PERSONAL DETAILS
Birth: İstanbul, Turkey Residency: Berlin, Germany
SKILLS
Zeynep Naz Özkan
znazozkan@gmail.com https://www.linkedin.com/in/nazozkan/
AutoCad Revit Sefaira
3Ds Max Design Google SketchUp Microsoft Office
PowerPoint, Word, Excel
Adobe Creative Suite
Photoshop, Illustrator, InDesign, Premiere Pro
Lumion Rhino
EDUCATION
2018-Present
Master of Architecture-Typology, Technical University of Berlin
WORKSHOPS
2013-2017
Bachelor’s degree in architecture, Yeditepe University, Turkey High honour degree
2013
2016
University of Waterloo School of Architecture, Canada Exchange Program
2015 2015 2016
PROFESSIONAL
Sept 2019-Present
Technical University of Berlin-Massivbau Architect, Research Assistant Infra-lightweight concrete housing project planning Technical detail design Preparation of design review panels Technotopia Exhibition Design, Maxxi Museum, Rome Construction and Structural Engineering Exhibition Design, BAU München
Jan-Feb 2016
MuuM Architects Architectural assistant Housing project 3D modelling with BIM Technical detail revision MIPIM, Pavilion design for Turkish Ceramics Research and design strategies for Caferaga Sports and Culture Center Competition Design development drawings
2017
Form Yapı Contruction Junior Designer Analysis of a housing restoration project Photography for initial design attempt of a restoration project Completion of CAD drawings of a old housing project Preparation of site measurements and coordinates Assistance to construction site management Documentation of the ongoing construction process
Memories of Le Corbusier - Workshop and Exhibiton Istanbul, Turkey and Paris, France Garbage - Recycle Workshop Salt Galata, Istanbul, Turkey Biomimetic Design and Bauhaus Bauhaus Denkmal Bundesschule, Bernau, Germany
AWARDS
2014 2014
State’s Scholarship For University Outstanding Academic Achivement Scholarship Yeditepe University
2014
Summer School Scholarship Riga Technical University
2016
Outstanding Academic Achivement Scholarship Yeditepe University Summer School Scholarship Bauhaus Denkmal Bundesschule Bernau
2017
INTERNATIONAL COMPETITIONS
2016 June-Dec 2015
Urban Livability - Summer Workshop Riga Technical University, Cesis, Latvia Ecoweek Istanbul - Contemporary Archeology Istanbul, Turkey
2018
Young Architects Competitions - Lighthouse Sea Hotel Syracuse, Italy Beebreeders - The Tiny Big Coffee House Challenge Northern Europe
LANGUAGES
Turkish English German
native fluent elementary
Urban Corridor Site: Dar es Salaam, Tanzania Year: 2019 Status: Typology Design Studio II (group) Instituition: Technical University of Berlin Collaboration with Timothy Villiers, Lutz Kneissl Big cities in eastern africa face problems such as rapid population growth, hunger, waste management and energy production. Belt and Road Initiative (a global infrastructure development strategy) offered by China creates opportunuties for these problematic cities. The investments are in favour of global China based companies however, in this project we try to hack the system and direct the investments to healthy growth of Tansanian cities. We think growth of cities should find problems to the global challenges.
Our city concept offers a linear city between 2 port cities that are Dar as Salaam and Bagamoyo. Urban Corridor offers housing opportunities, industrial and commercial facilities, transportation tools, food distribution methods and energy production sources. 3 types of building kits are designed to satisfy needs of 2 existing cities. These kits include very pragmatic industrial, commercial and housing typologies. In future this linear city concept can be applied to any eastern african cities which are connected through BRI developments.
POPULATION GROWTH
+ 5.0 million people
BRI + 4.6 million people
China
POPULATION DAR ES SALAAM
2019 6.3 million
2029 11.3 million
2050 15.9 million
Infrastructure
Tanzania
Investment
Natural resources
Cheap labour
Dar es Salaam 2016 5.4 million - 2026 10.8 million in 10 years. %4.4 is annual growth of the city. 75% of dwellers in Dar es Salaam are living in informal settlements. This contributes to urban sprawl and land underutilisation.
China is supporting financial facilities of Tanzania. Under the roof of BRI, China builds infrastructure to cities which creates potential for sustainable cities. Due to cheap labour in Tanzania, Far East and West make manufactural investment.
FOOD
WASTE MANAGEMENT 25% Nourished
HUNGER FOOD OOD OO IN RURAL AREAS Timothy Villiers - Naz Ă–zkan - Lutz Kneissl
70% Undernourished WASTE PRODUCED IN DAR ES SALAAM
2018 4.600 tonnes per day
2025 12.000 tonnes per day
67 percent of the total population lives in rural areas and relies on agriculture. Food is sufficient at national level but food isn’t accesible for all. Food supply chain is poor. There are clogistical barriers due to poor road networks.
Total waste of Dar es Salaam per day is 4600 tonnes per day which will be 12.000 tonnes per day in 2025.
Food insecurity due to rapid urban growth
75% of dwellers in Dar es Salaam are living in informal settlements. This contributes to urban sprawl and land underutilisation.
Low productivity in agriulture due to lack of technology and poor access to seeds and fertilizers.
Lack of infrastructure for waste management contributes to pollution on scarce water sources. 40% of total waste is organic.
1
MATERIAL FLOW
BRI
KNOWLEDGE
QUALIFICATION
WASTE MANAGEMENT
MANUFACTURE
DISTRIBUTION PROBLEM
COAL AND WOOD BASED
INSUFFICIENT ENERGY
OLD VEHICLE STANDART
FOSSIL FUEL BASED
FOOD
ENERGY
INDUSTY
BUILDING MATERIAL
TECHNOLOGY
INDUSTRIAL WASTE
BIOWASTE
HUNGER
HIGH EMSSION
POOR GRID
HIGH CO² EMISSIONS
INCREASING DEMAND
Bagamoyo local commercial zone
POLLUTING
BAD INFRASTRUCTURE LOW ACCESSIBILITY
INFORMAL HOUSING
MOBILITY
LAND UNDERUTILISATION
GROWING POPULATION NEED OF HOUSING
SECTOR CH A LLENG ES
HOUSING
HOUSING
Port related industry zone
noisreVlanoitacudESG
Fishery agro-processing based industry
noisreVlanoitacudESG
Ruvu river agro-processing based industry
CROPS FARMING
noisreVlanoitacudESG
27.%
LIQUIDS SOLIDS SOLIDS
73%
79%
TOTAL
LIFESTOOCK FARMING
21%
HARVESTED
SHUTTLE AI
4 6
Agro-processing based industry
LEGEND
LEGEND
16%
exicting urban pattern
linear city
exicting urban pattern
linear city
ports
ports
2%
main roads
main roads
proposed power-/ gas transmission
proposed power-/ gas transmission
BUILDING KIT
GSEducationalVersion
ports
main roads proposed power-/ gas transmission
GSEducationalVersion
GSEducationalVersion
HOUSING
REACHING CUSTOMER
LEGEND
exicting urban pattern
planed SEZ
8
SMALL SIZED HOUSING COMPONENT
MEDIUM SIZED HOUSING COMPONENT
BIG SIZED HOUSING COMPONENT
UR BAN COR IDOR
INDUSTY
URBAN DIGESTER
7 FOOD AI
U. CARGO SYSTEM
HOUSING KIT
2
5
IND. SYMBIOSIS
3
RESEARCH CEN.
LINEAR GRID
1
H ACK COMPONENTS
COMMERCE
Raw materials based industry
AGRO INDUSTRY AND MANUFACTURING
ENERGY PLANT COMPONENT
COMMERCE
PHARMACEUTICAL INDUSTRY
SMALL SIZED HOUSING
MEDIUM SIZED HOUSING
BIG SIZED HOUSING COMPONENT 10km
2
1
LINEAR GRID Electricity grid
3
SHUTTLE AI
Power grid
1.Physical station
2.Expresstrain
3.Physical station
4.Shuttle AI
Energy storage to store the renewable energy, to release it in the grid when it‘s needed
Energy produced in with biowaste trhough anaerobic digester
5.Virtual station
PRIVATE CAR
SHUTTLE AI
NO PARKING PLACES
USAGE / PARKING
Windparks in rural areas or seaside are feeding the grid with electricity
LESS DRIVING LANES
AVERAGE PERSON PER 5m²
Solar energy produced by residents or parks in rural area
AVERAGE CO2 eq
Urban Infrastructure Elements
3
CO2 eq 140 g/pkm
CO2 eq 30 g/pkm g
MORE ECO FRIENDLY
4
UNDERGROUND CARGO SYSTEM
5
INDUSTRIAL SYMBIOSIS Housing
Market
Manufacturer
Agro-industry
4. Manufacturing Ind.
self-autonomous e-vehicle
5. Construction Ind.
Agriculture
elevator
3.Pharmaceutical Ind. 2. Utility
1. Energy Ind.
trolley
Relief of the road networkt The supply is transferred via hubs, which enable fully automated loading and unloading of AI vehicles in the linear tunnel. The process is continuous, so that the operation is not interrupted. On autonomous pick-up stations eco-vehicles reach the supply to the final destination
Reducing waste water energy material
ecological balance up to 80% better compared to today's transport systems
receive give
More efficiency through continuous working AI
4
electricity biogas sulfur and limestone sand industrial enzyme fertiliser waste water clean water
Protecting clean water resources
avoiding costs and C02 caused by waste
Boosting production of materials and goods
Reduces dependence on fossil fuel
General Assembly Site: Moabit, Berlin, Germany Year: 2019 Status: Typology Design Studio I (group) Instituition: Technical University of Berlin Collaboration with Milyausha Garaeva, Mouhammad Allan
The general assembly, usually represented in the United Nations, is a formal space for discussions and votes in which 193 countries participate. This form of assembly doesn’t solve problems and doesn’t have a direct influence on the society. The participation of representatives is passive. According to Milo Rau, there are many societies that are excluded from the governmental attention and never concerned such as Non-governmental organizations and others.
We offer a space where representatives of those groups can not only have a discussion forum but also can have a platform where research and experiments may be performed. The place where issues can be studied, and the result can be shown. We studied typologies of early assembly spaces and we incorporated all these functions into one building. We offer an institution with a laboratory, a theatre, a library and a gallery buildings that is adapting the fundamental typologies to contemporary asssembly needs.
Axonometry
Section B-B
5
Laboratory Typology
Library Typology
Plan
Plan
Section
Section
Theatre Typology
Gallery Typology
Plan
Plan
Section
Section
Typology
Historical typology studies
6
Theatre Section
Library Section
Exploded Axonometry
Site Morphology 7
Concrete Site
Ground Floor Plan
Library Collage Section A-A 8
Sound of Nature Site: Pine Cove, French River, Canada, ON Year: 2016 (6th semester) Status: Studio V Project (individual) This project is a music therapy center located in the heart of French River and aims to let the nature diffuse inside body with the harmony of music. The role of human is manipulated into a transition channel between nature and music. Motion of nature and vibration of music are tied with a carefully designed spatial experiment.
All the musical therapy rooms not only try to utilise from the landscape but also experience the soundscape of French river within the therapy experiment. In order to integrate the nature into the experiment, rooms are distributed around the site, users are encouraged to connect to the nature.
intended for music experiment built area for music therapy
Soundscape
Landscape
Land use
Each zone of site is surrounded by different sounds, considering this map therapy, accommodation, communal areas and service
Photos are taken from the specific directions and buildings are oriented through these unique landscapes.
By integrating nature into a essential part of the therapy experiment unlimited amount of space will be used for recreation and
Master plan
SOUND of NATURE 9
Wall to roof detail 0
5m
10m
20m
Wall to foundation
Window detail Plan, section, 3D visualisation of therapy rooms 10
Plan and section of therapist accommodation 3D visualisation of therapy room
Shell in Motion Site: Drammen Science Park, Norway Year: 2018 Status: The Tiny Big Coffee House Challenge - International design competition (group project) Collaboration with Sedat GÜlada The main target of the kiosk design is to create a new approach to community’s coffee life with different functions: a public furniture acting as a coffee kiosk, an exhibition center and a breathing space for city dwellers. To operate the kiosk on different seasons, the shell is designed in motion by a manually controlled roller system. The sliding motion in vertical direction provide design a flexible use in both winter and summer terms with their adjustable panels which are useful to create open air exhibition, while the sliding roof on shell provide horizontal extension which is using special events and resting area. In the first case, the shell is located on ground floor and roof is sliding on adjustable panels which are provide new event space apart from kiosk.
In the second case, rising in vertically creates new volume under shell used as especially coffee production zone. Hence, the ultimate design allow the visitors to take part in these whole process conducted on coffee bean from bean to cup. Another prominent target of this design is creating a breathing shell working under negative pressure zones providing natural ventilation. Also use of ETFE as a shell material helps the kiosk environmental control between indoor and outdoor spaces when the kiosk is located on ground floor. The open-ended part of project includes connection aglea system and water collector system on its roof to supply its self energy required to lighting system and reduce the overall energy consumption.
Drammen Science Park, Norway 11
Configurations
Pneumatic motion: Adjustable holes provide natural ventilation by breathing motion
Enclosed box
Semi-open Shell extents by sliding outwards
0
40
80
200
Motion on facade: ETFE motion
Extension by panels
Vertical motion
Exhibition area
Adjustable panels for different events
Entrance panel by pulley system
Shell in motion project allows 3 components to move individually : Shell Movement: It can vetically move according to climate conditions. Roof Movement: With the extension of roof towards outdoors kiosk is open to new cupping sessions. Panel Movement: Panels enclose the kiosk at night during summer times. During daytime it can be rotated to accommodate variety of events.
Welcoming public place on ground floor 12
Shell serves as a lantern
Coffee production process
Section I
Section II
Exploded Perspective
Plan 13
14
Ambivert Pavilion Site: Cambridge, ON, Canada Year: 2016 (6th semester) Status: Studio IV, Built (group) Collaboration with Mariah Palantzas, Ien Boodan, Joshua Giovinazzo, Sarah Zheng The Ambivert Pavilion is a user-controlled envelope that can accommodate a myriad of small, social gatherings. With moveable louvres, users can dictate views and access points, subsequently affecting the social condition within the enclosure. A table was added to encourage standing drinking and casual conversation during the expo in which this pavilion debuted.
Enclosure
Configure Permeability
A transluent skin on the aforementioned louvres offers a playful canvas for light and shadows: trees block sunlight and their shadows flurry across the pavilion during the day; moving silhouetted and streams of light that radiate outward invite passersby during the night.
Social Education
15
Plan
Frame Framework
+
Moveable Louvres
+
Table
=
Ambivert Pavilion
SPF 2’’x4’’ Steel L-Bracket 2’’x4’’x8’’ 0° private
15°
45°
90° soci-
SPF 2’’x2’’ 8’’ Threaded Bolt Steel Washer Steel Nut Polyethylene Drop Sheet T50 Stable (x) Frame
Position of louvres 16
GROUP RinGB
RinGB
3D printing [h] assembly time [h]
cost of kite [€]
10 8
20 15
30
300
4
200
60
80
5 2
30
10 100
0
40 20
40
40 40
80
80
60
120
20
160
80
100
number of sails
200
12
120
8
6
4
10
2
50
4
0
6
10
00
40
number of joints
0
40
2000
0.8
8 10 15
11
00
16
60
3000
20
0
20
00 25
80
00
1.6
number of bars
80
0
10
4000
density [g/m3]
0
60
surface of sails [m2]
120
20
240 180
effective sail surface [m2]
total manufacturing time [h]
200 160
20 1000 0.4
Whole structure is too big to fit in any public transportation vehicle therefore, it is designed to be detachable if needed. The joints are the result of a research of durability to tension force studies. Wind creates a tension force on the joints. Each of 98 joints are 3D printed and glued by hand to the fabric. And glass fiber elements are attached to form the frame of the kite. Project video: https://youtu.be/HQj5ThTez9Q
1.2
2
100
5000
Can a structure float in the sky, look aesthetic and be detachable at the same time? We tried to push forward the limits of different materials. With glass fiber we created a kite structure that utilizes from tension force without any frame structure. Sailing fabric created a super light weight kite. There is a camera attached to the center of the kite, in which we recorded the flight of the kite far high in Berlin skies.
cutting time [h]
6
maximum flying time [min]
2 60
Collaboration with: Clara Salaun, Guilherme Gaspar, Leonard Zweck, Pablo de Britto
300
40
90
50
400
maximum flying height [m]
120
500
25
150
Site: Tempelhofer Feld, Berlin, Germany Year: 2019 Status: Flying Floating Structures Seminar/ Built (group)
length of strings [m]
volume [m3]
PLAN
weight [g]
length of bars [m]
FLYING STRUCTURES Property Chart GROUP RinGB 1:10
Clara Salaun Guilherme Gaspar Leonard Zweck Mathilde Pagneux Naz Özkan Pablo de Britto
SECTION A
TU Berlin | FG Borrego Colaborative Design Laboratory Flying Structures
FLYING STRUCTURES GROUP RinGB 1:10
Plan
Clara Salaun Guilherme Gaspar Leonard Zweck Mathilde Pagneux Naz Özkan Pablo de Britto
Section 17
TU Berlin | FG Borrego Colaborative Design Laboratory Flying Structures
OVERVIEW PARTS FLYING STRUCTURES GROUP RinGB
NYLON SAILS 69x
ELEVATION WIND DIRECTION
JOINTS 4 CONNECTIONS 42x
FLYING STRUCTURES GROUP RinGB 1:10
3 CONNECTIONS 29x
Materials 3 CONNECTIONS 29x
15x
Materials
13x
ELEVATION FLYING STRUCTURES GROUP RinGB 1:10
Clara Salaun Guilherme Gaspar Leonard Zweck Mathilde Pagneux Naz Özkan Pablo de Britto
GLASS FIBER BARS 99x
TU Berlin | FG Borrego Colaborative Design Laboratory Flying Structures
Joint
Elevation Clara Salaun Guilherme Gaspar Leonard Zweck Mathilde Pagneux Naz Özkan Pablo de Britto
18 TU Berlin | FG Borrego Colaborative Design Laboratory Flying Structures