Maja Czesnik Portfolio 2017

PORTFOLIO

MAJA CZESNIK ARCHITECT MAA

EDUCATION

EMPLOYMENT

Denmark 5 months

BIG (Bjarke Ingels Group) Design Assistant

Sep 16 - Jun 17

z

z

Sep 16 - Mar 17

Denmark

- Panda House in Copenhagen Zoo (DD, CD)

Copenhagen, Denmark Oct 14 - Jul 15

z

Denmark 8 months

- Panda House in Copenhagen Zoo (SD, DD) - Residential Centre & Hotel in France (DD) - Cultural Centre with Theater in Denmark (SD)

Sep 15 - Nov 15

z

- Obervatory Tower in Odense (SD) - Residential Centre & Hotel (SD)

Oct 10 - Jul 14 Poland

Mexico 4 months

Taller 5 (Mexico) Junior Architect - House (SD, DD, CD)

Jun 13 - Sep 13 Spain 3 month

Sep 12 - Jun 13 Spain

z

Poland 1 month

Erasmus Exchange Program Valencia University of Technology, Spain

United Kingdom

Summer School The Bartlett School of Architecture University College London, England

PUBLICATIONS

Ruben Muedra Studio Architectural Intern

House in Mexico (individual design)

- Restaurant Interior Design

http://www.archdaily.mx/mx/867541/casa-gp-taller5-arquitectos?utm_medium=email&utm_ source=ArchDaily%20M%C3%A9xico

- Single Family House

Jun 11 - Jul 11

Bachelor Degree Program Graduated with honors Faculty of Architecture Warsaw University of Technology, Poland

Jul 11 - Ago 11 Jun 14 - Oct 14

z

Rhino 3ds Max Grasshopper Autocad Photoshop Illustrator InDesign After Effect / Premier environmental analysis drawing & watercolor

C. F. Møller, Competition LAB Architectural Intern

Master in Advanced Architecture IAAC (Institute for Advanced Architecture of Catalonia) Awarded IAAC Top 5 Final Projects IAAC Barcelona, Spain

z

SKILLS

Denmark 3 months

z

english polish spanish

Spain

z

LANGUAGES

BIG (Bjarke Ingels Group) Architectural Intern

z

date of birth: 21.02.1991 nationality: Polish residence: Copenhagen, Denmark email: majaczesnik@gmail.com tel: +45 52670504 or +48 507165475

Nov 15 - Jun 16

z

PERSONAL INFORMATION

Master of Arts in Architecture Architecture and Extreme Environments The Royal Danish Academy of Fine Arts

Panda House

Construction Apprentice Cosmopolitan skyscraper

http://www.archdaily.com/867991/bigs-designs-yin-yang-shaped-panda-enclosure-for-the-copenhagen-zoo

Nano-Filter (over 150 000 views) https://www.facebook.com/futurism/videos/708526822659853/?pnref=story

2

CONTENTS PORTFOLIO

04 2015 2015-2017

06 2015

08 2015

12 2015

2014

2015

2014

PANDA HOUSE

HOUSE IN MEXICO

RESURRECTURE

FOOD JUNGLE

project of panda enclosure in Copenhagen ZOO

individual realized project of a single-family house in Mexico

innovative system of factories of the future focused on efficient recycling, reducing of waste output and producing of clean energy

unlimited megastructure inspired by the agglomeration of xanthium seeds, functioning as an artificial 3D food producing rainforest

done during my over one year practice at BIG (Bjarke Ingels Group)

individual design in collaboration with Taller 5, Mexico

Master Thesis Project IAAC, Barcelona

Student Project IAAC, Barcelona

16 2015

20 2015

22 2015

24 2015

2013

2016

2017

2014

RENT A CUBE

NANO-FILTER

TRANSITION

IDOLS TOWER

expandable modular system of buisiness incubators

graphene coated sand for water purification

water purifying bridge in China

tower inspired by Kostya Koval’s dance movement sequences

Student Project Warsaw University of Technology

Student Project The Royal Danish Academy of Fine Arts

Master Thesis Project The Royal Danish Academy of Fine Arts

3

Bachelor Thesis Project Warsaw University of Technology

“PANDA HOUSE” IN COPENHAGEN ZOO a project of panda enclosure done during my practice at Bjarke Ingels Group

“Architecture is like a portraiture. To design a home for someone is like capturing their essence, character and personality in built form. In the case of the two Great Pandas, their unique solitary nature requires two similar but separate habitats- one for her and one for him. The habitat is formed like a giant ying-yang symbol, two halves, the male and the female complete each other to form a single circular form. The curvy lines are ondulating in section to create the necessary separation between him and her, as well as between them and us. Located at the heart of the park, we have made the entire enclosure, accessible from 360 degrees, turining two Pandas into a new rotation point for Copenhagen Zoo.” Bjarke Ingels Project done during my over a year practice at Bjarke Ingels Group

to be realized in 2018

Pandas Enclosure Restaurant & Shop Educational Facilities

2000 m2

project phases: SD, DD, CD

4

my responsibilities: concept & design studies 3d modeling

renderings plans, sections diagrams

http://www.archdaily.com/867991/ bigs-designs-yin-yang-shaped-panda -enclosure-for-the-copenhagen-zoo

B1

01_ 37_K

37_K01_H3_N010-1

B3

A2

H3 011 _N

x3

A1

y3

Projekt koordinater x3 16.233 y3 38.812

2

1.16

2.0 00

Indgang Køkken

1.58 3

To-go vindue

Bord Håndvask

00

3.9 R.123 Depot/Tjenerrum

1.6 30 R.125 Køl A: 4 m2

R.128 Handikap WC A: 5 m2

84

640

Indgang møderum

200

00

00

H3 01_ 37_K

Siddetrin langs facade

23 4.9

2.0

1.660

37_K01_H3_N010-1

R.113 Butik A: 70 m2

Løst lavt inventar i butik

fan

thu

s kæ

lde

rvæ

g

550

00

x2 -22.317 y2 18.320

Ele

011 _N

500

Projekt koordinater

2.300

R 10.000

1.490

R3 Reolv

æg

Personaleindgang stalde

3.00

B3

7.7

3.6

2.0

00

Betaling

y2

Personaleindgang affaldsrum/teknik

400

22

B2

00

1.3

Bad R.118 Bad Dame omklædning R.120 A: 6 m2 Herre omklædning A: 57 6 m2 2.0

R.115 Møderum A: 30 m2

1.91 8

00

2.0

2.007 R.130 WC A: 4 m2

R.129 Forrum A: 6 m2

992

97

A: 4 m2

076 Skakt A: 1 m2

53 1.3

R.2.01127 WC 1 A: 2 m2

Kaffestation R.124 (Junge) Frys Kværn

41 3.8

Espresso maskine

00

Højskabe R.126 WC A: 2 m2

800

10 m2 Postmix A: og Kølebord fadeøl

45 6.4

09

70

R.116 Affald A: 14 m2 00 2.1

42 1.2

1.2

2.0

R.117 03 Gang A: 5 m2 4.2 00 1.5 R.119 WC 4.203 A: 2 m2

Tunnel opvask

Kasse

00

00 1.3

Hylder (aflukkede)

Emhætte

2.0

R.114 Restaurant 200 A: 268 m2

00

900 2.0

50

30

900

900 2.0

Indgang Butik

85

1.800

2.0

00

3.5

Håndvask

00

2.0

00

Trappe ned til teknik

R.122 Opvask A: 12 m2

Hul med låge

900

900

Ekstra flugtvej fra restaurant

Overdækket areal

2.0

00

To-go emaballage

Stativer

Ovn

3.6

1.100

00

1.3

Varmeskab Frima

3.1

2.0

1.400 1.600

80

00

900

2.0

Håndvask

3.8

Friture

Bord

00

2.0

2.0

Legeområde/ Vognparkering

x2

Wok 00 2.5Emhætte

900

4.200

Elevator

R.121 Køkken A: 60 m2

Neutral

Gas

00 1.2

din dgar Bran

2.0

Hul i dæk i tag ovenover

Gas

Gas

612

Gas 00

1.0

Bord til modtagelse af gæster Afsætningsniche Jalousi - evt. mulighed for at underopdele

1.300

00

Va

993

00 1.2

etæp

rm

3.2

Indbygget bænk

Sænket udeserveringsareal

Bord

Kasse

Kølebord

pe

Klatretov

7.500

1.336

Indgang Restaurant

R2

7.899

0

Pandavægt

F.04 Fælles udeareal

B2

F.02 Han udeareal

Vandkop

R1 R 24.000

R 27.000

R 20.000

4.026 Vandkop R.111 Ekstra boks A: 8 m2

2.000

Port 600 x 800 mm

Port 600 x 800 mm

Port 600 x 800 mm

17.900

Rende med afløb

R.112 Træningsboks A: 16 m2

3.421

B1

R.110 Nursury (Fødseldag/Teambuilding) A: 120 m2

26.364

A3 e 2,10

6.765

A3

Projekt koordinater

m

højd

Rum

x1 0 y1 0

ORIGIN

Rumhøjde

2,10 m

F.03 Gæster A: 108 m2 11.215

Spulehane/ Vandslange

R.100 Bambuskøler A: 13 m2

5.060

10.3

32

Træ

37_K01_H3_N012

F.01 Hun udeareal

3.86

37_K01_H3_N012

Bambusvægt 2.913

1.6 00 Plantehul i dæk

N

2

37_K01_H1_N001

Spulehane/ Vandslange R.109 Teknikkælder A: 19 m2

Personaleindgang hunstald

Spulekant

3.042

10

1.2

50 3.6

1

00

1.200

TEGNINGS NR.:

female enclosure male enclosure educational space shop restaurant

R.104 Kontrolrum/Personalerum A: 20 m2

1.2

00

Niveau 1

Spulehane/ 1.6 Vandslange 04

74

4.7

3.0

PROJEKTFORSLAG

EMNE:

1.371

R.108.01 Reservoir A: 30 m2

Port 600 x 800 mm 1.923 Port 600 x 800 mm Vask med 0 bord samt 2.15 Vandkop spulehane Vandkop R.107 2.620 R.106 Træningsboks/Fødehule Træningsboks/Fødehule A: 6 m2 6 m2 R.105 Port A: Fødehule 600 x A: 22 m2 800 mm med afløb Rende 2.250

69

2.434

1.492

9.4

36

PANDA KØBENHAVNS ZOO

00

øb

1.90

28

3.5

3.0

R.102 Vandkop Træningsboks A: 9 m2 4.3 72 Po 600 rt 800 x mm

R.103 Træningsboks A: 9 m2 3.9 44 Sp ule ka nt

d afl

10-2

N0

2.1

13

3_ 01_H _K

8.6

R.108 Teknikkælder A: 83 m2

R.101 Nursury (Fødseldag/Teambuilding) A: 36 m2

Pandavægt

Vandkop

me

Port 600 x 800 mm

37

R.002 Teknikkælder A: 28 m2

nde

Port 600 x 800 mm

50

Re

6.9

t væg lukke Vitrine/fødehule foran

37 10-2

N0

3_ 01_H _K

x4

37_K01_H1_N001 REVISIONS NR.: MÅL: DATO: REV. DATO: INIT.: KONTROL: GODKENDT

BYGHERRE Roskildevej 38 2000 Frederiksberg

ARKITEKT Kløverbladsgade 56 2500 Valby

INGENIØR: Solrød Center 29, 2. 2680 Solrød Strand

A1 Projekt koordinater

y4

Rev.

Dato

INIT.

Emne

Alle koter og mål kontrolleres på stedet (alle mål er angivet i mm.)

x4 13.270 y4 -32.006

Alle koter i Københavns ZOO er indmålt i KN (Københavns nul)

A3

4000

2850

850

1200

300600 450 200

4000

F.03 Gæster

R.108Teknik-kælder

R.111, 112Træningsboks

2280

R.114Restaurant

3121

Overdækket areal

+22,000

+22,000

PandaIndgang 60cmx80cm Rampe

F.02Hanudeareal

F.01Hunudeareal

The design of new Panda House begins with a circular shape, formed by the surrounding existing facilities at the intersection of multiple walkways, Panda house is designed to feel like humans are visitors in the Panda home, rather than Panda being the exotic guest from faraway lands. The habitat forms the freest and naturalistic environment for their lives and relationship with each other, providing the freedom to roam about and the ideal conditions to mate one of the major challanges facing Pandas from becoming extinct.* +43,410

*big.dk

A3

Elevator

1200

4000

850

+22,000 R.110Nursury

R.111, 112Træningsboks

R.108Teknik-kælder

+22,000

R.113Butik

R.114Restaurant

Overdækket areal

+22,000

Rampe

F.01Hunudeareal

F.02Hanudeareal

5

LANDSKAB: Esplanaden 8C, 4 tv. 1263 København K

1:100 14.12.2016 GG NG OEL

Københavns ZOO Tlf.: 72200200 www.zoo.dk BIG A/S Tlf.: 72217227 www.big.dk Strunge Jensen A/S Tlf.: 56141030 www.strunge.dk SCHØNHERR A/S Tlf.: 33186180 www.schonherr.dk

“HOUSE IN MEXICO�- INDIVIDUAL REALIZED PROJECT a project of a single-family house in Mexico

The client was a single person fascinated with minimalistic architecture. At her request, I have designed a simple, completely glazed house opened to the garden. The only materials used in the project are: raw concrete, stone, wood and glass. The path is surrounded by a massive wall, ensuring safety in a dangerous Mexican city, as well as privacity in the transparent house.

individual design in collaboration with Taller 5, Leon, Mexico

realized in 2017

single family house

180 m2

project phases: SD, DD, CD

my responsibilities: meetings with client architectural concept

6

design development renderings detailed plans & sections

http://www.archdaily.mx/ mx/867541/casa-gp-taller5arquitectos

The house consists of an open space containing living room, kitchen and bedroom. Other functions (bathroom, wardrobe and technical space) are closed in the wooden boxes.

RESURRECTURE innovative system of factories of the future focused on efficient recycling, reducing of waste output and producing of clean energy

“Resurrecture� is a proposal for solution to the global waste problem. The innovative recycling system aims to give back to the society lighter, smarter and environment-friendly products. This self-sufficient structure is spreading awareness in the society, focusing on efficient recycling, reducing of waste output and producing of clean energy.

Master Thesis Project

IAAC Institute for Advanced Architecture of Catalunia

2015

80 000 m2

floating structure recycling system clean energy production

8

research lab educational area C2C products production

team work: Maja Czesnik, Alessia Tosetto, Shruti Ramachadran

all drawings presented are produced by myself

FUNCTIONING PRINCIPLES INPUT:

quality check and tagging

waste

unloading bay

C2C product design

recycling matter

warehouse

dual material research

material research

shop data collection prototyping cell

product design loading bay

prototyping

multiple material research

OUTPUTS: awareness Cradle to Cradle products

recycling process

storage

energy

A SYSTEM OF MULTIPLYING FLOATING MACHINES consuming the waste of developed countries The target group are developed countries whose waste is mostly disposed to landfills or shipped to underdeveloped countries. The project is based on a floating machine that recycles the daily waste of a region, surrounding landfills and water bodies. The cycle continues for 3 years and then a secondary, permanent structure isbuilt to deal with the waste in the region in the future. The mother unit moves on to other parts of the coast. 2015

2030 9

2050

MATERIAL MOVEMENT IN THE ONE-DAY MACHINE input: waste

output: eco-friendly products and energy

waste

loading bay

eco-friendly products energy awareness

dual material research

data collection

multiple material

C2C product design

prototyping cell

quality check

design and warehouse

shop

warehouse

consuming the waste of developed countries

storage

recycling process

workshop

energy genera-

Movement of material is a crucial aspect in the factory. Resurrecture is a one-day machine – waste enters and matter exits within 24 hours. Waste enters by trucks and ships and follows a linear path via recycling pipelines, which twist and turn to enable crossings for the placement of material research, design and prototyping cells. Natural exhibition space is situated below. Quality checks, warehouse spaces and a shop have all been integrated. The waste that cannot be recycled is sent to the energy generator. To introduce a sense of consciousness and awareness of the processes, a visitor path with information centres was designed that mimics the waste flow.

10

unloading bay

11

FOOD JUNGLE unlimited megastructure inspired by the agglomeration of xanthium seeds, functioning as an artificial 3D food producing rainforest

When mother nature designed the xanthium seed she covered it with dozens of spiny hooks that stick not only to fur and clothing, but can also spontaneously agglomeratewith each other. By analysing this self-assembling behaviour it was discovered that a wireframe of the classic Euclidean icosahedron can display similar properties due to the high probability for interaction and connection. When hundreds of such regular geometric modules are combined the result is a spontaneous, dynamic, and potentially infinite megastructure.

Student Project Master Degree

IAAC Institute for Advanced Architecture of Catalunia

2014

food production megastructure aglomeration

12

my responsibilities: concept project developement

model & photos drawings visualizations

team work: Maja Czesnik, Louisa Roth, James Mitchell, Zach Trattner

UNIT´S STRUCTURE

Each unit has approximately 1m3 of volume to provide a home for the cultivation of a wide variety of climate appropriate plants. These plants will be arranged vertically according to light and temperature requirements, while the horizontal deployment will be determined by access along a predefined circulation route for human interventions including harvesting and maintenance. The icosahedron module serves many purposes including structural framing, spatial enclosure, support for plants (both climbers and terrestrial), and even rain water storage. Each of the 32 tubes that define the structure of every icosahedron consists of a perforated fiberglass shell and a highdensity spongy interior that will absorb rainwater and slowly release it to keep the plants constantly hydrated. The plants themselves are rooted in growing medium contained in a stretchy fabric plane integrated into a defined percentage of the modules. The environment that these icosahedrons create is essentially an artificial food producing rainforest. 13

14

15

THE SYSTEM

RENT A CUBE expandable modular system of buisiness incubators

business incubators materials recovery facility

basic modules materials recovery facility

materials recovery facility

assisting modulesmaterials recovery facility transportation

circulation

transportation

water

electricity

ventilation

The system is assumed to be an integrated expandable structure. The centres are built mainly from recycled materials. The materials recovery facility is an integral part of the system. The produced materials are transported to the individual centres and are processed in technological halls to final composites for the building modules.

PRODUCTION OF PANNELS FROM RECYCLED PLASTIC BOTTLES

The project’s aim was to create an appropriate working environment offering office space for co-working and for microcompanies. The object’s space should facilitate entrepreneurship, as well as support people and companies starting up businesses. They should be provided with basic working comfort at lowest possible costs. Analysing the growing popularity of start-ups and business incubators, I have decided there is a need to design an integrated expandable modular system of such centres. The project’s aim was to design a universal module which allows to build up various types of office space, which could adapt to different requirements and plot sizes. A further assumption was the possibility to adapt the size of the centres to the demand on office spaces, creating a system of add-on modules, which can later be dismantled when they are no longer needed.

student project

2012 3rd year of Bachelor Degree

Warsaw University of Technology

Multifunctional Center: coworking space offices

workshop public functions

16

10000 m2

FUNCTIONING PRINCIPLE FOR OFFICE SPACE RENTAL

MODULE’ S STRUCTURE

green roof (separate, mobile element)

steel grid roof/floor substructure (depending if a module above exists) the client who wants to rent a working space

working space rental

furniture, partition walls and other equipment rental

individual working space, flexible to the client needs mechanical ventilation

POSSIBILITY OF CHANGING INTERIOR DESIGN electrical installations

suspended ceiling the system of flexible 90 cm wide partition walls (enables changes of the interior design)

5 mins

wall composites: structure: steel pilars wall facings: plastic pannels produced from recycled plastic bottles)

VERTICAL EXTENTION PLAN

raised floor (supported by the steel grid of the module below)

electrical installations

17

GROUND FLOOR PLAN

AXONOMETRIC VIEW

DETAILED SECTION

a

b b

a

18

COMMON AREAS

MICRO-OFFICES

printing point

furniture rental

conference rooms shop

library

cafe reception

COWORKING AREA

gym

canteen

mini-hotel

WORKSHOP AND DIGITAL FABRICATION LAB

kindergarden conference room

19

NANO-FILTER STRUCTURE

NANO-FILTER graphene coated sand filter for water purification polluted water YELLOW RIVER WATER IS PLACED INTO A TOP CONTAINER IT IS INTRODUCED THROUGH THE FUNNELS INTO THE FILTRATION PIPES

PROCESS OF WATER PURIFYING WITH GRAPHENE COATED SAND (GRAVITY)

POLLUTED WATER

FUNNELS

FILTRATION TUBES

graphene sand GRAPHENE SAND COMPOSITE

FILTERED WATER COMING OUT

Nano-Filter is an architectural device functioning as a water filter for purifying heavily polluted water from the Yellow River in Lanzhou city in China. It is testing a novel absorbent material: graphene sand composite. The project has been complemented by a research phase done in collaboration with the Nano-Science Centre in Copengahen and a fieldwork expedition in Lanzhou during November 2016.

Master Project

The Royal Danish Academy of Fine Arts

collaboration with: Nano-Science Center, University of Copenhagen

https://www.youtube.com/ watch?v=9CQ65gHY9DU

2016

clean water

CLEAN WATER

ILLUMINATION

TRIPOD BASE

20 Polluted water is collected from the Yellow River and placed in a top container. It is then introduced

WATER POLLUTION IN THE YELLOW RIVER

GRAPHENE COATED SAND = LOCALLY PRODUCED MATERIAL CONVERTING YELLOW RIVER WATER TO DRINKABLE SOURCE

Filtration Efficiency [%]

REMOVAL OF POLLUTANTS [%] WITH DIRREFENT FILTRATION MATERIALS

0

Ni

10 90 80 70 60 50 40

06

30

60 70 80 10 0

H

07 08 1 00

srA

09

Methods for producing and utilizing graphene are based on utilizing very popular components like sand and coal/graphite, which are in abundance in the Gansu province. This idea seems particularly adequate for the Lanzhou area, as it is surrounded by the Gobi desert, so it has enormous deposits of sand, and in terms of graphene source there are huge graphenedeposits oxide coated sand of coal and graphite graphene coated sand 4% wt in the region. GSC with carbon loading of 4% wt showed overall the best performance. It has outstanding adsorption capacity graphene especially for heavy metals, which are very difficult to remove from water with other filtration techniques.

The data presented shows that this technology could be applied to incorporate GSC filters into architectural structures to be built on the Yellow River. The large adsorption capacity, the green and costeffective production technology and the availability of the materials in Gansu province, enables it to be used on a wide scale and can contribute to developing affordable solutions for drinking water in this region.

coated sand 2% wt

95%

efficiency in Lead removal

CANCER VILLAGES

80 % dnas detaoc edixoincrease enehpainrgdeath tw %4 dnas

rate due to cancer in the past 30 years in detaocChina enehparg

Cancer villages, by virtue of being surrounded tw %2 dnaby s chemical detaoc plants enehor pacoal-fired rg power plants,

are villages with soil and water supplies that are contaminated, usually with heavy metals. These are entire villages where every other house contains someone dying of cancer or some sort of respiratory problem. Water contamination from industrial pollution is believed to be the main cause of cancer villages, and there is a close relationship between China’s major rivers and the location of cancer counties.

FISH EXTINCTION

1/3 of Yellow River fish has extincted

THE POLLUTION MESH

IMPLEMENTING GRAPHENE TECHNOLOGY IN WATER PURIFYING BRIDGE PROJECT

The discharge of industrial effluents into water bodies negatively effects tourism, agricultural and industrial applications.

RESULTS

Heavy metals affect the photosynthesis and disturb the self-purification mechanism leading to extinction of some aquatic species.

Data Collected

Researching on graphene based materials for water purification, I have found that it is possible to anchor graphene on sand particles, combining properties of sand filter mechanism with purification properties of graphene. This ideas seemed particularly adequate for this site. Lanzhou is surrounded by the Gobi desert, so it has an enormous deposits of sand. In terms of graphene source, there are huge sources of carbon and graphite in the region (components that can be used for graphene production).

YELLOW RIVER POLLUTION Main Water Pollutants and Their Impact

GRAPHENE COATED SAND Combining Graphene Purification Properties with Sand Filer Mechanism

highly contaminated Yellow River water

photographed Thomas Chevalier Bostrup

clean water enjoyment center

+

drinkable tap water for inhabitants

The technology of graphene coated sand water filtration has been used in my thesis project: Transition, water purifying bridge in China, that converts highly contaminated river water into a drinkable source. The project is presented on following pages.

21

10 10

20

30

50

40

60

70

90

80

30

20 10 1 0

20

03

02

graphene coated sand 4% wt graphene coated sand 4% wt. graphene coated sand 2% wt graphene coated sand 2% wt.

04

Gansu Province is facing a severe water crisis. Mining and industry are using massive amounts of water, while at the same time creating massive water pollution. The main source of water supply is the Yellow River, which in almost 40% of its volume is heavily polluted and “unfit for human contact”. Among the various contaminants found in the water, heavy metals require special attention because of their toxic effect on humans.

10

20

20

10

40

30

40 30

40

50

Lead

70 60 50

50

graphene oxidesand coated sand graphene oxide coated

05

02 01 01

100

Ni

10 0 90 80 60

70

80

90

100

Lead

ORGANIC

01

02

p

CARBON

Gansu Province is facing a severe water crisis. The main source of water supply is the Yellow River, which in almost 40% of its volume is “unfit for human contact”. Currently used water purification techniques are not able to remove extremely toxic heavy metals from EFFECTS water.

70 80 90

Graphene coated sand removes up to 95% of heavy metals from water.

e cin

09

60

Chromium

90

06 05

30

04

20

03

10

08

50

20

Chromium

40

100

100

GRAPHENE

30

0

s Ar

10

80

20

90

GOB I DESERT SAND

0

10

10

80

en ic

90

OTHERS

10

10

50 70

40

20

40 60

90

80

100

30

conductivity

70

60

50

03

0 10

04

ty ni

07

001

20

*pH considered 100 % removal when pH level 7.0 reached

06

muimorhC

40

06

05

40

80

70

05

04

60 50

90

30

20

60

s Ar

09

08

001

daeL

07

06

05

04

03

02

01

02 04

03

70

30

50

30

20

70

en ic

02

01 03

02

80

70 60

10 10

10

60

0 10

03

0

01

Cd

01

01

0

90

04

02

10

50

80

05

03

20

20

PHOSPHORUS

PETROLEUM

40 30

50

06

04

50

40

08

Pb

07

05

60

20

Hg As

iN

09

06

+

Cr IV

1 00

07

70

10

lek c

08

80

30

09

90

sa li

40

001

AMMONIA NITROGEN

100

el ck

90

HEAVY METALS

evlossid latot sdilos d

VOLATILE PHENOL

total dissolved sol

100

el ck

R VE RI

M AI N

total dissolved solids

LUTANTS IN TH EY POL EL ER LO AT W COD W

20

GRAPHITE

TRANSITION water purifying bridge in China 1. Graphene Center 2. Filtration Forest 3. Clean Water Tanks 4. Entrance to Water Leisure Center Changing Rooms & Showers 5. Saunas 3

2

1

5 4

6 7

10

8

9

6. Swimming Pool 7. Baths 8. Recreational Pool 9. Children Pool 10. Wetlands (Artificial) Lake

3

“Transition� is an innovative water purifying bridge, converting highly contaminated river water to drinkable source; at the same time trying to explore the architectural potential of water purification process, breaking stereotypes of current water treatment plants - closed to the public. By incorporating swimming and bath facilities, it provides spatial and sensorial experience of clean water in all its forms. Moreover, on the urban level, it is connecting and revitalizing parts of the city. Master Thesis Project

The Royal Danish Academy of Fine Arts

2017

supervisor: Marianne Hansen

infrastructure water purification swimming pools

22

baths saunas cafeteria

total lenght: 900 m

https://kadk.dk/project/transitionwater-purifying-bridge-china

section

8

7

23

“IDOL´S TOWER” a tower inspired by Kostya Koval’s dance movement sequences

The subject of my Bachelor’s thesis was to design a tower dedicated to an idol I was free to choose. The idol I chose was Kostya Koval, an Ukrainian dancer and choreographer. This was at the time of the Euromaidan Revolution in Ukraine - I was fascinated that during such violent times people are still creating art, of which Kostya was a personification. The idea of the project resulted from my correspondence with Kostya, who summarized his dancing with the words: “You shouldn’t write about dancing, dancing should be danced”. This sentence became the inspiration to the idea of visitors exploring the tower through dancing. The way up the tower is marked by a serpentine, designed based on the analysis of Kostya’s dance movement sequences - he spins around the dance floor, allowing constant eye contact with the dancer and encouraging the viewer to join in.

Bachelor Thesis Project

individual work

2014

Warsaw University of Technology

dance floors observation tower

detailed construction drawings

24

supervisor: Ewa Kurylowicz

award for top 5 thesis project at the Warsaw University of Technology in 2014

rzut parteru 1:50 (przekrĂłj poziomy D-D)

The tower was designed enabling the user to experience and feel the relation with Kostya’s dancing. There are two dance floors, a retreat for contemplation and observational use, as well as a backroom with restrooms and a changing room. An additional requirement was that the tower is a temporary object, erected each year anew, functioning just over the summer.

25

Thank you for considering my application. 26