Wenhan Li 2009 - 2017 Selected Works
I don’t really believe there is a clear boundary between architecture design, interior design, furniture design etc. Design is design. It is all about how much we care, and what we care about.
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Beijing
2 Architectural Projects 3 Interior Projects 2 Digital Fabrication Projects
Anhui
1 Architectural Project
Jiangsu
1 Interior Project 3 Landscape Projects 2 Urban Planning Projects 2 Furniture Projects
Xinjiang
1 Interior Project
Shanghai
1 Interior Project
China
Shanxi
1 Urban Planning Project
Guangdong
1 Architectural Project 2 Interior Projects 1 Urban Planning Project
Guizhou
1 Interior Project
Sichuan
2 Architectural Projects
Zhejiang
1 Architectural Surveying & Mapping Project 1 Architectural Projects 1 Interior Project 2 Material Research Projects
Cambodia
Sun & Moon Gulf
1 Sculpture Project
Germany
United States of America
Stuttgart
2 Digital Fabrication Projects 2 Material Research Projects
Kansas
4 Architectural Projects 2 Digital Fabrication Projects
Louisiana Hawaii
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1 Architectural Projects 1 Architectural Project
2009 - 2017 19 academic projects 25 professional projects project leader for 4 of the professional projects 8 architecture/interior projects completed 10 Architecture Projects 10 interior projects 6 urban planning projects 3 landscape projects 1 architecture surveying and mapping project 1 infrastructure project (bridge) 3 material research projects 3 furniture design projects 1 sculpture project 1 structure design project 4 digital fabrication projects
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XS Academic 01
Adaptable Scaffolding Effector Design for Robot Arm Group Project | Concept Design, Mechanical Design, Mock up Making
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Vanishing Carrier Preparation and Structure/Function Analysis for Conductive Polymer Composite Nano PLA Fiber Individual Project
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Textile design and concrete reinforcement The New Construction Material - Design of Three-Dimension Braided Reinforced Concrete Structure Individual Project
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XS | Academic | 02
Preparation and structure function analysis of conductive polymer composite nano-PLA fiber Key Laboratory of Macromolecular Synthesis and Fractionalization, Ministry of Education, Hangzhou,China Instructor: Prof. Hongzheng Chen, Prof. Qiaozhen Yu Nanofibers, with large surface-to-volume ratio, have potential use in various applications where high porosity is desirable. Perhaps the most versatile and simple process for producing nanofibers with relatively high productivity is electrospinning. Nanofibers of conduct polymers can be made for applications in energy storage, healthcare, biotechnology, environmental engineering, and defense and security. Some basic conceptions and recent studies of conduct polymer and nanofibers are reviewed in this paper, also the development of the combination of electrospinning and conduct polymer is included. The H2SO4 doped polyaniline (PANI) and polypyrrole (PPy) hybrids with different molar ratio are synthesized by using chemical polymerization. The SEM is used to observe the morphologies of the samples. Some methods have been used to get the spinning solution, to make the process of electrospinning. But it seems that all the solution we made is not good enough for electrospinning of PANI and PPy hybrids. Considering the bad process performance of PPy, the poly L-lactic acid (PLLA) nanofibers were fabricated by electrospinning firstly, and then the PLLA/PPy hybrid fibers net were obtained by in situ polymerization PPy on the surface and in the pores of PLLA fibers. And we know that the low temperature is good for PPy to cover the PLLA nanofibers tightly and evenly. We hope this result can make a possible form that used in biology-medical.
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Conductive Polymer Trans Polyacetylene (TPA) polypyrrole (PPy) Polythiophene (PT)
Polyaniline (PANI)
Poly p-phenylene vinglene (PPV)
Ploy p-phenylene (PPP)
Electrospinning injection pump syringe polymer solution spinneret high voltage fibers collector
SEM image for the Final Product
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Chemical Synthesis of Sulfated Doped Conductive Polymers Invariant Step 2
Step 1
APS solution
Step 4
Step 5
Step 6 acetone
No
conductive polymer
Step 3
No
.2
.3
No.1 160ml
No.2 160ml
No.3 360ml
680ml 1M H2SO4 solution
No.1
ice bath magnetic stirring
No.1
No.2
5-10°C
ice bath magnetic stirring for 46h
clean with H2SO4 solution
vacuum oven 24h 50°C
PANI:PPy=1:3
PPy 100%
Variable (Conductive Polymer) PANI 100%
PANI:PPy=3:1
PANI:PPy=2:1
PANI:PPy=1:1
Scanning Electron Microscope (SEM) Micro Tentacle Structure
Particle morphology
Hysteresis Loop
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S Academic 01 Guide, Connector and Balancer
SD
DD
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B or N
CA
B or N
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Digital Fabrication Pavilion (Post Stressed Wooden Structure) Individual Project
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Insert, Rotate, and Lock
SD
DD
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Digital Fabrication Pavilion (Wooden Structure Without Neil & Glue) Individual Project
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SD
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B or N
CA
Completed
ICD/ITKE Research Pavilion 2016/17 (Carbon Fiber + Grass Fiber) Group Project | Biomimetic Research, Concept Design, Material Research, Collaborate
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SD CD DD B or N CA Harden Soft Material Research and Chair Design ( Canvas + Resin) Group Project | Concept Design, Mock up, 1:1 Scale model, Material Research and Test
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SD CD DD B or N Active Bending and Adaptable Form Research Pavilion ( GFRP + PTFE membrane) Group Project | Concept Design, Model Making, Detail Design
CA
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SD CD DD B or N CA Controllable Chaos Completed Parametric Design Workshop 2010,Tsinghua University,Beijing, China Group Project | Valedictorian | Grasshopper File Preparation, Fabracation and Installation
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B or N
CA
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Modular Binding Big Egg Funiture Design Competition Individual Project Modular Component Desk for Couple Carved Lacquer Funiture Design Individual Project 10
Professional 01 Flowing Light Towers
SD
DD
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B or N
CA
Sun & Moon Gulf International Tourism Area Entrance Sculpture Design Individual Project | Concept Design, Initial Structure Design
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Flower Table Atelier 100s+1 funiture design Individual Project
SD
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B or N
CA
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S | Academic | 02
ICD/ITKE Research Pavilion 2016-17 Project Information Address Completion Area Volume Fibre length Weight Overall dimensions
Keplerstr. 11-17, 70174 Stuttgart March 2017 26.5 m² 58 m³ 184 km 1000 Kg 12.0m x 2.6m x 3.1m
Project Team ICD Institute for Computational Design and Construction – Prof. Achim Menges ITKE Institute of Building Structures and Structural Design – Prof. Jan Knippers ITECH Master Program for Integrative Technologies and Architectural Design Research Scientific Development (ICD/ITKE) Benjamin Felbrich, Nikolas Früh, Marshall Prado, Daniel Reist, Sam Saffarian, James Solly, Lauren Vasey 12
System Development, Fabrication and Construction (ITECH) Wenhan Li, Miguel Aflalo, Bahar Al Bahar, Lotte Aldinger, Chris Arias, Léonard Balas, Jingcheng Chen, Federico Forestiero, Dominga Garufi, Pedro Giachini, Kyriaki Goti, Sachin Gupta, Olga Kalina, Shir Katz, Bruno Knychalla, Shamil Lallani, Patricio Lara, Ayoub Lharchi, Dongyuan Liu, Yencheng Lu, Georgia Margariti, Alexandre Mballa, Behrooz Tahanzadeh, Hans Jakob Wagner, Benedikt Wannemacher, Nikolaos Xenos, Andre Zolnerkevic, Paula Baptista, Kevin Croneigh, Tatsunori Shibuya, Nicoló Temperi, Manon Uhlen. With the support of Artyom Maxim and Michael Preisack.
In collaboration with: Institute of Aircraft Design (IFB) – Prof. Dr.-Ing. P. Middendorf, Markus Blandl, Florian Gnädinger Institute of Engineering Geodesy (IIGS) – Prof. Dr.-Ing. habil. Volker Schwieger, Otto Lerke Department of Evolutionary Biology of Invertebrates, University of Tuebingen – Prof. Olive r Betz Department of Palaeo ntology of Invertebrates, University of Tuebingen – Prof. James Nebelsick Personal Position: Biomimetic Research; Concept Design; Material Research; Material Physical Performance Test; collaborating with IFB etc. 13
08,2015
Study Abroad Program (M.Sc. Programme: ITECH) Begins
Biomimetic Research: Role Model: Trichoptera
Six identified stages of the case building process performed by caddisfly larvae
Analysis of the Aggregate Placement
Concept Design
long-spanning structure with high static depth and fiber-fiber interaction priNCiplEs
biology The Role models
intro
ly o n e t i a c l e r k e l l a
hypo
1 . p r i m a ry
Incremental tensioning system primary structural fibres
stratEgy 1.
stratEgy 1.
fabrication configuration
fabrication steps
fabrication steps
Step .2.
fibr
construction logic
2 . s e co n da ry d r o n e - l o n g s pa n
drone
Hooking high
Carrying spool
Drone accurary is increased by impolementing guides.
B+
B+
L+24
A+
secondary wrapping surface A-
Allows for controlled placement of wrapping fibres.
A-
BB+
B0
B+
B-
A+
BB0
B-
L0
agelena labyrinthica
A+
A0
A-
A+
A0
A-
B+
B0
A+
B+
B0
A+
A-
A0
B-
A-
A0
B-
radial fibres wrapping with spirals
B+
B+ L+13
fibre hierarchy also expressed by different fibre types
A-
drone wrapping Achieves structural depth
L+13
A+
B-
L-24
A-
A+
B-
B+
B0
B-
B+
B0
B-
A+
A0
A-
A+
A0
A-
B+
B0
A+
B+
B0
A+
A-
A0
B-
A-
A0
B-
kuka - tension Anchoring on the ground
References
https://millar153.wordpress.com/tag/moth-trapping/ https://naturfotografen-forum.de/o94906-labyrinthspinne
stratEgy 1.
priNCiplEs structural heirachy
1 . p r i m a ry tensioning
stratEgy 1.
fabrication steps
Step .1.
stratEgy 1.
fabrication steps
Step .3.
fabrication steps
hypo
fa b r i c at i o n s e t- u p
w r a p p i n g s y n ta x
Drone lays primary fibres
Truss component created by Wrapping Primary
Fibres are tensioned by the KUKA
Scaffolding with Secondary fibres.
core structure local control High accuracy Can apply force + strenght
2 . s e co n da ry Surface creation reinforcement global control can travel long spans not fixed
s t r u c t u r a l o p t i m i z at i o n Local/Global Control of Mean Density of Fibers in the Structure
Material Research Material Group Test
08,2016 Study Abroad Program Ends 03,2017 Project Completed
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Analysis of the REM images
Abstractions
stratEgy 2.
potENtials + ChallENgEs Step .4.
Abstractions
Using fibrous morphology to achieve span
eval.
outlook
stratEgy 2.
fabrication steps
Step .2.
re-fibre interaction
fabrication steps
p r i m a ry s t ru c t u r e Large Span + Self Supporting Structure
Kuka attached to the ground
Material Differentiation -> Maximum Utilization of Carbon Fibers Structural Optimization -> Adaptive to variable Scenarios
Layer 1
Open for many Different Setups/Global Geometries
Step .4.
ongoing and more.
yolo.
minimising anchor points
wrapping Drone wraps fibre around openings for shear
fibre placement is defined by the primary
connecitons.
structure.
Drone carries fibre
number of wraps per haul are minimised to
Fewer poles required
Different Levels of Transparency (with Glassfibers)
Drone hooks (max 4 times) in predetermined
maintain MIN friction when tension by kuka
No stoppers required
Environmental Optimization,
sequence
g eo m e t ry
Robot tensioning
Fibre placement is based on predetermined
planar not continuous surfaces → different
winding syntax.
geometries and curvature/ anticlastic shape
Layer 2
of primary structure ( also for better fibre
repeat sequence on second anchor points
****posiiton of fibre is based on start and end
interaction)
position**** third robot for third leg for global stability and more geometries three dimensional intercrossing primary structure not in seperate layers openings not normally extruded but offset
key Anchor points primary structure
stratEgy 2. Step .4.
stratEgy 2.
fabrication steps
Step .1.
study modEl
fabrication steps
Step .3.
fa b r i c at i o n s e t- u p
computing
Ground connections with kuka morphospace
MAX. Openings
CoNClusioN.
timelapse
exp.
So what have we learned
eval.
construction double layer surface with openings with geometry derives
MIN Anchor points
from drone path
2 levels of archoring on the posts for double
u t i l i s i n g t h e d r o n e t o e x t e n t t h e fa b r i c at i o n s pa c e
More Openings to increase no. of shear
layer.
wrapping fibres position
connections.
i n c r e m e n ta l b u i l d i n g p r o c e s s t h at c o u l d a d d r e s s l i m i tat i o n s o f c u r i n g
determined by sequence
Anchors based on openings creates
1.
Anchor pts
2.
Openings
MIN Opening size is determined by drone
d e s i g n e x p r e s s e s t h e fa b r i c at i o n p r o c e s s
tolerance + safety
g e o m e t r i c f r e e d o m a n d l a r g e s pa n s e l f s u p p o r t i n g b e n d i n g s t r u c t u r e
key Anchor points Kuka Morpho space
3.
Robotic Group Test
Obstructive lines del.
4.
resultant fibre layout
Structure Group Test
Bio Group Test
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The Institute for Computational Design and Construction (ICD) and the Institute of Building Structures and Structural Design (ITKE) at the University of Stuttgart together with students of the Master’s program Integrative Technologies and Architectural Design Research (ITECH) have completed a new research pavilion exploring building-scale fabrication of glass and carbon fibre-reinforced composites. The novel process is based on the unique affordances and characteristics of fibre construction. Because these materials are lightweight and have high tensile strength, a radically different approach to fabrication becomes possible, which combines low-payload yet long-range machines, such as unmanned
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aerial vehicles (UAV), with strong, precise, yet limited reach, industrial robots. This collaborative concept enables a scalable fabrication setup for long span fibre composite construction. The research builds on a series of successful pavilions, which investigate integrative computational design, engineering and fabrication, and explores their spatial ramifications and construction possibilities. The project was designed and fabricated by students and researchers within an interdisciplinary team of architects, engineers and biologists.
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Lightweight, Long Span Fibrous Construction Fibre composite materials have tremendous potential in architectural applications. Due to performative material characteristics, they are readily used in highly engineered applications, such as in the automotive and aerospace industries. The potentials within architecture, however, remain still largely unexplored. Within architectural scale production, where material self-weight is of high concern for larger span structures, lightweight fibre composites provide unparalleled performance. However, we currently lack adequate fibre composite fabrication processes to produce at this scale without compromising the design freedom and system adaptability required for the architecture and design industries. Traditional methods of fabrication require full-scale surface moulds and often restrict the process to serialized production of identical parts. Previous research at the ICD and ITKE has explored fibre composite construction without the need for surface moulds or costly formwork. These novel manufacturing processes have been utilized to create highly differentiated multi-layered structures, functionally integrated building systems and large element assemblies. They have freed the relatively formable material from the limitations of traditional fibre composite fabrication processes. However, the scale of these early investigations has been limited by the working space of the industrial robotic arms that were utilized. The goal of the ICD/ITKE Research Pavilion 2016-17 is to envision a scalable fabrication process and to test alternative scenarios for architectural application by developing a manufacturing process for long span continuous fibre structures.
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Process Biomimetic Investigation The focus of the project is a parallel bottom-up design strategy for the biomimetic investigation of natural construction processes of long span fibre composite structures and the development of novel robotic fabrication methods for fibre reinforced polymer structures. The aim was to develop a fibre winding technique over a longer span, which reduces the required formwork to a minimum whilst taking advantage of the structural performance of continuous filament. Therefore, functional principles and construction logics of natural lightweight structures were analysed and abstracted in cooperation with the Institute of Evolution and Ecology and the department for Paleobiology of the University of TĂźbingen. Two species of leaf miner moths, the Lyonetia clerkella and the Leucoptera erythrinella, whose larvae spin silk “hammocksâ€? stretching between connection points on a bent leaf, were identified as particularly promising for the transfer of morphological and procedural principles for long span fibrous construction. Several concepts were abstracted from the biological role models and transferred into fabrication and structural concepts, including: the combination of a bending-active substructure and coreless wound fibre reinforcement to create an integrated composite winding frame, fibre orientation and hierarchy over a long span structure and multi-stage volumetric fibre laying processes for the generation of complex three dimensional geometries.
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Multi-Machine Cyber-Physical Fabrication Creating a long span structure, beyond the working space of standard industrial fabrication equipment, required a collaborative setup where multiple robotic systems could interface and communicate to create a seamless fibre laying process. A fibre could be passed between multiple machines to ensure a continuous material structure. The concept of the fabrication process is based on the collaboration between strong and precise, yet stationary machines with limited reach and mobile, long-range machines with limited precision. In the specific experimental set-up, two stationary industrial robotic arms with the strength and precision necessary for fibre winding work are placed at the extremities
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of the structure, while an autonomous, long range but less precise fibre transportation system is utilized to pass the fibre from one side to the other, in this case a custom-built UAV. Combining the untethered freedom and adaptability of the UAV with the robots, opened up the possibilities for laying fibres on, around or through a structure, creating the potential for material arrangements and structural performance not feasible with the robot or UAV alone.
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Integrative Demonstrator The ICD/ITKE Research Pavilion 2016-17 was created by laying a combined total of 184 km of resinimpregnated glass and carbon fibre. The lightweight material system was employed to create and test a single long spanning cantilever with an overall length of 12 m as an extreme structural scenario. The surface covers an area of about 40 m² and weighs roughly 1000 Kg. The realized structure was manufactured offsite and thus the size was constrained to fit within an allowable transport volume. However, variations of the setup were found suitable for on-site or in situ fabrication, which could be utilized for much longer span and larger fibre composite structures. The pavilion’s overall geometry demonstrates the possibilities for fabricating structural morphologies through multi-stage
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volumetric fibre winding, reducing unnecessary formwork through an integrated bending-active composite frame, and increasing the possible scale and span of construction through integrating robotic and autonomous lightweight UAV fabrication processes. It explores how future construction scenarios may evolve to included distributed, collaborative and adaptive systems. This research showcases the potential of computational design and construction through the incorporation of structural capacities, material behaviour, fabrication logics, biological principles and architectural design constraints into integrative computational design and construction. The prototypical pavilion is a proof-of-concept for a scalable fabrication processes of long-span, fibre composite structural elements, suitable for architectural applications.
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Supported by Volkswagen Stiftung GETTYLAB Kuka Roboter GmbH Peri GmbH SGL Technologies GmbH Hexion Stuttgart GmbH Ed. Züblin AG Lange Ritter GmbH Stahlbau Wendeler GmbH Leica Geosystems GmbH KOFI GmbH Researchers on this project have received funding from the European Union’s Horizon 2020 research and innovation programme under the Marie Sklodoska-Curie grant agreement No 642877, from the Collaborative Research Centre CRC 141 of the German Research Foundation and from the Volkswagen Stiftung’s Experiment! funding programme.
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M Academic 01
Completed 1330 Brook Street Residence Group Project | Studio Website, Design Process, Mock up Making, Construction SD
DD
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B or N
CA
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SD CD DD B or N CA Extraversion and introversion Lawrence Private House Group Project | Team Leader, Chief Designer, Concept Design, 3D Model, Render
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SD
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B or N
CA
Green Restoration of the Culturally Important, Hurricane-Ravaged Lower 9th Ward of New Orleans Group Project | Construction DD
CD
Bridge to China, Anhui, Chizhou Group Project (Core Member) | Construction Management
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Surveying and Mapping at Fenghua, Xikou Group Project | Survey on site 28
B or N
CA
Completed
Professional 01 曲径通幽 | Translucency
SD
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B or N
CA
SD
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B or N
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SD
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Wanjia Agilawood Club Individual Project
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1, 2, 3 Apartment in Hangzhou Individual Project
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Design Analysis of Urban Indoor Substations in Guangzhou Area Group Project (project coordinator) | Research Organize
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SD
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B or N
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Completed
Fortune Residence Interior Design Group Project (Project Leader) | Concept Design, Construction Document, Construction Management
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Inward Garden Atelier 100s+1 Expansion Individual Project
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SD
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B or N
CA
SD
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200 Square Meter Apartment Interior Design Individual Project
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China Mobile Yangzhou Branch Roof Garden Group Project | Concept Design, 3D model
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China Red Star Furniture Mart Dome Structure Design Individual Project
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SD
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Bank of Nanjing Roof Garden Individual Project 29
M | Academic | 01
1330 Brook Street Resident Location:
Lawrence Kansas
Project Status:
Built
Year Completed:
2017
Size:
1,300 sq. feet
Construction Cost:
$249,000
Client:
Built as a speculative house
Architect/Contractor:
Studio 804, Lawrence, Kan. . Dan Rockhill (director and distinguished professor); Wenhan Li, Matthew Anderson, Faysal Bhuiyan, John Coughlin, Abigail Davis, Caitlin Fitzgerald, Brittany Hediger, Evan Liles, Charles Rotter, Assoc. AIA, Chris Roybal, Emily Stockwell, Gao Xuewei(students)
Structural Engineer:
Norton & Schmidt
Position:
Studio Website Rebuild and Maintain; Design Process; Mock up Making; Construction etc.
Participating:
2016 Fall Semester
This 3 bedroom, 2 bath home seeks to maintain a high level of sustainable design as well as remaining contextually sensitive to the East Lawrence community. By choosing an urban infill site, we have welcomed the opportunity to integrate the house into the existing neighborhood fabric. The low-cost, high-quality design strategy led to flexible spaces, while still maintaining plenty of built-in storage space, giving the owner control over use and layout of spaces. The home is ADA compliant allowing for unrestricted mobility across the 1,300 sq. ft. home while also incorporating an indoor/outdoor living relationship with the covered exterior walkway and porch area. As it was designed toward LEED Platinum standards, passive strategies for lighting and sun shading are integrated. With an exterior screening system and concrete floor for thermal mass, the southwest glazing allows optimal temperatures year round. Materials are selected based on a desire for longevity and ease of maintenance, including the re-purposed metal panel cladding system and insulated glass units for the southwest glazing. 30
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Utility Closest Kitchen
Living Area
Laundry
Closest ADA bathroom
Master Bedroom Dinning Area
Flex Area
Bedroom
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View from East View from the Kitchen
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Roof
Roof Structure
Roof Overhang
The overhang were located at the south and west to provide passive sun shading during the summer. The western red cedar soffit was formerly used for railroad bridge trestles.
Interior Element
Curtain Wall
Re-purposed Metal Panel Cladding System They were re-purposed from a local commercial project. The team chose this material for it’s high thermal performance, long life longevity and the ease of maintenance
Large 11-foot-tall by 5-f00twide glass panels supply the public spaces with ample daylight. They were acquired inexpensively five years ago from a failed project in Kansas City.
Insulated Glass Unit
Thermal Performance
Screening System Passive Sun Shading
Concrete Floor Thermal Mass
2015 Base Flood Elevation Site
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Along the west and north wall, a L-shape storage space lies on the plan, with half of them facing the living area and half of them hiding next to the corridor. It will provide the house sufficient storage space even if the house will be used as 3 bedroom and 2 bathroom house.
As it is built as a speculative house, it’s important that the layout can serve different needs for the future buyer. There for, the flex area is part of the open floor plan, joined with kitchen area and living area, separated by the curtain instead of solid wall.
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The screen system to the west and the south of the house is made of the existing steel tube that the team has stored in the warehouse. Angle and spacing were carefully adjusted to provide the shading during the summer and invite more sunshine during the winter.
Summer
Winter
08:00
10:00
12:00
14:00
16:00
18:00 37
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60 MIL TPO MEMBRANE TPO COVER TAPE
GRAVEL STOP FLASHING 2X4 NAILER
1 1/2" X 5" ROUGH CUT LUMBER 2X4 NAILER 3/4" PLYWOOD SHEATHING 1/2" OSB SHEATHING 2X4 NAILER
TAPERED RIGID INSULATION OSB SHEATHING 3/8" FIBER-CEMENT BOARD 2X2X1/8" STEEL TUBE 1 1/4" X 11 7/8" RIM BOARD BLOWN-IN CELLULOSE INSULATION 11 7/8" TJI PWI-20 @ 16" O.C. INTELLO INSULATION MEMBRANE
Roof Call-Out Foundation Call-Out
4" REINFORCED CONCRETE SLAB WITH #4 REBAR @ 2'x2' O.C. BOTH WAYS 4" AGGREGATE UNDISTURBED EARTH 6 MIL VAPOR BARRIER
1/2" X 8" THREADED ANCHOR BOLT TREATED SILL PLATE
3/8" FIBER-CEMENT BOARD 2" RIGID INSULATION
#4 REBAR @ 4' o.c.
(2) #4 REBAR CONTINUOUS
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L Academic 01
SD
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B or N
CA
SD
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Obama Presidential Library Individual Project
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Shared Garden Kansas City International Airport Individual Project 42
Professional 01
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Hotian Tianjin International Hotel Group Project | Construction Management
ARMADILLO Factory Expansion Individual Project
Environment Future Museum Group Project (Project Leader) | 3D Model, Concept Design, Presentation
Government Office Design of Guizhou Azalea Attraction Group Project | Interior Design for Entrance Hall, 3D Model DD
CD
Guangzhou Zengcheng Planning Museum Exhibition Design Group Project | Concept Design, 3D model
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SD
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Completed
Gaohecui Mall Interior Design Group Project (Core Member) | Concept Design, 3D Model, Render, Detail Design
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Completed
Completed
WWF Chengdu Anzihe Natural Reserve Education Center Group Project | Construction
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NewBud Eco-School Group Project | Construction
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Canlian Interior Design Individual Project 43
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Obama Presidential Library Location: Hawaii Size: Approximately 50,000 sq.ft. Instructor: Prof. Kapila Silva Individual Project The Presidential Libraries and Museums are an American Invention. They construct a uniquely American cultural institution and, therefore, form a distinctive architectural type that holds an exceptional place in American architectural history. The architecture and exhibit display at these centers create a narrative of each president’s individual legacy and of the shifting ideals of American democracy in a global world at a particular time. They shape public memory of the presidents’ identity and legacy as well as the nation’s history. In this studio, we aim to design the Presidential Center for President Barack Obama. There are two proposed sites, one in Chicago, IL (sponsored by the University of Illinois) and the other in Honolulu, HI (sponsored by the University of Hawaii). I picked up the one in Honolulu because the site has a 360 degree view of Hawaii, I would like this project to be a popular public building serve for the community near by, not just Museum that people only would go there once in their life. That goal create a huge challenge balance between the security level for the documents in the library and the accessibility of the public function. 44
The solution come out as the understanding of the circulation gets deeper. - An oval shape block is introduced into the site to pay respect to the oval office and the 360 degree view. - Then the first floor was partially lifted up to let pedestrians see/walk through. It also create the shaded outdoor space for public events (like outdoor wedding). - The center core (museum and library) was defined with solid wall as the highest security level function and lifted up along with the entrance hall. - Two outer circle is folded in at two place to naturally define the boundary of museum stuff office and president’s stuff office. 45
A
A B C
E
D
F G
H
A
1 Floor A: Ticketing Hall/ Temporary Exhibit Gallery 1 B: Security Check C: Gift Store D: Rest Room E: Storage Room F: Events Room G: Kitchen H: Cafe/ Restaurent
A
B
B
-1 Floor A: Mechanical Room B: Museum Shop
Program (Guideline) Total Area: Approximately 50,000 sq.ft.
Public 4,500sq.ft Lobby/Info 1000 sq.ft.; Café 20-30 seats/kitchen 1,700sq.ft.; Gift Store 1,000sq.ft; Restrooms 800sq.ft. Museum 21,500sq.ft. Main Galleries 12,000sq.ft.; Temporary Exhibit Gallery of 2000sq.ft.; Permanent Collection Storage 3,600sq.ft.; Prep Area 1,500sq.ft.; Preservation Studio 1000sq.ft.; Chief Curator 200sq.ft.; Curatorial Staff 750sq.ft.; Office Storage 150sq.ft; Staff/ Docents Lounge 300 sq.ft. Library 6,000sq.ft. Lobby (lounge/security/cloak room/orientation room) 500 sq.ft; Research Room 1500sq.ft; Chief Archivist 200sq.ft; Associate Archivists 750 sq.ft. (05 offices); Office storage 150sq.ft.; Sorting/Digitizing/Record Room 500 sq.ft; Document Preservation Room 300 sq.ft.; Archival Store 1500 sq.ft.; Staff Lounge 300 sq.ft.; Restrooms 300 sq.ft. 46
A
N M M L M
3 Floor C
O
E
J K
J K
E
J
H
H G
K
I
F
F
F
2 Floor
B Q Q R Q F O P L
D
B
L
A
L C D
E
N M
A: Lobby/Info B: Library Public Lobby C: Library Researcher Orientation D: Library Research Room E: Rest room F: Library Office G: Library Staff Lobby H: Library Staff Conference Room I: Library Staff Lounge J: Storage Room K: Library Processing Room L: Admin. Staff lounge M: President’s Staff Office N: President’s + First Lady’s Suite/ Office O: Library
I
I H J
J
L
F F G K
J
J
A: Lobby/Info B: Temporary Exhibit C: Main Galleries D: Oval Office E: Multi-purpose Hall/ Auditorium F: Rest Room G: Classrooms H: Administration Lobby/ Reception I: Administration Conference Room J: Administration Office K: Administration Staff Lounge L: Storage Room M: Permanent Collection Storage N: Temporary Exhibit Storage O: Museum Staff Lobby P: Museum Conference Room Q: Museum Office R: Museum Staff/ Docents Lounge
Events 4,500sq.ft. Multi-purpose Hall 2,000sq.ft.; Service 400sq.ft.; Storage 200sq.ft.; 3 Classrooms 400 sq.ft. each (multifunctional); Storage for Classes 200sq.ft; Lounge 500sq.ft. Administration / Presidential Office 4,300sq.ft. Lobby 300 sq.ft.; Director’s Office 200sq.ft; Associate Directors 750sq.ft; Administrative Staff 300 sq.ft; Office Storage 150sq.ft.; Conference Room 300 sq.ft.; President’s +First Lady’s Suit/Office 1000sq.ft.; Presidential Staff 1000 sq.ft.; Admin. Staff Lounge 300sq.ft; Utility /Maintenance 9000sq.ft. Maintenance Staff 500sq.ft; Security Staff 500sq.ft.; Staff Lounge 300sq.ft.; Janitorial Storage 300sq.ft; General Use Storage 500; Gift Store Storage 300 sq.ft.; Network Server Room 200sq.ft.; Mechanical Room 5,000sq.ft; Egress (2 stairs) 400 sq.ft./floor; Service Elevator 200sq.ft./ floor; Public Elevator 100sq.ft./floor; Restrooms 400sq.ft; Loading dock and service access 400sq.ft. 47
Shading, Ventilation & View
Solid Wall Direction for Ventilation & View
Movable Fin
48
Security Level
(For Public Accessible Area)
Library (Reading Area) Museum Gift Shop, Cafe, Event
49
XL Academic 01 Take a Breath
IFLA Competition Group Project | Chief Designer, 3D Model
50
SD
DD
CD
B or N
CA
4F: 露天剧场、会所 3F: 电商、展卖会 2F: 艺术机构 1F: 沙龙、银行 -1F: 超市
Professional 01
SD
DD
CD
B or N
CA
SD
DD
CD
B or N
CA
SD
DD
CD
B or N
CA
Liusi Area Land Use Planning and Development Individural Project
02
Cangyuan Tourist District Zone Plan Group Project | Research
03
Xiaolan Regional Urban Planning Group Project | Concept Design, 3D Model, Render, Physical Model, Research
04
SD
DD
CD
B or N
CA
Yan’an Urban Design Group Project (Core Member) | Concept Design, 3D Model(entire city)
05
SD
DD
CD
B or N
CA
SD
DD
CD
B or N
CA
Maoshan Tourist District Zone Plan Group Project | Bussiness Meeting
06
178 Farm Planning Group Project (Project Leader) | Contract Negotiate, Concept Design, 3D Model 51
XL | Professional | 04
Yan’an Urban Design Beijing Tsinghua Urban Planning Design Institute Instructor: Yuan Huang Project Time: 2012 52
Personal Position: Concept Design; Lead a team of around 20 to make city 3D model in SketchUp, etc. Yan’an’s history dated back to Sui Dynasty. It is always been the center for military, financial, cultural and political in the Shanbei Area. With the background of modern construction for the past a few decades, the vernacular architecture language is slowly lost. This urban design project aim to renewing the city, restoring the historic urban landscape, and adding tourist service facilities to help the city developed into a better tourist city 53
Tourism Service Facilities Building Plan
Commercial & Residential Facilities Commercial Service Facilities Hotel and Conference Facilities Educational Facilities Landscape Node
Overall City Renewing Plan
Demolition Area Suggested Demolition Area Reservation Area Renovation Area
54
Designed Tourism Area
Designed Touring Route
Touring Route Tourist Node
55
Vernacular Architecture Language Analysis
56
Vernacular Architecture Language Analysis
57
58
Landscape Node & Landscape Axis
Traffic Organization for Vehicle
Traffic Organization for Pedestrian
59
60
61
62
Interests
63
Sewing
Tra v e l
Micro
KUKA
Apartment
Furniture
Rock
Design
Climbing
Hiking
Affordable
Hand
Housing
To o l
Digital Fabrication
64
Handcraft
Logic
Archery
Reading
Cooking
Construction
Poem
Draw
Programming
Wooden
Puzzle
Joint
Game
Tiny House
65
Thank you!
66