Xiong’an 1.0

DESIGN ENERGY FUTURES

XIONG’AN 1.0

PARTICIPANTS

M.S.ARCH. ‘18 Chieh Wei Chiang Lei Feng Harshita Kataria Chun Yen Ku Chenxie Li Haoxiang Liao Wang Liao Xiao Lin Yanhan Liu Bingyu Zeng B.ARCH. ‘19 Brooke Calhoun Jose Sanchez Cruzalegui Spencer Gafa Aaron Guttenplan Ross Hanson Hanseul Jang Sang Ha Jung Nivedita Keshri Clarrisa Lee Yui Kei Lo Ian Masters Ryan Oeckinghaus Christina Rubino Furui Sun Katherine Truluck Evan Webb

DESIGN ENERGY FUTURES

XIONG’AN 1.0

DEAN’S INTRODUCTION

6

10

MS RESEARCH STUDIO

DESIGN ENERGY FUTURES

THE GLOBAL SPREAD: XIONG’AN NEW AREA

XIONG’AN, THE CITY FOR THE FUTURE

16

INTRODUCTION

42

WETLAND PURIFICATION BELT

60

NEW THEME LAND

74

HIGH-TECH HEADQUARTERS

INTEGRATED STUDIO

XIONG’AN, THE CITY FOR REGENERATION

86

INTRODUCTION

102

OTYUGH

114

YUÁN

126

RE-FRAME

134

142

BRICKING

148

UP

154

RECYCLING REVOLUTION

DEAN’S INTRODUCTION

DESIGN ENERGY FUTURES

6

Slowly, over the last half century, and more rapidly during the last decade, urbanization, climate change, and technological disruption have combined to shape an ever more volatile and unpredictable world. And yet it is a world more interconnected and interdependent than at any time in human history. In this new world, ENERGY has become increasingly important and changes, even small-scale ones, in energy production or consumption, have national, regional, and often global implications. Under pressure to address contemporary energy concerns, architects and urban designers have begun to develop strategies intended to reduce energy use at all stages of the design process. Sustainability, the most important and well known of these approaches, emphasizes the efficient management of resources and offers dramatic improvements over wasteful past practices. But in today’s volatile, inter-connected and interdependent world, such approaches are insufficient. And that is because sustainability is inherently conservative, focusing on the present rather than on what might exist in the future, on what is rather than on what might be. Science fiction writer William Gibson rather presciently remarked some years ago about the future that it “is already here, it is just not evenly distributed.” The future, then, is not distinct from the present, but is instead part of a marbled temporality where future and present coexist but do not overlap. Extrapolating from Gibson’s observation, we could say that the future is the name we give to all that we cannot know in advance, all that is

7

unpredictable and uncertain. The future is real but inaccessible and it shapes all that we are and can become. And it is in the eddies and swirls of this unevenly distributed future, in the vortices of uncertainty and unpredictability, that we find inspiration to DESIGN the solutions required to address the energy challenges we face in the 21st century. Unsatisfied with the present, DESIGN is an inherently future-oriented practice. At its best, DESIGN speculates through an iterative, prototype-driven process to pose and solve problems unanticipated by the problems of the present. Whether final built designs, or versions produced along the way, all designs are temporary, provisional solutions. We thus give the name FUTURES to these design prototypes—versions and final design alike—as each is not only a solution to an existing problem, but each is also a means by which to interrogate existing problems and formulate unanticipated problems and solutions. FUTURES are thus designs—industrial products, buildings, and urban designs—but they are also provocations that anticipate the unknown, the unpredictable, the future. DESIGN ENERGY FUTURES names a disposition towards this new world. But it also names a new research and design program at Syracuse Architecture that leads to a Master of Science (MS) in Architecture. Led and coordinated by Professor Fei Wang, the program focuses on energy and the built environment with research and design projects ranging across many scales, from urban design to high performance buildings, from VR and computational simulation to

material research and product design, and across a range of disciplinary practices. Students are directed for the duration of the program by faculty actively engaged in externally sponsored research and design projects, and have numerous opportunities for research internships with faculty, affiliated offices, and industry sponsors. The program requires the completion of 30 credit hours, typically over the course of three semesters. Coursework consists of two required studios paired with a research seminar and a series of electives meant to complement the studios. Applicants holding a professional degree in architecture, landscape architecture, urban design or urban planning are encouraged to apply. Applicants in related disciplines, including management, engineering, geography, graphic and product design many also be admitted at the discretion of the admissions committee in consultation with program administrators.

Michael Speaks, Ph.D. Dean and Professor Syracuse Architecture

8

DEAN’S INTRODUCTION

9

DEAN’S INTRODUCTION

THE GLOBAL SPREAD: XIONG’AN NEW AREA 1.0

10

Rem Koolhaas suggested in his 2014 Venice Biennale catalogue that modernization began to accelerate in 1914 with the onset of the first world war, transforming national identity, and thus national architecture identity, into a Universal Modernism that today, more than 100 years later, can be seen in cities around the world. Cities, Koolhaas suggests, and the buildings that define them, which in 1914 looked very different from one another, today look very much alike. Koolhaas’s assumption is that modernization begins in the West and quickly colonizes the rest of the world, leaving only “non-architectural” building practices and customs as traces of national architectural identity. That, in fact, is one of the story lines of the 2014 Venice Biennale. If Koolhaas is right, modernization creates, as it byproduct, a paste of Universal Modernism made from the pulverized remnants of local, regional and national architecture identity, which is spread evenly around the world, pushed even into the most underdeveloped economic crevices, cracks and deformations, to create a uniformly smooth surface. Evidence of this spread has given adherents and antagonists alike reason to believe that global modernization is the completion of a linear process that began in the West and that has smoothed over and re-made the rest of the world in its image and likeness. But Koolhaas is not right. Modernization is not homogeneous, and it is not linear. Modernization does not begin in the West, as Koolhaas and many others believe, and spread around the world, transforming difference

11

into sameness. Rather, global modernization is heterogeneous and non-linear and is defined neither by space nor by time, but instead by speed. Global modernization is a humming, churning chaos that operates at different speeds in different zones, quarters, and districts of the city and, indeed, in different cities within different countries all around the world—all at the same time, all simultaneously. Even the paste of Universal Modernism is not uniform and smooth, but is revealed, upon closer inspection, as a fractal urban spread of pockets, bands and swirls, all modernizing unevenly, at a relentless, though uneven, pace. Nowhere is this more evident than in Xiong’an New Area, which forms the spread of a very different temporality than the one imagined by Koolhaas and other minor Enlightenment architects, urbanists and theorists. Our contemporary world is more unpredictable, interconnected, and more interdependent than Rem Koolhaas and the minor deities of contemporary Enlightenment thinking ever imagined. And by definition, so too is the city, which architects and urbanists are increasingly called upon to manage and smooth into the paste of Universal Modernism that Koolhaas and others simultaneously loath and love. Dependent on normative master planning and data-driven smart solutions, strategies that are inherently conservative rather than future oriented, our best architects and planners continue to focus on managing the present rather than on speculating about what might exist in the future. As professionals, they focus on what is rather than on what might

be. Accepting Xiong’an New Area as a spread of global modernization moving at differentiated speed and experienced as a marbleized temporality, the work featured in this catalogue proposes temporary design solutions and provocations that pose problems unanticipated by the present: Each studio presumes to suggest that the city is more important now than ever; each project is thus a speculative aspiration to access the real-but-ultimately-inaccessible temporality that is the future; and each student takes on the responsibility to become a designer and not merely an architect, planner or urbanist.

Michael Speaks, Ph.D. Dean and Professor Syracuse Architecture

DEAN’S INTRODUCTION

:

1.0

12

13

14

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

MS RESEARCH STUDIO 16

Over the past 70 years, China has urbanized and modernized with unprecedented speed and efficiency. In turn, it requires extensive efforts to solve current and future problems related to energy efficiency, transport and congestion, solid waste, and water and air pollution. Established in April 2017, Xiong’an New Area is located about 100 km southwest of Beijing. Its main function is to serve as a development hub for the Beijing-TianjinHebei (Jing-jin-ji) economic triangle. China will develop this new area in the northern region parallel to the Shenzhen Special Economic Zone in the south and the Shanghai Pudong New Area in the east to serve as another economic engine and advance the coordinated development of the Beijing-TianjinHebei region. Additionally, “noncore” functions of the Chinese capital are expected to migrate here, including offices of some stateowned enterprises, government agencies, and research and development facilities. Xiong’an will spur economic growth and take over Beijing’s noncapital roles. The establishment of the Xiong’an New Area is a “major historic and strategic choice made by the Communist Party of China Central Committee with President Xi Jinping at the core.” “The decision to set up the new area is a strategy crucial for a millennium to come.” The area features geological advantages, convenient transportation, an excellent ecological environment, ample resources and lots of room for development. It has an initial phase development area of 100 km2, composed of 60 villages. The New Area plans to even-

tually expand to 2000 km2 in the future. The move will help phase out functions from Beijing that are not related to the capital, explore a new model of optimized development in densely populated areas and restructure the urban layout in the Beijing-Tianjin-Hebei region. Xiong’an is the most ambitious move in 21st Century urban planning with seven major tasks: 1. Building a world-class, green modern and smart new city; 2. Becoming a city with a scenic ecological environment, blue skies, fresh air and clean water; 3. Developing high-end innovative industries as new growth engine; 4. Having quality public services and infrastructure, as well as a new urban management model; 5. Establishing a fast, effective and green transport network; 6. Pushing for structural and institutional reforms to stimulate market vitality expanded to the outside world and becoming a new platform for foreign co-operation. In fall 2017, Syracuse University School of Architecture MS Research Studio investigated Xiong’an as the city for the future. Led by Professor Fei Wang, the studio researched modular architecture in the 1960s, new capital cities around world, urban research on Xiong’an New Area, and proposed alternative futures for its development. Students were asked to explore the history and existing conditions of Xiong’an, to discover the systems at various scales, including global, regional, metro-

politan, district, and architectural. Final proposals were based on students’ understanding of their chosen topics and sites, including Baiyangdian Wetland regeneration, high-tech headquarters, and residential communities for new millennium talents.

Fei Wang MS Program Coordinator School of Architecture Syracuse University

17

18

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

19

20

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

21

22

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

23

24

XIONG’AN

N 25

26

XIONG’AN -- Rongcheng County

27

©XINHUANET

28

XIONG’AN --Anxin County

29

©XINHUANET

30

XIONG’AN -- Xiongxian County

31

©XINHUANET

32

XIONG’AN -- Baiyangdian Wetland

33

©XINHUANET

34

XIONG’AN -- Baiyangdian Wetland

35

©XINHUANET

TIANJIN Population: 12.8 million Population Density: 14441 people/km² Proportion of the old: 17% GDP: $271 billion Green land per person: 11 m² Number of vehicles: 2,850,000

BEIJING Population: 18.7 million Population Density: 13347 people/km² Proportion of the old: 24.3% GDP: 377.3 billion yuan Green land per person: 16.2 m² Number of vehicles: 5,718,000

Population of Beijing

GDP 25000 20000 15000 10000

8117

23014 21330 19800 17879 16251 15113 1111512153 9846

2000 1350 1416

1500

1504 1581

1686 1740

1784 1825 1858

1877

1000 500

5000

0

0

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

BEIJING

XIONG’AN

Population of Tianjin

GDP 20000 15000 10000 5000

4462 5252

6719 7521

1572616538 14442 12893 11307 9224

Population: 21.2 million Population Density: 21242 people/km² Proportion of the old: 30.2% GDP: 415.5 billion yuan Green land per person: 12.5 m² Number of vehicles: 3,220,000

908 958 814 851

1034 1090

1152 1207

1248 1278

800 600 400 200

0

SHANGHAI

1400 1200 1000

0 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

TIANJING

SHENZHEN Population: 11.4 million Population Density: 10589 people/km² Proportion of the old: 6.6% GDP: $295.3 billion Green land per person: 16.8 m² Number of vehicles: 3,225,000

XIONG’AN Population of Shanghai

GDP 30000

2500

25000

2000

25123 23567 21818 1919520181 17165 1406915046 12494 15000 10572 10000 20000

0

Area

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

20000 15000 10000

Proportion of the old

5613

SHENZHEN

Vehicle

6801

7806 8201

0 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

1200 1000

865 876 883 890 902 799 830 732 764

600

200 0 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

XIONG’AN

AI ANG IAN

800mm 800mm 700mm 175mm

40°C

150mm

600mm 87°F

20°C

100mm

10°C

75mm 50mm

0°C 16°F -10°C

25mm

-20°C

0mm AN

A

A

A

N

A G

O

NO

I I A ION

125mm

I I A ION

36

500mm

30°C

953

800

400

5000 0

50°C

2173 2116

Population of Shenzhen

17502 16001 14500 12950 11505 9581

2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Location of Xiong’an

2056 2096 2126 2164

1000

GDP

GDP

Population

1897 1958

1500

500

5000

SHANGHAI

1742 1830

400mm 300mm 200mm 100mm 0mm XIONG’AN

INA

A IA

G O A

Toyko, Japan

Beijing, China

Shenzhen, China

Scale of Xiong’am

New York, USA

37

Water Pollution

Sandstorm

Deforest

Pollution

Traffic Jams

Farm Field

Green Space

Soil Pollution

Heat Island

Air Pollution

Scattered

Public Space

Rising Cars

Transportation Walkability

System of Issues in Xiong’an

Environment

38

Parking

Public Transportation

Society

Landfill

Resource

Coal

Recycle

Gasline

Dam

Floods

Water System

Drought

Drainage

Aging Society

Population

Education

Unemployment Littering

Population Explosion

Pollution

Sever Incomes Disparity

Brian Drain

Health Crisis

Low Incomes

People

Increasing Empty-nest elderly

Decrasing Arable Land

Mismanagement of Aging Population

Unblance Population Growth

Urbanization

High Education Young Move To City Work

GDP

Commodity Price

39

Insufficient Nursing House

Long Work Time Heavy Work

$

Housing Price

Food Shortage

Relying on Import Food

Increasing Missing Children

Gap of Education Background

Increasing Migrant Children

Hukou System

Movement of Working Population

Education Imbalance

Agriculture Structure Changing

Increasing Food Price

Monoculture of High-yield Crops

Dicreasing Biodiversity

Gene-modifIed Food

High Pressure Live In City

Economy

District

Abuse of Pesticides and Fertilizer

Insufficient Family Education Resource

Shortage of After-school tutoring

Cooking By Customers

Shopping Regions

Increasing empty-nest elderly

High Price Food

Food Safty

Decreasing Arable Land

System of Solutions in Xiong’an

Parking Lot

Hyper-Speed Rail System

Aging Population Issues

Food Issues

Walking Trails

Linear Parks

Rest Stop

Regional/ Theme Parks

Landscape

National/ Urban Park

Cycling System

Public Transportation

Green-Blue Grid System

Pocket Parks

Slow Traffic System

Transportation

Insufficient Nursing Homes

Living Intimacy But at a Distance

Walking System

Private Traffic system

Visit-Care

Transparent Food Processing

Pedestrian Streets

Vehicle-Free Area

community Nursing Homes

Public Bus System

Wetlands

Community Level

Block Level

Multi-Interchange System

Sharing bike parking space

Subway System

City Level Multi-Hierarchy Structure of Regional Scale

40

Affiliation

Transportation

Slow Traffic System

Walking System

Pocket Parks

Main Branch

Parallel Relationship

Normal Branch

Re-employment Adult Education

Guardian Service

Special Transportation

Low Incomes

Children Issues

Unlimited Registration School

After-school Center

Shortage of After-school Turtoring

Imbalance Education Resources

Increasing Missing Children

Energy Energy

Education Issues

Non-motorized Vehicles

Solar Panel

Environment Environment

Purification Algae System Plant

Solar Energy

Electrical E-Vehicle Vehicle

Solar Battery

Reduce Urban Farmlands

Companies

Reduce

Entertainment Zones

Effective Location of Resources

Density Density Distribution Distribution

Multi-Center Planning

Ecosystem within the City

Fixed Population

41

’ Right

Reuse

Recycle

Reuse

Recycle

Waste Waste Management Management

Low Incoming housing

Effective Location of Landfill

Migration Reforms

Better Quality of Life

Income Pisparity

Bio-energy

Green Building

Wind Wind Corridor Corridor

Online Education

Community Library

Law Law Enforcement Enforcement

Waste Recycle

Compress CNGGas Natural

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

WETLAND PURIFICATION BELT

42

Xiong’An is a new state-level district in Hebei, China. Established in April 2017, it is located about 100 km southwest of Beijing, the capital of China. Its primary function is to serve as a development hub for the Beijing-Tianjin-Hebei (Jing-Jin-Ji) economic triangle. As announced by the government, “non-capital” functions of Beijing are expected to move there. Xiong’An is expected to create a paradigm for China to build environmental-friendly cities. Through research and analysis in mega-cities, we discovered that there are some common issues, such as environmental issues, traffic congestion, high housing prices, etc. We built an analysis system through three categories: social, environmental, and economical. System maps helped us reach better understanding of issues on vari-

ous aspects; we discovered that the level of environmental problems is down currently. Baiyang Wetland, which takes almost one-tenth of the area of Xiong’An, is located in the center of this area, and poses a serious pollution challenge brought about by both drought and floods, and upstream high-pollution plantations in the last century. Our intent is to improve the environment of Baiyang Wetland from a systematic and forward-thinking way. According to the government, one of the reasons to build a city upon a seriously polluted wetland is to make full use of “Force” mechanism to improve the water environment. In order to return capacity of water storage and self-purification to the original level, we have produced an artificial wetland system consisting of three parts: riverside buffer corridor; artificial semi-wetland pocket park; and prospective urban water channels and ditches. Each is supposed to include plant vegetation with strong purification ability — used to different water depth (hydrophyte) or humidity (xerophyte) according to their environmental conditions and functions. By balancing water level and quality of this area, residents are provided with more recreational public space and a quality walking and cycling environment. Chenxie Li Wang Liao Harshita Kataria Bingyu Zeng 43

Littering

Recycle

Landfill

Gasline

Resource

Dam

Coal

Drought

Issue System in Chinese Cities

Population Explosion

Water System

Public Space

Heat Island

Drainage

Walkability

Rising Cars

District

$ Commodity Price

44

Green Space

Scattered

Society

GDP

Transportation

Public Transportation

Food Shortage

Housing Price

Water Pollution

Sandstorm

Air Pollution

Population

Unemployment

Pollution

Environment

Floods

Aging Society

Education

Soil Pollution

People

Economy

Gap in Wealth

Deforest

Farm Field

Traffic Jams

Parking

Littering

Recycle

Landfill

Gasline

Resource

Dam

Coal

Drought

Issue System in Jing-Jin-Ji Area

Population Explosion

Green Space

Scattered

Water System

Public Space

Heat Island

Drainage

Walkability

Rising Cars

Society

District

Transportation

Public Transportation

Food Shortage

Housing Price

Water Pollution

Sandstorm

Air Pollution

Population

Unemployment

Pollution

Environment

Floods

Aging Society

Education

Soil Pollution

Deforest

Farm Field

Traffic Jams

Parking

People

Economy

Gap in Wealth

$ Commodity Price

GDP

SOCIETY

45 ECONOMY

ENVIRONMENT

Littering

Recycle

Landfill

Gasline

Resource

Dam

Coal

Water Issue System in Jing-Jin-Ji Area

Drought

Population Explosion

Water System

Public Space

Heat Island

Drainage

Walkability

Rising Cars

District

$ Commodity Price

46

Green Space

Scattered

Society

GDP

Transportation

Public Transportation

Food Shortage

Housing Price

Water Pollution

Sandstorm

Air Pollution

Population

Unemployment

Pollution

Environment

Floods

Aging Society

Education

Soil Pollution

People

Economy

Gap in Wealth

Deforest

Farm Field

Traffic Jams

Parking

Water Eutrophication Index

EVALUATION METHOD Though extract the content of Chlorophyll a, Phosphorus, Nitrogen, Diaphaneity, Potassium Permanganate, and then be applied with comprehensive nutrition state index. Finally, quantify the content of nutrification of Baiyangdian wetland by TLI Index.

Oligotropher [ < 30 ] Mesotrophy [ 30 - 50 ] DANGEROUS !

Low [ 50 - 60 ]

Eutrophy [ > 50 ]

Mid [ 60 - 70 ]

High [ >70 ]

71.1

L K J I H G F E D C B A

54.3 55.6 57.5 57.4 59 64.6 59.6 57.2 75 68.6 70.1 0

20

40

60

80

China Water Quality Rating Grade Ⅰ-Ⅲ

High Quality

Grade

Ⅳ

Low Quality need water purification

Grade

Ⅴ

Undrinkable

Grade

>Ⅴ

Need to be purified before used

Ⅳ 17%

Ⅴ 5%

Ⅰ-Ⅲ 46% >Ⅴ 32%

BAIYANGDIAN [ Warning: Water quality lower than Grade Ⅳ should not touch human skin ]

47

Water Level & Area & Volume 1200

Area

1000 Jun.

Mar.

Dec.

800 Sep.

600 400 200

Water Inflow

water/m²

10.5

10.3

9.9

9.7

10.1

9.5

9.3

9.1

8.9

8.7

8.5

8.3

8.1

7.9

7.7

7.5

7.3

7.1

6.9

6.7

6.5

6.3

6.1

0

water/mÂł

Timeline of Baiyangdian Wetland

Precipitation

2

3 1 3 3 3

1950

1952

1954

1956

1958

1960

1962

1964

1966

1968

1970

1972

1974

1976

1978

1980

1

4 3

Several Drought in 60s-80s In 60s-80s, Baiyangdian suffered droughts for

1

48

Floods in 1963

2

First Drought in 60s

The severe floods in Haihe Area,

Baiyangdian suffered drought the 1st

which influenced Baiyangdian

time in January, 1966-August, 1966.

significantly.

6 times, which lasted for one month to nine months.

Reed

FarmLand

Left: Schemes for various applications; Right: Phasing

Water

8

4

1982

4

5

1984

6 7

1986

1988

1990

1992

The Most Serious Drought in Baiyangdian

1994 6

1996

1998

2000

2002

Water Transfer by The Government

2004

2006

2008 8

2010

2012

2014

2016

2018

The Death of Fish

Baiyangdian suffered its most serious drought in July, 1983 -

In 1992, the government began to bring water from

In 2006, the water pollution became incredibly severe, and it is

August, 1988, which lasted for more than five years.

nearby reservoir to Baiyangdian.

the first time that a lot of fish died in Baiyangdian . After that, this 7

49

5

Water Pollution

Important Water Inflow

The severe water pollution of Baiyangdian began in

Baiyangdian got the important water inflow in 1988,

2000, getting a lot of polluted water from its upper

which prevented it from drought in the future.

streams.

kind of matter happened very frequently.

Dried rivers Paper Mills Battery Plants Chemical Plants Machinery Plants Metal Plants Plastic Plants Coal Plants Clothing Factory Other

e Fuh

er

Riv

Water Issue System in Baiyangdian

Fuhe River

50

Import water resource Polluted by Industies that location in Upper Branches

There are nine rivers connecting to Baiyangdian Wetland in the past, but now only Fu he River and Yellow River can transfer water to Baiyangdian Wetland.

Zhaowang New River Export water resource to Ocean

Artificial Pipeline Import water resource 51

Program: South Water to North Water quality: Level 3

Dried Rivers

Zhaowang New River Water Outflow

Wetland Composition of Baiyangdian

Fuhe River Water inflow

52

Ground Grass Reed Woods Farmland Water Building

Artificial Pipeline Future Water Inflow

Ground Grass Reed Woods Farmland Building Water

Ground Grass Reed Woods Farmland Building Water

Ground Grass Reed Woods Farmland Building Water

Ground Grass Reed Woods Farmland Building Water

1987

1999

2007

Patch Numbers in Different Periods Ground

55

Grass Reed Woods

150 221 90

20

Farmland

55

15 63

Building Water

112 105 103

243

121

161

43

125 148

83

2007

195

1999

170

1987

150

Area in Different Periods/km² Ground

7

Grass Reed Woods

1 13

Changes Over Time in Baiyangdian Wetland

Building Water

8 9

195

135 1

83

Farmland

53

10 12

33

155 3 98

60 15

57

20

43

38

Natural Water Inflow Artificial Water Supply Precipitation Area of Baiyangdian Area of Water Biodiversity

Biology Variation

1983

1985

1987

1989

1991

1993

1995

1997

1999

2001

2003

2005

2007

2009

2011

2013

1983

1985

1987

1989

1991

1993

1995

1997

1999

2001

2003

2005

2007

2009

2011

2013

Shopping Regions

Walking Trails

Pedestrian Streets

Vehicle-Free Area

Linear Parks

Rest Stop

Walking System

Pocket Parks

Regional/ Theme Parks

Slow Traffic System

Private Traffic system

Transportation

Parking Lot

Hyper-Speed Rail System

Cycling System

Public Transportation

National/ Urban Park

Public Bus System

Community Level

Block Level

Multi-Interchange System

Sharing bike parking space

Subway System

City Level

Solution System

Multi-Hierarchy Structure of Regional Scale

Affiliation

Transportation

54

Slow Traffic System

Walking System

Pocket Parks

Main Branch

Parallel Relationship

Normal Branch

Energy Energy

Bio-energy

Non-motorized Vehicles

Green Building

Green-Blue Grid System

Solar Panel

Wind Wind Corridor Corridor

Environment Environment

Landscape

Purification Algae System Plant

Solar Energy

Electrical E-Vehicle Vehicle

Solar Battery

Reduce Urban Farmlands

Wetlands

Companies

Reduce

Entertainment Zones

Effective Location of Resources

Density Density Distribution Distribution

Multi-Center Planning

Ecosystem within the City

Fixed Population

55

Better Quality of Life

’ Right

Recycle Recycle

Waste Waste Management Management

Low Incoming housing

Effective Location of Landfill

Migration Reforms

Reuse Reuse

Law Law Enforcement Enforcement

Waste Recycle

Compress CNGGas Natural

20

50

100

Elevated Boardwalk Pond System

EDUCATIONAL Library Bookstores Cafe Wetland Museum Open space for Classes Gardens of Flower Nursery

10

20

50

KIDS PARK Fountain Dance Stepping Stones Skating Field Maze Playground

RECREATIONAL ZONE Open Air Theatre Restaurants Garden of Sculpture Lotus Pond

HEALTH Gymnasium Restaurants Sports Community Park Swimming Pool

100

PERFORMING ARTS Galleries Museum Outdoor theatre Shops for local goods

MONITORING POINT Use signal light to transmit the quality of water

WATER TREATMENT PARK Combine the entertainment program and water treatment function

Masterplan of Baiyangdian

0

56

WETLAND AREA Nature Purification Process

DAM

Water Outlet

Water Inlet

Water Treatment Park of Baiyangdian

MONITROING POINT

57

Provide the highest observational point

REFLECTION AND REFRACTION EFFECT Use the different refractive index of air, water and glass to make water color show on the ground

EXHIBITION The centre area provide the outdoor ehibition program function

RUNNING TRACK

10.5 m Flood Level 8.8 m Maximum Sotrage Level Ideal Water Level Range

8.0 m Ideal Level 7.3 m Lowest Level for Eco-Balance 7.0 m Warning Level for Drought 6.5 m Dry lake Level

Highest canal’s bottom

Water volume is 52 million m3 at this level; water surface area is 70km2, which could be considered as dry lake.

6.0 m Average canal’s bottom 5.5 m Lowest canal’s bottom

Time / Water Level

7.3 m Lowest Level for Eco-Balance 7.0 m Warning Level for Drought

April / Spring / Dry Season

Eco-Purification & Water Level Balance of Baiyangdian

8.8 m Maximum Sotrage Level

July / Summer / Wet Season

8.0 m Ideal Level

September / Early Fall / Normal Season

7.3 m Lowest Level for Eco-Balance 7.0 m Warning Level for Drought 6.5 m Dry lake Level

March / Spring / Extremly Dry Season (The Following Year) Terraces for Aerotion and Biological Purification

58

Sediment Degradation, Subsurface Filtration Water Quality Stabilization and Control Kashu

Water from Impoundment

Canal

Water from Nature

Heavy Mental Removal

Terraces for Aerotio

Nutrient Removal

Slow Traffic Belt

Porous Rock

Pavement

Water Flow

Sedim

Irragation

Irragation

Irragation Water Channel Separated

on and Biological Purification

59

ment Degradation

Heavy Mental Removal

Amenity Belt

Terraces for Aerotion and Biological Purification

Nutrient Removal

Sediment Degradation

Heavy Mental Removal

Reserved Terraces for Aerotion and Biological Purification

Water Impoundment

Block & Park

Nutrient Removal & Heavy Mental Removal

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

NEW THEME LAND

60

China is facing unsustainable population growth, including challenges of food shortage, insufficient educational resources, and safe day-care for children. As Beijing’s new supporting city, Xiong’An must strive to reduce traffic, population explosion, and pollution problems in the near future. All of these things must be carefully considered in new city planning. The main focus of our project is the new headquarters community in Xiong’An planned for Tencent, one of the largest internet companies in China, as a research prototype. Our intent is to create a new style of living for this new city. There are many cities in China where youth face a “brain drain.” People live in the big city under stressful pressure and long working schedules. Talented young workers leave after they earn their money. The headquarters community provides sufficient facilities and services for all ages that encourage youth to bring their families for a long stay. The project demonstrates a different approach to livable community and new resident relationships—the community has several public theme lands that appeal to millennials,Tencent’s major demographic. The proposal also includes for a more efficient road system, walkability and multiple scales of prototypes. The new living environment will make employees more willing to consider extended stays in Xiong’An.

61

Chieh Wei Chiang ChunYen Ku HaoXiang Liao YanHan Liu

GLOBAL RISKS

Glaciers Melting

Food Shortage Crsis Arable land Reduction

Increasing Fuel Consumption

Decling Agriculture Production

Enery Price Shock

Inefficient Transportation

Extrme Weather Event Species Loss

Food Price Fluctuation

Rising Green House Gas Emissions Ozone Layer Change

Soil Erosion

Air Pollution

Mismanagement of Population Aging

Mismanaged Urbanization

Unsustainable Population Growth

Environment Issue

Social Issue

Desertificantion

Incresed Private Automobiles

Sever Income Disparity

Racial Strife

Insufficient Medical Resources Insufficient Education Resources

Deforestation

Unmanged Migration & Refugee

Public Health Crsis

Food Safty Crsis Water Pollution

Economic Issue

DOMESTIC RISKS

Brian Drain

Global and Domestic Risks

Increasing Missing Children

Hukou System

Increasing Migrant Children

Education Imbalance

High Pressure Live In City

Long Work Time Heavy Work

High Education Young Move To City Work

Gap of Education Background

Low Incomes

Mismanagement of Aging Population

Health Crisis

Pollution Insufficient Nursing House

Abuse of Pesticides and Fertilizer

Unblance Population Growth Increasing Empty-nest elderly

Food Shortage Movement of Working Population

Urbanization

Decrasing Arable Land

Dicreasing Biodiversity Sever Incomes Disparity

62

Shortage of After-school tutoring

Increasing Food Price

Insufficient Family Education Resource

Agriculture Structure Changing

Gene-modifIed Food Monoculture of High-yield Crops

Environment Issue

Social Issue

Economic Issue

Relying on Import Food

IDEAL CITY PURPOSE User

Goal

Method

Healthy Life Elderly center

Able

Elderly

Elderly University

Disable Elderly Social

Livable Life Kids Library

Museum

Decent Education Allen Workers

Amusement Park

Efficient Economy Young Adult

White Collar Green Area

Environment

Elderly Care Talented

Workability

Treasure Talented Finanicial Center

Children Care Urban Children

Public Service Economy

New House

Children

Residential Area Rural Children

Land renting

Transportation Environment Friendly Entertainment

STRATEGIES

Re-employment

Ideal City Purpose and Strategy

Increasing Missing Children

Low Incomes

Guardian Service community Nursing Homes Special Transportation

Children Issues

Insufficient Nursing Homes

Imbalance Education Resources

Increasing empty-nest elderly

Unlimited Registration School Living Intimacy But at a Distance

Decreasing Arable Land

After-school Center Urban Farming Shortage of After-school Turtoring

Community Library

Food Safty

Transparent Food Processing

Education Issues

Food Issues High Price Food

Online Education Cooking By Customers Income Pisparity

63

Aging Population Issues

Visit-Care

Adult Education

Environment Pollution

AVAILABILITY OF RESOURCES

Beijing Daxing International Airport Beijing Capital International Airport

Shijiazhuang Zhengding International Airport

Tianjin Binhai International Airport

China Shipbuilding Industry Corporation

Qinhuangdao Port

NORTHEAST Number of students: 140 million GDP: 13,709 billion USD Number of Universities: 172

China Aerospace Science and Technology Corporation

Jingtang Port

China National Offshore Oil Corporation

Caofeidian Port

Aluminum Corporation of China Limited

NORTH CHINA Number of students: 291 million GDP: 20,396 billion USD Number of Universities: 200

Tianjin new Port

EAST CHINA Number of students: 534 million GDP: 21,436 billion USD Number of Universities: 420

SOUTH CHINA

Huanghua Port

Number of students: 110 million GDP: 12,118 billion USD Number of Universities: 110

NORTHWEST CHINA Number of students: 100 million GDP: 8,282 billion USD Number of Universities: 145

Baiyangdian Lake

LOCATION

SOUTHWEST CHINA

CENTRAL CHINA

Number of students: 130 million GDP: 7,290 billion USD Number of Universities: 184

Number of students: 220 million GDP: 9,696 billion USD Number of Universities: 248

CORPORATIONS

Financial Services Company 15 businesses 31.1 %

Other Advanced Technology Services 7 businesses 14.6 %

Beijing

Green Ecology Company

Xiong’an Resources

5 businesses 10.6 %

Tianjin

Rong Cheng County Xiong County Anxin County

Advanced technology Company 7 research institutes 14.6 %

Information Technology Company 14 businesses 29.1 % Market value of global internet company (multi-billion dollar) 7000 6000 5000 4000 3000 2000

64

1000 0 Google

Facebook Amazon

Alibaba

Tencent

Priceline

Netfix

paypal Baidu

TENCENT HEADQUARTERS ANAYSIS

Tencent Shenzhen Headquarters

Tencent Chengdu Headquarters

Built time: 2016 Construction Area: 345,570 m2 Land Area: 18,650 m2 Number of Employees: 12,000 Per Capita Area: 28.79 m2

Built time: 2015 Construction Area: 210,000 m2 Land Area: 34,000 m2 Number of Employees: 8,000 Per Capita Area: 26.25 m2

Tencent Beijing Headquarters

Tencent Wuhan Headquarters

Built time: 2014 Construction Area: 308,640 m2 Land Area: 77,525 m2 Number of Employees: 8,000 Per Capita Area: 38.58 m2

Built time: 20147 Construction Area: 73,330 m2 Land Area: 56,000 m2 Number of Employees: 2,600 Per Capita Area: 28.20 m2

Construction Area

Land Area

Number of Employees (1000persons)

POPULATION STRUCTURE ×11000 Elderly People

Couple Single

Couple

Couple

Single

Parents

Couple

Single

Couple

Parents

Parents

Parents

Tencent Headquarters Analysis

Product

Technology

×1370

Profession

×410

Product

×410

Technology

×860

×1760

Married people

Single people

Age above 40

Market

Profession

×260

Product

×260

Technology

×250

×500

Market

Profession

×75

×75

×9000 Tencnt

Age 20-30

Children

Spouse

One-Child

Age 30-40

Children

Spouse

Two-Child

One-Child

Children

Spouse

Two-Child

One-Child

Age above 40

Spouse

Two-Child

Children

One-Child

Spouse

Two-Child

×2900 Children

65

Single

Parents

Age 30-40

Market

×2800

Couple

Parents

Single people

Married people

Age 20-30

Single

Single

×2600 Spouse

Children

One-Child

Spouse

Two-Child

Children

One-Child

Two-Child

15-MIN QUALITY LIVING AREA

15 MINUTES WALKABLE LIFE CIRCLE

China Planning Guidance of 15-minute Community Life Circle 15 minutes

15 minutes walkable 3 - 5 Km² 50 - 100 Million People 1 - 3 Milliom / Km²

Vegetable mart

Green area 1.7 Km

0.8 - 0.9 Km

Mall Supermarket

Senior center

Pharmacy

Nursing home

Kindergarten 30 0 35 0 50 0 60

Home

15 minutes 1.2km

15 minutes 1.2km

5 Km²

3 Km²

1.7 Km 0.8 - 0.9 Km

Convenience store 3 Km²

5m in

Post office

10

0

min

80

01

Restaurant

00

15

Bank

0

min

15

00

Elementary school

800-900 m Health center

15 minutes walkable (Furthest Distance 1.2km)

Commerce

15 minutes walkable

Greenbelt

800-900 m

Education

0.8 Km²

Healthcare

24.83 Thousand People

Affairs

2.8 Thousand / Km² Welfare facilities

LIVABLE COMMUNITY FUNCTION

Greenbelt 223,470 m2

Green area

Brain Drain

Residential areas 690,000 m2

Home x 11000

Bicycle System

Car System

Mall Mismanagement of Aging Population

Vegetable mart Restaurant Commerce 45,936 m2

Walkability

Convenience store Supermarket

Elementary school

Food Shortage

Urban Strategy

Education 8,300 m2

Kindergarten

15 minutes walkable (Furthest Distance 1.2km) Recreation

Increasing Migrant Children

Cultural and leisure facilities 3,203 m2

Sports Library

Health center Pharmacy Healthcare 994 m2

Hospital

Gap of Education Background

Bank

447 m2

Senior center Welfare facilities

66

977 m2

Nursing home

L.R.T System

CONCEPT ---

CENTRALIZATION

100m × 100m

SCALE

MODULARIZATION

COMBINATION

Base Status BaiYang Wetland is one of central part of Xiong’an area. There are many acitivities surrounded by BaiYang Wetland.

Central Park

CENTRALIZATION

DIVERSION

CENTRALIZATION

COMBINATION

AGGREGATION

Conceptual Scene We created four central theme lands to provide a place for people to enjoy centralizational life circle.

Urban Strategy: Prototyping

BLOCK STRATEGY

L.R.T Station Accessibility

L.R.T Station Accessibility

L.R.T Station Accessibility

L.R.T Station Accessibility

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

L.R.T Station Accessibility

L.R.T Station Accessibility

L.R.T Station Accessibility

L.R.T Station Accessibility

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Headquarter Walkablity

L.R.T Taking Time (Commutes)

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

Interactive Between Work Area &Live Area

Connection Between Each Community

Headquarter Car Road

67

Central Park

L.R.T Station L.R.T Track

Residential Area

STREET TYPES

m

2.1 2.4

m

m

3.6 3.5 3.0

m

m

1.8 2.4

m

1.0

m

2.1

2.1

1.8

.7m

16

m

m

2

m

m

m 3.5

7.0

m

.2m

32

m

3.5 m

m

m

1.8

m

1.0

1.8

m

2.4

1

2.1

m

1.0

m

2.1

m

2.4 m

2.1

m

1.0

m

1.8

m

1.8

.2 12

m

3

1

3

4 2

m

1.8 LRT (Light-rail Transit)

RESIDENTIAL UNIT

×2900

× 2900 Separated Single People between the two places

Area: 30m

×880

Urban Strategy: Units

×1000

× 5100

×3000

Couple One-Child Couple Family

Single & Parent

×600

Area: 60m

×300

×500

Two-Child One-Child Family & Family Parent

Single & Couple Parents

× 2100

×1500 Area: 90m

×700

×300

68

One-Child Family & Couple Parents

Two-Child Family & Couple Parents

× 900 Area: 120m

m

1.0

2.1

m

5.9

1.0 m

m

4

RESIDENTIAL PORTOTYPE

Type 01

Type 02

Type 03

Type 04

Type 05

Type 06

Type 07

Type 08

Type 09

Type 10

Type 11

Type 12

Public facility Green area Residence

ELDERLY LIVING ARRANGEMENT

Home-visits 9m

8.1

m

Healthy elderly Sub-healthy elderly

Home-care

Short-term Institution Care

Day Care

.8m

40

12

m

Steepest Slope

Disale elderly

Institution Long-term Care

54m

.2m

Smallest Slope

Nursing Home

Medium- rise Units

16

69

.2m

25

Low-rise Units

18m

Urban Strategy: Units

Smallest slope Medium Slope

.2m

16

Relatives

Elderly

Health surveillance Wristband

High-rise Units + Elevators Community Health Center

EXTREME EXPERIENCE PARK

Parkour

Swimming

BMX

Skateboard

Indoor Skydiving

Bungee Jumping

Rock Climbing

Deep Diving

Inline Skating

Highly Social Looking for Experiences Over Possessions

HEALTHY FOOD PROVIDE PARK

Urban Strategy: Shared Parks

Vegetation Corridor

Stair Plaza

Green House & Roof Garden

Plant Laboratory

Growth Learning Room

Place Segregate in Residential Area

Food Truck &Market

Sharing Kichken & Picnic Area

Food Distribution Hub

Community Dining Hall

Highly Social

70

High Performance Farming

Sharing and Connectivity Eating and Exercising Right Looking for Experiences over possessions

Temporary Canopy For Farmers Market

Stair Landscape

SPORTS PARK

Children Fitness Trails

Sports Court

Public Exhibition Area

Public Community

Movable Rest Area

Multiple Use Space

Changeable Canopy

Bicycle Stands

Multiple Use Space

Sharing and connectivity Internet& Digital natives

Highly social

Urban Strategy: Shared Parks

SHARING OBSERVATION WHEEL

Teaching Space

Exhibition Gallery

Workshop

Exchange Program

PerformingStage

Station

Film Collection

Interactive Pavillion

Coworking Space

Sharing and Connectivity Internet& Digital Natives

71

Highly Social Pursue Efficiency and Creativity

72

Axon of Ideal City

73

MS RESEARCH STUDIO

XIONG’AN, THE CITY FOR THE FUTURE

HIGH-TECH HEADQUARTERS

74

Beijing-Tianjin-Hebei (JingJin-Ji) is a geographic area with a population of close to 100 million. The area is one of the three most burgeoning districts in China and faces serious problems generated by development. Pollution, population boom, disparate development, traffic, public health — all of these challenges should be considered systematically in any design proposal. A system of Jing-Jin-Ji coordinated development will help throughout the establishment of Xiong’an New Area. Energy, environment, economy, industry and talent will all play a key role in Xiong’an’s social development. Moreover, internet industry, new energy and other emerging industries have been included in the Chinese government’s industrial reform plan. Establishing a hightech industrial base will attract

high-end talents to Xiong’an. Tencent is China’s largest internet company. Following a people-oriented approach, company leaders avoid interfering in subordinates’ work and encourage a full trial of opportunity. Tencent often allows multiple teams to develop similar products simultaneously. Most of the company’s employment demand is in Shenzhen even though Beijing has many internet practitioners. Tencent’s regulation strategy includes flat management, decentralization, and an internal entrepreneurial talent market. The company is mainly divided into seven business groups; the IEG and MIG are particularly large. This reflects Tencent’s strategic focus on games and the mobile internet. Tencent’s WeChat group holds fewer than 1200 people. Good headquarter design should align well with company structure, management and culture. We propose a flexible modular strategy more suitable for different enterprises, each module designed to meet the basic needs for different kinds of work. A company could manipulate proportion of the modules. Lei Feng Xiao Lin

75

76

Research of Xiong’an

77

Research of Tencent

78

Research on Tencent System

79

Space and Program Research

80

Program Research

81

Program Research

82

Building Details

83

84

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

85

INTEGRATED STUDIO 86

Aiming to be the city for the future of China, and a model city for the world, Xiong’an New Area is facing challenges of regeneration from small agricultural villages and post-industrial towns. Collaborating with the Institute of Building Research, Shenzhen, Syracuse Architecture students focused on one post-industrial building and explored its potential as a green building research center with public programs for the city. Located in the heart of newly planned Xiong’an, this four-story factory building is a common typology in secondary cities across China. This work was part of Syracuse University School of Architecture spring 2018 fourth-year undergraduate Integrated Studio taught by Professor Fei Wang. Integrated Studio is the culminating undergraduate studio, combining advanced architectural design with technical knowledge acquired during the Building Systems and Structure sequences. Throughout the semester, students participated in a series of Systems and Structure workshops given by faculty and practicing professionals who provided real-world criticism and feedback. Parallel to technical and curricular requirements, the studio relied heavily on an introductory research component that examined the exceptional historic, political, and economic development of post-industrial sites throughout Xiong’an. This enabled students to produce speculative urban regeneration projects in response to the needs of new Xiong’an community that could also serve as prototypes for other urban regeneration sites of

similar characteristics. Fei Wang MS Program Coordinator School of Architecture Syracuse University

87

88

SITE IN XIONG’AN

N

90

SITE IN XIONG’AN: EXISTING BUILDING

91

SITE IN XIONG’AN: EXISTING BUILDING

92

SITE IN XIONG’AN: EXISTING BUILDING

93

SITE IN XIONG’AN: EXISTING BUILDING STRUCTURE MODEL

94

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

95

96

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

97

98

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

99

100

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

101

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

OTYUGH

102

New development as part of urbanization today is often accompanied by demolition of the existing. Thousands of structures have been demolished in China, leaving behind tremendous cultural loss and enormous environmental challenge from tons of waste. In China, demolition waste is typically sent to a landfill or burning facility. Our project attempts to tackle the long un-resolved issue of waste management. Our intent is to look beyond the simply adaptive reuse approach, and seek a possible new typology for the new capital of China, Xiong’an. By combining a power plant with the original need to reoccupy a manufacture building as a research facility located in Xiong’an, the proposed building presents itself as a manifestation within the process of the new development and also functions as a transitional model with permanent significance that hopefully could be transferred into the future city design of China. The superposition of components of

the power plant above the existing structure reinforces the building’s expressive character and begins to attract attention from residents in the region. The open display and framing of the power plant, and its working mechanism, transform the project into a giant showroom that advertises a distinct vision for architectural design and even urban planning. The system of the power plant is integrated into the mechanical system for everyday use by the research sector of the establishment. The combustion of biomass waste produces residual heat that can be utilized to generate electricity and fulfill the building’s heating needs. This enables the construct to achieve self-efficient autonomy as a strategy in dealing with the highly volatile context. As a result, the building may have extensive impact on the ever-changing built environment surrounding it. Furui Sun Sang Ha Jung

103

WASTE MANAGEMENT IN CHINA Metric Tons of Municipal Solid Waste (MSW) Generated Each Day (2012)

High % of Waste to Landfill vs Low Recycling Rate

0% - 9% 10% - 19% 20% - 29%

0% - 20%

30% - 39%

21% - 40%

40% - 49%

41% - 60% 61% - 80% 81% - 100%

50% - 59% over 60%

Percentage of Waste to Landfill

Recycling Rate

Current vs Projected Municipal Solid Waste Generation (lbs / year) CHINA : 520,538 METRIC TONS PER DAY in 2012

World’s Largest MSW Generators Today

175 MILLION TONS PER YEAR 2015

2025

WHY Waste-to-Energy?

Distribution of Waste to Energy Plants Across China

Environmentally conscious option for coping with waste Elimination of needs to transport waste in long distance - Reduction of travel related emissions Alternative of Landfills

62.4 % landfill

Potential development for hybrid programs with positive impacts towards society

site area (sq. m)

945

building footprint (sq. m)

1,100

waste imput (tonnes / year)

34.3 % Incineration

25,000

electric ourput (households)

4,700 3.3 % other 1000

5000

10000

20000

30000

Estimated Energy Production

190 WTE plants operating, 40 under construction, over 50 planning

34.3% of the MSW is treated by incineration

INCINERATION

FILTERING

TYPICAL CONFIGURATION

WATER & STEAM

HEAT & POWER GENERATION

NEW CONFIGURATION GAS RELEASE

1.

GAS RELEASE

11.5

11.0

4.0 2.0

6.25

4.0

3.0

2.5

2.5

2.5

10

8.0

8.0

INCINERATOR

SUPERHEATER

ECONOMIZER

EMERGENCY DIESEL

Dimensions : 8 m x 8 m x 11.5 m

Dimensions : 4 m x 6.25 m x 4 m

Dimensions : 3 m x 2.5 m x 11 m

Dimensions : 2.5 m x 2.5 m x 2 m

The incinerator is the combustion area where waste is fed and burned. The produced flue gas passes to the boilers while the residue is discharged from the bottom part of the component.

The superheater is a horizontal or vertical component through which tubes of steam are exposed to the high temperatures of the flue gases and heat is transferred to the steam through convection.

The last part of the boiler is the economizer. Here the water is heated before passing to the boiler drum and the evaporator, reaching just below boiling point for those pressure properties.

Emergency diesel generates electricity through burning diesel as the backup power source.

Maintenance : Once a year.

Maintenance : Tubes changed every 5 years

Maintenance : Every 10-15 years

Maintenance : N/A

1.

bunker hall control room

2.

evaporator

incinerator

3.

incinerator

4.

superheater

4.

superheater

5.

economizer

5.

economizer

6.

air cooled condenser

6.

air cooled condenser

7.

steam turbine & generator

7.

steam turbine & generator

8.

baghouse filter

8.

baghouse filter

9.

condensing unit

9.

condensing unit

10.

fan & chimney

10.

fan & chimney

11.

feed water tanks

11.

power transformer

12.

automation

12.

water chiller

13.

emergency diesel

10

8

9

2 5

3.5

1.6

3.6

4.2

9

5.0 1.6 6.0

10.0

3.0

4.6

3.5

6.0

6 AIR-COOLED CONDENSERS

WATER CHILLER

bunker hall

2. 3.

Dimensions : 6 m x 10 m x 3.5 m

Dimensions : 3 m x 6 m x 3.6 m

Dimensions : 3.5 m x 4.6 m x 4.2 m

Dimensions : 1.6 m x 5 m x 1.6 m

The air-cooled condensers are large dry-cooling components that bring the tubes of heated steam through fan-induced cooling air drafts in order to condense it back to water.

The water chiller is the use of water cooling instead of air cooling. In this case the condenser does not cool the hot refrigerant with ambient air, but uses water that is cooled by a cooling tower.

The evaporator vaporizes feed water into steam for further heating through the economizer.

The power transformers are located one step before the power generated in the facility goes to feed the building. It is used to transform electricity in both directions.

Maintenance : Low maintenance needs.

Maintenance : N/A

Maintenance : N/A

Maintenance : N/A

4

5

POWER TRANSFORMER

EVAPORATOR

6

8 4

12

11 3 3

7

11

12 1

7 ELECTRICITY OUTPUT

22.0 9.0 9.0 4.0

10.0

1

4.0 3.0

3.0

ELECTRICITY OUTPUT

8.0

7.0

5.0

Design Concept

BAGHOUSE FILTER

104

5.0

CONDENSING UNIT FAN & CHIMNEY

STEAM TURBINE GENERATOR

Dimensions : 7 m x 8 m x 9 m

Dimensions : 3 m x 3 m x 9 m

Dimensions : 5 m x 5 m x 22 m

Dimensions : 4 m x 10 m x 4 m

The baghouse filter is comprised of metal cages covered by fabric filters that capture fly ash particles. The flue gas passes from the outside of the fabric bags to the inside, leaving behind all ash particles, which are periodically cleaned by compressed air flowing in the opposite direction.

The condensing unit is another scrubber unit that is used to further cool the flue gases when the plant connects to district heating. Condensing steam to water improves the eďŹƒciency of the heat production.

The final step before releasing the clean flue gases to the atmosphere is the induced draft fan, that creates a boosting draft, and the chimney.

The steam turbine generator receives steam from superheaters and sends it to condensers.

Maintenance : Every 5 years.

Maintenance : N/A

Maintenance : Low maintenance needs.

Maintenance : Low maintenance needs

BOTTOM ASH

BOTTOM ASH

2

105

View from the City

INCINERATION INCINERATOR SUPERHEATER ECONOMIZER

HEAT & POWER GENERATION STEAM TURBINE GENERATOR EMERGENCY DIESEL POWER GENERATOR

BIOMASS POWERPLANT INCINERATION HEAT & POWER GENERATION WATER & STEAM FILTERING LOADING & STORAGE

WATER & STEAM AIR COOLED CONDENSERS WATER CHILLER EVAPORATOR

LOADING & STORAGE LOADING DECK BUNKER HALL SPIRAL CONVEYOR BELT FLUID TANKS INCINERATOR

Building System

GROUND LEVEL ATRIUM & RECEPTION CAFE KITCHEN

ELEVATOR CORE

CIRCULATION

WORK OFFICE MEETING ROOM MATERIAL WORKSHOP

PRIMARY PROGRAMS (FRONTAL SLAB) GROUND LEVEL (LOBBY) LABATORIES WORKSHOP & MEETING ROOM OUTDOOR PATIO

WORK ENVIRONMENTAL LABAROTRY ENVIRONMENTAL RESEARCH LAB BUILDING TECHNOLOGY LAB

FILTERING BAGHOUSE FILTER CONDENSING UNIT FAN & CHIMNEY

SECONDARY PROGRAMS (BACK SLAB) OFFICES MECHENICAL ELEVATOR CORE UTILITIES

OUTDOOR PATIO

OFFICES

106 OVERALL BIOMASS POWERPLANT CIRCULATION ATRIUM & RECEPTION WORKSHOP & LABATORIES MECHENICAL CONTROL MONITOR SECURITY STORAGE SERVER ROOM

UTILITIES RESTROOM JANITOR

LOADING & STORAGE

107

View from the West

CHIMNEY

POWER PLANT BAGHOUSE FILTER

STEAM TURBINE GENERATOR AIR COOLING CONDENSER AIR VENTILATION EVAPORATOR

COMBUSTION CHAMBER SUPERHEATER

LEVEL 5

HEATING/COOLING DISTRIBUTE

ELEVATOR SHAFT

AIR SUPPLY DISTRIBUTION CONVEYOR BELT

ASH COLLECT

BUILDING MONITOR

LEVEL 4 SPIRAL CONVEYOR BELT OFFICE

TOURIST ESCALATOR ENVIRONMENTAL RESEARCH LABORATORY

LEVEL 3

OFFICES

ENVIRONMENTAL RESEARCH LABORATORY

MEETING ROOM

LEVEL 2

ADMINISTRATION

BUILDING TECHNOLOGY LABORATORY

Exploding Axonometric Drawing

MEETING ROOM

LEVEL 1

BACKSIDE CURTAIN WALL

TOURIST ROUTE STARTS HERE

RECEPTION

LOADING DECK

CAFÉ

BASEMENT

FLYASH SILO

WATER MANAGEMENT

BUNKER HALL

MECHANICS UNDER LOADING DECK TRUCK ENTRANCE

108

FRONTAL CURTAIN WALL

LOUVER SYSTEM

E XP LO DED AXO NO METRY

109

East Facade and Section

Building System

fly ash

P OW ER PL ANT SYS T EM

WAT ER SYS T EM

V ENTIL ATION SYS T EM

HE ATIN G/ COOLIN G SYS T EM

110

111

Cross Section

112

Building Details

113

Interior View

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

YUÁN

114

Faced with growing development concerns, the Xiong’an Development Plan for China’s capital district must take into consideration its cultural relationship to its proposed context fabric. This project chooses to look at traditional Chinese courtyard houses and garden (Yuan)— common to the China — as an adaptive reuse response to the expected development of existing buildings. By inverting the organizational strategy of the Siheyuan homes, a programmatic core is contained within an enveloping greenspace to create an inviting public space

within the building. Housed exclusively in the structural remains of the existing building, this perimeter garden serves as a cultural amenity to symbolically represent the preservation of the city’s existing fabric, to better serve the city’s evolution through historical reference. Adding a dynamic circulatory experience, gardens are reached by navigating catwalks that weave through the structural skeleton. In a similar vein, the programmatic mass is constructed through a rammed earth, providing a distinct formal, spatial, and structural language sourced from local techniques. Spatially, the mass arranges programs into two distinct compartments, one for a material research laboratory and the other for art studios, to satisfy distinct performance concerns for the specialized programs. In its entirety, the project performs environmentally by completing a thermal mass heating cycle and various passive ventilation effects to regulate interior temperatures. By combining distinct architectural systems that are contextually sourced, this project satisfies rising developmental concerns while presenting itself as a potent cultural intervention. Jose Sanchez Cruzalegui Hanseul Jang

115

<Existing>

<Subtraction>

<Replication_Structure>

<Addtion_Program>

<Retrofit Diagram>

<Lab>

<Collective>

<Service>

Design Concept

<Studio>

116

<Program Diagram>

Axonometric Drawing 117

<Site Isometric>

Absorb Heat

Release Heat <Thermal Mass>

<Stack Ventilation>

<Summer_Cross Ventilation>

<Winter_Green House Effect>

Building System

<Passive System Diagram>

<Rammed Earth>

<Glass>

<Concrete>

<Metal>

118

<Material Diagram>

Design Concept 119

<New Xiong’an>

a

b

12’

c

12’

d

10’ - 6”

e

12’

f

g

12’

12’

h

12’

i

j

12’

12’

End of 5th Floor 60’ - 0”

5th Floor 48’ - 0”

4th Floor 36’ - 0”

3rd Floor 24’ - 0”

2nd Floor 12’ - 0”

1

Top of Labatory Chimney

Section and East Elevation

87’ - 0”

Roof 48’ - 0”

4th Floor 36’ - 0”

3rd Floor 24’ - 0”

2nd Floor 12’ - 0”

120

4

3

2 18’

18’

18’

5 18’

k

10’ - 6”

l

12’

m

12’

a

d

c

b 12’

12’

10’ - 6”

e 12’

g

f 12’

h

12’

12’

j

i 12’

k

12’

10’ - 6”

Roof 60’ - 0”

5th Floor 48’ - 0”

4th Floor 36’ - 0”

3rd Floor 24’ - 0”

2nd Floor 12’ - 0”

1

Roof 60’ - 0”

5th Floor 48’ - 0”

Sections

4th Floor 36’ - 0”

3rd Floor 24’ - 0”

2nd Floor 12’ - 0”

121

4

3

2 18’

18’

18’

5 18’

m

l 12’

12’

Roof

+76’

+66’

Munsell Soil Color: 10R 8/4

Office Soil Laboratory

+66’

Fifth Floor

Studio

Lavatory Storage

+50’

Munsell Soil Color: 10R 8/3

Workshop

Office Steel Laboratory

+50’

Fourth Floor

Studio

Lavatory Storage

+38’

Munsell Soil Color: 2.5YR 8/3

Workshop

Office Cement Laboratory

Lounge +38’

Third Floor

Lavatory +28’

Storage Munsell Soil Color: 2.5YR 8/4

Office Aggregates Laboratory

Lounge

+28’

Studio

Second Floor

Rammed Earth Axonometric Drawing

Studio

Lavatory

+12’

Munsell Soil Color: 5YR 8/3

Administration

122 +12’

Ground Floor

Lobby

0’

Munsell Soil Color: 5YR 8/4

Parapits

Roof

Research Laboratories

Studio

Wall Shelf Units Workshop

Stair Core

Eastern Wall

Bamboo Shoots

Landscaping

Railing

Roof Slab

Exploding Axonometric Drawing

Walkways

Shear Wall

Concrete Frame Structure

Mullions

Eastern Glazing

123

Rammed Earth Wall (without steel rebar) (1.5’ thick) Self Adhered Membrane Roof Underlayment Roof Sheathing (1/2”) Rigid Insulation (2”) Roof Sheathing (5/8”)

2 % Angled

Concrete Roof/Slab Roof Drain

Rammed Earth Arch

(to the gutter of the service cavity)

Pre-Fabrication Line

SIRE Wall (Structured Insulated Rammed Earth Wall)

Steel Rebar (10” spacing)

Rigid Insulation

Glass Railing

Rammed Earth Mound Edge

Mechnical Connection

Metal Mullion (Extension of the Concrete Structure)

Vertically Sliding Window

Concrete Beam (1.5’ x 1’)

Flashing 6”

Pre-Fabricated Rammed Earth Arch

Corrugated Slab

Concrete Slab (Stair Landings) Metal

Concrete Column (1.5’ x 1.5’)

Vapor Retarder Layer

Concrete underneath the paving

Filter Fabric Rigid Insulation (4”)

Reservoir Layer (1”) Moistrue-Retention Layer (.4”)

Building Details

Drainage System

Soil Grain

8”

Cavity for ground sliding window

Mechanical Connection

124 Concrete Footing

Drainage Pipe

Concrete Foundation

Aeration Layer (.4”) Thermal Insulation (1”) Drainage Layer (.5”) Root Barrier Protection Course

Rigid Insulation Soil

Fabric-Reinforced Hot-Fluid-Applied WaterProofing Membrane

6”

125

Interior View

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

RE-FRAME

126

Located in Xiong’an, China, this green building strives to effectively clean the environment while inspiring the community to contribute. On one side of the building, laboratories — traditionally a privatized program — are put on display in a museum-like fashion where patrons can circulate around four labs before being introduced into the product showroom and product salesroom. Green products produced by in-house researchers are made available for immediate purchase. The complementary side of the building is dedicated to the public, servicing an event space and an auditorium to encourage local involvement and foster guidance on going green. The two sides intermittently join together to allow access between the two at related

programmatic points to further blur the line between what is traditionally public and private. The building’s form derives from the demands of mechanical systems, circulation, and urban intervention. The incline of the superimposed new structure not only allows for the clean collection of rainwater that services the radiant heating system restrooms, but also develops a perspectival welcoming to the building that interrupts the urban fabric to intrigue passersby, while freeing the ground level for purpose of granting additional outdoor space, otherwise lost, but valuable to a green building. Glazing and textile facades are situated to prevent excess solar heat gain, and reveal the building’s structural system and primary circulation, similar to the theme of exposing private program. Inside and out, re-framing the building exposes all of its most valued assets that demonstrate the composition of a polysemic environmentally-friendly building. Ian Masters Ryan Oeckinghaus

127

128

Design Concept

HVAC

ALL LEVELS

Axonometric View and Building System

TO SUPPLY & RETURN CLEAN, COOL AIR

RADIANT HEATING

ALL LEVELS TO PROVIDE HEATING COMFORT THROUGHOUT

OVERALL THERMAL

ALL LEVELS

TO ACHIVE OPTIMAL THERMAL COMFORT

EXISTING STRUCTURE

TILTED STRUCTURE

OVERALL STRUCTURE

TRADITIONAL COLUMN-BEAM STRUCTURE

BEAMS, TRUSSES, COLUMNS, LOAD-BEARING WALL

EXISTING AND NEW ASSETS

EVENT STAIRS

LABORATORY STAIRS

129 FIRE STAIRS

LEVELS 1-5

CONSISTING OF TWO CORES, LOAD-BEARING

LEVELS 1-4

PROVIDES SERVICE TO PRIMARY PUBLIC SPACES

LEVELS 2-5

PROVIDES SERVICE TO PRIMARY PRIVATE SPACES

130

Southeast View and Sections

131

Narrative Axon

A

B 18’-0”

+72’-6”

Interior View and Short Section

MAX. HEIGHT

+48’-0” LEVEL 5

+37’-0” LEVEL 4

+26’-0” LEVEL 3

+13’-0” LEVEL 2

+0’-0” LEVEL 1

132

SECTION B 1/8” = 1’-0”

C 17’-0”

D 14’-0”

E 21’-0”

LABORATORIES

EVENT SPACES

RIGHT WING

LEFT WING

ROOF MEMBRANE THERMAL INSULATION METAL DECKING COPING COVER DOOR FRAME CONCRETE PANEL T-SECTION STEEL SUPPORTS DROP CEILING SET BASE SEALANT

DOUBLE GLAZING FLASHING DUROCK CEMENT PANEL METAL FRAMING VAPOR BARRIER

GYPSUM SHEATHING

SHEETROCK GYP. PANEL

THERMAL INSULATION STEEL I-BEAMS RADIANT HEATING PTFE TEXTILE FACADE SYSTEM CLIP ANGLE

CIP CONCRETE

STEEL RUNNER

WINDOW FRAME

DOUBLE GLAZING

SINGLE GLAZING

INSULATED WOOD PANELING

CONCRETE COLUMNS

REINFORCED CONCRETE SLAB

REINFORCED CONC. BEAM

DETAILED SECTIONS

A

B 18’-0”

Building Details and Short Section

+59’-0”

+48’-0” E E 5

+37’-0” E E 4

+26’-0” E E 3

+13’-0” E E 2

+0’-0” E E 1

133

SECTION C 1/8” = 1’-0”

C 17’-0”

D 14’-0”

E 21’-0”

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

SHIFTING

134

The science center focuses on engaging the public and drawing them in. The program consists of an exhibition space, café, store, labs, offices, and classrooms that exist within the structural system of an abandoned factory building in Xiong’an, China. These programs are divided into public and private realms that have varying views between each other. The private spaces are inserted into the existing public space that utilizes the old structure of the factory. The private labs, offices, and classrooms are encased in a steel structure that follows formal logic found in typical Chinese courtyard houses. Floor heights are shifted to allow the inhabitants of the public area to view into the private lab and office spaces. This arrangement increases the importance of circulation in the building; these areas become transitional zones that follow the logic of the existing structure as well as the new structural logic.

The exterior of the building utilizes a wooden cladding system that prevents unwanted glare and solar heat gain in the private spaces. This system responds to orientations as well as the required light necessary for program type. The wooden system also absorbs CO2 that would be produced from the steel structure of the building. As for the public space, a window treatment is applied based on the major zones where spaces are overlit. The building also incorporates a system for ventilation, prioritizing the labs requiring more air flow. Heating and cooling are provided by a geothermal system with the aid of a passive system using the open ground floor and operable ceiling in the exhibition space. The roof includes staggered roof terraces benefiting the offices adjacent to them. Solar panels sit on these roof spaces, obtaining light that will be used to power the other systems in the building. Ross Hanson Brooke Calhoun

135

Exhibition

+

Building Science Lab R e s e a rc h a n d Development Lab C l a s s ro o m s To t a l R e c o m m e n d e d

P ro d u c t i o n L a b O ffi c e s G re e n s c a p e s Cafe H o m e S t o re

P R O G R A M M AT I C O V E R V I E W

Module Area: 288 SqFt

12

24

FE

ET

Module Area: 288 SqFt

ET

FE

Activity

Activity

Light

Light

Ventilation

Ventilation

Energy

Energy

Flexability

Flexability

12

ET

24

FE

ET

FE

18

ET

FE

ET

10

FE

ET

ET

10

FE

Module Area: 100 SqFt

Module Area: 324 SqFt

Activity

Activity

Light

Light

Light

Ventilation

Ventilation

Ventilation

Energy

Energy

Energy

Flexability

Flexability

Flexability

Module Area: 400 SqFt Activity

20

ET

FE

ET

FE

Design Concept

20

18

22

FE

ET

136

ET

ET

22

FE

20

28

FE

10

FE

FE

ET

ET

16

ET

10

FE

ET

FE

ET

Module Area: 400 SqFt

Module Area: 560 SqFt

Module Area: 100 SqFt

Module Area: 256 SqFt

Activity

Activity

Activity

Activity

Light

Light

Light

Light

Ventilation

Ventilation

Ventilation

Ventilation

Energy

Energy

Energy

Energy

Flexability

Flexability

Flexability

Flexability

16

FE

FE

137

Exploding Axonometric Drawing

+ 96.12 ft Roof 2 + 86.39 ft Roof 1

+ 71.1 7 ft

East Facade View and Section

Level 6

+ 57.5 1 ft Level 5

+ 44.14 ft Level 4

+ 30.76 ft Level 3

+ 17 .3 9 ft Level 2

138

+ 0 ft Level 1

SE C T I O N A L P E R S P E CT IV E 1’ = 1/4”

139

First Floor Interior View

Gravel 2-Layer Bituminous Membrane Bituminous Vapor Barrier Mineral Wool Insulation Glue-Laminated Timber

70mm Mineral Wool Insulation 15mm Birch Veneer Plywood

3� Concrete 30mm Impact Sound Insulation 24mm Perlite 40mm Laminated Lumber 2x4 Floor Joist 70mm Mineral Wool Insulation 15mm Birch Veneer Plywood

Exterior Wood Cladding 14mm Air Barrier Vapor Barrier

Building Details

350mm of Mineral Wool Insulation Weather Resistant Barrier

Glue-Laminated Timber Beam

140

Glue-Laminated Timber Tie 2-Pane Glazing Bamboo Facade

141

Third Floor Interior View

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

BRICKING

142

Inspired by Chinese traditional courtyard houses, we wanted to create a central courtyard space that would allow the different programs of the building to share space, all while respecting hierarchies. To achieve this, the floor plates are enveloped by a series of half vaults to create a central public core. This produces overlapping space to help connect the public and private programs while still keeping them separate. These half vaults help to hide the truss systems that were added to the structure of the existing building, creating a sense of structural ambiguity. Some of the original structure was also removed to make room for the public space. Two bays were added to the back of the lot and one was added to the front as a cantilever. The half vaults also hide within them the cores for the HVAC, heating and cooling systems. Within the public space, the vaults would act

as a dropped ceiling concealing the overhead systems. While in the remainder of the building, the original concrete structure and systems would be exposed. This further differentiates the public space from the programmed private space. Programmatically the building is organized from the private at the top to public at the bottom. The first floor consists of the lobby, gift shop and the exhibition spaces. Within the exhibition space, there are two private showrooms for buyers to see the materials up close. The second floor consists of the cafe and rentable office space. The third and fourth floors hold the test and research labs. The fourth floor allows access to the public green space. The site conditions consist of cold harsh winters with hot summers. With the cold winds in the winter, a sunny wind-protected area would be key for public spaces. The winds are prominently from the north which is why the opening for the public space is facing east. This is also the side that faces the main street. The building should be well insulated and tightly sealed. For efficiency, natural ventilation techniques could be deployed in the public area to reduce but not eliminate air conditioning. The sunlight exposure is most contracted on the southern side of the site. Most of the fenestration will be on the southside, with a shading device to diffuse harsh sunlight in summer. A sunscreen made of heat retaining bricks could be used for shading and reduced heating in the winter. 143

Yui Kei Lo Katherine Truluck

144

Southeast Veiw and Entrance

145

Exploding Axonometric Drawing

L

1

72’

F4

MECHANICAL ROOM 2

36’

F3

GLASS ELEVATOR

24’

F2

12’

F1

Section

FLEXABLE PARTITION WALLS

146

2

3

4

5

6

7

8

9

10

11

MECHANICAL ROOM 1 EXTERIOR WALL SYSTEM Flyash conctrete blocks Insulation Waterproofing Air pocket Steel locking brackets and Frame Flyash modeled panels

SINGLE PANE GLASS WINDOW Steel loose lintel Vent/weep at maximum 24 inches on-center Two-piece sheet-metal head flashing Sheet-metal trim Sealant over backer rod Continuous air barrier sealant Continuous back dam

STEEL FRAMING SYSTEM

PLASTIC BRICKS

CHILLED BEAM SYSTEM Drop rods Primary air duct Cooling coil Lighting Motion detectors Sprinkler pipework Hot-water pipework Control vavles and actuators

147

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

UP

148

This project is focused on designing space for building material research facilities and for displaying that work to the public. The large cantilevered truss on the top acts as a clear contrast to the lower blocks set within the old structure. Similarly, the use of varying levels of transparency supports this contrast.

Within the existing concrete structural frame, individual programmatic blocks house the various testing areas and material research labs. Each block is dedicated to a specific material or task, while maintaining connections through adjacencies with related blocks. This lower part creates closed spaces for research, yet also allows for expansion given the large openings within the existing structure. It also serves to create a distinct character to the more clean and open gallery spaces above. In this upper cantilevered addition, a public showroom and gallery connects the building and the work within it to the surrounding community. A public stair that weaves through the lower research spaces serves to strengthen this connection by allowing moments to view the research spaces. Once the upper floors are reached, occupants are shown the finished products of the research done below. The upper floors make full use of solar exposure on the open south and east facades, while the cantilever helps shade the labs spaces. Aaron Guttenplan Spencer Gafa

149

PUBLIC PROGRAMS FLOORS 5-6

GREEN ROOF

EXHIBITION

Ventilation Illumination Occupancy Equipment Size

SHOP

CAFE

SHOWROOM

Ventilation Illumination Occupancy Equipment Size

FLOORS 5 + 6

MAIN STAIRS

RESEARCH LABS FLOORS 1-4

WOOD RESEARCH

GLASS RESEARCH

MATERIALS TESTING Ventilation Illumination Occupancy Equipment Size

Programs 150

Size

METALS RESEARCH

MASONRY RESEARCH

STRUCTURAL TESTING Ventilation Illumination Occupancy Equipment Size

INTERACTIVE DESIGN Ventilation Illumination Occupancy Equipment

Ventilation Illumination Occupancy Equipment Size

Ventilation Illumination Occupancy Equipment Size

Ventilation Illumination Occupancy Equipment Size

Ventilation Illumination Occupancy Equipment Size

ROOF

FLOOR 6

FLOOR 5

FLOOR 4

Exploding Axonometric Drawing

FLOOR 3

FLOOR 2

FLOOR 1

151

LANDSCAPING

ENVELOPE

CIRCULATION

TILE PAVED

FLOOR SLABS

STEEL STRUCTURE

BRICK CLADDING

MAIN STAIRWAY

PLANTED

EXISTING STRUCTURE

CONCRETE STRUCTURE

FLOORS 5 & 6 GLAZING

CORE CIRCULATION

AUGMENTED EXISTING STRUCTURE

COMPLETE STRUCTURE

FLOORS 1-4 GLAZING

COMPLETE CIRCULATION

STRUCTURE

STRUCTURAL WALLS

SYSTEM

A

Building System and Cross Sections

COMPLETE STRUCTURE WITH SLABS

NEW STRUCTURE

FOUNDATION

B

C

D

COMPLETE GLAZING

E

81’ - 0”

81’ - 0”

69’ - 0”

69’ - 0”

57’ - 0”

57’ - 0”

46’ - 0”

46’ - 0”

34’ -6”

34’ -6”

23’ - 0”

23’ - 0”

11’ - 6”

11’ - 6”

0’ - 0”

0’ - 0”

SECTION A

A

B

C

D

E

A

B

C

D

E

SECTION B

A

B

C

D

E

81’ - 0”

81’ - 0”

69’ - 0”

69’ - 0”

57’ - 0”

57’ - 0”

46’ - 0”

46’ - 0”

34’ -6”

34’ -6”

23’ - 0”

23’ - 0”

11’ - 6”

11’ - 6”

0’ - 0”

0’ - 0”

152

SECTION C

COMPLETE GLAZING

SECTION D

153

Exterior View and Section

INTEGRATED STUDIO

XIONG’AN, THE CITY OF REGENERATION

RECYCLING REVOLUTION

154

Free Range Fashion is an architectural project that emulates the idea of total sustainability. The site, located in Xiong’an, China, was once a factory and is being refurbished into an athletic sneaker production and testing facility. To maintain a healthy lifestyle, a healthy environment must be just as accessible. By incorporating passive and natural ventilation strategies along with soft scape features, the building acts as a

breeding ground for sustainable technology along with a sustainable environment. Produced in this building are sneakers made of various plant components, such as corn and cotton, and 3D printed conduits. The in-house assembly allows for in store sales and testing of these products in the running track and kickboxing studio. Specific programmatic requirements regarding heating and lighting were taken into account when dispersing the various stages of production and use throughout the building. The preservation of the original structure is key in the concept of sustainability. Only slight changes and additions to the structure were added to fit in additional square footage and allow for an atrium to create natural ventilation and allow sunlight. Along the south facing wall of the atrium is a living green wall that is responsible for the maintenance of ventilation in this four storey area. The concept of repurposing to promote the health of the earth and its inhabitants is the nature of Recycling Revolution. Evan Webb Christina Rubino

155

design

Original Building Program: Clothing Factory Original Building Square Footage: 60,000

production

water

artificial/natural light

artificial/natural ventilation

people

furniture

design printing materials assembly

Ventilation Strategy The adaptive reuse of the building splits it in two parts according to program and north/south orientation; this division is done via the atrium. The north face of the building is dedicated to design and production with controlled heating, cooling, and ventilation, while the south end showroom of the building uses a mix of passive strategies including green wall ventilation, trapping/releasing heat via external greenhouses, and controlled mechanical systems.

Structural Strategy The intention of recycling the original building materials. The changes made to structure included minimal demolishment for an atrium to provide natural ventilation. Additionally, an interior/exterior sloped running track wraps the exterior and is linked with light weight steel structural members.

water

artificial/natural light

artificial/natural ventilation

people

furniture

sales/cafe exposition

Building Concept

gym greenhouse

sales New Building Program: Sneaker production/sales/testing facility New Building Square Footage: 100,000

156

use

Exploded Axonometric

supply/return plumbing work mechanical work 70% fritted glass micro-rib exterior panels mechanical work supply/return

Roof Floor

70% fritted glass

concrete structure

design space HVAC system

PMMA acrylic glass

plumbing system 70% fritted glass materials library micro-rib exterior panels

design space

track HVAC system

Third Floor

70% fritted glass

PMMA acrylic glass greenhouse

concrete structure sneaker assembly HVAC system

plumbing system 70% fritted glass micro-rib exterior panels

atrium HVAC system

30% fritted glass

kickboxing studio

track 70% fritted glass

Second Floor greenhouse

track

printing and assembly

30% fritted glass PMMA acrylic glass

HVAC system

Exploding Axonometric Drawing

plumbing system

micro-rib exterior panels 70% fritted glass

track

atrium HVAC system

product testing 70% fritted glass

First Floor

greenhouse

track exposition HVAC system

30% fritted glass PMMA acrylic glass

cafe

bathrooms

plumbing wall mechanical room fire stairs micro-rib exterior panels 70% fritted glass columns for track

greenwall ramped ground plae atrium HVAC system product showroom elevators mechanical room

Ground Floor

157

fire stairs

exposed structure columns for track

70% fritted glass

Scale 1’=1/8�

Axonometric Diagrams

program

structure

systems

facade

Program Distribution design production sales exposition and usage greenhouse

Structural Additions original added building mass removed original/ new cores structural extentions for ramp overall

Mechanical Systems living green wall mechanical rooms HVAC plumbing

Building System

combined systems

Facade Allocation

158

solid 70% glass frit 30%glass frit PMMA arcylic glass

Scale 1’=1/32�

Section Detail Running Track, Greenhouse, Glass Exterior

PTFE Glass Mesh (1 1/4” thickness)

PMMA Glass (1 3/4” thickness)

Glass with 30% Frit Linear Texture (3/8” thickness)

Metal Decking (2” depth with 36” coverage)

Flashing & Exterior Cover in Aluminum Steel I-Beam (8” x 5 1/2”) Exterior Finish Covering Steel Bracket Support

Gypsum Board (3/8”) Polished Concrete Finish (1/2” thickness) End Cap for Spill Over Spacer Joint (2 1/4” gap) Metal Decking w/Concrete Finish (6” total) Rigid Insulation (3/4” thickness) Dampproofing or Waterproofing

Reinforced Concrete Beam (10” x6”) Rebar

Seam Joint Micro-rib Exterior Panels

Building Details

Window Glazing (thickness of 1/2”)

Polished Concrete Finish Aluminum Window Frame Flashing Protection Protection Board or Coating extends

Low Permeability Soil

Reinforced Concrete Retaining Wall

Rigid Insulation

159

Drainage Mat, Insulating Drainage Board

Dampproofing or Waterproofing

Filter Fabric Surrounding Course Gravel

Perimeter Drain System (2” diameter) Concrete Footing

MS Arch Program Inquiries: Brian Lonsway Associate Professor Chair of the Graduate Program Fei Wang Assistant Professor Coordinator of MS Arch Program 225 Slocum Hall Syracuse University School of Architecture Syracuse NY 13244 +1-315–443–1041 soa.syr.edu/programs/postgraduate archms@syr.edu

160

ACKNOWLEDGMENTS

REVIEWERS Amber Bartosh Ted Brown Bing Bu Junho Chun Greg Corso Julia Czerniak Al Daniels James D’Aloisio Britt Eversole Joseph Godlewski Terrace Goode Roger Hubeli Randall Korman Bess Krietemeyer Leslie Lok Brian Lonsway Daekwon Park Zhao Pei Francisco Sanin David Shanks Michael Speaks Linda Zhang EDITING Michael Speaks Elaine Wackerow Fei Wang TRANSLATION Ying Zuo BOOK DESIGN Common Name Fei Wang