Standards, Group 3: Structural hollow sections

EN 10219-1:1997

8

Cold formed welded structural hollow sections of non-alloy and fine grain steels - Part 1: Technical delivery requirements

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EN 1993-1-8 : 2005 (E)

EN 10219-2:1997

Cold formed welded structural hollow sections of non-alloy and fine grain steels - Part 2: Tolerances, dimensions and sectional properties

EN 10210-1:1994

Hot finished structural hollow sections of non-alloy and fine grain structural steels Part 1: Technical delivery requirements

EN 10210-2:1997

Hot finished structural hollow sections of non-alloy and fine grain structural steels Part 2: Tolerances, dimensions and sectional properties

1.2.4

Reference Standards, Group 4: Bolts, nuts and washers

EN 14399-1:2002

High strength structural bolting for preloading - Part 1 : General Requirements

EN 14399-2:2002

High strength structural bolting for preloading - Part 2 : Suitability Test for preloading

EN 14399-3:2002

High strength structural bolting for preloading - Part 3 : System HR -Hexagon bolt and nut assemblies

EN 14399-4:2002

High strength structural bolting for preloading - Part 4 : System HV -Hexagon bolt and nut assemblies

EN 14399-5:2002

High strength structural bolting for preloading - Part 5 : Plain washers for system HR

EN 14399-6:2002

High strength structural bolting for preloading - Part 6 : Plain chamfered washers for systems HR and HV

EN ISO 898-1:1999 Mechanical properties of fasteners made of carbon steel and alloy steel - Part 1: Bolts, screws and studs (ISO 898-1:1999) EN 20898-2:1993

Mechanical properties of fasteners - Part 2: Nuts with special proof load values Coarse thread (ISO 898-2:1992)

EN ISO 2320:1997

Prevailing torque type steel hexagon nuts - Mechanical and performance requirements (ISO 2320:1997)

EN ISO 4014:2000

Hexagon head bolts - Product grades A and B (ISO 4014:1999)

EN ISO 4016:2000

Hexagon head bolts - Product grade C (ISO 4016:1999)

EN ISO 4017:2000

Hexagon head screws - Product grades A and B (ISO 4017:1999)

EN ISO 4018:2000

Hexagon head screws - Product grade C (ISO 4018:1999)

EN ISO 4032:2000

Hexagon nuts, style 1 - Product grades A and B (ISO 4032:1999)

EN ISO 4033:2000

Hexagon nuts, style 2 - Product grades A and B (ISO 4033:1999)

EN ISO 4034:2000

Hexagon nuts - Product grade C (ISO 4034:1999)

EN ISO 7040:1997

Prevailing torque hexagon nuts (with non-metallic insert), style 1 - Property classes 5, 8 and 10

EN ISO 7042:1997

Prevailing torque all-metal hexagon nuts, style 2 - Property classes 5, 8, 10 and 12

EN ISO 7719:1997

Prevailing torque type all-metal hexagon nuts, style 1 - Property classes 5, 8 and 10

ISO 286- 2:1988

ISO system of limits and fits - Part 2: Tables of standard tolerance grades and limit deviations for hole and shafts

ISO 1891:1979

Bolts, screws, nuts and accessories - Terminology and nomenclature - Trilingual edition

EN ISO 7089:2000

Plain washers- Nominal series- Product grade A

EN ISO 7090:2000

Plain washers, chamfered - Normal series - Product grade A

EN ISO 7091:2000

Plain washers - Normal series - Product grade C

EN ISO 10511:1997 Prevailing torque type hexagon thin nuts (with non-metallic insert) EN ISO 10512:1997 Prevailing torque type hexagon nuts thin nuts, style 1, with metric fine pitch thread Property classes 6, 8 and 10 EN ISO 10513:1997 Prevailing torque type all-metal hexagon nuts, style 2, with metric fine pitch thread Property classes 8, 10 and 12 9

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1.2.5

Reference Standards, Group 5: Welding consumable and welding

EN 12345:1998

Welding-Multilingual terms for welded joints with illustrations. September 1998.

EN ISO 14555:1998 Welding-Arc stud welding of metallic materials. May 1995 EN ISO 13918:1998 Welding-Studs for arc stud welding-January 1997 EN 288-3:1992

Specification and approval of welding procedures for metallic materials. Part 3: Welding procedure tests for arc welding of steels. 1992

EN ISO 5817:2003

Arc-welded joints in steel - Guidance for quality levels for imperfections

1.2.6

Reference Standards, Group 6: Rivets NOTE: Information may be given in the National Annex.

1.2.7

Reference Standard, Group 7: Execution of steel structures

EN 1090-2

Requirements for the execution of steel structures

1.3 Distinction between Principles and Application Rules (1)

The rules in EN 1990 clause 1.4 apply.

1.4 Terms and definitions (1)

The following terms and definitions apply:

1.4.1 basic component (of a joint) Part of a joint that makes a contribution to one or more of its structural properties. 1.4.2 connection Location at which two or more elements meet. For design purposes it is the assembly of the basic components required to represent the behaviour during the transfer of the relevant internal forces and moments at the connection. 1.4.3 connected member Any member that is joined to a supporting member or element. 1.4.4 joint Zone where two or more members are interconnected. For design purposes it is the assembly of all the basic components required to represent the behaviour during the transfer of the relevant internal forces and moments between the connected members. A beam-to-column joint consists of a web panel and either one connection (single sided joint configuration) or two connections (double sided joint configuration), see Figure 1.1. 1.4.5 joint configuration Type or layout of the joint or joints in a zone within which the axes of two or more inter-connected members intersect, see Figure 1.2. 1.4.6 rotational capacity 10

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EN 1993-1-8 : 2005 (E)

The angle through which the joint can rotate for a given resistance level without failing. 1.4.7 rotational stiffness The moment required to produce unit rotation in a joint. 1.4.8 structural properties (of a joint) Resistance to internal forces and moments in the connected members, rotational stiffness and rotation capacity. 1.4.9 uniplanar joint In a lattice structure a uniplanar joint connects members that are situated in a single plane. 2

1

1

2

2

3

3

Joint

= web panel in shear + connection

a) Single-sided joint configuration

Left joint = web panel in shear + left connection Right joint = web panel in shear + right connection b) Double-sided joint configuration

1 web panel in shear 2 connection 3 components (e.g. bolts, endplate)

Figure 1.1: Parts of a beam-to-column joint configuration

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1

3

3 2

1

4 2

5

1

Single-sided beam-to-column joint configuration;

2

Double-sided beam-to-column joint configuration;

3

Beam splice;

4

Column splice;

5

Column base.

5

a) Major-axis joint configurations

Double-sided beam-to-column joint configuration

Double-sided beam-to-beam joint configuration

b) Minor-axis joint configurations (to be used only for balanced moments Mb1,Ed = Mb2,Ed )

Figure 1.2: Joint configurations

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1.5 Symbols (1)

The following symbols are used in this Standard:

d

is

the nominal bolt diameter, the diameter of the pin or the diameter of the fastener;

d0

is

the hole diameter for a bolt, a rivet or a pin ;

do,t

is

the hole size for the tension face, generally the hole diameter, but for a slotted holes perpendicular to the tension face the slot length should be used;

do,v

is

the hole size for the shear face, generally the hole diameter, but for slotted holes parallel to the shear face the slot length should be used;

dc

is

the clear depth of the column web;

dm

is

the mean of the across points and across flats dimensions of the bolt head or the nut, whichever is smaller;

fH,Rd is

the design value of the Hertz pressure;

fur

is

the specified ultimate tensile strength of the rivet;

e1

is

the end distance from the centre of a fastener hole to the adjacent end of any part, measured in the direction of load transfer, see Figure 3.1;

e2

is

the edge distance from the centre of a fastener hole to the adjacent edge of any part, measured at right angles to the direction of load transfer, see Figure 3.1;

e3

is

the distance from the axis of a slotted hole to the adjacent end or edge of any part, see Figure 3.1;

e4

is

the distance from the centre of the end radius of a slotted hole to the adjacent end or edge of any part, see Figure 3.1;

Ɛeff

is

the effective length of fillet weld;

n

is

the number of the friction surfaces or the number of fastener holes on the shear face;

p1

is

the spacing between centres of fasteners in a line in the direction of load transfer, see Figure 3.1;

p1,0

is

the spacing between centres of fasteners in an outer line in the direction of load transfer, see Figure 3.1;

p1,i

is

the spacing between centres of fasteners in an inner line in the direction of load transfer, see Figure 3.1;

p2

is

the spacing measured perpendicular to the load transfer direction between adjacent lines of fasteners, see Figure 3.1;

r

is

the bolt row number;

NOTE: In a bolted connection with more than one bolt-row in tension, the bolt-rows are numbered starting from the bolt-row furthest from the centre of compression. ss

is

the length of stiff bearing;

ta

is

the thickness of the angle cleat;

tfc

is

the thickness of the column flange;

tp

is

the thickness of the plate under the bolt or the nut;

tw

is

the thickness of the web or bracket;

twc

is

the thickness of the column web;

A

is

the gross cross-section area of bolt;

A0

is

the area of the rivet hole;

Avc

is

the shear area of the column, see EN 1993-1-1;

As

is

the tensile stress area of the bolt or of the anchor bolt; 13

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EN 1993-1-8 : 2005 (E)

Av,eff is

the effective shear area;

Bp,Rd is

the design punching shear resistance of the bolt head and the nut

E

the elastic modulus;

is

Fp,Cd is

the design preload force;

Ft,Ed is

the design tensile force per bolt for the ultimate limit state;

Ft,Rd is

the design tension resistance per bolt;

FT,Rd is

the tension resistance of an equivalent T-stub flange;

Fv,Rd is

the design shear resistance per bolt;

Fb,Rd is

the design bearing resistance per bolt;

Fs,Rd,ser is

the design slip resistance per bolt at the serviceability limit state;

Fs,Rd is

the design slip resistance per bolt at the ultimate limit state;

Fv,Ed,ser is

the design shear force per bolt for the serviceability limit state;

Fv,Ed is

the design shear force per bolt for the ultimate limit state;

Mj,Rd is

the design moment resistance of a joint;

Sj

is

the rotational stiffness of a joint;

Sj,ini

is

the initial rotational stiffness of a joint;

Vwp,Rd is

the plastic shear resistance of a column web panel;

z

is

the lever arm;

μ

is

the slip factor;

I

is

the rotation of a joint.

(2)

The following standard abbreviations for hollow sections are used in section 7:

CHS for “circular hollow section”; RHS for “rectangular hollow section”, which in this context includes square hollow sections. gap g

g

overlap ratio Oov = (q/p) x 100 %

g

q p (a) Definition of gap

(b) Definition of overlap

Figure 1.3: Gap and overlap joints (3)

The following symbols are used in section 7:

Ai

is

the cross-sectional area of member i (i = 0, 1, 2 or 3);

Av

is

the shear area of the chord;

Av,eff is 14

the effective shear area of the chord;

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L

is

the system length of a member;

Mip,i,Rdis

the design value of the resistance of the joint, expressed in terms of the in-plane internal moment in member i (i = 0, 1, 2 or 3);

Mip,i,Ed is

the design value of the in-plane internal moment in member i (i = 0, 1, 2 or 3);

Mop,i,Rd is the design value of the resistance of the joint, expressed in terms of the out-of-plane internal moment in member i (i = 0, 1, 2 or 3); Mop,i,Ed is the design value of the out-of-plane internal moment in member i (i = 0, 1, 2 or 3); Ni,Rd is

the design value of the resistance of the joint, expressed in terms of the internal axial force in member i (i = 0, 1, 2 or 3);

Ni,Ed is

the design value of the internal axial force in member i (i = 0, 1, 2 or 3);

WeƐ,i is

the elastic section modulus of member i (i = 0, 1, 2 or 3);

WpƐ,i is

the plastic section modulus of member i (i = 0, 1, 2 or 3);

bi

is

the overall out-of-plane width of RHS member i (i = 0, 1, 2 or 3);

beff

is

the effective width for a brace member to chord connection;

be,ov

is

the effective width for an overlapping brace to overlapped brace connection;

be,p

is

the effective width for punching shear;

bp

is

the width of a plate;

bw

is

the effective width for the web of the chord;

di

is

the overall diameter of CHS member i (i = 0, 1, 2 or 3);

dw

is

the depth of the web of an I or H section chord member;

e

is

the eccentricity of a joint;

fb

is

the buckling strength of the chord side wall;

fyi

is

the yield strength of member i (i = 0, 1, 2 or 3);

fy0

is

the yield strength of a chord member;

g

is

the gap between the brace members in a K or N joint (negative values of g represent an overlap q ); the gap g is measured along the length of the connecting face of the chord, between the toes of the adjacent brace members, see Figure 1.3(a);

hi

is

the overall in-plane depth of the cross-section of member i (i = 0, 1, 2 or 3);

k

is

a factor defined in the relevant table, with subscript g, m, n or p ;

Ɛ

is

the buckling length of a member;

p

is

the length of the projected contact area of the overlapping brace member onto the face of the chord, in the absence of the overlapped brace member, see Figure 1.3(b);

q

is

the length of overlap, measured at the face of the chord, between the brace members in a K or N joint, see Figure 1.3(b);

r

is

the root radius of an I or H section or the corner radius of a rectangular hollow section;

tf

is

the flange thickness of an I or H section;

ti

is

the wall thickness of member i (i = 0, 1, 2 or 3);

tp

is

the thickness of a plate;

tw

is

the web thickness of an I or H section;

Į

is

a factor defined in the relevant table;

și

is

the included angle between brace member i and the chord (i = 1, 2 or 3);

ț

is

a factor defined where it occurs;

μ

is

a factor defined in the relevant table;

ij

is

the angle between the planes in a multiplanar joint. 15

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EN 1993-1-8 : 2005 (E)

(4)

The integer subscripts used in section 7 are defined as follows:

i

is

an integer subscript used to designate a member of a joint, i = 0 denoting a chord and i = 1, 2 or 3 the brace members. In joints with two brace members, i = 1 normally denotes the compression brace and i = 2 the tension brace, see Figure 1.4(b). For a single brace i = 1 whether it is subject to compression or tension, see Figure 1.4(a);

i and j are integer subscripts used in overlap type joints, i to denote the overlapping brace member and j to denote the overlapped brace member, see Figure 1.4(c). (5)

The stress ratios used in section 7 are defined as follows:

n

is

the ratio (ı0,Ed / fy0 ) / ȖM5

(used for RHS chords);

np

is

the ratio (ıp,Ed / fy0 ) / ȖM5

(used for CHS chords);

ı0,Ed is

the maximum compressive stress in the chord at a joint;

ıp,Ed is

the value of ı0,Ed excluding the stress due to the components parallel to the chord axis of the axial forces in the braces at that joint, see Figure 1.4.

(6)

The geometric ratios used in section 7 are defined as follows:

ȕ

is

the ratio of the mean diameter or width of the brace members, to that of the chord:

-

for T, Y and X joints:

d1 d1 b ; or 1 d 0 b0 b0 -

for K and N joints:

d1  d 2 d1  d 2 b  b2  h1  h 2 ; or 1 2 d0 2 b0 4 b0 -

for KT joints:

d1  d 2  d 3 d0

3

;

d1  d 2  d 3 b  b2 or 1 3 b0

 b3  h1  h2 6 b0

ȕp

is

the ratio bi /bp ;

Ȗ

is

the ratio of the chord width or diameter to twice its wall thickness:

 h3

d0 b b ; 0 or 0 2 t0 2 t0 2 tf Ș

is

the ratio of the brace member depth to the chord diameter or width:

hi h or i d0 b0 Șp

is

the ratio hi /bp ;

Ȝov

is

the overlap ratio, expressed as a percentage ( Ȝov = (q/p) x 100%) as shown in figure 1.3(b).

(7)

Other symbols are specified in appropriate clauses when they are used. NOTE: Symbols for circular sections are given in Table 7.2.

16

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EN 1993-1-8 : 2005 (E)

a) Joint with single brace member

b) Gap joint with two brace members

c) Overlap joint with two brace members

Figure 1.4: Dimensions and other parameters at a hollow section lattice girder joint

17

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2 Basis of design 2.1 Assumptions (1)

The design methods given in this part of EN 1993 assume that the standard of construction is as specified in the execution standards given in 1.2 and that the construction materials and products used are those specified in EN 1993 or in the relevant material and product specifications.

2.2 General requirements (1)

All joints should have a design resistance such that the structure is capable of satisfying all the basic design requirements given in this Standard and in EN 1993-1-1.

(2)

The partial safety factors ȖM for joints are given in Table 2.1.

Table 2.1: Partial safety factors for joints Resistance of members and cross-sections

ȖM0 , ȖM1 and ȖM2 see EN 1993-1-1

Resistance of bolts Resistance of rivets Resistance of pins

ȖM2

Resistance of welds Resistance of plates in bearing Slip resistance - at ultimate limit state (Category C) - at serviceability limit state (Category B)

ȖM3 ȖM3,ser

Bearing resistance of an injection bolt

ȖM4

Resistance of joints in hollow section lattice girder

ȖM5

Resistance of pins at serviceability limit state

ȖM6,ser

Preload of high strength bolts

ȖM7

Resistance of concrete

Ȗc see EN 1992

NOTE: Numerical values for ȖM may be defined in the National Annex. Recommended values are as follows: ȖM2 = 1,25 ; ȖM3 = 1,25 and ȖM3,ser = 1,1 ; ȖM4 = 1,0 ; ȖM5 = 1,0 ; ȖM6,ser = 1,0 ; ȖM7 = 1,1 . (3)

Joints subject to fatigue should also satisfy the principles given in EN 1993-1-9.

2.3 Applied forces and moments (1)

The forces and moments applied to joints at the ultimate limit state should be determined according to the principles in EN 1993-1-1.

2.4 Resistance of joints (1)

The resistance of a joint should be determined on the basis of the resistances of its basic components.

(2)

Linear-elastic or elastic-plastic analysis may be used in the design of joints.

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EN 1993-1-8 : 2005 (E)

(3)

Where fasteners with different stiffnesses are used to carry a shear load the fasteners with the highest stiffness should be designed to carry the design load. An exception to this design method is given in 3.9.3.

2.5 Design assumptions (1)

(2)

Joints should be designed on the basis of a realistic assumption of the distribution of internal forces and moments. The following assumptions should be used to determine the distribution of forces: (a)

the internal forces and moments assumed in the analysis are in equilibrium with the forces and moments applied to the joints,

(b)

each element in the joint is capable of resisting the internal forces and moments,

(c)

the deformations implied by this distribution do not exceed the deformation capacity of the fasteners or welds and the connected parts,

(d)

the assumed distribution of internal forces should be realistic with regard to relative stiffnesses within the joint,

(e)

the deformations assumed in any design model based on elastic-plastic analysis are based on rigid body rotations and/or in-plane deformations which are physically possible, and

(f)

any model used is in compliance with the evaluation of test results (see EN 1990).

The application rules given in this part satisfy 2.5(1).

2.6 Joints loaded in shear subject to impact, vibration and/or load reversal (1)

Where a joint loaded in shear is subject to impact or significant vibration one of the following jointing methods should be used: –

welding



bolts with locking devices



preloaded bolts



injection bolts



other types of bolt which effectively prevent movement of the connected parts



rivets.

(2)

Where slip is not acceptable in a joint (because it is subject to reversal of shear load or for any other reason), preloaded bolts in a Category B or C connection (see 3.4), fit bolts (see 3.6.1), rivets or welding should be used.

(3)

For wind and/or stability bracings, bolts in Category A connections (see 3.4) may be used.

2.7 Eccentricity at intersections (1)

Where there is eccentricity at intersections, the joints and members should be designed for the resulting moments and forces, except in the case of particular types of structures where it has been demonstrated that it is not necessary, see 5.1.5.

(2)

In the case of joints of angles or tees attached by either a single line of bolts or two lines of bolts any possible eccentricity should be taken into account in accordance with 2.7(1). In-plane and out-of-plane eccentricities should be determined by considering the relative positions of the centroidal axis of the member and of the setting out line in the plane of the connection (see Figure 2.1). For a single angle in tension connected by bolts on one leg the simplified design method given in 3.10.3 may be used. NOTE: The effect of eccentricity on angles used as web members in compression is given in EN 1993-1-1, Annex BB 1.2.

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EN 1993-1-8 : 2005 (E)

1 Centroidal axes 2 Fasteners 3 Setting out lines

Figure 2.1: Setting out lines

3 Connections made with bolts, rivets or pins 3.1 Bolts, nuts and washers 3.1.1

General

(1)

All bolts, nuts and washers should comply with 1.2.4 Reference Standards: Group 4.

(2)

The rules in this Standard are valid for the bolt classes given in Table 3.1.

(3)

The yield strength fyb and the ultimate tensile strength fub for bolt classes 4.6, 4.8, 5.6, 5.8, 6.8, 8.8 and 10.9 are given in Table 3.1. These values should be adopted as characteristic values in design calculations.

Table 3.1: Nominal values of the yield strength fyb and the ultimate tensile strength fub for bolts Bolt class fyb (N/mm2) 2

fub (N/mm )

4.6

4.8

5.6

5.8

6.8

8.8

10.9

240

320

300

400

480

640

900

400

400

500

500

600

800

1000

NOTE: The National Annex may exclude certain bolt classes. 3.1.2 (1)

Preloaded bolts Only bolt assemblies of classes 8.8 and 10.9 conforming to the requirements given in 1.2.4 Reference Standards: Group 4 for High Strength Structural Bolting for preloading with controlled tightening in accordance with the requirements in 1.2.7 Reference Standards: Group 7 may be used as preloaded bolts.

3.2 Rivets (1)

20

The material properties, dimensions and tolerances of steel rivets should comply with the requirements given in 1.2.6 Reference Standards: Group 6.

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EN 1993-1-8 : 2005 (E)

3.3 Anchor bolts (1)

The following materials may be used for anchor bolts: –

Steel grades conforming to 1.2.1 Reference Standards: Group 1;



Steel grades conforming to 1.2.4 Reference Standards: Group 4;



Steel grades used for reinforcing bars conforming to EN 10080;

provided that the nominal yield strength does not exceed 640 N/mm2 when the anchor bolts are required to act in shear and not more than 900 N/mm2 otherwise.

3.4 Categories of bolted connections 3.4.1 (1)

Shear connections Bolted connections loaded in shear should be designed as one of the following: a) Category A: Bearing type In this category bolts from class 4.6 up to and including class 10.9 should be used. No preloading and special provisions for contact surfaces are required. The design ultimate shear load should not exceed the design shear resistance, obtained from 3.6, nor the design bearing resistance, obtained from 3.6 and 3.7. b) Category B: Slip-resistant at serviceability limit state In this category preloaded bolts in accordance with 3.1.2(1) should be used. Slip should not occur at the serviceability limit state. The design serviceability shear load should not exceed the design slip resistance, obtained from 3.9. The design ultimate shear load should not exceed the design shear resistance, obtained from 3.6, nor the design bearing resistance, obtained from 3.6 and 3.7. c) Category C: Slip-resistant at ultimate limit state In this category preloaded bolts in accordance with 3.1.2(1) should be used. Slip should not occur at the ultimate limit state. The design ultimate shear load should not exceed the design slip resistance, obtained from 3.9, nor the design bearing resistance, obtained from 3.6 and 3.7. In addition for a connection in tension, the design plastic resistance of the net cross-section at bolt holes Nnet,Rd, (see 6.2 of EN 1993-1-1), should be checked, at the ultimate limit state. The design checks for these connections are summarized in Table 3.2.

3.4.2 (1)

Tension connections Bolted connection loaded in tension should be designed as one of the following: a) Category D: non-preloaded In this category bolts from class 4.6 up to and including class 10.9 should be used. No preloading is required. This category should not be used where the connections are frequently subjected to variations of tensile loading. However, they may be used in connections designed to resist normal wind loads. b) Category E: preloaded In this category preloaded 8.8 and 10.9 bolts with controlled tightening in conformity with 1.2.7 Reference Standards: Group 7 should be used. The design checks for these connections are summarized in Table 3.2.

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Table 3.2: Categories of bolted connections Category

Criteria

Remarks

Shear connections A bearing type

Fv,Ed ” Fv,Ed ”

Fv,Rd Fb,Rd

No preloading required. Bolt classes from 4.6 to 10.9 may be used.

B slip-resistant at serviceability

Fv,Ed.ser” Fv,Ed ” Fv,Ed ”

Fs,Rd,ser Fv,Rd Fb,Rd

Preloaded 8.8 or 10.9 bolts should be used. For slip resistance at serviceability see 3.9.

C slip-resistant at ultimate

Fv,Ed ” Fv,Ed ” Fv,Ed ”

Fs,Rd Fb,Rd Nnet,Rd

Preloaded 8.8 or 10.9 bolts should be used. For slip resistance at ultimate see 3.9. Nnet,Rd see 3.4.1(1) c).

Tension connections D non-preloaded

Ft,Ed ” Ft,Ed ”

Ft,Rd Bp,Rd

No preloading required. Bolt classes from 4.6 to 10.9 may be used. Bp,Rd see Table 3.4.

E preloaded

Ft,Ed ” Ft,Ed ”

Ft,Rd Bp,Rd

Preloaded 8.8 or 10.9 bolts should be used. Bp,Rd see Table 3.4.

The design tensile force Ft,Ed should include any force due to prying action, see 3.11. Bolts subjected to both shear force and tensile force should also satisfy the criteria given in Table 3.4. NOTE: If preload is not explicitly used in the design calculations for slip resistances but is required for execution purposes or as a quality measure (e.g. for durability) then the level of preload can be specified in the National Annex.

22

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3.5 Positioning of holes for bolts and rivets (1)

Minimum and maximum spacing and end and edge distances for bolts and rivets are given in Table 3.3.

(2)

Minimum and maximum spacing, end and edge distances for structures subjected to fatigue, see EN 1993-1-9.

Table 3.3: Minimum and maximum spacing, end and edge distances Distances and spacings, see Figure 3.1

Maximum1) 2) 3)

Minimum

Structures made from steels conforming to EN 10025 except steels conforming to EN 10025-5 Steel exposed to the weather or other corrosive influences

End distance e1

1,2d0

4t + 40 mm

Edge distance e2

1,2d0

4t + 40 mm

Distance e3 in slotted holes Distance e4 in slotted holes Spacing p1

1,5d0

4)

1,5d0

4)

2,2d0

Spacing p1,0 Spacing p1,i Spacing p2 1)

5)

2,4d0

The smaller of 14t or 200 mm The smaller of 14t or 200 mm The smaller of 28t or 400 mm The smaller of 14t or 200 mm

Steel not exposed to the weather or other corrosive influences

Structures made from steels conforming to EN 10025-5 Steel used unprotected The larger of 8t or 125 mm The larger of 8t or 125 mm

The smaller of 14t or 200 mm

The smaller of 14tmin or 175 mm

The smaller of 14t or 200 mm

The smaller of 14tmin or 175 mm

Maximum values for spacings, edge and end distances are unlimited, except in the following cases: –

for compression members in order to avoid local buckling and to prevent corrosion in exposed members and;



for exposed tension members to prevent corrosion.

2)

The local buckling resistance of the plate in compression between the fasteners should be calculated according to EN 1993-1-1 using 0,6 p1 as buckling length. Local buckling between the fasteners need not to be checked if p1/t is smaller than 9 İ . The edge distance should not exceed the local buckling requirements for an outstand element in the compression members, see EN 1993-1-1. The end distance is not affected by this requirement.

3)

t is the thickness of the thinner outer connected part.

4)

The dimensional limits for slotted holes are given in 1.2.7 Reference Standards: Group 7.

5)

For staggered rows of fasteners a minimum line spacing of p2 = 1,2d0 may be used, provided that the minimum distance, L, between any two fasteners is greater or equal than 2,4d0, see Figure 3.1b).

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Staggered Rows of fasteners a) Symbols for spacing of fasteners

p1 d14 t and d 200 mm

p2 d14 t and d 200 mm

b) Symbols for staggered spacing

p1,0 d14 t and d 200 mm

p1,i d28 t and d 400 mm

1 outer row

2 inner row

c) Staggered spacing in compression members

d) Staggered spacing in tension members

e) End and edge distances for slotted holes

Figure 3.1: Symbols for end and edge distances and spacing of fasteners 3.6 Design resistance of individual fasteners 3.6.1

Bolts and rivets

(1)

The design resistance for an individual fastener subjected to shear and/or tension is given in Table 3.4.

(2)

For preloaded bolts in accordance with 3.1.2(1) the design preload, Fp,Cd ,to be used in design calculations should be taken as: Fp,Cd = 0,7 fub As / ȖM7

... (3.1)

NOTE: Where the preload is not used in design calculations see note to Table 3.2. (3)

24

The design resistances for tension and for shear through the threaded portion of a bolt given in Table 3.4 should only be used for bolts manufactured in conformity with 1.2.4 Reference Standard: Group 4.

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EN 1993-1-8 : 2005 (E)

For bolts with cut threads, such as anchor bolts or tie rods fabricated from round steel bars where the threads comply with EN 1090, the relevant values from Table 3.4 should be used. For bolts with cut threads where the threads do not comply with EN 1090 the relevant values from Table 3.4 should be multiplied by a factor of 0,85. (4)

The design shear resistance Fv,Rd given in Table 3.4 should only be used where the bolts are used in holes with nominal clearances not exceeding those for normal holes as specified in 1.2.7 Reference Standards: Group 7.

(5)

M12 and M14 bolts may also be used in 2 mm clearance holes provided that the design resistance of the bolt group based on bearing is greater or equal to the design resistance of the bolt group based on bolt shear. In addition for class 4.8, 5.8, 6.8, 8.8 and 10.9 bolts the design shear resistance Fv,Rd should be taken as 0,85 times the value given in Table 3.4.

(6)

Fit bolts should be designed using the method for bolts in normal holes.

(7)

The thread of a fit bolt should not be included in the shear plane.

(8)

The length of the threaded portion of a fit bolt included in the bearing length should not exceed 1/3 of the thickness of the plate, see Figure 3.2.

(9)

The hole tolerance used for fit bolts should be in accordance with 1.2.7 Reference Standards: Group 7.

(10) In single lap joints with only one bolt row, see Figure 3.3, the bolts should be provided with washers under both the head and the nut. The design bearing resistance Fb,Rd for each bolt should be limited to: Fb,Rd ” 1,5 fu d t / ȖM2

... (3.2)

NOTE: Single rivets should not be used in single lap joints. (11) In the case of class 8.8 or 10.9 bolts, hardened washers should be used for single lap joints with only one bolt or one row of bolts. (12) Where bolts or rivets transmitting load in shear and bearing pass through packing of total thickness tp greater than one-third of the nominal diameter d, see Figure 3.4, the design shear resistance Fv,Rd calculated as specified in Table 3.4, should be multiplying by a reduction factor ȕp given by:



ȕp =

9d 8d  3t p

but ȕp ” 1

... (3.3)

(13) For double shear connections with packing on both sides of the splice, tp should be taken as the thickness of the thicker packing. (14) Riveted connections should be designed to transfer shear forces. If tension is present the design tensile force Ft.Ed should not exceed the design tension resistance Ft,Rd given in Table 3.4. (15) For grade S 235 steel the "as driven" value of fur may be taken as 400 N/mm2. (16) As a general rule, the grip length of a rivet should not exceed 4,5d for hammer riveting and 6,5d for press riveting.

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0,7 fy,wc : kwc = 1,7  V com , Ed / f y , wc

... (6.14)

NOTE: Generally the reduction factor kwc is 1,0 and no reduction is necessary. It can therefore be omitted in preliminary calculations when the longitudinal stress is unknown and checked later. Welded joint

Joint with end-plate

Joint with angle flange cleats

a) Elevation

b) Rolled column

c) Welded column

Figure 6.6: Transverse compression on an unstiffened column (3)

The ‘column-sway' buckling mode of an unstiffened column web in compression illustrated in Figure 6.7 should normally be prevented by constructional restraints.

Figure 6.7: ‘Column-sway’ buckling mode of an unstiffened web (4)

74

Stiffeners or supplementary web plates may be used to increase the design resistance of a column web in transverse compression.

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(5)

Transverse stiffeners or appropriate arrangements of diagonal stiffeners may be used (in association with or as an alternative to transverse stiffeners) in order to increase the design resistance of the column web in compression. NOTE: In welded joints, the transverse stiffeners should be aligned with the corresponding beam flange. In bolted joints, the stiffener in the compression zone should be aligned with the centre of compression as defined Figure 6.15.

(6)

Where an unstiffened column web is reinforced by adding a supplementary web plate conforming with 6.2.6.1, the effective thickness of the web may be taken as 1,5 twc if one supplementary web plate is added, or 2,0 twc if supplementary web plates are added to both sides of the web. In calculating the reduction factor Ȧ for the possible effects of shear stress, the shear area Avc of the web may be increased only to the extent permitted when determining its design shear resistance, see 6.2.6.1(6).

6.2.6.3 (1)

Column web in transverse tension

The design resistance of an unstiffened column web subject to transverse tension should be determined from: Ft,wc,Rd =

Z beff ,t , wc t wc f y , wc J M0

... (6.15)

where: Ȧ (2)

is

a reduction factor to allow for the interaction with shear in the column web panel.

For a welded connection, the effective width beff,t,wc of a column web in tension should be obtained using: beff,t,wc = t fb  2 2 ab  5(t fc  s )

... (6.16)

where: –

for a rolled I or H section column:

s =



for a welded I or H section column:

s =

rc

2 ac

where: ac and rc are as indicated in Figure 6.8 and ab is as indicated in Figure 6.6. (3)

For a bolted connection, the effective width beff,t,wc of column web in tension should be taken as equal to the effective length of equivalent T-stub representing the column flange, see 6.2.6.4.

(4)

The reduction factor Ȧ to allow for the possible effects of shear in the column web panel should be determined from Table 6.3, using the value of beff,t,wc given in 6.2.6.3(2) or 6.2.6.3(3) as appropriate.

(5)

Stiffeners or supplementary web plates may be used to increase the design tension resistance of a column web.

(6)

Transverse stiffeners and/or appropriate arrangements of diagonal stiffeners may be used to increase the design resistance of the column web in tension. NOTE: In welded joints, the transverse stiffeners are normally aligned with the corresponding beam flange.

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(7)

The welds connecting diagonal stiffeners to the column flange should be fill-in welds with a sealing run providing a combined throat thickness equal to the thickness of the stiffeners.

(8)

Where an unstiffened column web is reinforced by adding supplementary web plates conforming with 6.2.6.1, the design tension resistance depends on the throat thickness of the longitudinal welds connecting the supplementary web plates. The effective thickness of the web tw,eff should be taken as follows: –



(9)

when the longitudinal welds are full penetration butt welds with a throat thickness a • ts then: –

for one supplementary web plate:

tw,eff = 1,5 twc

... (6.17)



for supplementary web plates both sides:

tw,eff = 2,0 twc

... (6.18)

when the longitudinal welds are fillet welds with a throat thickness a • t s / 2 then for either one or two supplementary web plates: –

for steel grades S 235, S 275 or S 355:

tw,eff = 1,4 twc

... (6.19a)



for steel grades S 420 or S 460:

tw,eff = 1,3 twc

... (6.19b)

In calculating the reduction factor Ȧ for the possible effects of shear stress, the shear area Avc of a column web reinforced by adding supplementary web plates may be increased only to the extent permitted when determining its design shear resistance, see 6.2.6.1(6).

6.2.6.4

Column flange in tranverse bending

6.2.6.4.1 Unstiffened column flange, bolted connection (1)

The design resistance and failure mode of an unstiffened column flange in tranverse bending, together with the associated bolts in tension, should be taken as similar to those of an equivalent T-stub flange, see 6.2.4, for both: –

each individual bolt-row required to resist tension;



each group of bolt-rows required to resist tension.

(2)

The dimensions emin and m for use in 6.2.4 should be determined from Figure 6.8.

(3)

The effective length of equivalent T-stub flange should be determined for the individual bolt-rows and the bolt-group in accordance with 6.2.4.2 from the values given for each bolt-row in Table 6.4.

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EN 1993-1-8 : 2005 (E)

rc

0,8 rc

m

e

e min

a) Welded end-plate narrower than column flange.

rc

0,8 rc

m

e min

b) Welded end-plate wider than column flange.

rc

0,8 rc

m

e

e min

c) Angle flange cleats.

Figure 6.8: Definitions of e, emin, rc and m Table 6.4: Effective lengths for an unstiffened column flange Bolt-row Location

Bolt-row considered individually Circular patterns Non-circular patterns Ɛeff,cp Ɛeff,nc

Bolt-row considered as part of a group of bolt-rows Circular patterns Non-circular patterns Ɛeff,cp Ɛeff,nc

Inner bolt-row

2ʌm

2p

End bolt-row

The smaller of: 2ʌm ʌm + 2e1

Mode 1:

Ɛeff,1 = Ɛeff,nc

Mode 2:

Ɛeff,2 = Ɛeff,nc

4m + 1,25e The smaller of: 4m + 1,25e 2m + 0,625e + e1 but

Ɛeff,1 ” Ɛeff,cp

p

The smaller of: ʌm + p 2e1 + p ™Ɛeff,1 = ™Ɛeff,nc

The smaller of: 2m + 0,625e + 0,5p e1 + 0,5p but

™Ɛeff,1 ” ™Ɛeff,cp

™Ɛeff,2 = ™Ɛeff,nc

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6.2.6.4.2 Stiffened column flange, joint with bolted end-plate or flange cleats (1)

Transverse stiffeners and/or appropriate arrangements of diagonal stiffeners may be used to increase the design resistance of the column flange in bending.

(2)

The design resistance and failure mode of a stiffened column flange in transverse bending, together with the associated bolts in tension, should be taken as similar to those of an equivalent T-stub flange, see 6.2.4, for both:

(3)



each individual bolt-row required to resist tension;



each group of bolt-rows required to resist tension.

The groups of bolt-rows on either side of a stiffener should be modelled as separate equivalent T-stub flanges, see Figure 6.9. The design resistance and failure mode should be determined separately for each equivalent T-stub.

1 2 3 4

End bolt row adjacent to a stiffener End bolt row Inner bolt row Bolt row adjacent to a stiffener

Figure 6.9: Modelling a stiffened column flange as separate T-stubs (4)

The dimensions emin and m for use in 6.2.4 should be determined from Figure 6.8.

(5)

The effective lengths of an equivalent T-stub flange Ɛeff should be determined in accordance with 6.2.4.2 using the values for each bolt-row given in Table 6.5. The value of Į for use in Table 6.5 should be obtained from Figure 6.11.

(6)

The stiffeners should meet the requirements specified in 6.2.6.1.

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Table 6.5: Effective lengths for a stiffened column flange Bolt-row considered individually Circular patterns Non-circular Ɛeff,cp patterns Ɛeff,nc

Bolt-row Location Bolt-row adjacent to a stiffener Other inner bolt-row

2ʌm

Įm

2ʌm

4m + 1,25e

2p

p

End bolt-row adjacent to a stiffener

The smaller of: 2ʌm ʌm + 2e1 The smaller of: 2ʌm ʌm + 2e1

For Mode 1:

Ɛeff,1 = Ɛeff,nc but Ɛeff,1 ” Ɛeff,cp

™Ɛeff,1 = ™Ɛeff,nc but ™Ɛeff,1 ” ™Ɛeff,cp

For Mode 2:

Ɛeff,2 = Ɛeff,nc

™Ɛeff,2 = ™Ɛeff,nc

Other end bolt-row

The smaller of: 4m + 1,25e 2m + 0,625e + e1

Bolt-row considered as part of a group of bolt-rows Circular patterns Non-circular patterns Ɛeff,cp Ɛeff,nc 0,5p + Įm ʌm + p í (2m + 0,625e)

e1 + Įm í (2m + 0,625e)

The smaller of: ʌm + p 2e1 + p

The smaller of: 2m + 0,625e + 0,5p e1 + 0,5p

not relevant

not relevant

Į should be obtained from Figure 6.11.

6.2.6.4.3 Unstiffened column flange, welded connection (1)

In a welded joint, the design resistance Ffc,Rd of an unstiffened column flange in bending, due to tension or compression from a beam flange, should be obtained using: Ffc,Rd = beff ,b , fc t fb f J , fb / J M 0

... (6.20)

where: beff,b,fc is the effective breath beff defined in 4.10 where the beam flange is considered as a plate. NOTE: See also the requirements specified in 4.10(4) and 4.10(6). 6.2.6.5 (1)

End-plate in bending

The design resistance and failure mode of an end-plate in bending, together with the associated bolts in tension, should be taken as similar to those of an equivalent T-stub flange, see 6.2.4 for both: –

each individual bolt-row required to resist tension;



each group of bolt-rows required to resist tension.

(2)

The groups of bolt-rows either side of any stiffener connected to the end-plate should be treated as separate equivalent T-stubs. In extended end-plates, the bolt-row in the extended part should also be treated as a separate equivalent T-stub, see Figure 6.10. The design resistance and failure mode should be determined separately for each equivalent T-stub.

(3)

The dimension emin required for use in 6.2.4 should be obtained from Figure 6.8 for that part of the end-plate located between the beam flanges. For the end-plate extension emin should be taken as equal to ex , see Figure 6.10.

(4)

The effective length of an equivalent T-stub flange Ɛeff should be determined in accordance with 6.2.4.2 using the values for each bolt-row given in Table 6.6. 79

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(5)

The values of m and mx for use in Table 6.6 should be obtained from Figure 6.10.

e

e

The extension of the end-plate and the portion between the beam flanges are modelled as two separate equivalent T-stub flanges. For the end-plate extension, use ex and mx in place of e and m when determining the design resistance of the equivalent T-stub flange.

p

Figure 6.10: Modelling an extended end-plate as separate T-stubs Table 6.6: Effective lengths for an end-plate Bolt-row considered individually Circular patterns Non-circular patterns Ɛeff,cp Ɛeff,nc Smallest of: Smallest of: 4mx + 1,25ex Bolt-row outside 2ʌmx tension flange e+2mx+0,625ex ʌmx + w of beam 0,5bp ʌmx + 2e 0,5w+2mx+0,625ex First bolt-row 2ʌm Įm below tension flange of beam Other inner 2ʌm 4m + 1,25 e bolt-row Other end 2ʌm 4m + 1,25 e bolt-row

Bolt-row considered as part of a group of bolt-rows Circular patterns Non-circular Ɛeff,cp patterns Ɛeff,nc

Mode 1:

Ɛeff,1 = Ɛeff,nc but Ɛeff,1 ” Ɛeff,cp

™Ɛeff,1 = ™Ɛeff,nc but ™Ɛeff,1 ” ™Ɛeff,cp

Mode 2:

Ɛeff,2 = Ɛeff,nc

™Ɛeff,2 = ™Ɛeff,nc

Bolt-row location

Į should be obtained from Figure 6.11.

80





ʌm + p

0,5p + Įm í (2m + 0,625e)

2p

p

ʌm + p

2m+0,625e+0,5p

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Figure 6.11: Values of Į for stiffened column flanges and end-plates 6.2.6.6

Flange cleat in bending

(1)

The design resistance and failure mode of a bolted angle flange cleat in bending, together with the associated bolts in tension, should be taken as similar to those of an equivalent T-stub flange, see 6.2.4.

(2)

The effective length Ɛeff of the equivalent T-stub flange should be taken as 0,5ba where ba is the length of the angle cleat, see Figure 6.12.

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(3)

The dimensions emin and m for use in 6.2.4 should be determined from Figure 6.13.

Figure 6.12: Effective length Ɛeff of an angle flange cleat

a) Gap g ” 0,4 ta Notes:

b) Gap g > 0,4 ta

-

The number of bolt-rows connecting the cleat to the column flange is limited to one;

-

The number of bolt-rows connecting the cleat to the beam flange is not limited;

-

The length ba of the cleat may be different from both the width of the beam flange and the width of the column flange.

Figure 6.13: Dimensions emin and m for a bolted angle cleat 6.2.6.7 (1)

Beam flange and web in compression

The resultant of the design compression resistance of a beam flange and the adjacent compression zone of the beam web, may be assumed to act at the level of the centre of compression, see 6.2.7. The design compression resistance of the combined beam flange and web is given by the following expression: Fc,fb,Rd = Mc,Rd / ( h í tfb )

... (6.21)

where: h

is the depth of the connected beam;

Mc,Rd is the design moment resistance of the beam cross-section, reduced if necessary to allow for shear, see EN 1993-1-1. For a haunched beam Mc,Rd may be calculated neglecting the intermediate flange. tfb 82

is the flange thickness of the connected beam.

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If the height of the beam including the haunch exceeds 600 mm the contribution of the beam web to the design compression resistance should be limited to 20%. (2)

(3)

If a beam is reinforced with haunches they should be arranged such that: –

the steel grade of the haunch should match that of the member;



the flange size and the web thickness of the haunch should not be less than that of the member;



the angle of the haunch flange to the flange of the member should not be greater than 45°;



the length of stiff bearing ss should be taken as equal to the thickness of the haunch flange parallel to the beam.

If a beam is reinforced with haunches, the design resistance of beam web in compression should be determined according to 6.2.6.2.

6.2.6.8 (1)

Beam web in tension

In a bolted end-plate connection, the design tension resistance of the beam web should be obtained from: Ft,wb,Rd = beff ,t , wb t wb f y , wb / J M 0

(2)

... (6.22)

The effective width beff,t,wb of the beam web in tension should be taken as equal to the effective length of the equivalent T-stub representing the end-plate in bending, obtained from 6.2.6.5 for an individual bolt-row or a bolt-group.

6.2.6.9

Concrete in compression including grout

(1)

The design bearing strength of the joint between the base plate and its concrete support should be determined taking account of the material properties and dimensions of both the grout and the concrete support. The concrete support should be designed according to EN 1992.

(2)

The design resistance of concrete in compression, including grout, together with the associated base plate in bending Fc,pl,Rd, should be taken as similar to those of an equivalent T-stub, see 6.2.5.

6.2.6.10 Base plate in bending under compression (1)

The design resistance of a base plate in bending under compression, together with concrete slab on which the column base is placed Fc,pl,Rd, should be taken as similar to those of an equivalent T-stub, see 6.2.5.

6.2.6.11 Base plate in bending under tension (1)

The design resistance and failure mode of a base plate in bending under tension, together with the associated anchor bolts in tension Ft,pl,Rd, may be determined using the rules given in 6.2.6.5.

(2)

In the case of base plates prying forces which may develop should not be taken into consideration.

6.2.6.12 Anchor bolt in tension (1)

Anchor bolts should be designed to resist the effects of the design loads. They should provide design resistance to tension due to uplift forces and bending moments where appropriate.

(2)

When calculating the tension forces in the anchor bolts due to bending moments, the lever arm should not be taken as more than the distance between the centroid of the bearing area on the compression side and the centroid of the bolt group on the tension side. NOTE: Tolerances on the positions of the anchor bolts may have an influence. 83

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(3)

The design resistance of the anchor bolts should be taken as the smaller of the design tension resistance of the anchor bolt, see 3.6, and the design bond resistance of the concrete on the anchor bolt according to EN 1992-1-1.

(4)

One of the following methods should be used to secure anchor bolts into the foundation: –

a hook (Figure 6.14(a)),



a washer plate (Figure 6.14(b)),



some other appropriate load distributing member embedded in the concrete,



some other fixing which has been adequately tested and approved.

(5)

When the bolts are provided with a hook, the anchorage length should be such as to prevent bond failure before yielding of the bolt. The anchorage length should be calculated in accordance with EN 1992-1-1. This type of anchorage should not be used for bolts with a yield strength fyb higher than 300 N/mm2.

(6)

When the anchor bolts are provided with a washer plate or other load distributing member, no account should be taken of the contribution of bond. The whole of the force should be transferred through the load distributing device.

1 Base plate 2 Grout 3 Concrete foundation

(a) Hook

(b) Washer plate

Figure 6.14: Fixing of anchor bolts 6.2.7

Design moment resistance of beam-to-column joints and splices

6.2.7.1 (1)

General

The applied design moment Mj,Ed should satisfy:

M j , Ed M j , Rd

84

” 1,0

... (6.23)

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(2)

The methods given in 6.2.7 for determining the design moment resistance of a joint Mj,Rd do not take account of any co-existing axial force NEd in the connected member. They should not be used if the axial force in the connected member exceeds 5% of the design plastic resistance NpƐ,Rd of its crosssection.

(3)

If the axial force NEd in the connected beam exceeds 5% of the design resistance, Npl,Rd , the following conservative method may be used:

M j , Ed M j , Rd



N j , Ed N j , Rd

” 1,0

... (6.24)

where: Mj.Rd is the design moment resistance of the joint, assuming no axial force; Nj.Rd is the axial design resistance of the joint, assuming no applied moment. (4)

The design moment resistance of a welded joint should be determined as indicated in Figure 6.15(a).

(5)

The design moment resistance of a bolted joint with a flush end-plate that has only one bolt-row in tension (or in which only one bolt-row in tension is considered, see 6.2.3(6)) should be determined as indicated in Figure 6.15(c).

(6)

The design moment resistance of a bolted joint with angle flange cleats should be determined as indicated in Figure 6.15(b).

(7)

The design moment resistance of a bolted end-plate joint with more than one row of bolts in tension should generally be determined as specified in 6.2.7.2.

(8)

As a conservative simplification, the design moment resistance of an extended end-plate joint with only two rows of bolts in tension may be approximated as indicated in Figure 6.16, provided that the total design resistance FRd does not exceed 3,8Ft,Rd , where Ft,Rd is given in Table 6.2. In this case the whole tension region of the end-plate may be treated as a single basic component. Provided that the two bolt-rows are approximately equidistant either side of the beam flange, this part of the endplate may be treated as a T-stub to determine the bolt-row force F1,Rd . The value of F2,Rd may then be assumed to be equal to F1,Rd , and so FRd may be taken as equal to 2F1,Rd .

(9)

The centre of compression should be taken as the centre of the stress block of the compression forces. As a simplification the centre of compression may be taken as given in Figure 6.15.

(10) A splice in a member or part subject to tension should be designed to transmit all the moments and forces to which the member or part is subjected at that point. (11) Splices should be designed to hold the connected members in place. Friction forces between contact surfaces may not be relied upon to hold connected members in place in a bearing splice. (12) Wherever practicable the members should be arranged so that the centroidal axis of any splice material coincides with the centroidal axis of the member. If eccentricity is present then the resulting forces should be taken into account.

85

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Type of connection a)

Welded connection

Centre of compression In line with the mid thickness of the compression flange

Lever arm

Force distributions

z = h - tfb h is the depth of the connected beam tfb is the thickness of the beam flange

b) Bolted connection with angle flange cleats

In line with the mid-thickness of the leg of the angle cleat on the compression flange

Distance from the centre of compression to the bolt-row in tension

c) Bolted end-plate connection with only one bolt-row active in tension

In line with the mid-thickness of the compression flange

Distance from the centre of compression to the bolt-row in tension

d) Bolted extended end-plate connection with only two bolt-rows active in tension

In line with the mid-thickness of the compression flange

Conservatively z may be taken as the distance from the centre of compression to a point midway between these two bolt-rows

e) Other bolted end-plate connections with two or more boltrows in tension

In line with the mid-thickness of the compression flange

An approximate value may be obtained by taking the distance from the centre of compression to a point midway between the farthest two boltrows in tension

A more accurate value may be determined by taking the lever arm z as equal to zeq obtained using the method given in 6.3.3.1.

Figure 6.15: Centre of compression, lever arm z and force distributions for deriving the design moment resistance Mj,Rd 86

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Figure 6.16: Simplified models for bolted joints with extended end-plates (13) Where the members are not prepared for full contact in bearing, splice material should be provided to transmit the internal forces and moments in the member at the spliced section, including the moments due to applied eccentricity, initial imperfections and second-order deformations. The internal forces and moments should be taken as not less than a moment equal to 25% of the moment capacity of the weaker section about both axes and a shear force equal to 2.5% of the normal force capacity of the weaker section in the directions of both axes. (14) Where the members are prepared for full contact in bearing, splice material should be provided to transmit 25% of the maximum compressive force in the column. (15) The alignment of the abutting ends of members subjected to compression should be maintained by cover plates or other means. The splice material and its fastenings should be proportioned to carry forces at the abutting ends, acting in any direction perpendicular to the axis of the member. In the design of splices the second order effects should also be taken into account. (16) Splices in flexural members should comply with the following: a)

Compression flanges should be treated as compression members;

b)

Tension flanges should be treated as tension members;

c)

Parts subjected to shear should be designed to transmit the following effects acting together:

6.2.7.2 (1)



the shear force at the splice;



the moment resulting from the eccentricity, if any, of the centroids of the groups of fasteners on each side of the splice;



the proportion of moment, deformation or rotations carried by the web or part, irrespective of any shedding of stresses into adjoining parts assumed in the design of the member or part.

Beam-to-column joints with bolted end-plate connections

The design moment resistance Mj,Rd of a beam-to-column joint with a bolted end-plate connection may be determined from: Mj,Rd =

6h

r

Ftr , Rd

... (6.25)

r

where: Ftr,Rd is the effective design tension resistance of bolt-row r ; hr

is the distance from bolt-row r to the centre of compression;

r

is the bolt-row number.

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NOTE: In a bolted joint with more than one bolt-row in tension, the bolt-rows are numbered starting from the bolt-row farthest from the centre of compression. (2)

For bolted end-plate connections, the centre of compression should be assumed to be in line with the centre of the compression flange of the connected member.

(3)

The effective design tension resistance Ftr,Rd for each bolt-row should be determined in sequence, starting from bolt-row 1, the bolt-row farthest from the centre of compression, then progressing to bolt-row 2, etc.

(4)

When determining the effective design tensin resistance Ftr,Rd for bolt-row r the effective design tension resistance of all other bolt-rows closer to the centre of compression should be ignored.

(5)

The effective design tension resistance Ftr,Rd of bolt-row r should be taken as its design tension resistance Ft,Rd as an individual bolt-row determined from 6.2.7.2(6), reduced if necessary to satisfy the conditions specified in 6.2.7.2(7), (8) and (9).

(6)

The effective design tension resistance Ftr,Rd of bolt-row r ,taken as an individual bolt-row, should be taken as the smallest value of the design tension resistance for an individual bolt-row of the following basic components:

(7)

(8)

(9)



the column web in tension

Ft,wc,Rd

-

see 6.2.6.3;



the column flange in bending

Ft,fc,Rd

-

see 6.2.6.4;



the end-plate in bending

Ft,ep,Rd

-

see 6.2.6.5;



the beam web in tension

Ft,wb,Rd

-

see 6.2.6.8.

The effective design tension resistance Ftr,Rd of bolt-row r should, if necessary, be reduced below the value of Ft,Rd given by 6.2.7.2(6) to ensure that, when account is taken of all bolt-rows up to and including bolt-row r the following conditions are satisfied: –

the total design resistance ™Ft,Rd ” Vwp,Rd /ȕ - with ȕ from 5.3(7)



the total design resistance ™Ft,Rd does not exceed the smaller of:

see 6.2.6.1;



the design resistance of the column web in compression Fc,wc,Rd

-

see 6.2.6.2;



the design resistance of the beam flange and web in compression Fc, fb,Rd -

see 6.2.6.7.

The effective design tension resistance Ftr,Rd of bolt-row r should, if necessary, be reduced below the value of Ft,Rd given by 6.2.7.2(6), to ensure that the sum of the design resistances taken for the bolt-rows up to and including bolt-row r that form part of the same group of bolt-rows, does not exceed the design resistance of that group as a whole. This should be checked for the following basic components: –

the column web in tension

Ft,wc,Rd

-

see 6.2.6.3;



the column flange in bending

Ft,fc,Rd

-

see 6.2.6.4;



the end-plate in bending

Ft,ep,Rd

-

see 6.2.6.5;



the beam web in tension

Ft,wb,Rd

-

see 6.2.6.8.

Where the effective design tension resistance Ftx,Rd of one of the previous bolt-rows x is greater than 1,9 Ft,Rd , then the effective design tension resistance Ftr,Rd for bolt-row r should be reduced, if necessary, in order to ensure that: Ftr,Rd ” Ftx,Rd hr / hx where: hx

88

-

is

the distance from bolt-row x to the centre of compression;

... (6.26)

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x

is the bolt-row farthest from the centre of compression that has a design tension resistance greater than 1,9 Ft,Rd .

NOTE: The National Annex may give further information on the use of equation (6.26). (10) The method described in 6.2.7.2(1) to 6.2.7.2(9) may be applied to a bolted beam splice with welded end-plates, see Figure 6.17, by omitting the items relating to the column.

Figure 6.17: Bolted beam splices with welded end-plates 6.2.8

Design resistance of column bases with base plates

6.2.8.1

General

(1)

Column bases should be of sufficient size, stiffness and strength to transmit the axial forces, bending moments and shear forces in columns to their foundations or other supports without exceeding the load carrying capacity of these supports.

(2)

The design bearing strength between the base plate and its support may be determined on the basis of a uniform distribution of compressive force over the bearing area. For concrete foundations the bearing stress should not exceed the design bearing strength, fjd , given in 6.2.5(7).

(3)

For a column base subject to combined axial force and bending the forces between the base plate and its support can take one of the following distribution depending on the relative magnitude of the applied axial force and bending moment: –

In the case of a dominant compressive axial force, full compression may develop under both column flanges as shown in Figure 6.18(a).



In the case of a dominant tensile force, full tension may develop under both flanges as shown in Figure 6.18(b).



In the case of a dominant bending moment compression may develop under one column flange and tension under the other as shown in Figure 6.18(c) and Figure 6.18(d).

(4)

Base plates should be designed using the appropriate methods given in 6.2.8.2 and 6.2.8.3.

(5)

One of the following methods should be used to resist the shear force between the base plate and its support: –

Frictional design resistance at the joint between the base plate and its support.



The design shear resistance of the anchor bolts.



The design shear resistance of the surrounding part of the foundation.

If anchor bolts are used to resist the shear forces between the base plate and its support, rupture of the concrete in bearing should also be checked, according to EN 1992. 89

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Where the above methods are inadequate special elements such as blocks or bar shear connectors should be used to transfer the shear forces between the base plate and its support. =

=

= NEd

= NEd

MEd

MEd

zC,r

zC,l

zT,r

zT,l

z

z

a) Column base connection in case of a dominant compressive normal force

b) Column base connection in case of a dominant tensile normal force

=

=

=

NEd

= NEd

MEd

MEd

zT,r

zC,l

zC,r

zT,l

z

z

c) Column base connection in case of a dominant bending moment

d) Column base connection in case of a dominant bending moment

Figure 6.18: Determination of the lever arm z for column base connections 6.2.8.2 (1)

Column bases only subjected to axial forces

The design resistance, Nj,Rd ,of a symmetric column base plate subject to an axial compressive force applied concentrically may be determined by adding together the individual design resistance FC,Rd of the three T-stubs shown in Figure 6.19 (Two T-stubs under the column flanges and one T-stub under the column web.) The three T-stubs should not be overlapping, see Figure 6.19. The design resistance of each of these T-stubs should be calculated using the method given in 6.2.5. 1 T-stub 1 2 T-stub 2 3 T-stub 3

2 1

3

Figure 6.19: Non overlapping T-stubs 6.2.8.3 (1)

90

Column bases subjected to axial forces and bending moments

The design moment resistance Mj,Rd of a column base subject to combined axial force and moment should be determined using the method given in Table 6.7 where the contribution of the concrete portion just under the column web (T-stub 2 of Figure 6.19) to the compressive capacity is omitted. The following parameters are used in this method: –

FT,l,Rd is the design tension resistance of the left hand side of the joint

-

see 6.2.8.3(2)



FT,r,Rd is the design tension resistance of the right hand side of the joint

-

see 6.2.8.3(3)



FC,l,Rd is the design compressive resistance of the left hand side of the joint

-

see 6.2.8.3(4)



FC,r,Rd is the design compressive resistance of the right hand side of the joint -

see 6.2.8.3(5)

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(2)

(3)

(4)

(5)

(6)

The design tension resistance FT,l,Rd of the left side of the joint should be taken as the smallest values of the design resistance of following basic components: –

the column web in tension under the left column flange

Ft,wc,Rd

-

see 6.2.6.3;



the base plate in bending under the left column flange

Ft,pl,Rd

-

see 6.2.6.11.

The design tension resistance FT,r,Rd of the right side of the joint should be taken as the smallest values of the design resistance of following basic components: –

the column web in tension under the right column flange

Ft,wc,Rd

-

see 6.2.6.3;



the base plate in bending under the right column flange

Ft,pl,Rd

-

see 6.2.6.11.

The design compressive resistance FC,l,Rd of the left side of the joint should be taken as the smallest values of the design resistance of following basic components: –

the concrete in compression under the left column flange

Fc,pl,Rd

-

see 6.2.6.9;



the left column flange and web in compression

Fc,fc,Rd

-

see 6.2.6.7.

The design compressive resistance FC,r,Rd of the right side of the joint should be taken as the smallest values of the design resistance of following basic components: –

the concrete in compression under the right column flange Fc,pl,Rd

-

see 6.2.6.9;



the right column flange and web in compression

-

see 6.2.6.7.

Fc,fc,Rd

For the calculation of zT,l, zC,l, zT,r, zC,r see 6.2.8.1.

Table 6.7: Design moment resistance Mj,Rd of column bases Loading

Lever arm z

Design moment resistance Mj,Rd

Left side in tension Right side in compression

z = zT,l + zC,r

NEd > 0 and

e > zT,l

The smaller of Left side in tension Right side in tension

z = zT,l + zT,r

0 < e < zT,l

z = zC,l + zT,r

z = zC,l + zC,r

NEd > 0 and

NEd > 0 and

FT ,r , Rd z

FT ,1, Rd z

zT ,1 / e  1

zT ,r / e  1

e ” -zT,r

 FC ,1, Rd z

NEd ” 0 and

z C ,r / e  1

-zT,r < e ” 0

zT ,r / e  1

and

0 < e < zC,l

and

and

NEd ” 0 and

The smaller of

 FC ,1, Rd z

zT ,1 / e  1 The smaller of

and

The smaller of

e ” -zC,r

 FC ,r , Rd z

and

The smaller of

zT ,r / e  1

Left side in compression Right side in compression

z C ,r / e  1

NEd > 0 and

FT ,1, Rd z Left side in compression Right side in tension

FT ,1, Rd z

NEd ” 0 and

FT ,1, Rd z zT ,1 / e  1 e > zC,l

FT ,r , Rd z z C ,1 / e  1

NEd ” 0 and

-zC,r < e ” 0

The smaller of

 FC ,r , Rd z

 FC ,1, Rd z

z C ,1 / e  1

z C ,r / e  1

and

 FC ,r , Rd z z C ,1 / e  1

MEd > 0 is clockwise, NEd > 0 is tension

e=

M Rd M Ed = N Ed N Rd

91

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6.3 Rotational stiffness 6.3.1 (1)

Basic model The rotational stiffness of a joint should be determined from the flexibilities of its basic components, each represented by an elastic stiffness coefficient ki obtained from 6.3.2. NOTE: These elastic stiffness coefficients are for general application.

(2)

For a bolted end-plate joint with more than one row of bolts in tension, the stiffness coefficients ki for the related basic components should be combined. For beam-to-column joints and beam splices a method is given in 6.3.3 and for column bases a method is given in 6.3.4.

(3)

In a bolted end plate joint with more than one bolt-row in tension, as a simplification the contribution of any bolt-row may be neglected, provided that the contributions of all other bolt-rows closer to the centre of compression are also neglected. The number of bolt-rows retained need not necessarily be the same as for the determination of the design moment resistance.

(4)

Provided that the axial force NEd in the connected member does not exceed 5% of the design resistance NpƐ,Rd of its cross-section, the rotational stiffness Sj of a beam-to-column joint or beam splice, for a moment Mj,Ed less than the design moment resistance Mj,Rd of the joint, may be obtained with sufficient accuracy from:

Ez 2

Sj =

P

1 ¦i k i

... (6.27)

where: ki

is

the stiffness coefficient for basic joint component i ;

z

is

the lever arm, see 6.2.7;

μ

is

the stiffness ratio Sj,ini / Sj , see 6.3.1(6).

NOTE: The initial rotational stiffness Sj,ini of the joint is given by expression (6.27) with μ = 1,0. (5)

The rotational stiffness Sj of a column base, for a moment Mj,Ed less than the design moment resistance Mj,Rd of the joint, may be obtained with sufficient accuracy from 6.3.4.

(6)

The stiffness ratio μ should be determined from the following: –



if Mj,Ed ” 2/3 Mj,Rd : μ = 1

... (6.28a)

if 2/3 Mj,Rd < Mj,Ed ” Mj,Rd : μ = (1,5M j , Ed / M j , Rd ) 0 (compression):



ȕ • 0,4

where ȕ = bi /d0

110

and

Ș”4

kp = 1 í 0,3 np (1 + np)

and

Ș = hi /d0

For np ” 0 (tension):

but

kp ” 1,0 kp = 1,0

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Table 7.4: Design resistances of welded joints connecting I, H or RHS sections to CHS members Chord face failure

h1

b1 t0

d0

N1,Rd = kp fy0 t02 (4 + 20ȕ2)(1 + 0,25Ș) / JM5 Mip,1,Rd = h1 N1,Rd/(1 + 0,25Ș) Mop,1,Rd = 0,5 b1 N1,Rd

N1 h1

N1 N1,Rd =

t0

d0

2

1  0,81E

1  0,25K / J M 5

Mip,1,Rd = h1 N1,Rd/(1 + 0,25Ș) Mop,1,Rd = 0,5 b1 N1,Rd

N1

h1

5k p f y 0 t 0

b1 t0

d0

N1,Rd = kp fy0 t02 (4 + 20ȕ2)(1 + 0,25Ș)/ JM5 Mip,1,Rd = h1 N1,Rd Mop,1,Rd = 0,5 b1 N1,Rd

N1 h1

N1 N1,Rd =

t0

d0

5k p f y 0 t 02 1  0,81E

1  0,25K / J M 5

Mip,1,Rd = h1 N1,Rd

N1

Mop,1,Rd = 0,5 b1 N1,Rd

Punching shear failure I or H sections:

V max t1 = N Ed / A  M Ed / Wel t 1 ” 2t 0 ( f y 0 / 3 ) / J M 5

RHS sections:

V max t1 = N Ed / A  M Ed / Wel t 1 ” t 0 ( f y 0 / 3) / J M 5

Range of validity

Factor kp

In addition to the limits given in Table 7.1:

For np > 0 (compression):



ȕ • 0,4

where ȕ = b1 / d0

and

Ș”4

kp = 1 í 0,3 np (1 + np)

and

Ș = h1 / d0

For np ” 0 (tension):

but

kp ” 1,0 kp = 1,0

111

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(3)

The design internal moment Mi,Ed may be taken as the value at the point where the centreline of the brace member meets the face of the chord member.

(4)

The design in-plane moment resistance and the design out-of-plane moment resistance Mi,Rd should be obtained from Table 7.3, Table 7.4 or Table 7.5 as appropriate.

(5)

The special types of welded joints indicated in Table 7.6 should satisfy the appropriate design criteria specified for each type in that table.

(6)

Values of the factor kg which is used in Table 7.2 for K, N and KT joints are given in Figure 7.6. The factor kg is used to cover both gap type and overlap type joints by adopting g for both the gap and the overlap and using negative values of g to represent the overlap q as defined in Figure 1.3(b).

kg

4.5 , 4.0 , 3.5 , 3.0 , 2.5 , 2.0 ,

J = 25 J = 22,5 J = 20 J = 17,5 J = 15 J = 12,5 J = 10 J = 7,5

1.5 ,

, 1.0

-12

-8

-4

Overlap type joints (q = -g)

0

4

8

g / t0

12

Gap type joints

Figure 7.6: Values of the factor kg for use in Table 7.2

112

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Table 7.5: Design resistance moments of welded joints between CHS brace members and CHS chords Chord face failure -

T, X, and Y joints

Mip,1 d1 Mip,1,Rd = 4,85

T1

f y 0 t 02 d1

t0

sin T 1

J Ek p / J M 5

d0 Chord face failure -

K, N, T, X and Y joints

Mop,1 d1 Mop,1,Rd =

T1

t0

f y 0 t 02 d1 sin T 1

2,7 kp /J M5 1  0,81E

d0 Punching shear failure - K and N gap joints and all T, X and Y joints When d1 ” d0 í 2t0 : Mip,1,Rd =

f y 0 t 0 d12 1  3 sin T 1 /J M5 4 sin 2 T 1 3

f y 0 t 0 d12 3  sin T 1 Mop,1,Rd = /J M5 2 3 4 sin T 1 Factor kp For np > 0 (compression): For np ” 0 (tension):

kp = 1 í 0,3 np (1 + np ) kp = 1,0

but

kp ” 1,0

113

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Table 7.6: Design criteria for special types of welded joints between CHS brace members and CHS chords Type of joint

Design criteria

The forces may be either tension or compression but should act in the same direction for both members. N1,Ed ” N1,Rd where N1,Rd is the value of N1,Rd for an X joint from Table 7.2.

Member 1 is always in compression and member 2 is always in tension.

N3

N1 T1

N1,Ed sin ș1 + N3,Ed sin ș3 ” N1,Rd sin ș1 N2,Ed sin ș2 ” N1,Rd sin ș1

N2 T3

where N1,Rd is the value of N1,Rd for a K joint from Table 7.2 but with

T2

d  d2  d3 d1 replaced by: 1 d0 3d 0

All bracing members should always be in either compression or tension. N1,Ed sin ș1 + N2,Ed sin ș2 ” Nx,Rd sin șx where Nx,Rd is the value of Nx,Rd for an X joint from Table 7.2, where Nx,Rd sin șx is the larger of: ŇN1,Rd sin ș1Ň and ŇN2,Rd sin ș2Ň

Member 1 is always in compression and member 2 is always in tension.

Ni,Ed ” Ni,Rd where Ni,Rd is the value of Ni,Rd for a K joint from Table 7.2, provided that, in a gap-type joint, at section 1-1 the chord satisfies: 2

2

ª N 0,Ed º ª V0,Ed º » ” 1,0 « » « ¬« N pl , 0,Rd ¼» «¬V pl ,0,Rd ¼»

114

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7.4.3

Multiplanar joints

(1)

In each relevant plane of a multiplanar joint, the design criteria given in 7.4.2 should be satisfied using the reduced design resistances obtained from 7.4.3(2).

(2)

The design resistances for each relevant plane of a multiplanar joint should be determined by applying the appropriate reduction factor μ given in Table 7.7 to the resistance of the corresponding uniplanar joint calculated according to 7.4.2 by using the appropriate chord force for kp .

Table 7.7: Reduction factors for multiplanar joints Type of joint

Reduction factor μ

TT joint

60° ” ij ” 90°

Member 1 may be either tension or compression.

μ = 1,0

XX joint Members 1 and 2 can be either in compression or tension. N2,Ed/N1,Ed is negative if one member is in tension and one in compression. μ = 1  0,33 N 2, Ed / N 1, Ed taking account of the sign of N1,Ed and N2,Ed where ŇN2,EdŇ ” ŇN1,EdŇ

KK joint Member 1 is always in compression and member 2 is always in tension.

60° ” ij ” 90°

μ = 0,9 provided that, in a gap-type joint, at section 1-1 the chord satisfies: 2

2

ª N 0,Ed º ª V0,Ed º » ” 1,0 « » « «¬ N pl , 0,Rd »¼ «¬V pl ,0,Rd »¼

115

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7.5 Welded joints between CHS or RHS brace members and RHS chord members 7.5.1

General

(1)

Provided that the geometry of the joints is within the range of validity given in Table 7.8, the design resistances of welded joints between hollow section brace members and rectangular or square hollow section chord members may be determined using 7.5.2 and 7.5.3.

(2)

For joints within the range of validity given in Table 7.8, only the design criteria covered in the appropriate table need be considered. The design resistance of a connection should be taken as the minimum value for all applicable criteria.

(3)

For joints outside the range of validity given in Table 7.8, all the criteria given in 7.2.2 should be considered. In addition, the secondary moments in the joints caused by their rotational stiffness should be taken into account.

Table 7.8: Range of validity for welded joints between CHS or RHS brace members and RHS chord members Joint parameters [ i = 1 or 2, j = overlapped brace ] Type of joint

bi /b0 or di /b0

bi /ti and hi /ti or di /ti Compression Tension

h0 /b0 and hi /bi

b0 /t0 and h0 /t0

Gap or overlap bi /bj

” 35 T, Y or X

bi /b0 • 0,25

bi /ti ” 35

and

and hi /ti ” 35 K gap N gap

bi /b0 • 0,35 and • 0,1 + 0,01 b0 /t0

and Class 2

bi /ti ” 35 and hi /ti ” 35

Class 2 • 0,5 but ” 2,0

” 35 and Class 2

K overlap N overlap Circular brace member

bi /b0 • 0,25

Class 1



Class 2

g /b0 • 0,5(1 í ȕ) but ” 1,5(1 í ȕ) 1) and as a minimum g • t1 + t 2 Ȝov • 25% but Ȝov ” 100% 2) and bi /bj • 0,75

di /b0 • 0,4 but ” 0,8

Class 1

di /ti ” 50

As above but with di replacing bi and dj replacing bj .

1)

If g /b0 > 1,5(1 í ȕ) and g /b0 > t1 + t2 treat the joint as two separate T or Y joints.

2)

The overlap may be increased to enable the toe of the overlapped brace to be welded to the chord.

116

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7.5.2

Uniplanar joints

7.5.2.1

Unreinforced joints

(1)

In brace member connections subject only to axial forces, the design internal axial force Ni,Ed should not exceed the design axial resistance of the welded joint Ni,Rd , determined from 7.5.2.1(2) or 7.5.2.1(4) as appropriate.

(2)

For welded joints between square or circular hollow section brace members and square hollow section chord members only, where the geometry of the joints is within the range of validity given in Table 7.8 and also satisfies the additional conditions given in Table 7.9, the design axial resistances may be determined from the expressions given in Table 7.10.

(3)

For joints within the range of validity of Table 7.9, the only design criteria that need be considered are chord face failure and brace failure with reduced effective width. The design axial resistance should be taken as the minimum value for these two criteria. NOTE: The design axial resistances for joints of hollow section brace members to square hollow section chords given in Table 7.10 have been simplified by omitting design criteria that are never critical within the range of validity of Table 7.9.

(4)

The design axial resistances of any unreinforced welded joint between CHS or RHS brace members and RHS chords, within the range of validity of Table 7.8, may be determined using the expressions given in Table 7.10, Table 7.11, Table 7.12 or Table 7.13 as appropriate. For reinforced joints see 7.5.2.2.

Table 7.9: Additional conditions for the use of Table 7.10 Type of brace

Square hollow section

Type of joint T, Y or X

K gap or N gap

Circular hollow section

Joint parameters bi /b0 ” 0,85

0,6 ”

b1  b2 ” 1,3 2b1

T, Y or X

K gap or N gap

b0 /t0 • 10

b0 /t0 • 15

b0 /t0 • 10

0,6 ”

d1  d 2 ” 1,3 2d1

b0 /t0 • 15

117

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Table 7.10: Design axial resistances of welded joints between square or circular hollow section Type of joint

Design resistance [i = 1 or 2, j = overlapped brace]

T, Y and X joints

Chord face failure

N1,Rd =

K and N gap joints

k n f y0t0

ȕ ” 0,85

2

§ 2E · ¨¨  4 1  E ¸¸ / J M 5 1  E sin T1 © sin T 1 ¹

Chord face failure

Ni,Rd =

ȕ ” 1,0

8,9J 0,5 k n f y 0 t 02 § b1  b2 · ¨¨ ¸¸ / J M 5 sin T i © 2b0 ¹

K and N overlap joints *)

Brace failure

Member i or member j may be either tension or compression but one should be tension and the other compression.

Ni,Rd = f yi t i ¨ beff  be ,ov 

25% ” Ȝov < 50%

§

Oov

©

50

2hi  4t i ·¸ / J M 5 ¹

Brace failure

50% ” Ȝov < 80%

>

@

Ni,Rd = f yi t i beff  be ,ov  2hi  4t i / J M 5 Brace failure

Ȝov • 80%

>

@

Ni,Rd = f yi t i bi  be ,ov  2hi  4t i / J M 5 Parameters beff , be,ov and kn

10 f y 0t0 bi b0 / t0 f yi ti

beff =

be,ov =

10 f yj t j bi b j / t j f yi t i

For n > 0 (compression): but beff ” bi

but be,ov ” bi

kn = 1,3  but For n ” 0 (tension):

0,4n

E

kn ” 1,0 kn = 1,0

For circular braces, multiply the above resistances by ʌ/4, replace b1 and h1 by d1 and replace b2 and h2 by d2 . *)

118

Only the overlapping brace member i need be checked. The brace member efficiency (i.e. the design resistance of the joint divided by the design plastic resistance of the brace member) of the overlapped brace member j should be taken as equal to that of the overlapping brace member.

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Table 7.11: Design axial resistances of welded T, X and Y joints between RHS or CHS braces and RHS chords Type of joint

Design resistance [i = 1] Chord face failure Ni,Rd =

ȕ ” 0,85

k n f y 0 t 02

· § 2K ¨¨  4 1  E ¸¸ / J M 5 (1  E ) sin T 1 © sin T 1 ¹

Chord side wall buckling 1) Ni,Rd =

f bt0 sin T i

ȕ = 1,0 2)

§ 2hi · ¨¨  10t 0 ¸¸ / J M 5 © sin T 1 ¹

Brace failure

ȕ • 0,85

Ni,Rd = f yi t i (2hi  4t i  2beff ) / J M 5 Punching shear Ni,Rd =

0,85 ” ȕ ” (1 - 1/Ȗ)

f y0t0

§ 2hi · ¨¨  2be , p ¸¸ / J M 5 3 sin T 1 © sin T 1 ¹

1)

For X joints with ș < 90° use the smaller of this value and the design shear resistance of the chord side walls given for K and N gap joints in Table 7.12. 2)

For 0,85 ” ȕ ” 1,0 use linear interpolation between the value for chord face failure at ȕ = 0,85 and the governing value for chord side wall failure at ȕ = 1,0 (side wall buckling or chord shear).

For circular braces, multiply the above resistances by ʌ/4, replace b1 and h1 by d1 and replace b2 and h2 by d2 . For tension: 10 f y 0t0 fb = fy0 beff = bi but beff ” bi For compression: fb = Ȥ fy0 fb = 0,8 Ȥ fy0 sin și

b0 / t0 f yi ti

(T and Y joints) (X joints)

be,p =

10 bi b0t0

but be.p ” bi

where Ȥ is the reduction factor for flexural buckling obtained from EN 1993-1-1 using the relevant buckling curve and a normalized slenderness O For n > 0 (compression): determined from:

§ h0 · 1 ¨¨  2 ¸¸ sin t Ti ¹ O = 3,46 © 0 E S f y0

but For n ” 0 (tension):

kn = 1,3 

0,4n

E

kn ” 1,0 kn = 1,0

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Table 7.12: Design axial resistances of welded K and N joints between RHS or CHS braces and RHS chords Type of joint K and N gap joints

Design resistance [i = 1 or 2] Chord face failure Ni,Rd =

8,9k n f y 0 t 02 J § b1  b2  h1  h2 · ¨¨ ¸¸ / J M 5 sin T i 4b0 © ¹

Chord shear

f y 0 Av

Ni,Rd =

3 sin T i

/J M5

N0,Rd = ª A 0  A v f y 0  A v f y 0 1  VEd / Vpl , Rd 2 º / J M 5 « » ¬

¼

Brace failure





Ni,Rd = f yi t i 2hi  4t i  bi  beff / J M 5 Punching shear Ni,Rd = K and N overlap joints

ȕ ” (1 - 1/Ȗ)

f y0t0

§ 2hi · ¨¨  bi  be, p ¸¸ / J M 5 3 sin T i © sin T i ¹

As in Table 7.10.

For circular braces, multiply the above resistances by ʌ/4, replace b1 and h1 by d1 and replace b2 and h2 by d2 . Av = (2h0 + Įb0)t0 For a square or rectangular brace member: Į=

1

1 4g 2 3t 0

2

where g is the gap, see Figure 1.3(a). For a circular brace member:

beff =

10 f y 0t0 bi b0 / t0 f yi ti

but beff ” bi

be,p =

10 bi b0t0

but be.p ” bi

For n > 0 (compression): kn = 1,3 

Į=0 but For n ” 0 (tension):

120

kn ” 1,0 kn = 1,0

0,4n

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EN 1993-1-8 : 2005 (E)

Table 7.13: Design resistances of welded joints connecting gusset plates or I or H sections to RHS members Transverse plate

Brace failure [i = 1] *)

N1,Rd = f y1t1beff / J M 5 Chord side wall crushing

bi

N1 ti

t0

when b1 • b0 í 2t0

N1,Rd = f y 0 t 0 (2t1  10t 0 ) / J M 5 h0

Punching shear

b0

N1,Rd = Longitudinal plate

f y0t0 3

when b1 ” b0 í 2t0

2t

 2be, p / J M 5

1

Chord face failure N1 hi ti t0

N1,Rd = h0

k m f y 0 t 02 1  t1 / b0

2h / b 1



 4 1  t1 / b0 / J M 5

0

b0

t1/b0 ” 0,2 I or H section As a conservative approximation, if Ș • 2 1  E , N1,Rd for an I or H section may be assumed to be equal to the design resistance of two transverse plates of similar dimensions to the flanges of the I or H section, determined as specified above. If Ș < 2 1  E , a linear interpolation between one and two plates should be made. Mip,1,Rd = N1,Rd (h1 í t1) Range of validity In addition to the limits given in Table 7.8: 0,5 ” ȕ ” 1,0 b0/t0 ” 30 Parameters beff , be,p and km beff = be,p = )

*

10 f y 0 t 0 b1 b0 / t 0 f y1t1

but beff ” bi

10 b1 b0 / t 0

but be.p ” bi

For n > 0 (compression): but For n ” 0 (tension):

km = 1,3(1  n) km ” 1,0 km = 1,0

Fillet welded connections should be designed in accordance with 4.10. 121

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(5)

Brace member connections subjected to combined bending and axial force should satisfy the following requirement:

N i , Ed N i , Rd



M ip ,i , Ed M ip ,i , Rd



M op ,i , Ed M op ,i , Rd

” 1,0

... (7.4)

where: Mip,i,Rd is the design in-plane moment resistance Mip,i,Ed is the design in-plane internal moment Mop,i,Rd is the design out-of-plane moment resistance Mop,i,Ed is the design out-of-plane internal moment (6)

The design internal moment Mi,Ed may be taken as the value at the point where the centreline of the brace member meets the face of the chord member.

(7)

For unreinforced joints, the design in-plane moment resistance and design out-of-plane moment resistance Mi,Rd should be obtained from Table 7.13 or Table 7.14 as appropriate. For reinforced joints see 7.5.2.2.

(8)

The special types of welded joints indicated in Table 7.15 and Table 7.16 should satisfy the appropriate design criteria specified for each type in that table.

7.5.2.2

Reinforced joints

(1)

Various types of joint reinforcement may be used. The appropriate type depends upon the failure mode that, in the absence of reinforcement, governs the design resistance of the joint.

(2)

Flange reinforcing plates may be used to increase the resistance of the joint to chord face failure, punching shear failure or brace failure with reduced effective width.

(3)

A pair of side plates may be used to reinforce a joint against chord side wall failure or chord shear failure.

(4)

In order to avoid partial overlapping of brace members in a K or N joint, the brace members may be welded to a vertical stiffener.

(5)

Any combinations of these types of joint reinforcement may also be used.

(6)

The grade of steel used for the reinforcement should not be lower than that of the chord member.

(7)

The design resistances of reinforced joints should be determined using Table 7.17 and Table 7.18.

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EN 1993-1-8 : 2005 (E)

Table 7.14: Design resistance moments of welded joints between RHS brace members and RHS chords T and X joints In-plane moments (ș = 90°)

Design resistance Chord face failure

ȕ ” 0,85

§ 1 2 K ·¸ /J M5   ¨ 2K 1  E 1  E ¸¹ ©

Mip,1,Rd = k n f y 0 t 02 h1 ¨

Chord side wall crushing

0,85 ” ȕ ” 1,0 2

Mip,1,Rd = 0,5 f yk t 0 h1  5t 0 / J M 5 fyk = fy0 fyk = 0,8 fy0

for T joints for X joints

Brace failure

0,85 ” ȕ ” 1,0





Mip,1,Rd = f y1 Wpl,1  1  b eff / b1 b1 h 1 t 1 / J M 5 Out-of-plane moments (ș = 90°)

Chord face failure

ȕ ” 0,85

§ h1 1  E 2b0 b1 (1  E ) · ¸ /J M5 ¨ 2 1  E  ¸ 1 E  © ¹

Mop,1,Rd = k n f y 0 t 02 ¨

Chord side wall crushing

0,85 ” ȕ ” 1,0

Mop,1,Rd = f yk t 0 (b0  t 0 ) h1  5t 0 / J M 5 fyk = fy0 fyk = 0,8 fy0

for T joints for X joints

Chord distortional failure (T joints only)

*)





Mop,1,Rd = 2 f y 0 t 0 h1t 0  b0 h0 t 0 b0  h0 / J M 5 Brace failure

0,85 ” ȕ ” 1,0



2

2



Mop,1,Rd = f y1 Wpl,1  0,5 1  b eff / b1 b1 t 1 / J M 5 Parameters beff and kn

10 f y 0 t 0 beff = b1 b0 / t 0 f y1t1

For n > 0 (compression): kn = 1,3  but

but beff ” b1 *)

For n ” 0 (tension):

0,4n

E

kn ” 1,0 kn = 1,0

This criterion does not apply where chord distortional failure is prevented by other means.

123

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EN 1993-1-8 : 2005 (E)

Table 7.15: Design criteria for special types of welded joints between RHS brace members and RHS chords Type of joint

Design criteria

The members may be in either tension or compression and should act as in the same direction for both members. N1,Ed ” N1,Rd where N1,Rd is the value of N1,Rd for an X joint from Table 7.11.

The member 1 is always in compression and member 2 is always in tension.

N3

N1 T1

N2 T3

N1,Ed sin ș1 + N3,Ed sin ș3 ” N1,Rd sin ș1 N2,Ed sin ș2 ” N1,Rd sin ș1 where N1,Rd is the value of N1,Rd for a K joint from Table 7.12, but with

T2 replaced by:

b1  b2  h1  h2 4b0

b1  b2  b3  h1  h2  h3 6b0

All bracing members should be either compression or tension. N1,Ed sin ș1 + N2,Ed sin ș2 ” Nx,Rd sin șx where Nx,Rd is the value of Nx,Rd for an X joint from Table 7.11, and Nx,Rd sin șx is the larger of: 

Member 1 is always in compression and member 2 is always in tension.

ŇN1,Rd sin ș1Ň and ŇN2,Rd sin ș2Ň

Ni,Ed ” Ni,Rd where Ni,Rd is the value of Ni,Rd for a K joint from Table 7.12, provided that, in a gap-type joint, at section 1-1 the chord satisfies: 2

2

ª N 0,Ed º ª V0,Ed º « » « » ” 1,0 ¬« N pl , 0,Rd ¼» ¬«V pl ,0,Rd ¼»

124

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EN 1993-1-8 : 2005 (E)

Table 7.16: Design criteria for welded knee joints and cranked-chord joints in RHS members Type of joint

Criteria

Welded knee joints The cross-section should be Class 1 for pure bending, see EN 1993-1-1. NEd ” 0,2NpƐ,Rd and

N Ed M Ed ”ț  N pl , Rd M pl , Rd

3 b0 / h0

If ș ” 90° :

ț=

If 90° < ș ” 180°:

ț = 1

0 ,8

>b0 / t 0 @





1 1  2b0 / h0



2 cos(T / 2) 1  N 90

where ț90 is the value of ț for ș = 90°.

tp • 1,5t

and • 10 mm

N Ed M Ed  ” 1,0 N pl , Rd M pl , Rd

Cranked-chord

i Ni,Ed ” Ni,Rd

j where Ni,Rd is the value of Ni,Rd for a K or N overlap joint from Table 7.12. Imaginary extension of chord

125

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EN 1993-1-8 : 2005 (E)

Table 7.17: Design resistances of reinforced welded T, Y and X joints between RHS or CHS brace members and RHS chords Type of joint

Design resistance [ i = 1 ]

Reinforced with flange plates to avoid chord face failure, brace failure or punching shear. Tension loading

ȕp ” 0,85   and

hi  b p b p  bi  sin T i • 1,5hi / sin T i 

Ɛp •

bp • b0 í 2t0 Ni,Rd =

f yp t 2p

1  b / b sin T i

p

˜… i

§ 2h / b

·

i p ... ˜ ¨¨  4 1  bi / b p ¸¸ / J M 5 © sin T i ¹

Compression loading

ȕp ” 0,85

hi  b p b p  bi sin T i • 1,5hi / sin T i 

Ɛp •

and bp • b0 í 2t0 Take Ni,Rd as the value of Ni,Rd for a T, X or Y joint from Table 7.11, but with kn = 1,0 and t0 replaced by tp for chord face failure, brace failure and punching shear only. Reinforced with side plates to avoid chord side wall buckling or chord side wall shear.

Ɛp • 1,5hi / sin T i  Take Ni,Rd as the value of Ni,Rd for a T, X or Y joint from Table 7.11, but with t0 replaced by (t0 + tp ) for chord side wall buckling failure and chord side wall shear failure only.

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Table 7.18: Design resistances of reinforced welded K and N joints between RHS or CHS brace members and RHS chords Type of joint

Design resistance [i = 1 or 2]

Reinforced with flange plates to avoid chord face failure, brace failure or punching shear.

§ h1 h ·  g  2 ¸¸ sin T 2 ¹ © sin T1

Ɛp • 1,5¨¨

bp • b0 í 2 t0 tp • 2 t1 and 2 t2 Take Ni,Rd as the value of Ni,Rd for a K or N joint from Table 7.12, but with t0 replaced by tp for chord face failure, brace failure and punching shear only. Reinforced with a pair of side plates to avoid chord shear failure.

§ h1 h ·  g  2 ¸¸ sin T 2 ¹ © sin T1

Ɛp • 1,5¨¨

Take Ni,Rd as the value of Ni,Rd for a K or N joint from Table 7.12, but with t0 replaced by ( t0 + tp ) for chord shear failure only.

Reinforced by a division plate between the brace members because of insufficient overlap.

t1

N1

t2

N2

tp • 2 t1 and 2 t2

to

bo

Take Ni,Rd as the value of Ni,Rd for a K or N t o overlap joint from Table 7.12 with Ȝov < 80%, but with bj , tj and fyj replaced by bp , tp and fyp in the expression for be,ov given in Table 7.10.

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7.5.3

Multiplanar joints

(1)

In each relevant plane of a multiplanar joint, the design criteria given in 7.5.2 should be satisfied using the reduced design resistances obtained from 7.5.3(2).

(2)

The design resistances for each relevant plane of a multiplanar joint should be determined by applying the appropriate reduction factor μ given in Table 7.19 to the resistance of the corresponding uniplanar joint calculated according to 7.5.2 with the appropriate chord load in the multiplanar situation.

Table 7.19: Reduction factors for multiplanar joints Type of joint

Reduction factor μ

TT joint

60° ” ij ” 90°

Member 1 may be either tension or compression.

μ = 0,9

XX joint Members 1 and 2 can be either in compression or tension. N2,Ed/N1,Ed is negative if one member is in tension and one in compression.



μ = 0,9 1  0,33N 2, Ed / N 1, Ed



taking account of the sign of N1,Ed and N2,Ed where ŇN2,EdŇ ” ŇN1,EdŇ

KK joint

60° ” ij ” 90°

μ = 0,9 provided that, in a gap-type joint, at section 1-1 the chord satisfies: 2

2

ª N 0,Ed º ª V0,Ed º « » « » ” 1,0 ¬« N pl , 0,Rd ¼» ¬«V pl ,0,Rd ¼»

128

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7.6 Welded joints between CHS or RHS brace members and I or H section chords (1)

Provided that the geometry of the joints is within the range of validity given in Table 7.20, the design resistances of the joints should be determined using the expressions given in Table 7.21 or Table 7.22 as appropriate.

Table 7.20: Range of validity for welded joints between CHS or RHS brace members and I or H section chord members Joint parameter [ i = 1 or 2, j = overlapped brace ] Type of joint

dw /tw

Class 1 X

and dw ” 400 mm

bi /ti and hi /ti or di /ti Compression Class 1 and

hi ” 35 ti

T or Y Class 2 K gap and N gap dw ” 400 mm

K overlap

Tension

bi ” 35 ti di ” 50 ti

N overlap

hi ” 35 ti

hi /bi

• 0,5 but ” 2,0

bi ” 35 ti di ” 50 ti

b0 /tf

bi /bj



Class 2 1,0



• 0,5 but ” 2,0

• 0,75

(2)

For joints within the range of validity given in Table 7.20, only the design criteria covered in the appropriate table need be considered. The design resistance of a connection should be taken as the minimum value for all applicable criteria.

(3)

For joints outside the range of validity given in Table 7.20, all the criteria given in 7.2.2 should be considered. In addition, the secondary moments in the joints caused by their rotational stiffness should be taken into account.

(4)

In brace member connections subjected only to axial forces, the design axial force Ni,Ed should not exceed the design axial resistance of the welded joint Ni,Rd , determined from Table 7.21.

(5)

Brace member connections subject to combined bending and axial force should satisfy:

N i , Ed N i , Rd



M ip ,i , Ed M ip ,i , Rd

” 1,0

... (7.5)

where: Mip,i,Rdis the design in-plane moment resistance; Mip,i,Ed is the design in-plane internal moment.

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Table 7.21: Design resistances of welded joints between RHS or CHS brace members and I or H section chords Type of joint

Design resistance [ i = 1 or 2, j = overlapped brace ]

T, Y and X joints

Chord web yielding t1

h1

b1 T1 tf

K and N gap joints

f y 0 t w bw

N1,Rd =

N1

r

sin T 1

/J M5

Brace failure

bo tw

ho

[i = 1 or 2]

N1,Rd = 2 f y1t1 p eff / J M 5 Chord web stability Ni,Rd =

f y 0 t w bw

sin T 1 Brace failure

/J M5

Ni,Rd = 2 f yi t i p eff / J M 5

Brace failure need not be checked if: g/tf ” 20 í 28ȕ ; ȕ” 1,0 í 0,03Ȗ where Ȗ = b0/2tf and for CHS: 0,75 ” d1 / d2 ” 1,33 or for RHS: 0,75 ” b1 / b2 ” 1,33

Chord shear

f y 0 Av

Ni,Rd =

3 sin T i

/J M5



N0,Rd = ª A0  Av f y 0  Av f y 0 1  V Ed / V p1, Rd

«¬

K and N overlap joints *)

[i = 1 or 2]

Members i and j may be in either tension or compression.

Brace failure



2

º /J »¼ M 5

25% ” Ȝov < 50%





Ni,Rd = f yi t i p eff  be ,ov  (hi  2t i )Oov / 50 / J M 5 Brace failure



50% ” Ȝov < 80%



Ni,Rd = f yi t i p eff  be ,ov  hi  2t i / J M 5 Brace failure



Ȝov • 80%



Ni,Rd = f yi t i bi  be ,ov  2hi  4t i / J M 5 peff = t w  2r  7t f f y 0 / f yi

Av = A0 í (2 í Į) b0 tf + (tw + 2r) tf

For RHS brace:

Į=

For CHS brace:

Į=0

1  4 g



1 2

but peff ” bi+hi-2ti hi for T, Y, X joints and K and bw = 5tf r N gap joints and sin T i beff ” bi+hi-2ti for K and N overlap joints. but

/ 3t f

2



be,ov =

10 f yj t j bi b j / t j f yi t i



bw ” 2ti + 10 (tf + r)

but be,ov ” bi For CHS braces multiply the above resistances for brace failure by ʌ/4 and replace both b1 and h1 by d1 and both b2 and h2 by d2. *)

130

Only the overlapping brace member i need be checked. The efficiency (i.e. the design resistance of the joint divided by the design plastic resistance of the brace member) of the overlapped brace member j should be taken as equal to that of the overlapping brace member.

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(6)

The design internal moment Mi,Ed may be taken as the value at the point where the centreline of the brace member meets the face of the chord member.

(7)

The design in-plane moment resistance Mip,1,Rd should be obtained from Table 7.22.

(8)

If stiffeners in the chord (see Figure 7.7) are used, then the design bracing failure resistance Ni,Rd for T-, X-, Y-, K-gap and N-gap joints (Table 7.22) is determined as follows: Ni,Rd = 2 fyi ti (beff + beff,s) / ȖM5

... (7.6)

where: beff = tw + 2r + 7 tf fy0 / fyi

but

” bi + hi - 2ti

beff,s = ts + 2a + 7 tf fy0 / fyi

but

” bi + hi - 2ti

beff + beff,s ” bi + hi - 2ti where:

(9)

a

is

s

refers to the stiffener.

stiffener weld throat thickness, '2a' becomes 'a' if single sided fillet welds are used;

The stiffeners should be at least as thick as the I-section web.

Table 7.22: Design moment resistances of welded joints between rectangular hollow section brace members and I or H section chords Type of joint

Design resistance [i = 1 or 2, j = overlapped brace]

T and Y joints

Chord web yielding

Mip,1,Rd = 0,5 f y 0 t w bw h1 / J M 5

Brace failure

Mip,1,Rd = f y1t1beff (h1  t1 ) / J M 5

Parameters beff and bw

beff = t w  2r  7t f f y 0 / f y1

but beff ” bi

bw =

h1  5 t f  r but bw ” 2t1  10 t f  r sin T1

131

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Bracing effective perimeter, without (left) and with (right) stiffeners

Figure 7.7: Stiffeners for I-section chords 7.7 Welded joints between CHS or RHS brace members and channel section chord members (1)

Provided that the geometry of the joints is within the range of validity given in Table 7.23, the design resistances of welded joints between hollow section brace members and channel section chord members may be determined using Table 7.24.

(2)

The secondary moments in the joints caused by their bending stiffness should be taken into account.

(3)

In a gap type joint, the design axial resistance of the chord cross-section N0,Rd should be determined allowing for the shear force transferred between the brace members by the chord, neglecting the associated secondary moment. Verification should be made according to EN 1993-1-1.

Table 7.23: Range of validity for welded joints between CHS or RHS brace members and channel section chord Joint parameter [ i = 1 or 2, j = overlapped brace ] Type of joint

K gap

bi /b0 • 0,4 and

N gap b0 ” 400 mm • 0,25 K overlap N overlap

and b0 ” 400 mm

bi /ti and hi /ti or di /ti Compression

and

hi ” 35 ti bi ” 35 ti di ” 50 ti

This condition only apply when ȕ ” 0,85.

132

b0 /t0

Class 1

ȕ* = b1/b0* b0* = b0 - 2 (tw + r0) 1)

Tension

hi /bi

Gap or overlap bi /bj 0,5(1-ȕ*) ” g/b0* ” 1,5(1-ȕ*) 1)

hi ” 35 ti bi ” 35 ti di ” 50 ti

and • 0,5 but ” 2,0

g • t1 + t 2 Class 2 25% ” Ȝov < 100% bi/bj • 0,75

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Table 7.24: Design resistance of welded joints between RHS or CHS brace members and channel section chords Type of joint

Design resistance [i = 1 or 2, j = overlapped brace]

K and N gap joints

Brace failure

hi bi

bj

Nj

Ni



Tj

Ti

Chord failure t0

tw

r0

Ni,Rd = h0

b0

bi

/J M5



Tj

º /J »¼ M 5



Brace failure

r0 b0

50% ” Ȝov < 80%





Ni,Rd = f yi t i beff  be ,ov  2hi  4t i / J M 5

t0 tw

2

25% ” Ȝov < 50%



bj

Ti



Ni,Rd = f yi t i beff  be,ov  2hi  4t i Oov / 50 / J M 5

hj

Nj

Ni

3 sin T i

Brace failure tj

ti

f y 0 Av

N0,Rd = ª A0  Av f y 0  Av f y 0 1  V Ed / V pl , Rd «¬

K and N overlap joints *) hi



Ni,Rd = f yi t i bi  beff  2hi  4t i / J M 5

hj

tj ti

h0

Brace failure

Ȝov • 80%





Ni,Rd = f yi t i bi  be ,ov  2hi  4t i / J M 5

Av = A0 í (1 í Į) b0* t0 b0* = b0 - 2 (tw + r0) For RHS:

Į=

For CHS:

Į=0

Vpl,Rd =

f y 0 Av

3

1  4 g

/J M5

1 2

/ 3t f

2



beff =

10 f y 0 t 0 bi * b0 / t 0 f yi t i

but

beff ” bi

be,ov =

10 f yj t j bi b j / t j f yi t i

but

be,ov ” bi

VEd = (Ni,Ed sin și )max For CHS braces except the chord failure, multiply the above resistances by ʌ/4 and replace both b1 and h1 by d1 as well as b2 and h2 by d2. *)

Only the overlapping brace member i needs to be checked. The efficiency (i.e. the design resistance of the joint divided by the design plastic resistance of the brace member) of the overlapped brace member j should be taken as equal to that of the overlapping brace member.

133

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Riproduzione vietata - Legge 22 aprile 1941 Nº 633 e successivi aggiornamenti.