Portfolio-xiao wen Wu by jijiewu

Architectural Portfolio

Xiaowen Wu

Application Number:23189853

Applying forMArch Architectural Design , Bartlett School Of Architecture, UCL

E-mail:wuuu_xwww1127@126.com

TEL:+86 15957304129

EDUCATION

XIAOWEN WU

GPA: 3.99/5 Rank: 1/45 Degree: Bachelor

HONORS

First-class Scholarship of College of Science & Technology Ningbo University, College of Science & Technology Ningbo University

Merit student of College of Science & Technology Ningbo University, College of Science & Technology Ningbo University

ATX design of the year 2020——Third place in Visitors center, ArchiterraX

The scholarship of The People's Government of Zhejiang Province, Department of Education of Zhejiang Province

Ningbo City thought creation and construction——2021 Second prize of ancient painting analysis of ancient architecture in colleges and universities, Ningbo Tianyige museum: Ningbo Baoguosi Museum of Ancient Architectures

The "CCB Cup" 7th Zhejiang International "Internet +" University Student Innovation and Entrepreneurship Competition——Gold award, The Organizing Committee of the seventh Zhejiang "Internet+" College Students Innovation and Entrepreneurship Competition

The "CCB Cup" China International College Students' 'Internet + Innovation and Entrepreneurship Competition for the seventh consecutive year——Silver award, The Organizing Committee of the seventh China "Internet+" College Students Innovation and Entrepreneurship Competition

China National Scholarship, China Scholarship Council

INTERNSHIP

Assistant Architect, Zhejiang Innovation Architectural Design Co., LTD

Audited the program report ;Organized data, such as drawings, design proposals Modelled according to CAD drawings

ACTIVITIES

Director, Youth League Cultural Center, College of Science & Technology Ningbo University Civil Engineering and Architecture, College of Science & Technology Ningbo University civil Engineering and Architecture

Responsible for docking and coordinating various associations and organizations in the college President, Architectural Association of College of Science & Technology Ningbo University, College of Science & Technology Ningbo University

Organized various competition activities, such as: college marker competition, architectural handpainting competition, architectural hand-painting teaching, freshmen exhibition, senior sketching sharing meeting, lectures of outside institutions and so on Compere, Beautiful village Transformation Competition of Sidang South Village, Kandun Street, Cixi, College of Science & Technology Ningbo University civil Engineering and Architecture

Participated in the photographic activities of the association

SKILLS

Photoshop, Indesign, Auto CAD, Rhino, Grasshopper, SketchUp, Lumion, V-ray, Enscape

College of Science & Technology Ningbo University, Zhejiang Major: Architecture 09 2018-06.2023 07 2019-09.2019 09 2019-09.2020 09 2020-09.2021 11.2021 07 2020-09.2020 08 2022-11.2022

of Achitecture Jiaxin, Zhejiang, P.R. China

12.2019 12.2019 04.2020 12.2020 06.2021 07.2021 10.2021 12.2021

THE LINK P22-25 Architectural Design of Tiny Library in Shaoxing | China | 04.2021-05.2021 THE SAVE TUVALU PLAN P3-7 Architectural Design of Revival of Village in Fongafale | Tuvalu | 12.2021-03.2022 LIGHT IN THE FUTURE P12-16 Architectural Design of Bioluminescent in Shenzhen | China | 04.2022-06.2022 INTERACTIVE SHIELD P8-11 Architectural Structure Design of Umbrella in Hangzhou | China | 10.2022-11.2022 UTOPIA OF THE COUNTRYSIDE P17-21 Urban Design of the Revival of Village in Ningbo | China | 07.2022-09.2022 OTHER WORKS P26-27

01 THE SAVE TUVALU PLAN

The exploration of survival mode of future climate refugees

Project Type: Individual Academic Work

Work Time: 12.2021-03.2022

Instructor: Hua Chengling

Site: Fongafale, Tuvalu

Massive floods, devastating wildfires, rising sea levels - and the countless lives and disrupted livelihoods they claim - are a reality that many countries are already facing.

And suppose the current rate of temperature increase is anything to go by. In that case, global sea levels will rise by 1.4 metres by 2100, forcing 10 per cent of the world's population to relocate, creating tens of thousands of climate refugees. Tuvalu, an island nation in the Pacific Ocean, is not only suffering from the effects of global climate change and sea level rise but also has underdeveloped primary, secondary and tertiary industries and has been repeatedly predicted by the World Meteorological Organisation to sink in fifty years.

The project aims to create a sustainable industry of coconut palm trees, fishing, rainwater harvesting and coral conservation through the local flora of Tuvalu, to alleviate their poverty to a certain extent, improve the living conditions of the people of Tuvalu and reduce the impact of climate change on the local people. The design is also an exploration of the future of climate refugee survival.

The Process of Making Coconut Vinegar and Oil

Effect of Coconut Chaf in Coastal Soil

The Process of Making Coconut Coir

Effect of coconut chaff on nutrient contents in soil

Picking

Sourting

Coconuts still clinging to tall trees are harvested by human climbers. To remove the fruit from the seed, the coconut is impaled on a steel-tipped spike to split the husk.

The Use of Making Coconut Coir in Daily Life

Husking

Cleaning

Beating Workers beat the retted pulp with wooden mallets to separate the fibers from the pith Ripe coconuts are husked immediately and extracted coir.

They are buried in pits dug along riverbanks, immersed in tanks.

Retting Drying

Extracting

After soaking, coconut fibers need to be washed with water. The clean fibers are spread loosely on the ground to dry in the sun. Separation of the bristle fibers is accomplished in machines

The Flow Chart

Husking

Bristle fibers that will not immediately be further processed are rolled up.

Spinning

The yarn may be twisted into twine and bundled for shipment.

Knitting

After drying, the long fibers can be used as ropes and fishing nets.

B-B' Profile Rendering

Recycling in Tuvalu canal waste water energy purification

A-A' Profile Rendering

Water

Living Area

The

Agricultural Area

The fibres of the niu kafa are longer and make the weaving easier. 1. Picking 2. Twisting 3. Filtering 4. Enwinding

Mgigmagi sennit They are soaked in water for two days or more and then they are put out in the sun to dry. They are taken out one by one and beat with beater on a log of wood to clean out all bits that stick to the fibres. It involves remembering the process using the warp and weft to make the weave in the correct order. Pandanus tectorius has many traditional uses. The fruit can be eaten, the leaves can be used to make fabric. 1. Picking 2. Beating 3. Filtering 4. Weaving

The processe of making

Axonometric drawing Axonometric drawing After burning the spines, the leaves are left in the sun for three days and then beaten with mallet to soften them. Using an iron tool called a bwere, a cross between a comb and peeler, the leaves are cut lengthwise into thin strips. Depending on the thickness of the leaves, they can be woven into objects for different purposes. 1.Roof: 1.Floor: Thatched mulch 10mm wood floor

mixture of sand,dried leaves,and soil The dry leaves of the Guettarada speciosa L and Heliotropium foertherianum 40mm waterproof plywood Bamboo structure Humus 2.Planting area: Thatched mulch 3.Floor: 1 2 3 60*80mm wooden keel 15mm plywood 10mm waterproof 40mm Secondary waterproof layer covering Coconut tree trunk strucutre roof The leaves of the coconut tree 70mm insulating layer 10mm waterproof 20mm concrete cushion layer 15mm plywood 120mm coconut structure load-bearing beams 10mm damp-proof course 2.Balcony: 10mm cement mortar surface course 60*80mm wooden keel 10mm damp-proof wood floor 15mm plywood 60*80mm wooden keel 10mm waterproof 20mm concrete cushion layer 40mm Secondary waterproof layer covering 15mm plywood Coconut tree trunk structure roof 120mm coconut structure load-bearing beams 1 2

processe of making Roba or Raeroba

Humus

Color precoated steel

Transverse support steel frame

Sun protection and heat insulation paint

Color precoated steel

Insulating foam board

Calcium silicon plate

Color precoated steel

Water purification factory

Water channel

Wood floor

Algae nurture area

Wooden fence

Floor keel made of coconut tree trunks

Water purification factory

Central garden

Concrete stone wall

Toilet

Water pipe

Office

Water purification Laboratory

Veranda Veranda Water Purification Lab Axonometrical Drawing Water Purification Factory Algae Nurture Area Central Garden

02 INTERACTIVE SHIELD

Experimental design of interactive origami structure

Project Type: Individual Academic Work

Work Time: 10.2022-11.2022

Instructor: Hua Chengling

Site: Hangzhou, China

On the basis of umbrella structure, this project explores the shape changes of the structure in different quantities and combinations, and selects a stable structure with symmetrical beauty and abundant variability under the consideration of symmetry, diversity, stability and other factors.

At the same time, the project developed a custom feedback control system, which allows the structure to develop autonomously through infrared sensing. In terms of assembly, there is no need for glue, just replace the corresponding parts when damaged, and disassembly is very convenient.

This project expects to improve the feedback control system in the future to make the connection nodes more flexible and enhance the interaction with humans.

Reference

Melancon, D., Gorissen, B., García-Mora, C.J. et al. Multistable inflatable origami structures at the metre scale. Nature 592, 545–550 (2021). https://doi.org/10.1038/s41586-021-03407-4.

Design Options

Single

The best performing test was chosen to add electronic controller

Twosome

Quaternion

Force-bearing Points number: 1

Force-bearing Points number: 2

Force-bearing Points number: 3

Force-bearing Points number: 2

Force-bearing Points number: 4

Stability Flexibility Variety Variety Variety Variety Variety Variety Variety Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry Symmetry Stability Flexibility Stability Flexibility Stability Flexibility Stability Flexibility Stability Flexibility Stability Flexibility

Triad

A computer simulation was set up to test the trajectory of the structure.Modeling was done using rhino, followed by simulated folding using kangaroo and crane in grasshopper. The figure on the right shows all the parts and the specific quantity of the structural model.

Sectional Perspective 13x 8x 110x D=4mm 40x 12x 4x 4x 110x D=4mm L=12mm 4x D=4mm L=20mm

Simulation Test Parts List

Interactive System Introduction

This diagram shows how the structure works as a whole, as well as a vision for the future of the project, which aims to make changes to the structure more flexible through software such as unity.

Test-bed Introduction

Interactive Display

The robotic control system includes infrared sensor for collecting human movements, computers and unity environments, and actuators to control fishing line.

Drawing Distance:120mm Drawing distance:300mm Drawing distance:600mm Sensing Distance:50mm Sensing Distance:150mm Sensing Distance:20mm Time to Final State:15s Time to Final State:25s Time to Final State:10s

03 LIGHT IN THE FUTURE

The exploration of the relationship between man and nature

Project Type: Individual Academic Work

Work Time: 04.2022-06.2022

Instructor: Hu Yun

Site: Shenzhen, China

Although our current era is one of highly sophisticated technology and civilization, hydrocarbon reserves are running out. According to research conducted by the University of Exeter, light pollution has increased by as much as 270 per cent globally in recent years. In addition, the red tide disaster is growing worldwide. In the future, around 12,000 offshore oil rigs will be abandoned globally in the near future as the red tide calamity worsens globally.

According to the international dark-sky association, light pollution has a direct impact on energy waste and carbon emissions; red tide has become a typical ecological disaster that threatens human food security and damages marine ecosystems; and 'Rigs-to-Reefs' from abandoned oil rigs still have the potential to further damage the ecosystem.

This project proposes a strategy to replace polluting artificial light with bioluminescence from algae as a solution to red tide and urban light pollution. Algae can sequester carbon and generate bioenergy, thus providing sustainable energy for buildings, reducing their carbon emissions and allowing them to adapt to new environments and situations. The 'ecological treatment' of abandoned offshore oil rigs can also remedy the shortcomings of the 'Rigs-to-Reefs ' strategy.

The whole design is a bold exploration of a future model of harmony between humans and nature. The future building will be transformed from a passive shell into an adaptive, breathing living facility.

Site Analysis

The Construction History of Offshore Oil Rigs

The Research of The Algae

of light pollution distribution in China source:https://www.lightpollutionmap.com Abandon offfshore oil RIGS Noctiluca scintillans Sanitary wastewater Industrial wastewater Ni,Zn,Ag... N,S,NH3 source:https://www.lightpollutionmap.com 0.10 0.00 0.30 1.50 3.00 15.0 40.0 80.0 0.25 0.35 2.00 6.00 30.0 65.0 150+ The range of red tide in 1980 TUEN MUN DISTRICT ISLANGDS DISTRICT GUISHANZHEN TSUEN WAN DISTRICT TUEN LONG DISTRICT NANSHAN BAO'AN GUANGMING The range of red tide in 2010 Residential area Ship route Sewer line Factory area Map of red tide distribution in China

Map

Waterside Terrace A good place for a leisurely walk. Rational utilization of abandoned crane and a good place for a paddle. Coastal walk with amazing ocean views and good communication. The open ground floor platform increases the fun of daily life. Preserve the original bottom structure of the oil drilling platform. Do not change the base style, maintain the Marine ecological environment. Preserve and reinforce the core structure of the oil rig for use as the core of the new building. Connectivity is enhanced through aerial corridors. The exterior structure, shaped like a shelf on a drilling rig, makes the building more harmonious. Recreational Corridor Recreational Corridor Bottom Structure Integral Shape Core tube Construction Connectiong Structure Exterior Structure Swimming Facility 113°55′E 113°50′E 113°45′E 113°40′E 113°35′E 114°05′E 114°E 22°10′N 22°20′N 22°25′N 22°30′N 22°35′N 22°40′N 22°45′N 22°15′N

FLow Chart Dead algal channel Noctiluca channel Flat algal channel Soothing channel

Station in Noctiluca Algaee Large Flat Algae Feeding Area Noctilucent Algae Feeding Area Scale 1/700 Scale 1/700 Scale 1/700 The noctilucent algae are distributed. Living Room Clean water storage tank Sewage Storage Tank Fertilizer making apparatus Circulator Death seperation tank Death seperation tank Special clay is used to capture free algae in seawater,and a separator is sifted to get availiable glow in the dark algae,which is then transported to an incubator in the upper. Noctilucent algae feed pond Circulating apparatus Noctilucent algae soothing pool Transporting noctilucent algae Isolate captured Noctilucent algae capture Device Clay catches algae Kitchen CO₂ N,P, S The noctilucent algae are distributed from the bottom area.

Transfer

The Reuse Of Offshore Oil Rigs With Micro Algae By The Shenzhen Bay

Feeding Area For Platymonas Subcordigoramis

Algae can sequester carbon and generate bioenergy, thus providing sustainable energy for buildings, reducing their carbon emissions and allowing them to adapt to new environments and situations.

Everyone can come and visit the Platymonas Subcordigoramis 's feeding area and learn how it works.

Air Lounge Bridges

On the air lounge bridges,you can not only enjoy the beautiful sea scenery,but also greet your neighbors.

Bottom Working Area

The work equipment of the oil rig is still preserved at the bottom,where people can feel the industrial charm.

Plan A Plan B Plan C

A B C

Residential Area

Construction

Residential Area Plan

Planting Area

Exterier wall construction:

plaster system

concrete

reinforcement fabric

100mm foam glass insulation board

60mm plasterboard

Floor construction:

10mm special generation floor

60mm leveling course

1mm plastic release Layer

1mm root piercing layer

20mm impact sound insulation layer

180mm reinforced concrete layer

Abnormal metal plate

Construction

Plan of Planting Area

Roof construction:

150-200mm planting soil

Filter layer

500mm anti-siphon drainage reuse system

1mm root piercing layer

120mm waterproof layer

120mm suspended deck structure

Floor construction:

150-200mm planting soil

Filter layer

500mm anti-siphon drainage reuse system

1mm root piercing layer

120mm waterproof layer

120mm suspended deck structure

The Office

Construction Office Plan

Roof construction:

φ10mm wire rope

reinforcement fabric

steel frame

6(low-e)+12A+6mm hollow tempered glass

Floor construction:

10mm special generation floor

60mm leveling course

1mm plastic release Layer

1mm root piercing layer

20mm impact sound insulation layer

180mm reinforced concrete layer

Abnormal metal plate

Research on the social integration of migrant workers under the background of urbanization

Project Type: Individual Academic Work

Work Time: 07.2022-09.2022

Instructor: Prof.Diego

Site: Ci Xi, Zhejiang Provinve, China

In the course of China's urbanisation and modernisation, the number of migrant workers has gradually increased, and there are now 292.5 million migrant workers. The Yangtze River Delta and the Pearl River Delta in China have a large migrant population, with Ningbo being the first prefecture-level city in terms of the number of migrants. The importance of social integration issues is also becoming increasingly apparent.

Based on a study in Cixi, Zhejiang, it was found that in the process of social integration, various factors, such as institutions, social capital and culture, have led to the formation of compartmentalisation between migrant workers and local residents in terms of residence, work and social relations. In order to achieve social integration, it is necessary to break down and eliminate the boundaries of compartmentalisation.

In order to avoid a 'top-down' design model, the project highlights the initiative of the migrant workers and the local residents to form an organic flow within the site. In order to create a path that enables both groups of people to communicate with one another fully and to provide functional space along the path, the project is based on a viscous algorithm and a spatial syntax in combination with the site's original conditions. This way, every future migrant worker can enjoy public space equally and truly live in equality and harmony with the locals.

"The force that stabilises social relations is not emotion but understanding. By understanding, I mean receiving the same system of meanings, where the same stimuli cause the same reflections."

---- ‘From the Soil’ by Xiaotong Fei

04 UTOPIA

OF THE COUNTRYSIDE

Analysis of Local Population Structure

WORLD,2021

169 MILLION international migrant workers worldwide. 1/20 of the world's workforce is made up of migrant workers, and 58% are men.

CHINA,2021

20.71% of China's total population are migrant workers

292.5 MILLIONof migrant workers in China, with 171.7million working far from home.

NINGBO,2021

4.3 MILLION migrant workers, accounting for 43% of the total population. The city with the LARGEST migrant workers in Zhejiang Province.

source

www.statista.com

Changes in the Proportion of migrant workers and local residents in Cixi

Source distribution map of migrant workers

The Yangtze River Delta and the Pearl River Delta in China have a large migrant population, with Ningbo being the first prefecture-level city in terms of the number of migrants. ACTIVITIES for the locals in usual

for migrant workers in usual

ACTIVITIES

Typology in Changhe Location

A B C D E F G H I J K L M N P O Q R S T U Age structure of migrant population in Cixi

Zhejiang,

Changhe Town 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 0 15 30 45 60 75 KM Beauty Regimen Catering Education area Leisure area Market Factory Bus stop B C E L M F Farmland Residential River 1 2 3 4

conditions of migrant workers in Cixi

Alone 2 Couple

Out of

parents

China,

Ningbo, Cixi

Living

work with

4 A family working outside the home and raising the next generation

MW 0.43Million 1.03Million LP MW LP Percentage of Population in 2010 Percentage of Population in 2021

source from: www.cixi.gov.cn Grew by 25.10%,with an average growth rate of 2.26% Average annual growth rate of 2.26% 1.12Million 0.70 Million 7% Guizhou 6% Jiangxi 75% Anhui Cixi Zhejiang Corridor space Waterfront space There is no communication between people on both sides The open green space is full of abandoned fields, overgrown and untended The corridor space is dark and damp,not suitbale for activitise 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4K games chatting fitness chess 0 1.0 2.0 3.0 4.0 5.0 6.0 7.0K games chatting fitness chess 7-15 years old 15-59 years old 59-65 years old >65 years old 2010 46% 9% 11% 34% 2021 23% 10% 8% 59% 30-45 years old 45-60 years old 1-15 years old 15-30 years old source from:

source from: www.cixi.gov.cn Open green space

from:

www.cixi.gov.cn

P=Population of Agents MS=MAX Speed DDR=Division Detect Radius PCD=Possibility of Changing Direction SA=Sensor Angle RA=Rotate Angle T=Time Optimal solution Final solution Potential points of interest of the future population Obstacles between Attraction Points PCD=10 MS=10 DDR=0.5 P=2000 SA<RA,T=10 Plane Surface(380m x 270m) and Emitter Point P=1000 MS=10 PCD=10 DDR=1 SA>RA,T=∞ PCD=10 MS=15 DDR=0.5 P=1000 SA<RA,T=10 PCD=15 MS=15 DDR=0.5 P=1000 SA<RA,T=10 MS=10 PCD=10 P=1000 SA<RA,T=10 DDR=0.6 PCD=10 MS=10 DDR=0.5 P=1500 SA<RA,T=10 MS=10 PCD=10 P=1000 DDR=0.3 SA<RA,T=10 MS=5 PCD=15 P=1000 DDR=1 SA=RA,T=10 PCD=5 DDR=0.5 P=1000 MS=15 SA<RA,T=10 PCD=10 MS=3 DDR=0.5 P=1000 SA<RA,T=10 PCD=3 DDR=0.5 P=1000 MS=15 SA<RA,T=10 MS=10 PCD=10 P=1000 DDR=0.5 SA<RA,T=10 P=1000 MS=5 PCD=15 DDR=1 SA>RA,T=10 MS=10 PCD=10 P=1000 SA<RA,T=10 DDR=1 PCD=10 MS=5 DDR=0.5 P=1000 SA<RA,T=10 Generation of Paths Vertification of The Path Connectivity Case Study Areas Changhe Town Integratation [HH] Mean Depth Result Modified Route Directness x<1 x<1 x<1 x<1 x<1 Walking Shed Intersection Density Shape Index: 8.0 1.1%↑ Total: 18 Density: 3.50 Cross-sections: 8 T-sections: 10 1.38 The average score of MRD 0 20 40 60 80 100 120 140 kg

Module Introduction

Corridor Space

The original dark corridor space will be used to develop the catering industry and other industries, improve the original environment.

Waterfront Space

New functions are inserted to activate the riparian space and increase the possibility of communication between residents on both sides.

Open Green Space

The original abandoned green space will be transformed into scattered leisure areas in the village to improve the happiness of villagers.

Waterfront Space Profile

Window construciton: 1

25mm Shutter

20mm x 15mm Aluminum guide

9mm Wood

160mm x 160mm Shutter box

Exterior wall construciton: 2

24mm Weatherboard

40mm Lath, ventilation chamber

18mm Low density fiberboard (airtight film)

120mm Insulation layer, frame

Steam trap layer

50mm Lath (equipment space)

12mm Cement particle board

Floor construction: 3

24mm Wood floor

40mm Impact sound insulation layer, cross layering

Rubber strip(For impact sound insulation layer)

100mm Real wood floor

24mm Batten

15mmCement particle board

Exterior wall construciton: 4

Ventilated cavity

16mm Isolair NK

20mm Mineral fiber board

80mm Insulation board

120mm Upper return beam (located in spandrel paneling)

Lining layer. Conform to board veneer

Floor construction: 5

30mm Emulsion,2 layers (It's made of plaster and asphalt cardboard)

21mm Particle board backing

20mm Sound insulation layer,PS81

65mm x 50mm Slats are laid over the grille

Sand and gravel serve as bedding

Polyethylene plate

1000mm x 320mm Wooden box cavity construction plate(Lignatur LFE)

A. Window detail S:1/ 10 B A

B. Base detail S:1/ 2 400 125 160 37 600 140 480 430 210 370 1400 580 220 140 220 400 125 160 37 600 140 480 430 210 370 1400 580 220 140 220 4 5 Outside GL ±0.000 Stairs 37 35 140 37 35 140 2 3 3 1 Weaving room Outside

A tiny library that promotes interactive public learning and community development

Project Type: Individual Academic Work

Work Time: 04.2021-05.2021

Instructor: Xie Ming, Hua Chengling

Site: Shaoxing, China

When putting forward the concept of "vulnerable community", most people will focus on remote villages. This time, we will focus on Shaoxing, the cultural capital of East Asia. In this city with a strong cultural heritage, the site is located in a remote area of the city, lacking the cultural connection with the main urban area, as if forgotten.

The design concept of the library is integrated with Shaoxing's local traditional concept of Shang-ssu Festival, as well as its main elements scroll and eight character bridge, which not only respects this historical and cultural city, but also injects new vitality into it. The winding water cups and scrolls are designed to awaken the memory of the local people, and also represent the people of Shaoxing. The traffic part, which is similar to the traditional eight character bridge of Shaoxing, is a link between ancient and modern times and cultural knowledge, providing a medium for the people of the water area to communicate, learn and live with the outside world.

05 THE LINK

Shang-ssu Festival

Structural Analysis

The supporting structure and architectural flow lines are two intersecting arcs. 'The glass' on the roof is fastened to the wooden trusses with special metal glass big.

Self-study Space

The villagers can enjoy a solitary reading space here

Elevation

Villagers can enter the library by boat

Dock Entrance

The library has multiple entrances, making it easier for villagers to come by boat

Physical Model

1:200 Building Model The translucent membrane roof lightens the volume of the building The passageway connects the building to the shore and blends in with its surroundings The main structure of the building is 3d-printed, and the site model is made of wood.