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ENERGY ATLAS Future Concept Renewable Wilhelmsburg
INTERNATIONALE BAUAUSSTELLUNG HAMBURG (ED.)
ENERGY ATLAS Future Concept Renewable Wilhelmsburg
JOVIS
6 8 11 14
The IBA Future Concept Renewable Wilhelmsburg Christoph Ahlhaus The Modern Metropolis as Green Capital Anja Hajduk The Necessity of a Climate Protection Concept for a Renewable Wilhelmsburg Uli Hellweg Climate Change and Climate Policy Klaus Töpfer
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
21 27 36
The Post-fossil and Non-nuclear Energy Metropolises of Tomorrow Simona Weisleder, Karsten Wessel Our Urban Destiny Peter Droege A Brief Energy History of the Elbe Island Margret Markert
METHODOLOGY AND STRATEGY DEVELOPMENT
43 50
The Basics and the Initial Situation Dieter D. Genske, Jana Henning-Jacob, Thomas Joedecke, Ariane Ruff Prototype Urban Environments (UET) in the IBA Area
FUTURE SCENARIOS FOR WILHELMSBURG
71 79
Wilhelmsburg on the Way to the Solar Industrial Age Harry Lehmann Forecasts for the Reference Scenarios Dieter D. Genske, Jana Henning-Jacob, Thomas Joedecke, Ariane Ruff
97 118
121
Forecasts for the Excellence Scenarios Dieter D. Genske, Jana Henning-Jacob, Thomas Joedecke, Ariane Ruff Comparison of Scenarios People, Cities, Climate Change Stefan Schurig
ENERGY EFFICIENCY THROUGH COST EFFICIENCY
130 146
Costs and Gains of the Future Concept Renewable Wilhelmsburg Joost Hartwig Challenges and Opportunities of Urban Energy Policy: Not a Cost Issue Irene Peters
SOCIOLOGICAL ASPECTS OF CLIMATE CHANGE
156
Energy and Awareness Udo Kuckartz, Anke Rheingans-Heintze
ROAD MAP FOR WILHELMSBURG
170 189 196
Spatial Energy Concept Manfred Hegger Spatial Energy Action Plan for the Elbe Islands Simona Weisleder, Karsten Wessel
Project Gallery
218 Glossary 222 Authors 223 Picture Credits 224 Imprint
CHRISTOPH AHLHAUS
The IBA Future Concept Renewable Wilhelmsburg
When, if not now? Where, if not here? Who, if
tainability and the quality of life of the people
not us? Cities as we experience them today,
living in them. Energy supplies play a key role
from their built-up environments, their econo-
in this because not only electricity and heating
mies, and their traffic through to their social
production, but also our mobility, are almost
structure, are the result of industrialisation and
entirely dependent on the climate-damaging
are therefore dependent on the combustion
combustion of fossil fuel resources.
of coal, oil, and gas. Agriculture, too, is largely
The question of how cities need to be react-
directed at supplying cities with foodstuffs. The
ing to these challenges is now being posed all
overall flow of goods within and for the world’s
over the world. How can they be converted to a
conurbations is based on fossil fuel energy
sustainable energy system within a short period
production. Hence the fact that around 80 per
of time? How can the energy exploited be used
cent of all oil, gas, and coal reserves worldwide
more efficiently? How much mobility will be nec-
are used to supply cities, despite cities covering
essary in the future, or, be possibly improved?
less than 1 per cent of the world’s surface. More
Asking ourselves these questions is no easy
than two-thirds of all people in the industria-
task, of course, for, ultimately, this is also about
lised countries today live in cities. This trend
how we are to live and work in the future. New
is on the increase: according to the United Na-
technologies, new land use planning concepts,
tions, forecast growth in the world population
and new energy supply concepts are required,
will occur primarily in the cities.
but without forgetting the question of people.
In view of the growing threats presented by
Climate protection, economic development,
climate change, cities are both victims and cul-
fair educational opportunities, integration, and
prits. Culprits, because they are responsible for the largest proportion of worldwide CO2 emis-
culture also need to be considered in the quest for sustainable urban development solutions.
sions. Victims, because the majority of all cities are situated close to the coast, where they are
I am therefore especially pleased that the
therefore to some extent fully exposed to rising
Internationale Bauausstellung (International
sea levels. Then there is also the consider-
Building Exhibition; IBA) has adopted precisely
able economic damage due to climate change.
this focus. And it has stood up to the test. The
Researchers warn that Germany alone will face
many innovative ideas and concepts already
costs to its national economy of around 800
developed are now the subject of discussion
billion euros over the next fifty years due to
way beyond Hamburg itself. The first concrete
climate change.
projects such as the “IBA DOCK” have been
Man’s ability to halt the rapid rise in global
realised and are making a significant impact.
temperature therefore depends primarily on
The “Klimaschutzkonzept Erneuerbares
how the cities organise the future. The seismo-
Wilhelmsburg” (“Climate Protection Concept
graphs for successful cities are their future sus-
Renewable Wilhelmsburg”) presents an overall
6
Climate protection, economic development, fair educational opportunities, integration, and culture also need to be considered in the quest for sustainable urban development solutions.
The IBA’s many future-oriented ideas and projects are already of tremendous benefit for the whole of Hamburg. Furthermore, they provide a strong impetus for international discussion on sustainable urban development.
model of how a city district can become inde-
With the IBA, Hamburg has a special opportuni-
pendent in terms of energy, step-by-step, as
ty to be able to develop concepts for a sustain-
well as becoming a great deal more attractive
able city and thus to exert a positive influence
for its residents and from an economic perspec-
on the development of cities throughout the
tive. Based on a comprehensive scientific study,
world. With the IBA ENERGY ATLAS, Hamburg
different scenarios establish and compare
is taking a leading position on the issue of how
future energy demand, identifying savings and
societies in cities will live in the future.
renewable energy potential, and ultimately devising very concrete measures. A series of four steps—beginning with the realisation of the IBA projects up until 2013 and the perspectives for 2020/2030/2050—shows how a city district is able to gradually reduce its energy supply CO2 emissions to zero. The first step is the climate neutrality of all of the IBA’s own construction projects. The new buildings’ unavoidable CO2 emissions are off-set by savings in existing buildings and by the development of renewable energy projects on the Elbe Islands. Not only does the IBA’s climate protection concept initiate innovative steps in Wilhelmsburg, the IBA’s many future-oriented ideas and projects are already of tremendous benefit for the whole of Hamburg. Furthermore, they provide a strong impetus for international discussion on sustainable urban development.
INTRODUCTION
7
ANJA HAJDUK
The Modern Metropolis as Green Capital
Climate change is a great urban challenge. Half
And last but not least, the issue of Cities and
of the world’s population now lives in cities, and
Climate Change has been from the outset one
this proportion is set to increase further. Cities
of the three central topics of the Internationale
now claim the lion’s part of the resources that
Bauausstellung (International Building Exhibi-
the world has available, but as economic and
tion; IBA) in Hamburg.
scientific centres they are also capable of making the key contributions in the battle against
In a large, modern city little is not related to
climate change. If they fail to do so, they will
energy. The conversion of the energy system is
remain the main cause of climate change.
therefore a complex task. The complexity also
Hamburg is facing up to its responsibility with
harbours tremendous potential, however, for
ambitious climate protection targets. These ef-
energy supplies based on renewable sources
forts have played an important role in Hamburg
will mean that the intelligent integration of
being nominated European Green Capital in
energy production, distribution, and consump-
2009. With this title, we are obliged to continue
tion will play a key role. Examples of this include
producing examples of how the quality of the
virtual power plants, the use of electric vehicles
urban environment can be improved, as well
as decentralised storage units, or the product-
as to act as the inspiration and facilitator for
related control of the electricity demand of
the exchange of ideas between European cit-
individual consumers. Energy supplies therefore
ies. To this end, we held an international city
have to be linked as well with the rest of the
conference in the autumn of 2009, formulating
urban infrastructure, such as mobility or refuse
demands for the Copenhagen Climate Summit,
disposal.
as well as reinforcing the commitment of cities
With the “Klimaschutzkonzept Erneuerbares
to climate protection.
Wilhelmsburg” (“Climate Protection Concept Renewable Wilhelmsburg”), the IBA provides
The climate protection steps already under-
an exemplary illustration on the Elbe Islands
taken by Hamburg include the comprehen-
of how such a comprehensive undertaking
sive climate protection programme; the high
for a city might appear. As demanding as the
energy standards for buildings included in the
undertaking may be, Hamburg and Wilhelms-
Hamburg climate protection regulations; the
burg have the potential to turn it into reality.
co-operation between the Senate and the eco-
What’s more, it enables us to demonstrate that
nomic sector aimed at energy-efficiency within
the climate-conscious city will also be the city
the scope of the environmental partnership;
with a better quality of life: a city with more
as well as the founding of the city’s energy
user-friendly buildings, with less traffic noise
supply company Hamburg Energie, which is
but with greater mobility for all—a city where
committed to the development of sustainable
participation in achieving this reality is of
energy supplies for Hamburg in the future.
great benefit to all of its residents.
8
IBA DOCK The headquarters where concepts for the metropolis of the twenty-first century are developed. The Elbe islands are a model for the entire city.
ULI HELLWEG
The Necessity of a Climate Protection Concept for a Renewable Wilhelmsburg
This ENERGY ATLAS of the Elbe Islands is a
the “Energieberg” (“Energy Hill”) project came
very special step for the IBA Hamburg. On the
into being.
one hand, it provides us with a reflection of our
The energy specifications applying to all the
own work over the last three years with regard
IBA’s construction projects are stricter than those prescribed by law—exceeding the Ener-
to the key theme of “Stadt im Klimawandel”
Optimised building services engineering and the ambitious renovation of existing buildings reduce energy consumption, while co-generation units and regional and local energy association systems improve energy efficiency. The proportion of renewable energy is gradually being raised to 100 per cent.
(“Cities and Climate Change”) and, on the other,
gieeinsparverordnung (German Energy Saving
it is the IBA Hamburg’s attempt to bring a new
Regulations; EnEV) of 2009 by 30 per cent.
direction to the Internationale Bauausstellun-
In fact, the majority of the projects in fact set
gen (International Building Exhibitions)—moving away from an incrementalist perspective
themselves targets that are even more ambitious. For example, the “open house” housing
towards concept-based projects—meaning that
construction project is being implemented
the projects become sustainable only when
under the name “Passivhaus Plus” (“Passive
incorporated into coherent overall concepts.
House Plus”), meaning that the overall electric-
Since 2007, the IBA Hamburg has been develop-
ity requirements are taken into consideration
ing and improving projects following its main
and largely generated locally from renewable
themes—some of these projects based on ap-
sources. The construction of the new Urban De-
proaches from specialists; some of them taken from the Weissbuch (White Book) of the Zukun-
velopment and Environment Authority building
ftskonferenz Wilhelmsburg (Future of Wilhelms-
to be a model project, certified according to
burg Conference),1 drawn up in the course of a
the guidelines of the Deutsche Gesellschaft
broadly participative process on the Elbe Island
für Nachhaltiges Bauen (German Sustainable
in 2001/02; and of course the projects initiated
Building Council; DGNB), and achieving its Gold
by the IBA. The same has also applied to the
Standard.
key theme “Stadt im Klimawandel” (“Cities and
In addition to the many ambitious energy
Climate Change”): the Wilhelmsburg bunker
projects, the IBA Hamburg increasingly worked
project stemmed from the idea of setting up a
towards not merely having these projects stand
large solar thermal plant inside a World War II
in isolation but utilising the special features of
bunker, and thereby transformed into the Energy Bunker by the IBA, and developed into the
this urban island, and to attempt the preparation of an overall concept, a kind of road map,
sound and viable project that it is today. Plans
showing the way into the post-fossil fuel and
to build a photovoltaic unit on the Georgswerd-
nuclear-free age—the “Klimaschutzkonzept
er refuse dump, as well as to repower, to revital-
Erneuerbares Wilhelmsburg” (“Climate Protec-
ise and upgrade the old wind energy units there
tion Concept Renewable Wilhelmsburg”).
were arose in existence before loud calls from
IBA Hamburg intends to set new standards
within the neighbourhood for this “mountain”
for resource conservation and climate-neutral
to be made suitable for public use—and hence
construction with this concept: optimised build-
in the centre of Wilhelmsburg is also intended
INTRODUCTION
11
ing services engineering and the ambitious
earth’s desert regions, or whether support for
renovation of existing buildings reduce energy
decentralisation in fact harbours undreamt-of
consumption, while co-generation units and
possibilities for new multiskilled markets, highly
regional and local energy association systems
innovative engineering skills, and many new
improve energy efficiency. The proportion of re-
jobs—not to mention the high degree of energy
newable energy is gradually being raised to 100
security.
per cent. The IBA Hamburg, together with the
We have a year of intensive discussion with
resident population and numerous other par-
the group of authors involved in this ENERGY
ticipants, aims to show how cities can become
ATLAS behind us. We would not have been able
powerful champions of climate protection.
to achieve the present level of quality without
The aim of this ENERGY ATLAS of the Elbe
this panel of experts and the comprehensive
Islands is to formulate spatial energy guidelines
groundwork carried out by Dr. Genske and his
and a plan of action that can serve as a proto-
team. Our special thanks go to all of those
type for a renewable Hamburg. The intention
involved for their committed and pioneering
is not the development of theories but a very
work.
practical demonstration for this showcase area
Nevertheless, it is still not a finished product to
of how it could be, what the influences affecting
be interpreted on a 1:1 basis. The complexity, the
the IBA projects already highlighted are, and
innovative character, and the process orienta-
what needs to happen after 2013 in order for
tion of the ENERGY ATLAS mean that it is not
climate neutrality and 100 per cent renewable
a static plan but an instrument demonstrating
energy to be achieved.
options for the climate-neutral Elbe Island as it
International building exhibitions are urban
gradually converts to 100 per cent renewable
laboratories, working under real conditions on a
energy and presenting these topics for discus-
scale of 1:1. This means that the actual politi-
sion as examples for the energetic renewal of
cal, social, legal, financial, and other relevant
metropolises.
parameters have to be incorporated into our
The goal is the intensive examination and fur-
concepts and projects as “variables.” In the
ther development of this road map in the years
context of the “Climate Protection Concept
ahead, together with many institutions, associa-
Renewable Wilhelmsburg” this also means deal-
tions, experts, and the general population. This
ing with real economic, social, and demographic
also means closer consideration of further mod-
situations and taking them into consideration
ules in the next few years—particularly the issue
as key parameters for the implementation of
of mobility and the development of solutions
strategic climate protection concepts. We have
specially adapted to the Elbe Island.
therefore expanded our Climate and Energy Advisory Board2 to include the expertise of the environmental communication experts from the University of Marburg,3 in order to be able to explore the needed sociodemographic implementation strategies in more detail. The examination of the commercial and economic side of the “decentralised” approaches to the “Climate Protection Concept Renewable Wilhelmsburg” was no less important to us. There is the fundamental question, however, of whether we envisage the post-fossil fuel age as supported by a new industrial mega-structure with gigantic offshore wind parks and huge expanses of photovoltaic installations in the
12
Notes 1 Zukunftskonferenz Wilhelmsburg (ed.): Zukunftskonferenz Wilhelmsburg—Insel im Fluss—Brücke in die Zukunft. Weissbuch. Bericht der Arbeitsgruppen Mai 2001–Januar 2002. Wilhelmsburg 2002. 2 The members of the Climate and Energy Advisory Board are: Prof. Peter Droege (World Council for Renewable Energy), Dr Harry Lehmann (Federal Office for the Environment, Dessau), Prof. Irene Peters (HafenCity University Hamburg), Prof. Manfred Hegger (TU Darmstadt), Stefan Schurig (World Future Council, Hamburg), Prof. Matthias Schuler (Transsolar, Stuttgart). 3 Prof. Dr Udo Kuckartz and Dr Anke Rheingans-Heintze.
The goal is the intensive examination and further development of this road map in the years ahead, together with many institutions, associations, experts, and the general population.
Dieser ENERGIEATLAS der Elbinseln ist aus
Umwelt in der Wilhelmsburger Mitte als Vor-
Sicht der IBA Hamburg ein ganz besonderer
bildprojekt, nach den Richtlinien der Deutschen
Schritt. Zum einen reflektieren wir damit die
Gesellschaft für Nachhaltiges Bauen (DGNB)
eigene Arbeit der vergangenen drei Jahre im
zertifiziert, den Gold-Standard erreichen.
Leitthema „Stadt im Klimawandel“ und zum
Neben der Vielzahl der energetisch ambitionier-
anderen versucht die IBA Hamburg damit eine
ten Projekte wuchs zudem der Anspruch der IBA
neue Ausrichtung der Internationalen Bau-
Hamburg, diese Projekte nicht für sich stehen zu
ausstellungen zu implementieren – weg von inkrementalistischen Akupunkturen hin zu
lassen, sondern die Besonderheit der urbanen In-
konzeptbasierten Projekten –, sprich die Projekte werden erst dann nachhaltig, wenn sie in schlüssige Gesamtkonzepte eingebaut sind. Seit 2007 entwickelt und qualifiziert die IBA Hamburg in ihren Leitthemen Projekte – zum Teil basierend auf Ansätzen aus den Fachbehörden, einiges aufgenommen aus dem Weißbuch der Zukunftskonferenz Wilhelmsburg1, welches in einem breiten partizipativen Prozess auf den Elbinseln in den Jahren 2001/02 erarbeitet wurde; und natürlich kommen auch Projekte zum Tragen, die durch die IBA neu entstanden sind. Beim Leitthema „Stadt im Klimawandel“ war das nicht anders: Das Projekt für den Wilhelmsburger Flakbunker kam mit der Idee der Umsetzung einer großen Solarthermieanlage aus der Fachbehörde, wurde durch die IBA zum „Energiebunker“ qualifiziert und zu dem starken und damit auch umsetzbaren Projekt entwickelt, welches es heute darstellt. Das Vorhaben, auf der Deponie Georgswerder eine Photovoltaik-Anlage zu bauen und dort auch die alten Windenergieanlagen zu „repowern“, war schon existent, dazu kam die starke Forderung aus dem Stadtteil, diesen „Berg“ für die Öffentlichkeit nutzbar zu machen – und so entstand das Projekt „Energieberg“. Für alle IBA-Bauprojekte gelten strengere energetische Vorgaben als die gesetzlich vorgeschriebenen – Unterschreitung der Energieeinsparverordnung (EnEV) 2009 um 30 Prozent. Bei der Mehrheit der Projekte entwickeln sich die tatsächlichen Ziele noch ambitionierter. So wird zum Beispiel das Wohnungsneubauprojekt „Open House“ als sogenanntes „Passivhaus Plus“ realisiert, das heißt auch, der gesamte Strombedarf wird betrachtet und überwiegend vor Ort regenerativ erzeugt. So soll auch der Neubau der Behörde für Stadtentwicklung und
sel zu nutzen, und sich an ein Gesamtkonzept, eine Art Roadmap, heranzuwagen, welche den Weg ins postfossile und atomfreie Zeitalter weist – das „Klimaschutzkonzept Erneuerbares Wilhelmsburg“. Mit diesem Konzept will die IBA Hamburg neue Standards für Ressourcenschutz und klimaneutrales Bauen setzen: Optimierte Gebäudetechnik und ambitionierte Bestandssanierungen reduzieren den Energieverbrauch, Blockheizkraftwerke, regionale und lokale Energieverbundsysteme verbessern die Energieeffizienz. Der Anteil erneuerbarer Energien wird schrittweise auf 100 Prozent gesteigert. Zusammen mit der Bevölkerung und zahlreichen Akteuren will die IBA Hamburg zeigen, wie Städte zu Vorreitern des Klimaschutzes werden können. Ziel dieses ENERGIEATLAS für die Elbinseln ist es, ein räumlich-energetisches Leitbild und Handlungskonzept zu formulieren, das beispielhaft für ein erneuerbares Hamburg steht. Keine Theorie zu entwickeln, sondern ganz praktisch für dieses Demonstrationsgebiet aufzuzeigen, wie es gehen könnte, welchen Einfluss unsere bereits angeschobenen IBA Projekte haben und was auch nach 2013 passieren muss, damit Klimaneutralität und 100 Prozent erneuerbare Energien erreicht werden. Internationale Bauausstellungen sind Stadtlabore, die unter realen Bedingungen im Maßstab 1:1 arbeiten. Das heißt, die tatsächlichen politischen, sozialen, rechtlichen, finanziellen und sonstigen relevanten Rahmenbedingungen müssen als „veränderliche“ Rahmenbedingungen in unsere Konzepte und Projekte einfließen. Im Kontext des „Klimaschutzkonzeptes Erneuerbares Wilhelmsburg“ heißt dies ferner, sich auch mit realen wirtschaftlichen, sozialen und demografischen Situationen auseinanderzusetzen und sie als entscheidende Parameter der Umsetzung von strategischen Klimaschutzkon-
KLAUS TÖPFER
Climate Change and Climate Policy
The United Nations Framework Convention on Climate Change‘s 15th Conference of the
crises. Leading company directors in Germany also, are seeing Blue-collar jobs2 going and
Parties (COP 15) was held in Copenhagen one
Green-collar jobs3 coming. The race for the
year before the publication of this book from
best technological solutions, the Green Race,
7–18 December 2009. At a critical juncture in
seems to have begun. An unparalleled effort by
the unravelling global climate conditions it was
non-governmental organisations saw the issue
a particularly disappointing example of the
and importance of Copenhagen being anchored
inherent difficulties of this global negotiation
in civil society more strongly than ever. The cli-
process, and yet, before this meeting, the ideal
mate experts were clearer and more urgent in
preconditions for a new, successful, internation-
their demands for political action. Expectations
ally co-ordinated climate policy seemed to be
were high—without any clear and matter-of-fact
in place. For the first time, the global threat of
consideration really having been given to what
climate change had been placed on the agenda
would make “Copenhagen” a success or what
by the heads of state themselves—more than
any alternative might look like. This significant
100 government leaders took part: from Obama
weakness on the part of all the negotiating par-
to Wen Jiabao, Angela Merkel, Brazil’s Lula, and
ties was evident even in the preliminaries to the
the Indian premier Singh, through to Zenawi,
conference. Neither was the indiscriminate el-
Ethiopia’s head of government, and the presi-
evation of Copenhagen to a kind of end game in
dents of the small island states in the Pacific.
planetary climate salvation particularly helpful.
The preparations for Copenhagen were based on the Bali Road Map, the guideline for further
Against this background, the outcome of this
negotiations agreed upon two years ago by the
“Copenhagen Accord,” has been largely labelled
nations party to the UN Framework Convention
inadequate or, drastically, determined an abso-
on Climate Change. Exceptionally difficult nego-
lute failure.
tiations were even able to achieve approval of this Road Map by the then Bush government.
All of this dust is slowly beginning to settle. It
The run-up to Copenhagen also featured, for
achievements of Copenhagen mean without
the first time, an increasing number of actively
the tactical rhetoric, and how the substance of
involved and prominent voices from within the private sector. Green Tech, namely environ-
these achievements can be rendered useable.
mentally and climate-friendly technologies,
the basis of the positions of the key negotiating
was already being defined as the driver behind
parties, such as the United States of America
a new, long “Kondratiev Wave”1 holding the promise of green growth. A Green New Deal was
and China, but more especially also of India,
presented as a paradigm shift in the common
the small island states. Retrospective finger
battle against economic and environmental
pointing does little to create a good negotiating
14
conference so laden with expectation, the
is time to take an objective look at what the
We need to analyse the considerations forming
the developing countries in Africa, as well as
Hamburg House at Expo 2010 in Shanghai The first certified passive house in China
With the pilot project in Wilhelmsburg, the IBA Hamburg creates an example of what many Wilhelmsburg residents will be able to achieve in the future.
atmosphere to achieve tangible and urgently
to increase. Climate policy will therefore be
required successful outcomes.
particularly successful if cities are increasingly
Co-operation on climate policy on a worldwide
able to use energy efficiently in an improved,
scale cannot be postponed further. Climate
indeed revolutionary, way. This will be pos-
change is a reality. The thirteen-year gap
sible if city energy supplies are able to become
between the conclusion of the UN Framework
increasingly decentralised, and thus also more
Convention on Climate Change and the imple-
likely to become less carbon-intensive.
mentation of the Kyoto measures is alarming.
This makes cities the focus of the climate policy
Meanwhile, rising greenhouse gas emissions
agenda and it is therefore especially welcome
leave no room for a repetition of this failure.
that Hamburg is taking on a pioneering role in
This gap of global silence is sheer lost time. It
this regard. In setting itself the goal of gradual-
could carry a high price if the forecasts of the
ly moving this large, cosmopolitan, vibrant city
climate experts prove to be true. It is therefore
in the direction of climate neutrality, the IBA
crucial that immediate action be taken—action
in Hamburg sends a signal to the world. This
with concrete results in terms of a reduction of CO2 and all other emissions, caused directly or
signal comes at just the right time. The recent
indirectly by human beings, which influence our
was “Better City—Better Life”. Partnership
climate.
between cities is a tremendous opportunity
At least 80 per cent of the world’s resources are
for mutual support in efforts aimed at energy-
used in cities. This percentage and the associat-
efficient and carbon-neutral energy supplies—
ed emissions will increase with ongoing urbani-
and it is possible for the IBA Hamburg to adopt
sation. Cities thus bear tremendous responsibil-
a global agenda based on this event as it moves
ity for avoidance of and adjustment to climate
into its final implementing years.
change. This obligation can be met only with
In the city context, these are perspectives
clear strategies and innovative solutions. The
linked to a decentralised approach. Hence the
“Zukunftskonzept Erneuerbares Wilhelmsburg”
city’s overall target has to be broken down
(“Future Concept Renewable Wilhelmsburg”) is
according to the individual city districts and
very easily integrated into such an approach. It
neighbourhoods. In this regard, too, Hamburg is
is not about waiting for internationally binding
exemplary. It is therefore to be welcomed that
targets to be set from above but about initiating change from below. It demonstrates how climate
this “Future Concept Renewable Wilhelmsburg” takes the form of its own ENERGY ATLAS. It is
neutrality can be brought about through civil
to be hoped that the measures already achieved
involvement and creative solutions. With the
and those still to be implemented here will have
pilot project in Wilhelmsburg, the IBA Hamburg
a multiplying effect in Germany and beyond. Be-
creates an example of what many Wilhelmsburg
yond the EXPO 2010, as the IBA moves towards
residents will be able to achieve in the future.
completion in 2013, there is the opportunity for
EXPO 2010 took place in Shanghai: its theme
working together on city district concepts in Three starting points for concrete action de-
Shanghai. The dynamics of this huge Chinese
serve special mention:
megacity certainly provides conditions requiring the ongoing development of new solutions with
City Involvement
scientifically verifiable effectiveness.
It has been reported often enough that, with
Concentration on Existing Buildings
the new millennium, the world has entered an “urban millennium.” More than 50 per cent of
More than 40 per cent of greenhouse gas emis-
the world’s population now lives in cities, in
sions derive from buildings already in existence.
agglomerations, in megacities, and large ur-
It is therefore rational, and imperative, that at-
banised regions. This percentage will continue
tention is paid to this source of climate-damaging
INTRODUCTION
15
emissions. A further major advantage is that in-
mobility becomes less and less. Here, too, there
vestment in improved building energy efficiency
are examples to be found in the emerging cities
also has the effect of reducing the energy costs
of the Third World that could find meaning-
for the building’s residents or users. Economic
ful application in urban development in highly
and ecological criteria therefore go hand in hand
developed countries. This particularly applies
here, thus facilitating implementation.
to the preference for public transport when it
The initiation of concrete measures in this
comes to the road network.
regard and their exemplary implementation in
A climate-friendly alternative also requires the
Hamburg, more specifically in Wilhelmsburg, is
use of new energy sources for transport. The
again very significant. There is a direct link with
trend towards electrical mobility will become
China in this respect as well. Over 50 per cent
part of this when the electricity required can be
of building activity worldwide takes place in
supplied on a renewable basis. The mobility de-
China. What is not currently being incorporated
bate, therefore, must not be limited to a single
by way of improved insulation, greater energy
technology but needs to be further optimised
efficiency, and the supply of renewable energy
within the system as a whole.
to buildings will not be able to be redressed in
Overall, an ecological approach should not be
the long term in China and in many of the other
viewed as a negative challenge but rather as an
rapidly growing developing countries. Close
opportunity. We live in a world with just under
co-operation is therefore a basic prerequisite
seven billion people. In the year 2050 it will be
for the development of global concepts and for
nine billion. Such rapid population growth also
their incorporation in a legally binding form in
means a rise in the number of people living
later negotiations.
in poverty. The hunger for energy on the part
Notes 1 Named after the Russian economist Nikolai Kondratiev, this refers to technologies triggering a sustained economic upturn. Examples include the investments made in the development of a comprehensive rail network and, more recently, IT technologies. 2 Blue-collar job = occupation largely characterised by physical labour. 3 Green-collar job = occupation in the environmental sector.
of those attempting to free themselves from
Mobility
this is increasing at the same time. China is again a much-cited example in this regard. This
Mobility is the third concrete area of activity.
hunger for energy will not be able to be satis-
Emissions from the various modes of transport
fied by fossil fuels alone, however. If energy
continue to rise significantly. The range of op-
and resource efficiency are not raised and if
tions available to a city needs to focus specially
the range of energy options is not subjected
on passenger and goods transport within the
to a fundamental expansion, then resource
city in question. The key task will be to develop
shortages and price increases will be unavoid-
urban structures in such a way that they do
able. Initiatives such as the “Future Concept
not necessitate mobility through too great a
Renewable Wilhelmsburg” therefore represent
segregation of the individual functions of hu-
not only a necessary step in avoiding climate
man life at a local level. This also corresponds
change; they will also increasingly become
to a general tendency towards social unity.
an economic necessity and a driving force
City centres are again becoming increasingly
for creativity in our economies. Germany is
sought-after locations, particularly by single
a technology leader and needs to retain this
households and by older members of the popu-
top position—preferably expanding on it. It is
lation. The development of public spaces into
to our advantage to be the country with the
areas of social contact and the incorporation
greatest energy efficiency, providing products
of retail and service outlets are job-creating in-
and production processes with minimal energy
vestments on the one hand and, on the other, a
requirements, and standing at the forefront
basic condition for a way of life that also avoids
of technological developments in renewable
unnecessary traffic.
energy. If we recognise and use this innovation
In addition to these requirements at a planning
potential in good time, we will also be able to
level, there is also a need to make public trans-
maintain Germany’s competitiveness as a busi-
port so attractive that the need for individual
ness location in the future.
16
Oil disaster in the Gulf of Mexico, 2010 Harvesting fossil-based energy involves ever greater risks: the consequences for the environment are often underestimated.
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
SIMONA WEISLEDER, KARSTEN WESSEL
The Post-fossil and Non-nuclear Energy Metropolises of Tomorrow
The IBA Hamburg’s project area: The Elbe islands of Wilhelmsburg and Veddel, together with Harburg upriver port.
The IBA Hamburg has set itself the overall goal
“Cities and Climate Change” is: how are cities
of demonstrating “projects for the future of our
to follow the path into the post-fossil fuel and
cities.” The cities of tomorrow are faced with
nuclear energy-free age?
pressing challenges resulting from globalisa-
The Elbe Islands constitute a classic example of
tion, migration, economic dynamics, environ-
the seeming clash between economic growth
mental destruction, a shortage of resources,
and environmental concerns. Cities are charac-
and the consequences of climate change. For
terised by competing demands for space for dif-
a seven-year period—from 2007 to 2013—the
ferent uses—housing, traffic, trade, industry. At
Internationale Bauausstellung (International
the same time, they are places of high energy
Building Exhibition) Hamburg is therefore dedi-
consumption and concentrated emissions. The
cating itself to precisely those urban develop-
IBA Hamburg projects provide examples of how
ment issues whose effects will have a signifi-
growth and sustainability can be brought into
cant influence on the future of cities. The IBA
harmony in built-up urban areas.
Hamburg is thus part of a long and ambitious
For more than five hundred years, marsh farm-
tradition of international building exhibitions in
ers have been reclaiming the Elbe Island from
Germany.
the river, defending it against the storm tides
The IBA instrument is always put into use when
of the North Sea. It was originally an archi-
the proven, institutionalised approaches no lon-
pelago of almost two dozen shallow islands; the
ger suffice for the pressing problems at hand,
ring dyke around “Europe’s largest inhabited
the solution to which means finding new alli-
river island” was first completed in the mid-
ances and a course of action to enable econom-
nineteenth century—but it has not always been
ic, administrative, and political barriers to be
effective, as the devastating storm tide of 1962
overcome. “It is about the social and cultural is-
showed. Awareness of the sea level dangers
sues of the future. All of the international build-
posed by climate change is therefore greater
ing exhibitions to date have provided a central
in Wilhelmsburg than it is anywhere else in
theme and agenda for which model solutions
Hamburg.
were sought. An IBA is not a purely theoretical
The IBA’s key theme “Cities and Climate
event; instead, it seeks concrete solutions and
Change” did not have to be invented for the
these have to be exemplary and enduring. …
Elbe Island; it had been on the agenda at least
This also requires the courage to experiment.”1 Hamburg has displayed this courage with the
since the 4th IPCC (Intergovernmental Panel on
choice of demonstration area—Hamburg’s
report by the United Nations panel of experts
Elbe Islands and the future-oriented projects
provides scientific evidence that climate change
making up the IBA’s key themes: “Kosmopolis”
has anthropogenic causes, and makes it clear
(“Cosmopolis”), “Metrozones,” and “Stadt im
that just the most important industrialised
Klimawandel” (“Cities and Climate Change”).
nations have to reduce their greenhouse gas
The issue addressed by the IBA Hamburg with
emissions by 80–95 per cent (based on 1990
Climate Change) report of February 2007. This
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
21
emissions levels) by the year 2050, simply to be
projects—as part of this important step being
able to prevent drastic consequences.
taken by the city of Hamburg.
Cities consume 80 per cent of all resources,
With its projects and the “Klimaschutzkonzept
even though they occupy just 2 per cent of the
Erneuerbares Wilhelmsburg” (“Climate Protec-
world’s surface area, and urbanisation contin-
tion Concept Renewable Wilhelmsburg”), the
ues unabated worldwide (by 2030 the propor-
IBA Hamburg’s main aim is to demonstrate solu-
tion of the world’s population living in cities
tions for the urban, largely built-up environ-
will rise from the current 50 per cent to 60 per cent).2 Consequently, no contemporary exhibi-
ment—in contrast to Masdar, for instance, where
tion related to building and urban development
sustainable city from scratch. Moreover, the IBA
is able to avoid addressing the issue of climate
Hamburg examines ways in which maximum use
protection—through energy savings, energy
can be made of local renewable energy sources intra muros, such as energy savings and energy efficiency, and how local economies can be strengthened as a result. In addition to its distinct spatial boundaries, the IBA Hamburg’s demonstration area also has an important strategic advantage: it does not form part of the Hamburg district heating network’s supply area, reliant on conventional, non-renewable energy sources. This means that, here, the IBA Hamburg does in fact have a real opportunity for testing and evaluating the numerous decentralised and local approaches to energy supply! How can this goal of comprehensive renewable energy supply and maximum climate relief be implemented as a feasible “hands-on” strategy of action for the Elbe Islands? The elements making up this road map are: to identify consumers and levels of consumption; to determine the potential and location of the projects relating to energy saving, increased efficiency, and the implementation of renewable energy; and to draw up an implementation timeframe—these are the constituent elements of the ENERGY ATLAS of the Elbe Islands—in which the IBA projects are instrumental. In order to develop this ENERGY ATLAS, the IBA Hamburg shifted in 2008 its focus to energy consumption (electricity and heating) in existing buildings, commissioning the Bremer Energie Institut (Bremen Energy Institute) to carry out a survey of current heating and energy consumption in residential, service, office, and administrative buildings on the Elbe Islands. A joint venture with the local network operators Vattenfall Europe Distribution and E.ON Hanse in the planned
efficiency, and the increasing use of renewable energy—and adjustment to the consequences of climate change. The future of our climate will be determined by and in our cities! With its projects and concepts, the IBA has now become an established feature of the city of Hamburg’s efforts to face up to its responsibility as a significant climate factor. The Hamburg Senate’s 2007–2012 Climate Protection Concept and Hamburg’s climate protection regulations established ambitious energy standards for emission avoidance and energy efficiency, going beyond Germany‘s federal targets. Hamburg‘s ambitious path has received international recognition: the city has been named European Green Capital 2011. In the run-up to Hamburg’s year in this capacity the IBA, as a kind of “urban laboratory,” constitutes a special and unique opportunity for developing and testing innovative concepts for renewable energy supply as well as for emission and resource cutbacks at a city level—from individual buildings through to entire districts. In the overall urban context, the founding in 2009 of the city’s own new energy firm HAMBURG ENERGIE, to supply its own energy without the use of coal or nuclear energy, is also an important milestone for the Hanseatic city. This is a topic currently being debated throughout the Federal Republic of Germany: how cities and municipalities can regain increased influence over their energy supplies and actively co-ordinate their climate and energy policy. The IBA Hamburg has sought concrete co-operation in this regard, is aiming for valuable synergies, and sees itself as an inspiration for innovative
22
the opportunity is for building a brand new
The IBA’s demonstration area does not form part of the Hamburg district heating network’s supply area, meaning that the IBA Hamburg does in fact have a real opportunity for testing and evaluating the numerous decentralised and local approaches to energy supply!
With its projects and the ”Climate Protection Concept Renewable Wilhelmsburg” the IBA Hamburg’s main aim is to demonstrate solutions for the urban, largely built-up environment—in contrast to Masdar, for instance, where the opportunity is for building a brand new sustainable city from scratch.
EnEff:IBA project means that the IBA Hamburg
to incorporate concrete IBA projects and also
will also have access to concrete consumption
to examine different areas of emphasis in
data (electricity/gas) for the years 2008–2013.
renewable energy supplies. The first scenario
The implementation strategy was consolidated
is characterised by a strong focus on possible
together with local and international experts
local deep geothermal opportunities, which—if
as well as interested Elbe Island residents in an
realised—would produce significant yields. This
IBA Laboratory in 2009: a workshop to advance
is being initiated by the IBA Hamburg with
a creative approach to the islands’ potential for
its 2010 research project. The second excel-
renewable energy, for energy efficiency, and
lence scenario focuses on the diversification of
energy savings.
renewable energy sources. The two scenarios
Motivated by the federal Experimental Residen-
share the fact that they are local and decentra-
tial Study Program (ExWoSt) research project
lised solutions adapted to the special local abil-
“Nutzung städtischer Freiflächen für erneuer-
ity to achieve autonomy in renewable energy.
bare Energien” (Use of urban spaces for renewable energy)3 of the Federal Ministry of Trans-
The results of the study, undertaken in close co-
port, Building, and Urban Development and the
Climate Advisory Board, form the most impor-
Federal Office for Building and Regional Plan-
tant basis for this ENERGY ATLAS of the Elbe
ning, the IBA Hamburg sought an exchange of
Islands, and represent the strategic instruments
ideas. Based on these experiences and informa-
and projects for the Elbe Islands’ future energy
tion, a working group—comprising JHJ Bleich-
supply systems. The aim is the presentation of
erode and the egs Netzwerk Nordhausen—was
a spatial energy model for the IBA’s demonstra-
commissioned in 2009 to undertake the study
tion region.
“Energetische Optimierung des Modellraums
The IBA Hamburg has attempted to develop a
IBA Hamburg” (Energy Optimisation of the
uniform approach that (a) is grounded in the
IBA Hamburg Model Region). This study used a
place in question; (b) demonstrates a clear
scenario analysis to compare future energy de-
direction in energy savings, efficiency, and
mand and the potential for savings, increased
renewable energy implementation; (c) takes
efficiency, and the use of renewable energy in
the economic dimension into account; and (d)
the various types of urban environment on the
accommodates the special social conditions on
Elbe Island, and to develop strategic measures
the Elbe Islands.
operation with the IBA’s specialist Energy and
for the optimisation of energy supplies. The study undertook a concrete examination of two different reference scenarios illustrating developments in 2013/2020/2050, applying Germany-wide trends in renovation, efficiency, and the introduction of renewable energy to the Elbe Islands. Use was made of two reference scenarios in order to demonstrate the possible impact of a district heating network on the Elbe Islands, supplied by the Moorburg coal power station currently under construction, and, as a distinct counterbalance, the opportunities that would arise (a) if the focus was no longer on this fossil fuel technology locally, and (b) if, the
Notes 1 Engelbert Lütke Daldrup: “Die Zukunft Internationaler Bauausstellungen”. In: IBA Hamburg GmbH (ed.): IBA meets IBA. Zur Zukunft Internationaler Bauausstellungen. Berlin 2010, pp. 50–55, here p. 53. 2 Herbert Girardet (ed.): Zukunft ist möglich—Wege aus dem Klima-Chaos. Hamburg 2007. 3 The project “Nutzung städtischer Freiflächen für erneuerbare Energien” (“Use of urban spaces for renewable energy”) is part of the research programme “Experimenteller Wohnungs- und Städtebau” (“Experimental residential and urban development”) research programme by the Federal Ministry of Transport, Building, and Urban Development, and the Federal Office for Building and Regional Planning, 2009.
construction of new coal power stations were to be stopped elsewhere. Two so-called excellence scenarios were developed as alternative to the reference scenarios
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
23
Declaration of the Hamburg City Climate Conference 2009* 7 Facts, 7 Commitments and 7 Calls for a Low-carbon Future The signatory cities declare that combating climate change is above all a matter for cities. They commit to do everything in their power to mitigate climate change and to master the consequences of climate change. They support the commitments by the cities of the Covenant of Mayors. They call upon COP15, national governments and international bodies, to adopt regulations which will make it possible to achieve the 2-degree target.
Declaration of the Hamburg City Climate Con7 facts about cities in the face of climate change
80 per cent by 2050, to permit achievement of
7 commitments of the signatories
the global goal of 50 per cent. The signatory cities, towns, and regions commit 5. Cities need national and international
to the following principles:
support. 1. Cities are key players and key parties
The cities want to mitigate climate change by
1. A new dimension of global cooperation
affected by climate change.
efficient use of renewable resources, by using
Cities will work together actively, in internation-
Cities and towns account for 75 per cent of the
energy-efficient motors and equipment, and by
al city networks, for the transfer of knowledge
world’s greenhouse gas emissions. That is why
drastically reducing their energy consumption.
in their twin city partnerships and to specifi-
they have a key role to play in achieving the
They need effective international agreements
cally support cities in the developing countries.
global reduction goal of 50 per cent by 2050.
and national legislation to do that.
They will develop new models for bilateral and
2. Mitigation is mainly an urban issue.
6. Cities are particularly exposed to risk.
multilateral climate partnerships. They encourage the Climate Alliance CO2 emissions reduc-
Per capita emissions can be particularly low in
Almost all cities are located on rivers or seas, or
tion targets, the declaration by EUROCITIES on
cities. Urban life can be organised with shorter
in valleys, and are therefore specifically vulner-
climate change, the Local Government Climate
travelling distances, denser housing, and syner-
able to flooding, and rising sea levels. They are
Roadmap Process initiated by ICLEI and the
gies in energy supply, in such a way that the
also threatened by storms, heat waves, and
Energie-Cités initiatives.
reduction targets are met.
scarcity of drinking water. Due to concentration of people, infrastructure and values, cities have
2. Cooperation with surrounding areas
3. Cities of the world start from different
particularly high loss potentials. International
Cities will cooperate increasingly with the sur-
conditions.
and national regulations are needed to manage
rounding areas in the use of renewable energies
That is why they have to support one another.
the consequences of climate change.
and in measures to adapt to climate change.
future belong together. Cities in developing
7. Cities need a stronger voice.
3. Municipal climate action programme
countries have to be empowered by the inter-
Despite their key role in mitigating climate
Cities will develop climate programmes ori-
national regulatory system to contribute to cli-
change, the cities of the world are currently
ented towards the two-degree target, and will
mate action and to deal with the consequences
not sufficiently involved in the political decision
implement them and continuously monitor
of climate change.
making process. Their experience should be
their effectiveness.
Fighting poverty and fighting for a low-carbon
used to set up regulations that are effective in 4. Cities in the industrial countries have to
practice.
4. Cities as models
cut carbon emissions by 80 per cent.
City administrations will become role models
Populations and economies in developing
in public procurement and in their own build-
countries are growing. They can reduce their
ings, for private sector businesses and for
greenhouse gas emissions only in the longer
citizens.
term. So cities in the industrialised countries have to reduce their GHG emissions by at least
24
5. Energy-saving policy Cities will implement policies to encourage energy efficiency action in private households and in industry and commerce; to support public
7 calls for support by COP15, governments and international organisations
transport and to prevent unnecessary traffic
of intercontinental power grids for renewable energies. 4. Energy efficiency and energy savings Industrialised countries are required to legislate
volumes; and to encourage the use of electric
1. Binding commitment of the global
for high efficiency thermal insulation of new
cars, bicycles, and walking.
community to the two-degree target of the
buildings right now, and for subsequent insula-
IPCC
tion of existing buildings by 2025 at the latest.
6. Pro-climate urban planning
Global warming of more than two degrees
The construction of transport infrastructure
Cities will encourage and implement mitigatory
would destabilise the global ecosystems and
and adaptive measures by means of regulations
economies. It is therefore essential for emis-
and subsidies to / taxation of means of transport must be based on their CO2 emissions.
and incentives in their urban planning.
sions to be limited in such a way that this level is not exceeded. The international reduction
5. Protection of primeval forests
7. Citizen participation
agreements must specify concrete goals for in-
The cities call for international agreements on
Cities will actively involve their citizens in
dustrialised and developing countries, achieving
protection of primeval forest areas in Africa,
planning and implementation of climate action
at least a 50 per cent reduction by 2050.
Asia, and Latin America, including financial compensation for the countries affected. Trade
programmes and motivate them to make a contribution by their efforts to combat climate
2. Fair solutions, because only fairness will
in wood obtained non-sustainably from these
change.
help in the long term
forests must be banned, and the ban must be
To keep within the 2-degree target, a maximum of 750 gigatonnes CO2 emission is permissible
effectively monitored.
up to 2050. An allocation mechanism based on
6. Flood defences and protection of drinking
the principle of equal per capita emissions is
water reserves
needed. Financial compensation must be cre-
We need international agreements to support
ated for those countries and populations that
cities in protection from the rise in sea levels. It
generate fewer emissions. The historic emis-
is also necessary to set up international coop-
sions by the industrialised countries have to be
eration for protection of freshwater reserves.
taken into consideration in this calculation. 7. Appropriate involvement of cities
* During the Hamburg City Climate Conference in November 2009, around 290 participants from forty countries reiterated their solidarity and responsibility in the battle against global warming by signing the Hamburg Declaration
3. Boost of renewables
Cities must be involved in the decision-making
A tremendous joint international effort is
processes at national and international levels to
needed in order to obtain about 80 per cent of
combat climate change.
energy from renewables by 2050. It requires exchange of technologies, funding of technology transfer, and development of renewable infrastructures. That includes the establishment
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
25
Als übergeordneten Anspruch hat sich die
Emissionen. Wie Wachstum und Nachhaltigkeit
IBA Hamburg das Ziel gesteckt, „Projekte für
in den gebauten Städten in Einklang gebracht
die Zukunft der Metropolen“ zu zeigen. Die
werden können, zeigen beispielhaft die Projekte
Metropolen von morgen sehen sich durch
der IBA Hamburg.
Globalisierung, Migration, ökonomische Dyna-
Über mehr als 500 Jahre hinweg haben Gene-
mik, Umweltzerstörung, Ressourcenknappheit
rationen von Marschbauern die Elbinseln dem
und Folgen des Klimawandels vor drängende
Elbstrom abgerungen und gegen die Sturmflu-
Herausforderungen gestellt. Die Internationale
ten der Nordsee verteidigt. Ursprünglich ein
Bauausstellung Hamburg widmet sich deshalb
Archipel von fast zwei Dutzend flachen Inseln,
sieben Jahre lang – von 2007 bis 2013 – ge-
wurde der Ringdeich um „Europas größte
nau jenen Fragen der Stadtentwicklung, deren
bewohnte Flussinsel“ erst in der Mitte des 19.
Wechselwirkungen maßgeblichen Einfluss
Jahrhunderts geschlossen – nicht immer erfolg-
auf die Zukunft der Städte haben werden. Die
reich, wie man spätestens nach der verheeren-
IBA Hamburg steht damit in einer langen und
den Sturmflut von 1962 weiß. Das Bewusstsein
anspruchsvollen Tradition Internationaler Bau-
über die Gefahren des Klimawandels ist daher
ausstellungen in Deutschland.
anderswo in Hamburg kaum so ausgeprägt wie
Das Instrument IBA wird immer dann ergrif-
in Wilhelmsburg.
fen, wenn für die drängenden Probleme die
Das IBA Leitthema „Stadt im Klimawandel“
bewährten, institutionalisierten Handlungsmus-
musste somit für die Elbinseln nicht erfunden
ter nicht mehr greifen und für die Lösung neue
werden, sondern stand spätestens seit dem
Bündnisse und Aktionsformen gefunden werden
4. IPCC-Bericht (Intergovernmental Panel on
müssen, die ein Durchbrechen von ökonomi-
Climate Change) vom Februar 2007 auf der
schen, administrativen und politischen Barrie-
Agenda. Jener Bericht des ExpertInnen-Rats
ren ermöglichen. „Es geht um gesellschaftliche
der United Nations belegt wissenschaftlich,
und kulturelle Zukunftsfragen. Dazu haben
dass der Klimawandel anthropogene Ursachen
bislang alle Internationalen Bauausstellungen
hat, und macht deutlich, dass die wichtigsten
eine programmatische Leitidee gegeben, zu
Industrieländer allein nur zur Verhinderung der
der modellhafte Lösungen gesucht wurden.
drastischsten Folgen ihre Treibhausgasemissi-
Eine IBA ist keine reine Theorieveranstaltung,
onen bis zum Jahr 2050 um 80 bis 95 Prozent
sondern sucht konkrete Lösungen und diese
reduzieren müssen (gemessen am Emissionsni-
müssen exemplarisch und einprägsam sein.
veau von 1990).
Daneben bedarf es des Muts zum Experiment.“ 1 Diesen Mut zeigt Hamburg mit der Auswahl des
80 Prozent aller Ressourcen werden in den
Demonstrationsgebietes – den Hamburger Elb-
Fläche einnehmen, und die Verstädterung
inseln und den zukunftsorientierten Projekten
schreitet weltweit unaufhaltsam voran (bis
in ihren Leitthemen „Kosmopolis“, „Metrozo-
2030 wird der Anteil der Weltbevölkerung, der
nen“ und „Stadt im Klimawandel“. Die Frage, die die IBA Hamburg in ihrem Leitthe-
in Städten lebt, von derzeit gut 50 auf 60 Prozent steigen).2 Angesichts dessen kommt heute
ma „Stadt im Klimawandel“ umtreibt, ist: Wie
keine Ausstellung, die mit Bauen und Stadtent-
kann die Metropole den Weg in das postfossile
wicklung zu tun hat, umhin, den Klimaschutz
und atomenergiefreie Zeitalter beschreiten?
– durch Energieeinsparung, Energieeffizienz
Auf den Elbinseln treffen Wachstums- und
und den zunehmenden Einsatz erneuerbarer
Umweltbelange beispielhaft aufeinander.
Energien – und die Anpassung an die Folgen des
Metropolen befinden sich im Spannungsfeld
Klimawandels zu thematisieren. Die Zukunft des
konkurrierender Flächenansprüche von unter-
Klimas entscheiden die Städte!
schiedlichen Nutzungen – Wohnen, Verkehr,
Die IBA ist mit ihren Projekten und Konzepten
Handel, Industrie. Gleichzeitig sind sie Orte
inzwischen fester Bestandteil in den Bestre-
hohen Energieverbrauchs und konzentrierter
bungen der Stadt Hamburg geworden, sich der
Städten verbraucht, die nur zwei Prozent der
PETER DROEGE
Our Urban Destiny
The IBA Hamburg is achieving success at a local level without waiting for global agreements, the conclusion of which seems to lie ever further in the future.
Shenyang in China, 2005 As viewed from the International Space Station
The historical contribution being made by the
combustion of a depleting resource—fossil fuel.
Internationale Bauausstellung (International
More than 85 per cent of global primary com-
Building Exhibition; IBA) Hamburg lies in the creative and practical approach to the global
mercial energy is supplied by non-renewable, toxic sources2—and these sources, especially oil,
challenges of a multifaceted energy crisis.
are entering a historical peaking stage. Some
This crisis extends from the shortage of non-
95 per cent of motorised transport—essential
renewable resources, far-reaching structural
to economies, cities, and the very dynamics of
issues at an economic level, through to climate destabilisation. It is highly significant that the
urban growth and lifestyles—is petroleum dependent.3 Peak oil—the inexorable arrival of the
IBA Hamburg is characterised by intensive local
maximum point of oil production beyond which
involvement and a quest for effective, practical
demand increasingly outstrips supply—exposes a
solutions pointing the way towards sustainable
structural flaw in the global urbanisation archi-
existence. Success is being achieved here at a local level without waiting for global agree-
tecture. Global oil production probably already reached its peak in 2006.4 And given continued
ments, the conclusion of which seems to lie
demand trajectories, the production downturn
ever further in the future. The IBA shows what
is also likely going to be much sharper and more
needs to become normal practice worldwide
dramatic than predicted by most peak oil ex-
within a few years. It is in this respect that
perts, due to the “net peak” effect: as reserves
IBA Hamburg also differs from all the previous
become scarcer it takes an increasing amount
international building exhibitions before it by
of energy to produce the dwindling resource. In
portraying within a specific social and eco-
2000, it took one barrel of oil to extract eleven
nomic context, a path of hope that is relevant and necessary at a worldwide level. This path
barrels in the United States—down from a ratio of 1:100 in the nineteen-thirties.5 As the point
promises the residents of Wilhelmsburg real
of peak is approached and transgressed, the
improvements, economic advantages, access
rapidly decreasing production efficiency leaves
to new technologies, and new expertise—all of
substantially less in net usable production
which are important in view of the scale of the
capacity than the 50 per cent of total available
impending energy turnaround. The task at hand is a massive one. Of the nearly
resources usually depicted.6 By its very nature, the abundant fossil energy
330 billion tons of carbon released by fossil fuel
system supported the rise of cities. Cities
burning and cement production since the middle
bulged as a direct consequence—and poisoned,
of the eighteenth century, a full half has been
paved, filled, or drained vast stretches of aqui-
emitted since the nineteen-seventies, and con-
fers, rivers, and lakes in the process. Wetlands,
tinues to rise at the precipitous rate of 3.4 per cent each year.1 But climate change is not the
bushlands, and grasslands disappeared at
only reason to act, and to act quickly, because
tered with highways and landfill sites. And they
three-quarters of this emission rise is due to the
emerged as the narrative backdrop for count-
growing rates. Metropolitan regions grew lit-
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
27
less human lives lost in income, class, energy
heaval; targets that should be as low as 350 or,
inequities, oil wars, and environmental catas-
better, 280 parts per million.
7
trophes like the great Gulf of Mexico calamity of 2010. Mapped onto city geographies around the globe, misguided energy policy emerged as an avoidable tragedy, because decision makers
Winner of the Solar Decathlon 2009 in Washington D.C. The sur-PLUShome designed by Technische Universität Darmstadt
Seven Tools to Achieve Urban Energy Autonomy
ignored the sun—a practically limitless, ubiqui-
As renewable energy (RE) autonomy emerges
tous, and free source, embodied in solar, wind,
as an inexorable global goal, cities—being
water, and bio-energy.
most endangered by the threat—must lead the
When assessing the costs of this destructive
way. Each city must find its own path based
process, its most menacing legacy turns out to
on climate and weather, available resources,
be the atmosphere. The cocktail of anthropo-
development history, degree of globalisation or
genic carbon dioxide, nitrous oxide, methane,
trade dependence, the relation to the region,
and chlorofluorocarbons that enriches the thin
governance capacity, and the manner in which
layer of terrestrial air is the global gaseous
civil society is engaged. Unlike the old fossil and
waste pool resulting from generations of fossil
nuclear power systems, the technical tools to
fuel burning, cement production, and rapacious
achieve energy autonomy are local: roof and
land management practice. The oceans serve as
façade surfaces for solar conversion into elec-
overflow receptacle. The most immediate alarm
tricity and thermal energy; small wind power;
is struck in both runaway Arctic and Greenland
heat pumps and deep geothermal sources; bio-
ice melts and African droughts. Erroneous
methane capture and use; biomass, in autono-
assumptions are now exposed: any further
mous islands or as distributed networks. Cities
temperature rise over the 0.7º Celsius already
can become extremely effective in implement-
experienced in the twentieth century will signifi-
ing 100 per cent renewable strategies, using a
cantly increase the risks.
comprehensive set of tools:
The two degrees Celsius (C) rise advocated in international climate talks is unacceptable as
Regulation, legislation, and standards
a policy target not only because it accepts the
Cities can issue suitable building regulations,
drowning of low-lying regions and evaporating
efficiency standards, and mandatory renew-
water supplies for millions of urban and rural
able energy provisions for new buildings. Cities
dwellers. It also risks the unravelling of features
can embrace a full alternative energy supply
that helped stabilise climatic conditions for a
as mandatory, where climate and national
large and somewhat advanced human civilisa-
resource pricing mechanisms allow this. Regula-
tion to evolve. These have already begun to
tions and standards can also be provided in co-
shift or unravel at the seemingly small rise
operation with state and national governments,
experienced during the twentieth century.
wherever municipal powers are limited.
With melting permafrost soils and lakebeds increasingly venting methane, the point of no
Incentives
return—beyond which no human intervention
Incentives for taking efficiency measures and
can halt the climatic cataclysm—is likely to be
developing RE installations, but also for renew-
reached below 450 parts per million, which is
able energy service companies, can be provided
the political benchmark so many cling to like
through taxation and pricing policies. Free or
a magic mantra. Instead, levels substantially
highly affordable, well-designed public transport
below the present level of 390 parts per million
systems will induce changes in commuter behav-
concentration—involving the removal of excess
iour. Cities can also regulate priority access for
greenhouse gas in the atmosphere-land-ocean
electric vehicles, provide production and market
carbon cycle—must be aimed at to have some
incentives for green energy charging stations,
reasonable hope of managing the climate up-
and encourage solar car-share providers.
28
Solar settlement in Vauban A district of Freiburg im Breisgau, 2007, Rolf Disch Solar Architecture
The facilities and stock owned, operated, man-
Institutional reform: strategic and general
aged and/or controlled by the city—from the
planning practices
urban infrastructure apparatus, to the develop-
Established city government is modelled on
ment of municipal buildings, to streetlights, car
nineteenth- and twentieth-century realities,
fleets, and undeveloped or underused proper-
including energy practices. It is highly stratified
ty—can be deployed as a readily available tool
and structured around specialised sectors—the
as well. Indeed, the public sector has a higher
famous guilds of bureaucracy. But the modern
degree of accountability and responsibility and
world of energy and emissions-conscious gover-
hence an obligation not only to do better than
nance has no room for such over-specialisation.
the private sector—or no worse than the best
Now is a time for the broad-banding of skills,
of the private industry. It is also obliged to use
outcome-oriented practice, and institutional
its asset management and capital investment
structures in which all departments are focused
policies and practices to set a powerful example to the community.
on moving towards energy autonomy. The primary rule is: Know Thy Assets. Understanding
Furthermore, institutional assets in the form
the city’s energy flows is a necessary starting
of municipal power companies can be used as
point. The next step is to map renewable energy
powerful tools in projecting renewable energy
potential, realising what roof and open space
and efficiency policies, develop infrastructure,
assets are available for renewable electricity
and engage in farsighted measures of all kinds.
and thermal energy conversion.
Where no public power assets exist, these can sometimes be established or re-acquired.
Community action, industry alliances,
These asset establishment initiatives can be
information, and education
summarised as follows: . The development of virtual utilities or area
Outreach is another very traditional but underused municipal function. Much can be achieved
renewable power developers as policy instru-
without large assets or capital investment
ments in the absence of real public power
capacity. The examples of effective municipal
companies is a real and practical option for
agencies, activist support organisations, edu-
large metropolitan areas or smaller cities in
cational and information programmes, and com-
alliance with regional or state government. . Renewable power asset investment, such as
munity aid entities focused on improved energy practice are legion. Cities and their community
bond financing, city assets, public-private
organisations could take up the energy au-
partnerships, and contracting arrangements,
tonomy agenda—neighbourhood by neighbour-
can be used by cities to develop projects
hood, precinct by precinct, and ward by ward.
near or far. . Long-term renewable power purchasing con-
Some cities will be culturally more amenable to this agenda than others.
tracts, as bulk purchasing for end-consumer use, are becoming increasingly popular,
Fostering urban and regional carbon
allowing cities to act as non-profit agents to
sequestration practice
acquire renewable electricity at large-volume
The methodical use of open space for urban
rates and passing the savings on to the com-
garden and forest, wetland development, and
munity by distributing the power without
water management can contribute to lowering
price mark-up. . Conversion of existing city-owned buildings
a city’s carbon footprint. This means rebuilding regional links, one of the most exciting and
into high-efficiency structures, and develop-
challenging, but also promising, opportunities.
ment of a comprehensive renewable energy
From nurturing regional forests, to making food
infrastructure.
supplies more locally based, building up humus combined with the use of biochar, producing bioenergy crops, anaerobic digestion and
30
Solar Decathlon 2007 in Washington D.C. Façade of the Plus Energy House of Texas A&M University
methane capture of farm wastes, and solar
emissions generated from operational energy
and wind farms—the reconnection of city and
use only. This approach is problematic because
region promises to become a powerful driver of
the targets are typically set arbitrarily and for
geographically proximate partnerships among
political purposes; they are set too low and for
long-separated neighbours: city cores, suburban
too distant a time horizon; and they cover only
rings, and rural economies.
a small band in the energy use spectrum. In wealthy cities, energy embodied in goods and
Renewable movement in and between cities
services consumed represent up to 70 per cent
Perhaps the most astonishing feature of the
of household energy use—yet this lifestyle fac-
fossil fuel revolution is the lure of mass mobility of people and goods: our “mass consumption of
tor is not reflected in municipal statistics or policies.8 Understanding embodied and imported
global space,” the seemingly limitless possibility
fossil energy or emissions is crucial in assigning
of moving around the globe by air, sea, rail, and
responsibility to consumers and reducing the
road. The very psychology of societal attitudes
ecological footprint of urban dwellers. Con-
has been deeply influenced by this: global mo-
sumption emissions are easy to understand, yet
bility and trade patterns, as well as a myriad of
their control is seen to go beyond the tradition-
personal and public choices are being driven by
al scope of urban public policy. Nevertheless,
an accelerating ease of mobility. The fact, how-
embodied fossil fuel and carbon emissions can
ever, is that oil combustion is needed to achieve
be countered with a wide array of measures,
this. Virtually all global motorised movements
ranging from local food supply strategies to
depend on oil, whether it is cheap but polluting
building local renewable energy powered indus-
bunker crude oil being burnt by global shipping
trial production capacity, from enhancing and
fleets, or subsidised aviation kerosene sending
promoting local and regional environmental and
millions of travellers aloft each month. Signifi-
cultural qualities, to lowering the demand for
cant changes are imminent.
international recreational travel.
But intraurban mobility is another critical issue.
In all of these areas, communities lead the way,
To decouple transportation from the use of
supported by enlightened government policy.
oil, a good start can be made in cities. Today’s
The IBA Hamburg, together with the interna-
call is for a 100 per cent renewable electricity-
tional garden show and, by extension, its home,
based individual and public transport system.
the city of Hamburg as Europe’s Green Capital
Most cities can find ways to supply vehicles
in 2011 have taken up the important task of
with the renewable energy sourced locally—and
leading the way into a resilient, just, and more
the batteries of these vehicles can even be
sustainably prosperous urban future.
used as floating storage systems—for electricity peak shaving, for example. Electric and hybrid vehicle technology can greatly reduce urban air and noise pollution and is a near-perfect fit for urban integration. Lower embodied energy and resource content An all-encompassing, global effort—far beyond the current timid action—is unavoidable and urgent. Only the pursuit of total renewable energy reliance is useful. This will cover all electricity and thermal consumption, transport energy—and also include consumed energy, embodied in the goods and services procured. Most fractional targets aim at the direct use of
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
31
Notes 1 Boden, T.A./ Marland, G./ Andres, R.J.: Global, Regional, and National Fossil-Fuel CO2 Emissions. Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, U.S. Department of Energy, Oak Ridge, Tenn. 2009. 2 EIA – US Energy Information Administration. 1986. World Energy Outlook 1996–2006. http://www.eia.doe. gov/iea/overview.html. 3 IPCC – Intergovernmental Panel on Climate Change: Climate Change 2001: Mitigation. Contribution of Working Group III to the Third Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge 2001. 4 Zittel, J./ Schindler, W: Geht uns das Erdöl aus? Freiburg 2009. 5 Cleveland, C.J.: “Net energy from the extraction of oil and gas in the United States.” In: Energy, Volume 30, Issue 5, April 2005, pp. 769–782. 6 Murphy, D.: The Net Hubbert Curve: What Does It Mean? http://netenergy.theoildrum.com/node/5500 (2009). 7 Hansen, J. et al.: Target Atmospheric CO2: Where Should Humanity Aim? NASA/Goddard Institute for Space Studies, http://www.columbia.edu/~jeh1/2008/ TargetCO2_20080407.pdf (2008). See also: Meinshausen, M.: On the Risk of Overshooting 2°C. Paper presented at Scientific Symposium “Avoiding Dangerous Climate Change,” MetOffice, Exeter, 1–3 February 2005. http://www.pik-potsdam.de/~mmalte/simcap/ publications/meinshausenm_risk_of_overshooting_final_webversion.pdf 8 Lenzen, M. et al: “Embodied Energy: the Importance of Lifestyle.” In Droege, P. et al.: Urban Energy Transition. München 2008.
Bibliography This article is based in part on excerpts from Peter Droege: “One Hundred Tons to Armageddon.” In: Gary Bridge, Sophie Watson: The Blackwell Guide to the City, new edition, 2010; and Peter Droege: 100% Renewable for Cities and Beyond. World Future Council and HafenCity University 2010.
32
Following double page Vision 2030 Georgswerder Energy Hill with Veddel and Kleiner Grasbrook district
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
33
MARGRET MARKERT
A Brief Energy History of the Elbe Island
Seen from today’s perspective, power generation on the Elbe island of Wilhelmsburg was
Harbour Development and Industrialisation
ahead of its time even in the seventeenth century. In an era when growth constraints and
With Hamburg joining the German customs
a shortage of energy resources were yet to be-
union in 1888 and the development of the free
come evident, the River Elbe and the wind were
port, Wilhelmsburg from early on became a link
used to generate power for the production and
in the southern expansion of the harbour, even
transport of goods. There is written mention in
though it did not even belong to Hamburg at
1582 of a windmill, rebuilt after a fire in 1874.
that stage. As the “most ideal industrial area
In addition to the dairy farming that formed
in the German empire” and the “Eldorado of
the livelihood of the Elbe island’s residents,
the future!” within a decade the island was
wood rafting and the timber trade have been
being exploited for future industrial estates by
a feature of Reiherstieg since the seventeenth
property speculators and real estate compa-
century. This building material was transported
nies. New harbour basins, canals, factories,
along the River Elbe to the timber docks where
and today’s Reiherstieg district had been
there was a saw mill and, as of 1706, to the first
built by the outbreak of the First World War in
shipyards on the northern Reiherstieg.1 A good two hundred years later, the industrial
1914. In 1875, Wilhelmsburg had almost 4,000
community of Harburg-Wilhelmsburg was one
reached 32,000. The island community became
of the most important centres of the German
an industrial town with substantial energy
oil industry. The origins of this development
requirements. Investors such as Hermann Ver-
form part of colonial history: Harburg mer-
ing initiated extensive development measures
chants made palm oil from Africa the lubricant
in the west of Wilhelmsburg. As of 1890, smoke
of the emergent industrialisation, processing
began belching from the factory chimneys. The
it for both engineering and for cosmetic and
local authorities were completely overwhelmed
pharmaceutical production. In 1880, the com-
by the rapid industrialisation process. In 1890,
pany Noblée und Thörl was a leading European
the local council still largely comprised farmers,
processor of tropical oil seed.2 The refineries and tank facilities belonging to
shipbuilders, and other artisans; a few years
Shell (then still Rhenania Ossag), Schindler,
companies, chairmen of property companies,
and DEA (Deutsche Erdöl Aktiengesellschaft/
and the Wilhelmsburg industrial railway.
German Oil Company) on the Reiherstieg and
In the period before the First World War,
Köhlbrand then transformed what was once the
Neuhof, in the extreme north-west of Wilhelms-
natural Wilhelmsburg Elbe island landscape into
burg, became a location for the oil industry.
an expansive harbour and industrial area, a pro-
The petroleum harbour had already been
cess that extended into the nineteen-twenties.
established in 1879 in Finkenwerder, and this
36
residents—by 1914 the population had already
later it was dominated by heads of industrial
Reiherstieg shipyard with saw mill From a steel engraving by F.C. Löhr, around 1775
benefit. In 1918, 10,863 people earned their living in the shipyards. It was only after the great inflationary crisis of 1923 that overall industrial development stabilised. Pre-war population numbers were again reached in Wilhelmsburg in 1929. Following their merger in 1927, HarburgWilhelmsburg was one of the largest industrial regions in the Weimar Republic, its around 110,000 residents and an industrial workforce of approximately 26,000 in more than a hundred large enterprises making it more important than Breslau, Königsberg, Halle, or Kassel.4 In the mid-nineteen-twenties Hamburg’s harbour further encroached on Wilhelmsburg, with Rethe and Reiherstieg being dredged. The Prussian premier Otto Braun wanted a unified industrial policy for Prussia. “The plans for Harburg and Wilhelmsburg were part of this overall Power for the first steamships Coal supplies are bunkered in Hamburg harbour
A breath of fresh air in Wilhelmsburg‘s urban development The Dutch windmill on Siedenfelder Weg, restored in 1997
industrial sector was further developed in the
strategy, ensuring the German empire’s supply
nineteen-twenties. The Neuhof power station,
of cheap potash for agriculture and oil products
connected to the grid in 1928, with what was
for industrial use and for mass consumption,
then the largest diesel engine in the world,
while simultaneously consolidating the lower
became the most important power supplier.
Elbe region in the face of competition from
Unlike Hamburg, which “had already boasted
Rotterdam and London, with defensive aspects
electric lights and trams for decades, as well as
also playing a role: the imperial army provided
electromotive power in its shipyards and facto-
support for the development of Harburg into an
ries,” Wilhelmsburg was connected to the electric grid only in 1912. The Siemens Elektrischen
oil port.”5 The Great Depression of 1929 brought with it
Betriebe power station in Harburg had a total
tremendous problems for the Wilhelmsburg
output of 670 kilowatts distributed across seven
economy as the majority of the commercial
transformer stations via a 10,000-volt line.3 From this point until well into the era of the Wei-
operations were reliant on the import of raw
mar Republic, Wilhelmsburg was a working-class
ic region despite the developing crisis, Hamburg
residential area of Hamburg. Up until about
and Prussia agreed on the foundation of the
1925, approximately one-third of Wilhelmsburg’s
Hamburgisch-Preussische Hafengemeinschaft
residents were factory workers who earned
GmbH (Hamburg-Prussian Harbour Association)
their living with Hamburg companies.
in July 1929. The objective was the financing of
materials. In order to stabilise the Elbe econom-
the building and operation of future harbours in
Economic Fluctuations and Industrial Crises
the lower Elbe economic region, as well as new
The First World War brought a halt to the rapid
Wartime Economics
transport and infrastructure measures.
industrial development, production declined, and employment figures dropped accordingly.
As of 1934, the National Socialist regime
A significant dependence on imports meant
began systematically planning for the war. By
problems for the oil and chemical industries
1938, the major Howaldtswerke shipyard and
in particular. The major shipyards, producing
the Maschinenfabrik Augsburg-Nürnberg AG
warships for the navy, were the only ones to
(M.A.N.) engineering works had housing built
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
37
for their workforces in Wilhelmsburg. The war-
Electricity consumption increased twenty-fold
time economy was booming and the power in-
by the nineteen-seventies.
dustry was centralised. Under the terms of the
The major coking plant, which went into opera-
Gross-Hamburg-Gesetz (Greater Hamburg Act),
tion in 1960, was built on an area double the size
the Hamburg-Harburg municipal electricity
of the Binnenalster on Kattwyk Island, and made
producer became the property of the Hambur-
Wilhelmsburg the centre of Hamburg’s gas sup-
gischen Elektrizitätswerke (HEW) in 1940.
ply. The raw material, coal, from which approxi-
During the Second World War, the Wilhelms-
mately 70 per cent of the gas was produced,
burg industrial area was one of the main areas
was brought by bulk carriers to Kattwyk quay.
targeted by Allied bombers and it enjoyed top
During the nineteen-sixties 500,000-800,000
air defence priority as one of the centres of the
cubic meters of gas were produced daily.
German oil industry, as well as for its situation in the middle of Hamburg’s harbour. This fact
Disastrous Dependency
played a role in the choice of location for the bomb shelter built in 1942 in the centre of the Reiherstieg district.6 This bunker was primarily
More enduring than the destruction of the Sec-
used for attacking the English and American
demonstration of the susceptibility to natural
bomber squadrons with anti-aircraft guns. It
disaster of a highly mechanised city, with its
also provided protective shelter for the popula-
power supply as its arteries. The electricity
tion, a great many of whom were employed by
network was the first to collapse: thousands
wartime industry.
of people were left without heating, unable to
Almost all industrial operations had been
cook, cut off from the outside world.More than
destroyed or badly damaged by the end of the
200 people drowned in Wilhelmsburg on the
war in 1945. The bombing had contaminated
night of 16/17 February 1962. Almost all of the
vast expanses of the industrial area, a legacy
industrial operations were flooded. Inconclu-
that continues to hinder development right up
sive plans by the Hamburg Senate to turn the
to the present day. The west of Wilhelmsburg
west of Wilhelmsburg into a solely industrial
will remain a harbour logistics location, other
area facilitated a gradual decline until the late
utilisation options being largely futile. The ma-
nineteen-seventies: housing stood empty, there
jority of the industrial operations were rapidly
was no more investment, industrial operations
rebuilt. With the exception of the Deutsche
relocated.
Erdöl-Aktiengesellschaft/German Oil Company
At the same time, however, Hamburg was work-
(DEA), which relocated production to Heide in
ing on further harbour expansion plans. In the
Holstein, the large refineries were again achiev-
mid-nineteen-seventies, Altenwerder was the
ing pre-war production figures within just a few
first Elbe marshland village to make way for
years. Köhlbrand Industrie GmbH, now British
the harbour expansion, with Neuhof next. The
Petroleum (BP), doubled its employee numbers.
whole of the lower Elbe area was industrialised:
The Neuhof power station saw a sharp rise in
from Dow Chemical near Stade to Reynolds
electricity consumption. The number of meter
Aluminium in Waltershof, the flagships of the
connections rose from 10,550 in 1945 to 16,100
chemical industry lined up along the banks of
ten years later, while the average consump-
the Elbe, their basic power supplies coming
tion of almost 500 kilowatt/hours annually per
from the Stade nuclear power station at cheap,
resident increased to 863.3 kilowatt/hours. In
industry-friendly rates. Hamburg’s long-stand-
1954, Wilhelmsburg had 53,285 residents, and
ing competition with Rotterdam and Antwerp
total annual electricity consumption rose to 46 million kilowatt/hours.7 The electricity was
for the title of the largest harbour in Europe
supplied to sixty industrial and 952 commercial
The scandal of the Georgswerder refuse site,
operations, as well as to 13,868 households.
where in 1984 highly toxic dioxin seeped out
38
ond World War, the floods of 1962 were a tragic
thus entered a new phase.
Side effect of the industrial upturn Fire at Deutsche Erdöl AG, Reiherstieg, in 1928
oriented project was thus also a throwback to the past: the old windmill in the east of the island was restored as “a visible sign that things are finally turning around in Wilhelmsburg …”8 Notes 1 Hermann Keesenberg: Wilhelmsburg in Wort und Bild. 3rd rev. ed., Hamburg 1980. 2 Quoted from Heiko Möhle (ed.): Branntwein, Bibeln und Bananen. Der deutsche Kolonialismus in Afrika. Hamburg 1999. 3 HEW (Hamburgische Elektrizitätswerke) advertisement in Ernst Reinstorf: Geschichte der Elbinsel Wilhelmsburg. Hamburg 1955. 4 Dirk Stegmann: “Die industrielle Entwicklung Harburgs 1900 bis 1937.” In: Jürgen Ellermeyer / Klaus Richter / Dirk Stegmann (ed.): Harburg. Von der Burg zur Industriestadt. Hamburg 1988. 5 Cf.: ibid., p. 318ff. 6 Henning Angerer: Flakbunker—betonierte Geschichte. Hamburg 2000, p. 22. 7 Wilhelmsburger Heimat-Kalender. Wilhelmsburg 1961. 8 Dittmar Machule / Jens Usadel: “Fünf Jahre Wilhelmsburg im Aufbruch. Die Zukunft des Stadtteils wird mitgestaltet.” In: DIE INSEL. Zeitschrift des Vereins für Heimatkunde Wilhelmsburg, Vols 34/35, 1999.
The euphoria of progress and pride in the most modern technology View of the Shell refinery on the Hohe Schaar, 1965
of the soakaways, was a reminder to Wilhelmsburg’s population of the powder keg they were sitting on in such close proximity to industrial operations. From household refuse through to extremely toxic industrial waste, the city of Hamburg had been dumping practically everything discarded by consumer society here since 1945. The outrage was expressed in major protests; there were hearings with experts and politicians, culminating in an international symposium to draw up a restoration plan. Wilhelmsburg’s population felt abandoned and political disenchantment was widespread. In fact, it was the residents of Wilhelmsburg themselves who in 1995 brought about a rapid acceleration in the turnaround process by coming up with the slogan “Stadtteilentwicklung statt Müllverbrennung!” (“Urban development not refuse incineration!”), following the attempt by the Senate to consolidate Wilhelmsburg’s role as the city’s backyard with the construction of a new rubbish incineration plant. The wind has since changed direction in this long-neglected area of the city. The first future-
WILHELMSBURG ON THE WAY TO THE FUTURE OF RENEWABLE ENERGIES
39
METHODOLOGY AND STRATEGY DEVELOPMENT
DIETER D. GENSKE, JANA HENNING-JACOB, THOMAS JOEDECKE, ARIANE RUFF
The Basics and the Initial Situation
The goal is the transformation of the fossil fuel/nuclear city into a solar, sustainable city that is ultimately able to source 100 per cent of its supply from renewable energy.
The IBA Hamburg’s key theme of “Stadt im Kli-
consideration of additional energy protagonists
mawandel” (“Cities and Climate Change”) is a
will form the subject of later reviews.
reaction to the current challenges facing cities
Energy potential needs to be compared with the
as a result of climate changes and the growing
energy requirements necessary for electricity
scarcity of fossil fuel resources. The goal is the
generation and heating. To this end, a scenario
transformation of the fossil fuel/nuclear city
analysis
into a solar, sustainable city that is ultimately
1. determines the current and long-term devel-
able to source 100 per cent of its supply from
opment of energy requirements
renewable energy. This transformation is taking
2. establishes the potential for energy savings
place at a sociocultural, urban planning, eco-
3. examines the options for increasing efficiency,
nomic, and ecological level and requires entirely new strategies. Meeting the energy requirements within the
and 4. analyses the impact of implementing renewable energy.
IBA area solely by means of renewable energy
This then allows measures to be deduced for
will save resources. Decentralised renewable
optimising energy supply and reducing green-
energy production also reduces ecological energy footprints extra muros. This means that
house gases.
no resources will be consumed from outside
forecast horizon of 2050, each of them being
the IBA area, no space will be taken up, and no
considered with two different scenarios:
greenhouse gases will be emitted. The regen-
1. The IBA Hamburg’s starting year, 2007
erative energy supply, the increased energy
2. The IBA Hamburg’s final year, 2013
efficiency, and the reduced energy consumption
3. The European Commission’s target year of
will reduce greenhouse gas emissions, particularly CO2, within the IBA area. The different energy consumers—households, commerce, trade, service providers, industry, and mobility—have to share energy resources. Each of these energy protagonists has their own spatial resources that they can utilise for
Four periods are determined up until the
2020, also the city of Hamburg’s target year for the reduction of greenhouse gas emissions by 40 per cent 4. The EU’s target year of 2050, by which time CO2 emissions in all of the industrialised nations are to have been reduced by up to 95 per cent in comparison to 1990.
energy production. The areas to be used for
The first projects aimed at the goal of post-
energy purposes comprise not only wasteland,
fossil fuel energy supplies on the Elbe Islands
open areas, and traffic areas in the urban envi-
are being implemented within the scope of the
ronment, but more specifically roof and façade
IBA up until 2013.
surfaces. Only households, commerce, trade, and service providers are taken into consideration as energy protagonists here. The further
METHODOLOGY AND STRATEGY DEVELOPMENT
43
Energy Savings and Energy Efficiency
of the forecast horizon. The efficiency of the
The urban environment harbours diverse op-
and that of the twenty-forties generation about
tions for increasing energy efficiency. With
40 per cent greater. In the interests of simplici-
private households currently using two-thirds
ty, an increase in photovoltaic module efficiency
of their overall energy requirements for space
of around 30 per cent in comparison with today
heating, the renovation of residential buildings
is assumed for the time period up to 2050.
2030s generation photovoltaic module is around 25 per cent greater than that of today,
in particular represents tremendous savings potential. The following measures1 ought to be undertaken to reduce energy consumption: 1. Reduction of energy consumption through
Fluctuations in Energy Consumption The energy requirements of all energy consum-
non-investment measures such as changing
ers are subject to fluctuations. The demand
user behaviour, through improved control of
fluctuations are seasonal, weekly, and daily,
heating and hot water, for instance
and affect electricity as well as heating and
2. Building shell renovations (roof, windows, and façade) 3. Renovation of the building’s utilities aimed
hot water supplies. The fluctuations in electricity demand are still compensated via the grid, but in the future they will have to be absorbed
at increased efficiency, in particular through
by means of smart grid technology and the
improved installations technology
development of electricity storage (with the
4. Supply of remaining energy requirements
introduction of electric cars, for instance).
through renewable energy production in and
The calculation of the seasonal fluctuations in
on the building and on the Elbe Islands
heating demand is based on the heating days 08 Abb.1_GuA
01 Development of the heating energy standard in Germany from 1990 to the present
Carrying out all of the necessary construction measures together within the scope of overall
Heating energy standards
renovations is both more efficient and makes economic sense. The renovation rate and depth form the parameters of the renovation
250
process. The target values for new buildings have been set as the values prescribed in the German Thermal Insulation and Energy Savings Regulations (WSVO, EnEV), as well as the more far-reaching IBA standards in the excellence scenarios. In addition to heating energy requirements, hot water and electricity demand can also be reduced by efficiency measures. With regard to energy production, the replacement of older installations results in an increase in technical efficiency, in addition to the building measures. The generation of renewable energy can be
Heating energy standards (final energy) [kWh/m2a]
and for the renovation of residential buildings 200
2. WSchVo (Thermal Insulation Regulations) 1984
150 3. WSchVo 1995 100 1. EnEV (German Energy Saving Regulations) 2002 2. EnEV 2007
50
3. EnEV 2009
increased by the use of efficient photovoltaic units on the roof and on the building shell in particular. It is assumed that all photovoltaic units will have been replaced at least once by the end
44
1990
2000
2010
2020 Time [a]
2030
2040
as their greenhouse gas emissions.
Seasonal fluctuations
This forms the basis for determining both the current and the future energy demands for the urban and landscape environment types.
0.16
This is followed by an analysis of the efficiency pro rata demand [%]
and savings potential, involving the determina0.12
Standardised hot water demand
tion of the type of energy to be saved, to what degree, in which urban and landscape environment type. Of particular importance here are
0.08
Standardised heating energy demand
0.04
the heating requirements that, as indicated, can be considerably reduced through building renovations. Furthermore, linking buildings by means of modern technology enables the pro-
Dec
Nov
Oct
Sep
Aug
Jul
Jun
May
Apr
Mar
Feb
Jan
duction of renewable energy in diverse forms and in a very efficient manner. In the next step, the different options for regenerative energy production in the IBA area are 02 Seasonal fluctuations in heating energy and hot water demand
of the German Weather Service (DWD) and the
examined and their potential assessed. Mapping
local climatic conditions applying to Hamburg,
the energy capability of the urban and land-
expressed as the number of degree days. This
scape environments forms the central focus
enables an estimation of the heating require-
of the analysis. One selection criterion is the
ments for each heating month. The estimation
surface relevance. Certain forms of renewable
of hot water demand is based on the guidelines
energy production are surface-neutral, meaning
of the German Engineers’ Association.2 The consequences of climate change in the
that they are “invisible” in the urban environ-
form of rising temperatures over the forthcom-
space. This applies to geothermal probes or
ing decades have been taken into account in
wastewater heat recovery, for example, as
these scenarios. The optimistic scenario in the Norddeutsche Klimaatlas (North German
well as to roof- and façade-surface integrated
Climate Atlas) by the Norddeutsche Klimabüro
to these are options requiring additional space,
(North German Climate Office) assumes an
such as an open-area photovoltaic unit or else
average temperature increase of one degree
the cultivation of biomass. These spaces are
Celsius by 2050.
then no longer available for other uses such as
ment or that they do not take up any additional
photovoltaic or solar thermal units. In contrast
the cultivation of foodstuffs.
Methodology
This needs to form the basis for developing a strategy that
Adapting the urban environment to the use of renewable energy sources as well as to the more efficient and sparing use of resources is a multifaceted task. It confronts cities with tremendous challenges that they will only be able to meet through a co-ordinated strategy.
1. eliminates the dependency on fossil fuel energy sources 2. focuses on renewable energy that, ideally, does not require additional space 3. saves resources and/or makes efficient use of materials, creating sustainable cycles.
In the first step, the model environment is divid-
The important foundations of sustainable
ed into homogeneous energy units. Urban and
energy supplies are the spatial and tempo-
landscape environment types are developed,
ral matching of potential with the urban and
types that are comparable with regard to their
landscape environments’ energy requirements,
energy demand, their suitability for energy pro-
as well as intelligent load management. Heating
duction, and their increased efficiency, as well
requirements in particular need to be met in
METHODOLOGY AND STRATEGY DEVELOPMENT
45
close proximity to consumers as the transportation and storage of heat entails substantial losses.
08 abb.3_TeilA
Methodology
Energy sources such as coal, natural gas, oil, or biomass can be converted into heating directly Divided according to prototype urban and landscape environments
by consumers but these options are either not sustainable, not efficient, or are limited in terms of their potential. For this reason, within the IBA area, preference is given to either decentralised options for renewable heating supplies or
Determination of current energy demand
Determination of efficiency potential
Determination of long term energy demand
Determination of potential energy yields
renewable heating networks. The IBA projects are targeted initiatives for meeting the established heating and electricity requirements through renewable energy. Heating can be produced in a wide range of regenerative ways, while the simplest and most flexible
Determination of self-sufficiency coverage
way to generate electricity is via photovoltaic units (on buildings) and wind energy (in the urban and landscape environment). In principle, therefore, in all areas where heating can be
Determination of CO2-equivalent savings
provided by other renewable energy sources, the existing roof and/or façade surfaces are being fitted with photovoltaic rather than solar
GIS visualisation
thermal units for the purposes of electricity production. The visualisation of the energy demand and of the renewable energy potential, as well as the
Optimisation
comparison between potential and demand by means of coverage maps, clearly illustrate the energy strengths and weaknesses of the IBA region and the individual urban and landscape
retreat of the glaciers resulted in the formation
environment types.
of glacial lakes, in which initially fine sand and
03 Procedures in developing the methodology
later clay were deposited. This clay is typical of
The Natural Environment
North Germany and is called Lauenburg Clay
The structure of the natural environment in the
after the town of Lauenburg on the River Elbe.3 As it is barely permeable to water it seals the
IBA area was determined by the Pleistocene, or
ice age channels (as artesian wells), thus creat-
the Ice Age (approximately 1.8 million to 12,000
ing independent aquifers.
years ago). Almost half a million years ago, the
The glaciers finally retreated for the last time
glaciers advancing from Scandinavia covered
NN15,000 years ago, leaving behind landabout
what is now Hamburg. They retreated on a
forms that are still visible today and that are
repeated basis, only to return again later. Melt
characterised by glacial, fluvial, and aeolian (de- 100
08 abb.4_TeilA
water beneath the ice sheet created channel
Geological profile Geologisches Profil
posited by glaciers, water, and wind) sediments.
systems cutting deep into the pre-Ice Age (ter-
They formed ground and terminal moraines
tiary) sediments. The glaciers deposited a de-
as well as a specific (glaciofluvial) morphology
bris of clay and marlstone, as well as both fine
with alluvial deposits (sandy areas), eskers, and
and coarse sediments (clays, sands, pebbles,
- 300 mounds (kames). The melt waters flowed gravel
stones, and boulders) in these channels. The
into the glacial valley of the River Elbe. The Elbe
- 200
- 400
46
- 500
Top GOKground surface back filling/clay Auffüllung / Klei Sands Sande (Quartär) (Quarternary) Upper clay Oberermica Glimmerton (Tertiary) (Tertiär) Clays/sands Tone / Sande (Tertiary) (Tertiär) Channel filling Rinnenauffüllung Glacial drift Geschiebemergel (Quarternary) (Quartär) Sands (Quartär) Sande (Quarternary) Lauenburg clay Lauenburger (Quarternary) Ton (Quartär)
eilA
The Urban Environment
Geological profile
The industrial and harbour growth was accomNN
Top ground surface back filling/clay Sands (Quarternary) Upper mica clay (Tertiary) Clays/sands (Tertiary)
- 100
- 200
- 300
Channel filling Glacial drift (Quarternary)
- 400
Sands (Quarternary) Lauenburg clay (Quarternary)
- 500
[m]
West
04 Geological profile of Hamburg-Wilhelmsburg (simplified after GLA-Hamburg 2009)
East
panied by a wave of urban development that brought with it a significant expansion in housing construction for the rapidly growing population. At the end of the nineteenth century, targeted housing construction saw the development of Wilhelmsburg into the industry and harbour workers’ quarter. The acceleration of the armaments industry during the Third Reich reinforced this trend, with Volkswohnungen (municipal housing) being built in the southern Reiherstieg district.4 The autobahn was built in 1935–36, forming a further north-south barrier and cutting the south-east section of Wilhelmsburg off from the further developments on the Elbe Island as a nature and landscape zone. Wilhelmsburg was bombed by the Allies in 1944.5 Almost
Island of Wilhelmsburg forms part of this glacial
the entire harbour industry, as well as many
valley. The ensemble of exposed, partly eroded
residential buildings, were destroyed.
gravel forms is referred to as geest, a sandy,
The storm floods of 1962 constituted a grave
stony, and generally infertile landform contrast-
historical landmark. When the dykes broke in
ing with the fertile marshes still being formed
Wilhelmsburg during the night of 16/17 Febru-
by rivers and oceans today.
ary, the majority of the more than three hun-
The development of the Hanseatic city has
dred flood victims drowned in the single-storey
caused a significant metamorphosis of this original natural environment. River courses have
makeshift homes and shacks built following the end of the war.6 Following the flood catastro-
been filled in and canals created, with consider-
phe, the Hamburg senate initially abandoned
able intervention in the morphology of the area.
Wilhelmsburg as a residential location.7 It was
The result, over the centuries, has been an
only with the key Sprung über die Elbe (Leap
urban environment with technically functional
over the Elbe) project that Wilhelmsburg’s ur-
sectors adapted to the needs of a harbour
ban character was rediscovered by Hamburg’s
city. On the Elbe Island of Wilhelmsburg these include the harbour basin, the coastal defences
city planners.8 The nature of Wilhelmsburg’s past has meant
and the traffic embankments.
that only few historical urban planning testimonies survive. In most cases, these are fragments and solitary buildings that constitute only a limited reflection of the urban planning guidelines in force at the time of their construction. This has led to a tremendous diversity of urban planning and architectural structures and typologies. These include:
. pre-industrial village-like settlement remnants
. neighbourhoods laid out according to nineteenth-century (historicism, 1840–approximately 1930) principles of urban and artistic
METHODOLOGY AND STRATEGY DEVELOPMENT
47
development (Camillo Sitte and Lenné)
. urban expansion in accordance with the
area utilisation changes as well as the implementation of new heating energy standards
welfare principle of the nineteen-twenties
(Low Energy and Passive House Standard),
and nineteen-thirties, characterised by the
resulting in the introduction of four new urban
influence of Hamburg’s senior director of
environment types (VIIc+, IXb+, Xc+, Xa+). Over-
construction Fritz Schumacher . settlement areas in the garden city and
all, twenty-three prototype urban environments
Siedlerheimstadt (settler home) tradition of the nineteen-thirties and nineteen-fifties . reconstruction ensembles from the nineteenforties and nineteen-fifties with reconstructed building components based on the original construction (rows of housing, reconstructive rebuilding, new buildings with traditional adaptations) . examples of “Urbanity through Density” (1960–70), the consolidated “subdivided and detached city” (Athens Charter, 1933) with its spatial segregation of living, working, service providers, and leisure, as well as vertical residential units situated in green belts (example: “Interbau,” IBA Berlin 1957)9 . single-family home areas dating from the nineteen-sixties through to the nineteennineties . examples of the prudent urban transformation and renewal of the nineteen-eighties as “critical reconstruction” (example: IBA Berlin 1984) . urban development measures since the nineteen-nineties, principally directed at sustainability (example: IBA Emscher Park 1989–99) . commercial, industrial, and purpose-built constructions. These are the urban development models characterising the existing buildings in the urban environment.10 They determine urban characteristics such as area ground plans, building patterns, density, existing open spaces, compactness, external and internal access systems, and so forth.
distinguished for the area under consideration
and three landscape environment types were (Fig. 5). The residential and mixed construction category is dominated by single family home areas (IX) and village-like, small-scale patterns (IV) with approximately 17 per cent of the built-up area. Overall, industrial and harbour areas (Xb) take up the largest proportion of space at approximately 55 per cent. In the undeveloped category, the green and water areas (XII, XIVb) make up approximately 60 per cent and agricultural land (XIII) 8 per cent. The model area comprises a total of 3,613 ha, 33 per cent of which being built up in the reference year 2007. The individual urban and landscape environments constitute zones dominated by a specific prototype. Individual buildings or small landscape elements can deviate from the zoning within an urban or landscape environment.
Urban Environment Types Based on a detailed analysis of the historical development of the model,11 the IBA area was divided into spatial prototypes, with imminent
48
05 Relative proportion of different city environments in the developed area and of the developed area in relation to the overall IBA area 2007
08 Abb.6_GuA Surface proportion of the urban and landscape environment types in 2007
Pre-industrial/historic city centre < 1840 (I)
(0,16 ha)
Nineteenth-century construction units < 1938 (IIa)
(9,68 ha)
Nineteenth-century and pre-war imitative buildings > 1990 (IIb)
(2,33 ha)
Nineteenth-century and pre-war villas < 1938 (IIc)
(2,38 ha)
Reconstructed areas 1950s (III)
(7,62 ha)
Village-like, small-scale (IV)
(30,36 ha)
Nineteenth-century and pre-war company and co-operative housings < 1938 (V)
(27,42 ha)
Urban environment types
1950s social welfare housings (VI)
Residual areas (traffic, disposal, water) (XIVa) 37%
(9,47 ha)
1970s high-rise housings (VII)
(28,77 ha)
Multistorey housings 1960s-1980s (VIIIa)
(34,09 ha)
Multistorey housings 1990s (VIIIb)
Built-up areas 33%
(1,41 ha)
Multistorey housings Low Energy Standard > 2002 (VIIIc)
(0,00 ha)
Multistorey housings Passive House Standard > 2013 (VIIIb+)
(0,00 ha)
Green areas (XII) 22%
Agriculture (XIII) 8%
Single-family home dwellings > 1950 (IXa)
(176,33 ha)
Single-family home dwellings Low Energy Standard > 2002 (IXb)
(2,35 ha)
Single-family home dwellings Passive House Standard > 2013 (IXb+)
(0,00 ha)
Commercial areas (Xa)
(106,53 ha)
Commercial areas Passive House Standard > 2013 (Xa+)
(0,00 ha)
Industry + harbour (Xb)
(655,75 ha)
Functional buildings and public facilities (Xc)
(83,49 ha)
Functional buildings and public facilities Passive House Standard > 2013 (Xc+)
(0,00 ha)
Commercial in mixed use areas (Xd)
(17,51 ha)
Schumacher buildings 1920s–1930s (S1)
(6,85 ha) 0
10
20
30
40
50
60
Percentage [%]
METHODOLOGY AND STRATEGY DEVELOPMENT
49
Prototype Urban Environments (UET) in the IBA Area
08 Abb.5_GuA
Prototype urban environments (UET) in the IBA area Use
UET
Era
Description
Mixed use
I
Pre-1840
Pre-industrial/historic city centre
IIa
Pre-1938
Nineteenth-century construction units
IIb
As of 1990
Nineteenth-century and pre-war imitative buildings
IIc
Pre-1938
Nineteenth-century and pre-war villas
III
1950s
Reconstructed areas
IV
Middle Ages to present
Village-like, small-scale
V
Pre-1938
Nineteenth-century and pre-war company and co-operative housings
VI
1950s
Social welfare housings
VII
1970s
High-rise housings (from about six floors)
VIIIa
1960s-1980s
Multistorey housings
VIIIb
As of 1990s
Multistorey housings
VIIIc
Since 2002
Multistorey housings Low Energy Standard and better
»
06 Division of the IBA area into prototypical UET IIa UET IIb UET IIc UET III UET IV UET V urban and green areas in 2007
N
Residential
VIIIc+ As of 2013
Multistorey housings Passive House Standard 1
IXa
As of 1950
Single-family home dwellings
IXb
As of 2002
Single-family home dwellings Low Energy Standard and better 1
IXb+
As of 2013
Single-family home dwellings Passive House Standard 1
Xa
Industrialisation to present
Commercial areas
Xa+
As of 2013
Commercial areas Passive House Standard 1
Industrial
Xb
Industrialisation to present
Industry + harbour
Functional
Xc
Industrialisation to present
Functional buildings and public facilities
Xc+
As of 2013
Functional buildings and public facilities Passive House Standard 1
Commercial I-IV
Xd
Since Industrialisation
Commercial in mixed use areas 2
Special types
S1
1920s-1930s
Schumacher Buildings
Undeveloped
XII
Green areas
XIII
Agriculture
XIV
Residual areas (parking spaces and garages, traffic areas, wastewater treatment plants, disposal sites), Areas of water
Commercial (solely)
SRT I UET
UET SRT IIa
UET SRT IIb
UET SRT IIc
UET SRT VI
UET SRT VII
UET SRT VIIIa
UET SRT IXa
UET SRT IXb
UET SRT IXb+
UET SRT Xc+
UET SRT Xd
UET SRT S1
UET SRT III
UET SRT VIIIb
UET SRT IV
UET SRT VIIIc
UET SRT Xa
UET SRT XII
UET SRT V
UET SRT VIIIc+
UET SRT Xa+
UET SRT XIII
UET SRT Xb
UET SRT Xc
UET SRT XIV
2 2 Low Energy Energy House: House: heating heating energy energy demand requirements 30 kWh/(m a); Passive heating requirements 15 kWh/(m2a). of 30 of kWh/(m a); Passive House:House: heating energyenergy demand of maximumof15maximum kWh/(m2a). In ground ground floors floors of of nineteenth-century 19th-century construction units, imitative buildings, reconstructed areas,areas,nineteenth-century 19th-century villas, village-like and ofareas historic In construction units, imitative buildings, reconstructed villas,areas village-like andcity centres. of historic city centres.
11
2 2
00
50
500 500
1.000 1.000 Meter metre
51
08 Abb.5_GuA
Prototype urban environments (UET) in the IBA area Use
UET
Era
Description
Mixed use
I
Pre-1840
Pre-industrial/historic city centre
IIa
Pre-1938
Nineteenth-century construction units
IIb
As of 1990
Nineteenth-century and pre-war imitative buildings
IIc
Pre-1938
Nineteenth-century and pre-war villas
III
1950s
Reconstructed areas
IV
Middle Ages to present
Village-like, small-scale
V
Pre-1938
Nineteenth-century and pre-war company and co-operative housings
VI
1950s
Social welfare housings
VII
1970s
High-rise housings (from about six floors)
VIIIa
1960s-1980s
Multistorey housings
VIIIb
As of 1990s
Multistorey housings
VIIIc
Since 2002
Multistorey housings Low Energy Standard and better
»
06 Division of the IBA area into prototypical UET IIa UET IIb UET IIc UET III UET IV UET V urban and green areas in 2007
N
Residential
VIIIc+ As of 2013
Multistorey housings Passive House Standard 1
IXa
As of 1950
Single-family home dwellings
IXb
As of 2002
Single-family home dwellings Low Energy Standard and better 1
IXb+
As of 2013
Single-family home dwellings Passive House Standard 1
Xa
Industrialisation to present
Commercial areas
Xa+
As of 2013
Commercial areas Passive House Standard 1
Industrial
Xb
Industrialisation to present
Industry + harbour
Functional
Xc
Industrialisation to present
Functional buildings and public facilities
Xc+
As of 2013
Functional buildings and public facilities Passive House Standard 1
Commercial I-IV
Xd
Since Industrialisation
Commercial in mixed use areas 2
Special types
S1
1920s-1930s
Schumacher Buildings
Undeveloped
XII
Green areas
XIII
Agriculture
XIV
Residual areas (parking spaces and garages, traffic areas, wastewater treatment plants, disposal sites), Areas of water
Commercial (solely)
SRT I UET
UET SRT IIa
UET SRT IIb
UET SRT IIc
UET SRT VI
UET SRT VII
UET SRT VIIIa
UET SRT IXa
UET SRT IXb
UET SRT IXb+
UET SRT Xc+
UET SRT Xd
UET SRT S1
UET SRT III
UET SRT VIIIb
UET SRT IV
UET SRT VIIIc
UET SRT Xa
UET SRT XII
UET SRT V
UET SRT VIIIc+
UET SRT Xa+
UET SRT XIII
UET SRT Xb
UET SRT Xc
UET SRT XIV
2 2 Low Energy Energy House: House: heating heating energy energy demand requirements 30 kWh/(m a); Passive heating requirements 15 kWh/(m2a). of 30 of kWh/(m a); Passive House:House: heating energyenergy demand of maximumof15maximum kWh/(m2a). In ground ground floors floors of of nineteenth-century 19th-century construction units, imitative buildings, reconstructed areas,areas,nineteenth-century 19th-century villas, village-like and ofareas historic In construction units, imitative buildings, reconstructed villas,areas village-like andcity centres. of historic city centres.
11
2 2
00
50
500 500
1.000 1.000 Meter metre
51
Scenarios
corresponds to about 18 per cent of the built-up area. Commercial areas experience the greatest
Both the reference and the excellence scenarios
increase in area, with an almost three-fold in-
assume a change in the area distribution of
crease to more than 292 hectares. In the single
the urban and landscape environment types.
family home category (IXb, IXb+) the area in-
The implementation of new heating energy
crease amounts to 55 hectares. The category of
standards (Low Energy and Passive House
multistorey housing with high energy standards
Standard) means that the urban environment
(VIIIc, VIIIc+) assumes growth amounting to 84
types multistorey housing (VIIIc+), single-family
hectares, while the proportion of industrial and
homes (IXb+), purpose-built constructions, and
harbour areas declines by 93 hectares.
public facilities (Xc+), as well as commercial (Xa+) in particular, are increasing.
Scenario Comparison A comparison of the area development in the
Reference Scenarios
two scenarios makes it clear that there is a
The reference scenarios implement contempo-
smaller proportion of single-family homes in the
rary plans in accordance with construction and
excellence scenarios, while the proportion of
land use planning. The proportion of built-up
multistorey housing is greater, thus achieving a
areas increases in the reference scenarios by
higher urban development density. The decline
about 200 hectares from 2007 to 2050. This
in industrial and harbour areas is twice as high
equates to an increase of around 17 per cent
in the excellence scenario as in the reference
for the built-up area. Commercial areas make
scenario. The reason for this is the much more
up the largest proportion. They will more than
extensive conversion of industrial and harbour
double (from approximately 106 hectares in
areas into commercial and residential areas,
2007 to about 228 hectares in 2050). The pro-
through the IBA project “Neue Mitte Wil-
portion of industrial and harbour area declines
helmsburg” (“New Wilhelmsburg Centre”), for
by 46 hectares, on the other hand. In the single-
instance.
family home category, the building types with
The energy demand and renewable energy
high energy standards (IXb, IXb+) in particular
production developments in the prototype
increase in area from about 2 to about 96
urban and landscape environments depend on
hectares by 2050, while the area covered by
the scenario in question, with distinctions being
the remaining, conventional single-family home
made between the reference scenarios and ex-
category declines slightly due to demolition and
cellence scenarios. The first case—the reference
renovation. The area covered by the urban en-
scenarios—is a continuation of current develop-
vironment types featuring high heating energy
ments; the minimum legislative requirements
standards for multistorey housing (VIIIc, VIIIc+)
for the energy-efficiency of buildings and the
will increase to 52 hectares.
foreseeable technological developments of the next few years are assumed. The second case—
Excellence Scenarios
the excellence scenarios—exploits and imple-
The IBA projects have meant the definition
ments innovative and future-oriented energy
of new development areas in the excellence
concepts.
scenarios, bringing significant changes to the zoning development and leading to a greater building density. The IBA projects also led to the more rapid implementation of the higher heating energy standards. The proportion of built-up areas in the excellence scenarios increases by a total of around 211 hectares between 2007 and 2050. This
52
Wilhelmsburg Central Concrete designs and development areas, up to the port of Spreehafen
07 Development of prototypical urban and landscape areas within the IBA area in the reference scenario to 2050
Pre-industrial/historic city centre pre-1840
»
Nineteenth-century construction units pre-1938 Nineteenth-century imitative buildings since 1990
N
Nineteenth-century villas pre-1938 Nineteen-fifties reconstructed areas Village-like, small-scale Company and co-operative housing pre-1938 Nineteen-fifties social welfare housing Nineteen-seventies high-rise housing (as of approx. six floors) Multistorey housing 1960s–1980s Multistorey housing since 1990 Multistorey housing Low Energy Standard since 2002 Multistorey housing Passive House Standard as of 2013 Single-family home dwellings since 1950 Single-family home dwellings Low Energy Standard since 2002 Single-family home dwellings Passive House Standard as of 2013 Schumacher buildings 1920s–1930s Commercial areas from Industrialisation to present Commercial areas Passive House Standard as of 2013 Functional buildings and public facilities from Industrialisation to present Functional buildings and public facilities Passive House Standard as of 2013 Industry and harbour from Industrialisation to present Green areas Agricultural/horticultural areas Residual areas 0
500
1000 500 metre
0
0
0 500 1.000 Meter
54
500
2010
2050 1.000 Meter
1.000 Meter
0 500 1.000 Meter
2020
0 500 1.000 Meter
2030
08 Development of prototypical urban and landscape areas within the IBA area in the excellence scenarios to 2050
Pre-industrial/historic city centre pre-1840
»
Nineteenth-century construction units pre-1938 Nineteenth-century imitative buildings since 1990
N
Nineteenth-century villas pre-1938 Nineteen-fifties reconstructed areas Village-like, small-scale Company and co-operative housing pre-1938 Nineteen-fifties social welfare housing Nineteen-seventies high-rise housing (as of approx. six floors) Multistorey housing 1960s–1980s Multistorey housing since 1990 Multistorey housing Low Energy Standard since 2002 Multistorey housing Passive House Standard as of 2013 Single-family home dwellings since 1950 Single-family home dwellings Low Energy Standard since 2002 Single-family home dwellings Passive House Standard as of 2013 Schumacher buildings 1920s–1930s Commercial areas from Industrialisation to present Commercial areas Passive House Standard as of 2013 Functional buildings and public facilities from Industrialisation to present Functional buildings and public facilities Passive House Standard as of 2013 Industry and harbour from Industrialisation to present Green areas Agricultural/horticultural areas Residual areas
2050 0
0
0 500 1.000 Meter
500
01000 500
500
metre
2010
1.000 Meter
1.000 Meter
0 500 1.000 Meter
2020
0 500 1.000 Meter
2030
METHODOLOGY AND STRATEGY DEVELOPMENT
55
In the reference scenarios, the number of residents increases by approximately 14,000 between 2007 and 2050, in the excellence scenarios, on the other hand, by almost 18,000.
09 Population development within the IBA area in the reference and excellence scenarios
Population Development
The fact that the area occupied by the individual urban environment types differs in the
The population prognosis for the city of Ham-
reference and excellence scenarios results in
burg up to 2030 forecasts a slight population
differing values with regard to the development
increase, with the number of residents declining
of resident numbers, indicated in the tables. In
as of 2030.12 The IBA Hamburg assumes stable
the reference scenarios, the number of resi-
population development in the areas of existing
dents increases by 13,980 between 2007 and
buildings within the IBA area. There will be a
2050, in the excellence scenarios, on the other
population increase in the planned new devel-
hand, by 17,898. The higher number of residents
opment areas.
in the excellence scenarios, approximately
The specific urban environment population
4,000 residents in 2050, derives from the as-
density—residents per hectare—and the specific
sumptions of area use changes with a greater
urban environment household size—members
proportion of multistorey housing. Accordingly,
per household—(Figs. 15 and 16) are the impor-
the additional population primarily lives in the
tant factors for determining the households’
urban environment type multistorey housing to
hot water and electricity requirements. For the
Passive House Standard (VIIIc+).
sake of simplicity, it is assumed that the specific
As a result of consolidated construction meth-
urban environment population and household
ods and the increased appeal of the living en-
densities remain unchanged in the future. This
vironment through high energy standards, the
assumption applies to both the reference and
population density in the Excellence Scenario
the excellence scenarios.
sees a greater increase than in the Reference
08 Abb.19_GuA
Scenario. An increase in density of 12.8 percent in the Excellence Scenario as opposed to 7.4
Demographic development
percent in the Reference Scenario is testimony to the improved quality of the environment.
75.000 73.078
Residents in the IBA area
70.000
69.160
65.391 65.000 62.817 60.000 Excellence scenario
57.251 56.489 55.000
2007
56
Reference scenario
55.180 2013
2020 2030 Time [a]
2040
2050
08 08Abb.17_GuA Abb.17_GuA
ECA per ha/UET in ha 2
Residents per ha UET 4
Living area per unit value in m2
I
Pre-industrial/historic city centre < 1840
1,2
0,77
7680
334
22,99
0,21
0,21
0,21
0,21
71
70
70
70
IIa
Nineteenth-century construction units < 1938
2
1,28
12800
520
24,62
12,91
12,84
12,53
12,53
6711
6676
6514
6514
IIb
Nineteenth-century and pre-war imitative buildings > 1990
2
1,28
12800
520
24,62
3,11
3,11
3,11
3,11
1619
1619
1619
1619
IIc
Nineteenth-century and pre-war villas < 1938
0,3
0,19
1920
29
66,21
3,17
3,17
3,17
3,17
92
92
92
92
III
Reconstructed areas 1950s
2
1,28
12800
555
23,06
10,16
10,01
9,92
9,92
5640
5554
5503
5503
IV
Village-like, small-scale
0,3
0,19
1920
29
66,21
40,5
40,5
40,5
39
1174
1174
1174
1130
1
0,64
6400
256
25
27,4
27,3
27,3
27,3
7021
6977
6977
6977
0,5
0,32
3200
123
26,02
9,47
9,47
9,47
9,47
1164
1164
1164
1164
1
USE Urban environment types
ECA per ha/UET in m2 3
FAR
5
Development of resident numbers in the IBA model area reference scenario in the period 2007 to 2050
Residents 7
Total UET area in ha 6 2007
2013
2020
2050
2007
2013
2020
2050
MIXED USE
RESIDENTIAL V
Nineteenth-century and pre-war housings < 1938
VI
1950s social welfare housings
VII
1970s high-rise housings
1,3
0,83
8320
363
22,92
28,77
28,77
28,77
28,77
10445
10445
10445
10445
VIIIa Multistorey housings 1960s–80s
0,8
0,51
5120
199
25,73
34,1
34,1
34,1
34,1
6783
6783
6783
6783
VIIIb Multistorey housings 1990s
0,8
0,51
5120
199
25,73
1,41
1,4
1,4
1,4
280
279
279
279
VIIIc Multistorey housings Low Energy Standard
0,8
0,51
5120
199
25,73
5,03
5,03
1000
1000
VIIIc+ Multistorey housings Passive House Standard
0,8
0,51
5120
199
25,73
0
30,3
0
6022
172,58
172,68
8456
8412
IXa
Single-family home dwellings > 1950
0,35
0,22
2240
49
45,71
IXb
Single-family home dwellings Low Energy Standard
0,35
0,22
2240
49
45,71
15,9
15,9
779
779
0,35
0,22
2240
49
45,71
0
12,4
0
609
IXb+ Single-family home dwellings Passive House Standard
176,33
168,14
8640
8239
COMMERCIAL (SOLELY) Xa
Commercial areas
1
0,64
6400
0
106,53
106,93
178,23
228,54
0
0
0
0
Xa+
Commercial areas Passive House Standard
1
0,64
6400
0
0
0
0,73
0,73
0
0
0
0
1
0,64
6400
0
656
652
672
610
0
0
0
0
INDUSTRIAL Xb Industry + harbour FUNCTIONAL Xc
Functional buildings and public facilities
2
1,28
12800
8
83,5
83
77,1
75,4
668
664
617
603
Xc+
Functional buildings Passive House Standard
2
1,28
12800
8
0
0
0
0
0
0
0
0
2
1,28
12800
694
6,85
6,85
6,85
6,85
4756
4756
4756
4756
1213,25
1341,03
56489
62817
SPECIAL TYPES S1
Schumacher buildings 1920S–30S
TOTALS / AVERAGE VALUES Assumed average floor-area ratios based on the Federal Land Use Ordinance BauNV (§17) and Everding (2007), as well as own estimates. Energy consumption area per hectare of urban environment type, in ha. 3 Energy consumption area per hectare of urban environment type in square metres (calculation basis for average living area per resident 2007, cf. 5). 4 Calculated residents per hectare of urban environment type 2007 (calculation basis for residents per statistical area—empirical study). 1
2
58
18,44 25,97
5 Calculated average living area per resident in the respective urban environment type, in square metres. 6 Overall urban environment type area in hectares during this period (illustrates the area development). 7 Calculated number of residents in the respective urban environment types.
08 Abb.18_GuA
ECA per ha/UET in ha 2
Residents per ha UET 4
Living area per unit value in m2
1,2
0,77
7680
334
22,99
0,21
0,21
0,21
0,21
71
70
70
70
Nineteenth-century construction units < 1938
2
1,28
12800
520
24,62
12,91
12,83
12,52
12,52
6711
6672
6510
6510
IIb
Nineteenth-century and pre-war imitative buildings > 1990
2
1,28
12800
520
24,62
3,11
3,11
3,11
3,11
1619
1619
1619
1619
IIc
Nineteenth-century and pre-war villas < 1938
0,3
0,19
1920
29
66,21
3,17
3,17
3,17
3,17
92
92
92
92
III
Reconstructed areas 1950s
IV
Village-like, small-scale
1
USE Urban environment types
ECA per ha/UET in m2 3
FAR
5
Development of resident numbers in the IBA model area excellence scenario in the period 2007 to 2050
Total UET area in ha 6
Residents 7
2007
2013
2020
2050
2007
2013
2020
2050
MIXED USE I
Pre-industrial/historic city centre < 1840
IIa
2
1,28
12800
555
23,06
10,16
10,01
9,92
9,92
5640
5554
5503
5503
0,3
0,19
1920
29
66,21
40,48
40,48
40,48
39,98
1174
1174
1174
1130
1
0,64
6400
256
25
27,42
27,17
27,17
27,17
7021
6956
6956
6956
RESIDENTIAL V
Nineteenth-century and pre-war housings < 1938
VI
1950s social welfare housings
0,5
0,32
3200
123
26,02
9,47
9,47
9,47
9,47
1164
1164
1164
1164
VII
1970s high-rise housings
1,3
0,83
8320
363
22,92
28,77
28,03
27,74
27,73
10445
10176
10069
10065
VIIIa Multistorey housings 1960s–80s
0,8
0,51
5120
199
25,73
34,09
33,31
33,29
32,96
6783
6630
6626
6559
VIIIb Multistorey housing 1990s
0,8
0,51
5120
199
25,73
1,41
1,4
1,4
1,4
280
278
278
278
VIIIc Multistorey housings Low Energy Standard
0,8
0,51
5120
199
25,73
1,23
1,23
245
245
VIIIc+ Multistorey housings Passive House Standard
10,52
51,71
2094
10291
174,91
171,60
8571
8409
0,8
0,51
5120
199
25,73
IXa
Single-family home dwellings > 1950
0,35
0,22
2240
49
45,71
IXb
Single-family home dwellings Low Energy Standard
0,35
0,22
2240
49
45,71
5,88
5,88
288
288
0,35
0,22
2240
49
45,71
5,53
15,48
271
758
0
0
0
0
0
0
IXb+ Single-family home dwellings Passive House Standard
176,33
168,18
8640
8192
COMMERCIAL (SOLELY) Xa
Commercial areas
1
0,64
6400
0
0
Xa+
Commercia lareas Passive House Standard
1
0,64
6400
0
0
4,99
1
0,64
6400
0
0
655,75 650,73 658,37
563,15
0
0
0
0
83,49
66,95
668
611
552
536
30
30
4756
4756
57251
65391
106,53
119,83
207,55 229,20
0
4,99
INDUSTRIAL Xb Industry + harbour FUNCTIONAL Xc
Functional buildings and public facilities
2
1,28
12800
8
Xc+
Functional buildings Passive House Standard
2
1,28
12800
8
2
1,28
12800
694
14,816
148160
76,32
68,97
3,78
3,78
6,85
6,85
SPECIAL TYPES S1
Schumacher buildings 1920S–30S
TOTALS / AVERAGE VALUES Assumed average floor-area ratios based on the Federal Land Use Ordinance BauNV (§17) and Everding (2007), as well as own estimates. Energy consumption area per hectare of urban environment type, in ha. 3 Energy consumption area per hectare of urban environment type in square metres (calculation basis for average living area per resident 2007, cf. 5). 4 Calculated residents per hectare of urban environment type 2007 (calculation basis for residents per statistical area—empirical study). 1
2
18,44 25,97
6,85
1229,78 1364,91
6,85
4756
4756
5 Calculated average living area per resident in the respective urban environment type, in square metres. 6 Overall urban environment type area in hectares during this period (illustrates the area development). 7 Calculated number of residents in the respective urban environment types.
METHODOLOGY AND STRATEGY DEVELOPMENT
59
Renewable Energy Potential in the IBA Area
pumps. Where geothermal energy is used, this
Wind
for any supplementary heating that might be
Only large-scale wind power stations are taken
necessary is disregarded. During the summer
into consideration in the IBA area. Small-scale
months geothermally linked heat pumps (geo-
wind power is disregarded on the grounds of
thermal sensors) could also be used for cooling
low efficiency, acceptance problems, and ad-
purposes.
verse urban environment impact.13
Geothermal sensor potential within the IBA
Photovoltaic and Solar Thermal Technology
area is limited due to the specific geological condition.18, 19 As a result, there are three homo-
With solar energy production a special focus is
geneous areas distinguished here where drill
placed on units that are integrated within the
lengths of twenty-five, fifty, and eighty metres
building shell. Open area units take up extra
are permitted.
has the positive ecological effect of allowing the thermal recovery of the subsoil. The energy
space and so are only resorted to when located on what is otherwise unusable space—such as a
Wastewater Heat Recovery
disposal site, for instance.
Wastewater heat recovery in the IBA area is
The energy yield derives from the irradiation
carried out by means of shafts directly on
characteristic for the region, the unit’s degree
the building. The auxiliary electricity require-
of utilisation, and the space in the urban envi-
ments for operating heat pumps are taken into
ronment available for solar use. The space that
account but wastewater heat recovery is only
is theoretically available needs to be reduced to
economically viable in buildings with more than
an economically meaningful extent due to the
thirty housing units, however.20 With one resident producing an average of
urban parameters, such as possible shadow and listed building regulations, in particular.14 These
100–150 litres of wastewater per day, the heat
constitute what is known as the specific urban
extraction theoretically possible could be
environment type solar figures of merit for
estimated by means of the number of residents
roofs and façades.
per urban environment. Practical projects have
15
For the whole of the IBA area, the heating demand in 2007 amounted to a total of 550 gigawatt-hours per year and the overall electricity demand to 143 gigawatt-hours per year.
since shown that, under favourable conditions, Geothermal Energy
meaning a high energy standard construc-
The energy yield from geothermal sensors
tion, all hot water requirements can be met via
derives from the feasible number of geothermal
wastewater heat recovery.21
sensors per hectare or urban environment and the energy yield per geothermal sensor.16 The energy yield of a geothermal sensor depends on the sensor’s integral length, the ground-specific extraction capacity per meter, and the seasonal performance factor.17 What also needs to be taken into consideration is that the geothermal sensor density that is theoretically possible is limited by technical parameters such as obstructions in the drilling field (trees, canals, piping, space problems) and the risk of the thermal exhaustion of the subsoil. It is therefore assumed that only half of the geothermal sensors that are theoretically possible are implemented technically. It is assumed that possible supplementary heating in summer is not supported by heat
60
10 Current heating, hot water and electricity requirements (2007), according to type of urban area
08 Abb.21_GuA Status quo in the IBA’s Starting Year 2007
Final energy demand of urban environment types [GWh/a]
The status quo is defined as the energy demand and the renewable energy production in
Pre-industrial/historic city centre < 1840 (I)
the IBA’s starting year, 2007. This is the status quo that needs to be improved and converted
Nineteenth-century construction units < 1938 (IIa)
to sustainable energy supplies.
Nineteenth-century and pre-war imitative buildings > 1990 (IIb)
Energy Demand
Nineteenth-century villas < 1938 (IIc)
Energy demand is estimated on the basis of the specific urban environments.22 The heat-
Reconstructed areas 1950s (III)
ing requirements for an urban environment are comprised of heating energy require-
Village-like, small-scale (IV)
ments, hot water demand, and process heat
Nineteenth-century and pre-war company and co-operative housings < 1938 (V)
demand. In Fig. 10 the heating energy demand figure for
Urban environment types
1950s social welfare housings (VI)
purpose-built constructions (Xc), commercial buildings (Xa), and single-family homes (IX) is
1970s high-rise housings (VII)
especially noticeable, which can be attributed to the high proportion of these building types,
Multistorey housings 1960s-1980s (VIIIa)
their specific requirements, and their poor
Multistorey housings 1990s (VIIIb)
Heating
condition from an energy perspective. Hot water energy demand depends on the
Multistorey housings Low Energy Standard > 2002 (VIIIc)
Hot water
household size characteristic of the urban
Multistorey housings Passive House Standard > 2013 (VIIIb+)
Electricity
environment in question and amounted to 890–1050 kilowatt-hours per household member and year for German households in 2005.23 For the IBA’s starting year, 2007, an
Single-family home dwellings > 1950 (IXa) Single-family home dwellings Low Energy Standard > 2002 (IXb)
average consumption of 900 kilowatt-hours per resident and year is assumed. The heating
Single-family home dwellings Passive House Standard > 2013 (IXb+)
requirements for the IBA’s starting year, as illustrated in Fig. 13, derive from heating energy and hot water.24 For the whole of the IBA area,
Commercial areas (Xa)
the heating demand in 2007 amounted to a
Commercial areas Passive House Standard > 2013 (Xa+)
total of 550 gigawatt-hours per year. As is to be expected, the urban area heating
Industry + harbour (Xb)
demand in the consolidated urban environFunctional buildings (Xc)
ments is high. In the commercial areas, process heat demand is also taken into account
Functional buildings Passive House Standard > 2013 (Xc+)
based on current statistics and employee numbers.
Commercial in mixed use areas (Xd)
Overall electricity demand for the IBA area amounts to 143 gigawatt-hours per year. Fig. 14
Schumacher buildings 1920s–1930s (S1)
depicts the electricity demand for the indi0
20
40
60
80
Final energy demand in GWh/a
100
vidual urban environment types. It is clear that the consolidated districts have increased heating and electricity requirements.
METHODOLOGY AND STRATEGY DEVELOPMENT
61
The commercial districts are also characterised by especially high electricity demand. The cur-
CO2 Emissions Building renovations and increasing the propor-
rent electricity requirements here are based on
tion of renewable energy bring about a reduc-
the number of employees in the commercial,
tion in greenhouse gases. The potential for the reduction of CO2-equivalent emissions can thus
trade, and service provider sectors represented
be derived from two components:
in the IBA area.
. Savings through the energy renovation of buildings and more efficient energy supply technology in existing buildings
. Savings through the production and use of renewable energy.
11 Energy demand in individual urban areas in 2007
08 Abb.24_GuA
The CO2-equivalent savings according to urban environment type are based on the difference
Energy demand 2007
electric kWh/EW
Demand per resident (final energy demand)
measures undertaken in each scenario. This
thermal kWh/EW
electric kWh/m2
Demand per energy consumption area (final energy demand) thermal kWh/m2
electric GWh/ha
Demand per hectare UET (final energy demand) thermal GWh/ha
electric GWh/a
thermal GWh/a
Urban environment types
Absolute demand per UET (final energy demand)
USE
in emissions before and after the energy-saving
Pre-industrial/historic city centre < 1840
IIa
Nineteenth-century construction units < 1938
IIb
effect that the funding of energy renovations in the individual urban environments will have on CO2 reduction. The CO2-equivalent emissions are further reduced by the production and use of renewable energy. CO2 credits result when the electric-
MIXED USE I
enables localisation that then illustrates the
ity produced using renewable energy exceeds
0,29
0,05
1,84
0,32
239
42
4107
721
25,84
5,20
2,67
0,54
209
42
3851
775
electricity deficit has to be compensated by the
Nineteenth-century and pre-war imitative buildings > 1990
3,89
1,26
1,66
0,54
130
42
2400
775
established electricity mix. The Federal German
IIc
Nineteenth-century and pre-war villas < 1938
1,07
0,16
0,45
0,07
234
34
n/a
n/a
III
Reconstructed areas 1950s
20,10
3,51
2,64
0,46
206
36
3564
623
mix that will become ever “greener” in the decades to come.25 The emission factor of the
IV
Village-like, small-scale
8,95
1,87
0,29
0,06
154
32
n/a
n/a
typical Wilhelmsburg heating mix is assumed
demand. It needs to be noted that a renewable
electricity mix emission factor is assumed, a
for a renewable heating deficit (Table 19).26, 27
RESIDENTIAL
Energy production using fossil fuel energy is
V
19th-century and pre-war company and co-operative housings
38,61
6,32
1,41
0,23
220
36
5500
900
predominant in the IBA’s starting year. Heat-
VI
1950s social welfare housing
7,08
1,27
0,75
0,13
234
42
6079
1093
ing energy and hot water demand is met by a
VII
1970s high-rise housings
50,58
8,86
1,76
0,31
211
37
4842
848
VIIIa
Multistorey housings 1960s–1980s
36,65
6,28
1,08
0,18
210
36
5403
926
ation is not connected to the Hamburg district
VIIIb
Multistorey housings 1990s
0,94
0,26
0,67
0,18
131
36
3374
927
heating network; there is only a relatively small
VIIIc
Multistorey housings Low Energy Standard
0,00
0,00
0,00
0,00
60
36
n/a
n/a
VIIIc+ Multistorey housings Passive House Standard
0,00
0,00
0,00
0,00
45
36
n/a
n/a
solar collectors is negligible, while electricity
IXa
Single-family home dwellings
74,13
13,43
0,42
0,08
188
34
8580
1554
demand is also largely met by conventional
IXb
Single-family home dwellings Low Energy Standard
0,32
0,18
0,13
0,08
60
34
n/a
n/a
IXb+
Single-family home dwellings Passive House Standard
0,00
0,00
0,00
0,00
45
34
n/a
n/a
SPECIAL TYPES S1
Schumacher buildings 1920s–1930s
variety of energy sources (heating oil, gas, coal) and by electricity. The area under consider-
island network in the eastern section of Central Wilhelmsburg. Hot water supply by means of
means. The model assumes the Federal German electricity mix, which comprised about 15 per cent renewable energy in 2007. Renewable electricity production began in the IBA’s starting
20,16
3,68
2,94
0,54
230
42
4239
775
year with wind power units at the Georgs‑ werder disposal site and in the direct proximity
62
thereof (approximately thirteen gigawatt-hours
year (for the residential and the commercial,
of electricity per year). Smaller photovoltaic
trade, service provider sectors only). The high
roof-mounted units are used for electricity
CO2 emissions are due to the fact that, in 2007,
generation in individual cases but these are of
only 1 per cent of the heating demand and
little consequence.
about 10 per cent of electricity requirements
Emissions in the IBA’s starting year 2007 thus amounted to 207,823 tonnes of CO2. This means
were met by renewable means.
CO2 emissions per resident of 3.76 tonnes per 08 Abb.20_GuA
Emissions of households, commerce, trade, service providers in the IBA’s starting year 2007 thus amounted to 207,823 tonnes of CO2.
Direct CO2 emission values for the different forms of energy production (without upstream and disposal) Energy production
thermal tCO2/GWhEnd1
electric tCO2/GWhEnd1
Source
Federal Germany Energy Mix 2007
245 2
579 2
2013
230 2
512 2
(BMU5 2009b), (UBA 6 2008)
2020
211 2
429 2
(BMU5 2009b), (UBA 6 2008)
2050
118 2
25 2
(BMU5 2009b), (UBA 6 2008)
5
6
2008
Wilhelmsburg Heating Mix Households
2173
(BEI 2009)
Commerce, trade, service industry
2253
(BEI 2009) (GEMIS 7 2009)
Fossil fuels Heating oil
266–270
646
(UBA 6 2009a)
Natural gas
202
456
(UBA 6 2009a)
Anthracite
344–353
862
(UBA 6 2009a)
Brown coal
359–367
1050
(UBA 6 2009a)
District heating from Coal 4 70% Co-generation
219
(GEMIS 7 2009)
35% Co-generation
313
(GEMIS 7 2009)
0% Co-generation
407
(GEMIS 7 2009)
Moorburg grid
238
(IBA-Hamburg 2009)
Renewable energy
0
0
(UBA 6 2009a)
Based on final energy demand. 2 Based on the projected energy mix for the 2009 guideline scenario (BMU 2009. Table 10. p. 95). 3 Weighted mean based on the energy mix calculated by the Bremen Energy Institute (BEI 2009. Table 5–11. p. 42) and the fossil fuel emission factors listed in this table. 4 Electricity credit for electricity produced by coal taken into account. 5 Federal Ministry for the Environment, Nature Conservation and Nuclear Safety. 6 Federal Environment Agency. 7 Global Emissions Model of Integrated Systems. 1
12 Direct CO2 emission values for the different forms of energy production
METHODOLOGY AND STRATEGY DEVELOPMENT
63
13 Current heat and hot water demand of households and of the commerce, trade and service provider (GHD) sector energy users (2007), including processing GHD heat demand, in the IBA area GWh/(ha*a)