Portfolio 2.0 by Ondřej Pokoj

ING. ARCH.

ˇ ONDREJ POKOJ

* 8. 4. 1992, PRAGUE +420 732 523 243 POKOJ.ONDREJ@GMAIL.COM U LESA 3306, 272 01 KLADNO, CZECHIA

Education 2011–2018 2015 2003–2011 Experience 2019 2015, 2017, 2019 2015–2019 2014–2015 2013

Architecture and Urbanism, Faculty of Architecture, Czech Technical University in Prague Architecture A III, Academy of Arts, Architecture & Design in Prague SGY - Gymnasium in Kladno

Atelier DPROJEKT architect Experimental Architecture Biennial in Prague production & coordinator Jaroslav Fragner Gallery / gallery of architecture in Prague coordinator & technical realization Experimental Centre, Faculty of Civic Engineering, CTU in Prague research assistant Atelier AURS drafter

Workshops 4/2019 4/2017 9/2016 7/2016 4/2016 1/2015 11/2014 11/2013 11/2012

Interactive Soft Actuated Environments, Prague Aerial Stigmergy, IAAC & Noumena, Barcelona Angewandte Architectural Challenge '16, University of Applied Arts Vienna Intelligent Tectonics, Design Morphine, Sofia The Language of Santini, Zdar nad Sazavou Sonic Reflection, Re.Code.Nature, Prague Videomapping, Re.Code.Nature, Prague Porous Formation & Virtuosity, Re.Code.Nature, Prague PETower, MOLAB, Prague

Languages Czech English German

native speaker active in speech and writing (C1) beginner (A1)

Software Skills ***** *** * Skills

Rhinoceros 5.0+6.0; Grasshopper; KeyShot; Adobe Photoshop, Illustrator, InDesign Processing; Python; Autodesk Maya, 3DMax; V-Ray; Adobe Premiere UDK Unreal Engine; CATIA + Digital Project Small team leadership. Consulting of contracted companies. Coordinating with client and VIP persons. Use to work 24/7.

MAYA WORKOUTS

NAME

NAME SUBTITLE YEAR POSITION CLIENT PLACE cibus fringilla. Duis bibendum, lectus ut viverra rhoncus, dolor nunc faucibus libero, eget facilisis enim ipsum id lacus. Integer rutrum, orci vestibulum ullamcorper ultricies, lacus quam ultricies odio, vitae placerat pede sem sit amet enim. Phasellus rhoncus. Cum sociis natoque penatibus et magnis dis parturient montes, nascetur ridiculus mus. Ut enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat. Nulla accumsan, elit sit amet varius semper, nulla mauris mollis quam, tempor suscipit diam nulla vel leo. In laoreet, magna

TRANSFERIUM PRAHA MULTIMODAL TRANSFER HUB, VĂ CLAV HAVEL AIRPORT 2018 AUTHOR STUDIO FLO|W FACULTY OF ARCHITECTURE, CTU IN PRAGUE

Air Traffic Control The design of the operating center is completely prefabricated from a steel sandwich system. Membrane Roofing The shell of the building consists of an insulating membrane with perforated mesh for visual contact with the exterior. Glass Skylights with Ventilation Built on trusses, they provide sufficient sunlight for the interior. The holes include vents for natural ventilation through the chimney effect throughout the building.

Trusses Pillars The rope net of the memrane structure is supported by a five big steel pillars.

Steel Waffle Construction The structure of the interior consists of an area freely moving from a vertical to a horizontal structure. Pre-fabricated steel sandwich.

The project is based on two main synchronise intentions. On the one hand an extension of Terminal 2 as part of a bigger development of the Airport City and on the other hand linking the airport with rail transport, i.e. the net of European highspeed trains, an extension of Metro A and the suburban railway Prague â&#x20AC;&#x201C; Kladno. The goal is to design a transfer transport hub at the crossing point of these traffic routes and create a human-friendly and clearly organized environment with an accent on quick movement of passengers and their comfort while waiting for the next traffic connection.

HELIOTROP HABITAT ACTIVE FAMILY HOUSE | BACHELOR THESIS 2015 AUTHOR STUDIO FLO|W FACULTY OF ARCHITECTURE, CTU IN PRAGUE

The surface of the facade is printed with translucent solar panels based on nanofibers (DSSC). Their deployment is generated based on the analysis of solar radiation.

Cytoplasmae is an intelligent glass façade with layers and coatings that control energy penetration outside and into the building to actively shape the inner microclimate. Ventilation is naturally with a chimney effect. FN Nano™ coating Planibel Clearvision Low - E coating

Static simulation of dome structure and interior design.

LIGHT

Transmission 72 Reflection 17

Krypton 90% Stopray Vision™ T50

ENERGY

Planibel Clearvision

Solar factor

Krypton 90%

Ug [W/(m .K)]

Low - E coating

0,5

Planibel Clearvision Polyvision™ electrochromic

DURAN ® Tubing PVB laminating film OLED film PVB laminating film DURAN ® Tubing steel

5 0,8 0,05 0,8 5

65 6

Planibel Clearvision Low - E coating

THICKNESS [mm] 38,38 WEIGHT [kg/m2] 36

The dome is made of glass tubes with steel rods and stainless steel elements. In selected tubes, an OLED foil is inserted to illuminate the interior in a night.

The structure of the bulb and the room cocoons defines the living interior with the integrated furniture and the winter garden.

kWh 30 20

PHOTOVOLTAIC

VENTILATION

COOLING

-50

HEATING

-20

-40

8 -56

-10

-30

WATER WARM.

LIGHTING

Construction of grate and residential cells made of epoxy wood-plastic composite. PERIPHERAL WALL VENTILATION THERMAL BRIDGE OTHER FLOOR

% 55 21 13 7 4

-60

Foundations of steel earth screws.

A heat pump with a deep well and a heat pump with a heat recovery with earth exchanger are used for heating and cooling.

BEER SET SET OF GLASSES 2017 CO-AUTHOR WITH MICHAL PRAZSKY ACADEMY OF ARTS, ARCHITECTURE AND DESIGN IN PRAGUE

In this project, we respond to the increasing level of beer culture by proposing a set for various beers. The collection was designed as a prototype for industrial production. The set excels in the plastic decor that can be created on glasses by means of industrial technology by pressing. The motive is based on historic glasses with nails, but in our design it is applied by parametric modelling to our own pattern, which fulfils a number of functions. The set includes a bottle opener, serving as a beverage closure. Collaboration with Michal PraĹžskĂ˝.

RUSTY CLUTCH BAG GENERATIVE DESIGN 2018 COâ&#x20AC;&#x201C;AUTHOR GABO GUZZO ITALY/CZECHIA

Rusty is a prototype of emergent woman evening accessory to carry the necessities like smart-phone, lipstick or a business card. With a limited series of just few pieces this fashion design became a piece of art. Process From a 2D grey-scale map to 3D virtual model. Shape printed with high-definition SLA printer. With negative form moulded the final product.

MATTONI AQA PET BOTTLES CONCEPTS 2017 AUTHOR FOR MIKOVEC DESIGN

ŠKODA FIBRE IDEA CAR CONCEPT 2016 CO-AUTHOR ŠKODA AUTO ACADEMY OF ARTS, ARCHITECTURE AND DESIGN IN PRAGUE

Škoda Fibre is a concept of an autonomous car, which will be produced using the 3D printing technology. The main idea of this concept is to reduce material to required minimum — a fatless structure. To achieve this requirement we have used swarm simulating algorithm to generate wire system. Based on a static analysis we have controlled a density and distribution of the fibres. This project was designed for the Škoda Auto car manufacturer.

OSSO SELF–ASSEMBLY STRUCTURE 2015 CO-AUTHOR AIII ACADEMY OF ART, ARCHITECTURE AND DESIGN, PRAGUE

The OSSO project (bone, in italy) examines new possibilities of working with mass-space. Deriving from a space-filling truncated tetrahedron. The original shape is transformed into a new component. It creates space in itself. Joining components over triangular surfaces. A 3D printed prototype was created and the connection method was tested by joining three flat neodymium magnets. The joint allows connection at three different angles. The primary pair can thus be arranged in a combination of 12 different structures. To test static and aesthetic

qualities, 26 epoxy resin castings were made. A design and component design proposal was designed and tested using an electric motor and electromagnets. By physical examination a rigid spherical structure was created. Colour variants of white, black and silver were tested. In the virtual environment, an arc structure was created and self-assembly was tested using gravity simulations. For the presentation, 360 ° visualization for virtual reality use (VR Glasses) and poster visualization was created.

Group project: Eleonora Orlandi (I), Jan Adamus (CZ), David Fořt (CZ), Ondřej Pokoj (CZ).

INTERACTIVE SOFT ACTUATED ENVIRONMENTS SOFT-ROBOTIC WORKSHOP 2019 MOLAB CTU, PRAGUE

HACKING PAPER WORKSHOP 2017 TUTOR EXPERIMENTAL ARCHITECTURE BIENNIAL #3 JAROSLAV FRAGNER GALLERY, PRAGUE The workshop is focused on material properties research and fabrication of specific shelter form as aggregation out of paper elements. Usually, we perceive paper as a soft and delicate material. We have speculated and designed patterns and borders to modify the material into more structural, stronger and smarter form transforming the given environment of Betlémské náměstí. Three types of laser cutted paper components folded into three-dimensional static structure were hanged from a ceiling. With their spacial rotation we created one continuous plastic structure. With the integrated LED stripes controlled via bluetooth it works like an interactive light installation. We have designed and created this canopy as a structure inside the Jaroslav Fragner Gallery. The project was a part of the Experimental Architecture Biennial exhibition.

INTIMATE SKIN REALâ&#x20AC;&#x201C;SCALE PAVILION BUILT OF UNIQUE PAPER UNITS 2017 CO-AUTHOR MOLAB FACULTY OF ARCHITECTURE, CTU IN PRAGUE

An intimate skin is a research pavilion inspired by elements of selected natural species. We focused on the study of the exoskeleton "Echinus esculentus", its materiality and the process of growth. Using a microscope, we examined the spectrum of space that is not visible to the normal eye. As a result, we understood the basic behavior of growth and designed a new mechanism for creating a natural structural process through visual coding, with

which we created new spatial and tectonic associations for the initial concept. The aim of the project was to realize user intimacy in a public environment. Using variations with different levels of porosity, we have developed a skin that allows you to create your own privacy almost anywhere. Martin Gsandtner Visiting Studio with Karen Alamo Avila, Ondrej Room, Maria Petsani, Marc Lencina

BAROQUE 2.0 INTERPRETATION OF SANTINI'S ARCHITECTURE WITH DIGITAL TOOLS 2016 COâ&#x20AC;&#x201D;AUTHOR THE LANGUAGE OF SANTINI WORKSHOP CASTLE ZDAR NAD SAZAVOU, CZE At present, it is no longer desirable to design architectural forms using conventional pen and paper techniques. In the desire to find a new architecture, new tools of creation need to be used. Computer technology is getting directly into the creative design process. The architect programs geometry and coordinates a number of parameters. New possibilities for robotic production allow for the creation of multiform and plastic structures. Work on the project so far uses a 3D scanner to scan motion. Using the scanner, we record voxels, points with coordinates in The project is inspired by the dance performance of Andrey Milner, interpreting the relationship between movement and space. The Kinect motion detection of the human body and its transcription into geometric form form a series of spatial sketches. The connection with the forms of the chapel at ZelenĂĄ Hora creates a specific morphology with which we continue to work in creating more complex forms. The project explores the creation of a spatial structure through motion, a process that contemporary technologies allow us to do.

the space of the light, resp. colors. To capture human motion, the skeleton analysis is used and the motion trajectory is recorded. In parametric modeling tools, we generate geometry on recorded motion trajectories. The initiation geometry is the profile curve of the Santini Chapel. Five-axis symmetry, typical of santini's work, is applied to the spatial sketch thus created. The result is a study for the chapel vault. We apply the aesthetics of digital baroque to the lantern object. Another form is the aggregation of two components according to the DLA (diffusion-limited aggregation) growth algorithm.

ARCHITECTURAL CHALLENGE 3D ROBOTICALLY BENT POLYMER STRUCTURE 2016 PROJECT TEAM INSTITUTE OF ARCHITECTURE UNIVERSITÄT FÜR ANGEWANDTE KUST, WIEN Description The project is an ongoing research on the development of three-dimensional folding of profiles without the use of expensive form-work or time consuming additive processes. A robotic work-flow is employed to achieve in a fast and efficient fashion the production of a highly intricated spatial installation. Since the beginning, parametric computation was applied to design the overall configuration towards the detailing and fabrication setup. Formally, the project introduces an idea of spatial frames with a high degree of freedom, bending and twisting in space. Through the precise calculation with Finite Elements Analysis, a bundling system is used to develop a vertical structure made of light plastic profiles. Surfaces are produced from linear elements with textiles, creating different spatial and surface effects.

Structural Performance The bundling system is able to produce continuous structural behaviour from 2 meter long elements. With connections in multiple directions, the structure achieves great height with 3x3cm PE plastic profiles. The organization of material and orientation of components were defined with the constant and real time feedback of Karamba structural analysis.

Fabrication Strategy With the collaboration of Clever Contour and their unique research on complex bending and twisting, an integrative workflow was introduced. From the conceptual design, a computational work-flow was created to automatize the whole process: From initial ideas, structural analysis was used to guide and optimize design decisions. Rationalization of the overall form fed the fabrication system, creating a seamless flow from design to materialization. The geometry was translated into robotic production through KUKA|prc, allowing the simulation and pre-visualization of each component considering the specific material behavior. The construction setup was developed and optimized using a continuous digital design chain towards full scale production.

NEOPLASM GENETICALLY SCULPTED ARCHITECTURE 2017 AUTHOR STUDIO FLO|W FACULTY OF ARCHITECTURE, CTU IN PRAGUE During the 20th century there was led to a major battle between Russia and the USA in the space conquest. In the 21st century this battle focuses on an entirely different scale - nano. Since the turn of the millennium we can follow an exponential development in biotechnology. These are genetic manipulation and change or creation of new biological forms. Another step to reach the first phase of the Kardashev scale of civilization. The project NEOPLASM is based on one of the biggest inventions on a field of medicine in 2016 called CRISPER Cas9. This new method enables us to manipulate easily with an existing DNA sequence of every living organism on the Earth. In a

genetic code of DNA there is encoded every information about morphology and physiology of the whole living organism, how it grows and how it behaves. When we can modify genomes of DNA or add completely synthetic ones, we are able to design an organism according to our current needs and requirements by changing of DNA in a unicellular embryo that then divides, growths and lives based on a new edited DNA. These types of objects can be brought back into the nature with its full functionality and sustainability. Editing genomes within a DNA sequence with the method of CRISPER Cas9 is similar to a computer scripting language. We can talk about an open-source architec-

ture when designing of the environment is simply open to everyone. The design process could be explained as building with LEGO bricks as putting together different types of units to create one complex structure. With this tool we got a power to our hands and we are prepared to start sculpting the evolution. What took millennia through natural evolution can be carried out because of genetic engineering tools during a few hours in a lab environment. The goal of the project is not to provide a specific design for specific purpose, but propose the way of thinking about architecture as an environment of flexible, living objects compounding one great sustainable organism.

TWEETBOT ROBOTIC TOOL FOR REAL-TIME DATA PLOTTING 2016 AUTHOR STUDIO FLO|W FACULTY OF ARCHITECTURE, CTU IN PRAGUE

Visualisation of geolocated Twitter posts “tweets”. This session was performed on Sunday of 29th May with location filter of London, UK. The pattern is emerged from two inputs - inner behaviour of robot and external data flow from Twitter feed. Input data stream can be vary according to the needs of the user.

OMÍTKA 15 MM

Viplanyl - vnitřní kout 50/50

Ý DETAIL C-a Viplanyl - vnitřní kout 50/80

min. 50

min. 80

KLAD RHOMBUS (21x95) SIBIŘSKÝ MODŘÍN VĚNÁ LAŤ (40x60) PUSTNÁ FOLIE ATA 100MM KA ZDIVO 24 PROFI (PROFI DRYFIX) AZENÁ SPOROTHERM KARI SÍTÍ 80 MM MÍTKA 10 MM MÍTKA SFALTOVÉ PÁSY 2x 5MM

3000 500 (1750)

625

3x PTH KP 1750

3x PTH KP 1250

250 350

125

800 2250

p 06

1.08 -0,100

800 2500

1000

250

5200 2200

3900

200

250

2500

2475

1000 2750 750 3500 (2000)

(P3) ŽBP 5900 12

130 125

XPS TL. 50 MM -0,150

3x PTH KP 1750

10 750 500 (2000)

1200

01 P

1500 2750

1175

5400 2200 6550

550

250

140

2000

250

4500

250 250 50 200

550

6000

250 200

13900

6550 20350

6000

300 350

250

2475

800

1.06

7000

2975

300

700 1970

125

1.01 ±0,000 s.v. 2,75 m

13500

250

STI

PLOCHA

15,5 7,5 5,1 7,5 41,6 4,6 5,2 39,1 126,1

S JÍDELNOU

PODLAHA KER. DL. DŘEV. PODLAHA KER. DL. DŘEV. PODLAHA DŘEV. PODLAHA KER. DL. DŘEVĚNÉ STUPNICE ANHYDRID

PRVEK, 40x3mm

LKEM:

5375

250

200

p 03

1900

250

100

250

L 02

3x PTH KP 1000

MŘÍŽKA PŘIVĚTRÁNÍ KOMÍNU 100X200

1500 2500

1530

02 P

450

250

1000

DILATAČNÍ 20 MIRELONOVÁ 40 VLOŽKA 200

970

18x 271/173,3

1.07

PŘIVĚTRÁNÍ KOMÍNU V PODLAZE 100x200

3x PTH KP 1750 16

1300

400 800

7000

700 1970

250

02 P

04 P

550

900 125

600

725

125

1300 2750

900 2200

2600

3x PTH KP 1750

1.05 ±0,000 s.v. 2,75 m

2500

800

800 1970

4400

1.02

125

1750

2500

125

7000

2500

7500

1500 2500

7000

7900

6/20-XC2 S KARI SÍTÍ ∅8, HU 08

2700

125

8500

1.03

700 1970

2975

1.04

450

s.v. 2,60 m

350

450

3x PTH KP 1750

1000

1500 2500

ŠTUKOVÁ OM JÁDROVÁ OM KERAMICKÉ Z XPS TL. 50MM LEPICÍ STĚRK KERAMICKÉ Z A' JÁDROVÁ OM ŠTUKOVÁ OM

3x PTH KP 1750

7200

(P2) ŽBP 3150

625

100

3x PTH KP 1750

1500 1500 (1000)

750

2600

p 05

6500

900 2500

1600

3x PTH KP 1250

375

2000

1500 1500 (1000)

1000

100

3x PTH KP 3500

900

100

250

1900

2750 2500

1125

2875

250

200

1750

1500 2500

2250

min. 50

Kotva pro ploché střechy

STĚNY OMÍTKA OMÍTKA OMÍTKA OMÍTKA OMÍTKA KER. OBKL. 2000 MM OMÍTKA OMÍTKA

TABULKA PŘEKLADŮ

SPECIFIKACE

MICKÝ PŘEKLAD POROTHERM 1000 MM

POČET (KS) 3

MICKÝ PŘEKLAD POROTHERM 1250 MM

MICKÝ PŘEKLAD POROTHERM 1750 MM

MICKÝ PŘEKLAD POROTHERM 3500 MM PŘEKLAD 5900 MM, 240x300 MM, C25/30 4+4∅R12 + TŘMENY ∅R6/150 PŘEKLAD 3150 MM, 240x250 MM, C25/30 4+4∅R12 + TŘMENY ∅R6/150

SPECIFIKACE

01 02

LEGENDA STAVEBNÍCH MATERIÁLŮ POČET (KS) LEVÉ

PRAVÉ

CELKEM

DŘEVĚNÉ DVEŘE VCHODOVÉ 1000/2750 S BOČNÍM SVĚTLÍKEM 500/2750

DŘEVĚNÉ DVEŘE VNITŘNÍ 700/1970

DŘEVĚNÉ DVEŘE VNITŘNÍ 800/1970

DVEŘE VNITŘNÍ 900/2200 S NADSVĚTLÍKEM 550 A BOČNÍM SVĚTLÍKEM 400/2750

DVEŘE DŘEVĚNÉ VENKOVNÍ PROSKLENÉ 800/2500

DVEŘE DŘEVĚNÉ VENKOVNÍ 800/2250

DŘEVĚNÉ DVEŘE POSUVNÉ (1200+1550)/2500

DŘEVĚNÉ OKNO PEVNÉ 1500x2500

DŘEVĚNÉ OKNO 1500x1500

DŘEVĚNÉ OKNO 750x500

DŘEVĚNÉ OKNO 1500x500

11 12

GARÁŽOVÁ VRATA 5200/2200

DŘEVĚNÉ FRANCOUZSKÉ OKNO 925/2500 + 575

POROTHERM 24 PROFI DRYFIX / PEVNOST P10 pěna Wienerberger POROTHERM 24 PROFI DRYFIX / PEVNOST P15 pěna Wienerberger POROTHERM 11,5 PROFI DRYFIX PS 200 MM MINERÁLNÍ VATA 100 MM DŘEVĚNÝ OBKLAD S PROVĚTRÁVANOU MEZEROU D

DILATAČNÍ SPÁRA MEZI OBJEKTY VYPLNĚNA MINERÁLNÍ VATOU TL. 50 MM

TYP DOMU SO 03 - RD C1

OSAZENÍ OBJEKTŮ RODINNÝCH DOMŮ ZÁKLADOVÁ SPÁRA (-1,400) [m.n.m.] 241,65 35

ČÍSLO POZEMKU

250

243,05

242,75

244,15

SO 03 - RD C1

244,12

245,52

zpracovatel Ing. arch. Dana Pokojová dokumentace Ing. arch. Mariana Langová Ing. Radek Kaemer Štefánikova 52, 150 00 Praha 5 - Smíchov zodpovědný Ing. arch. Dana Pokojová část stavební: projektant Ing. arch. Ondřej Pokoj vypracoval: Davídkova Group s.r.o. investor Kotršálova 301/12 196 00 Praha 9 Třeboradice místo stavby

Město Odolena Voda, k. ú. Odolena Voda, lokalita Pod Humny.

stavba

Výstavba 38 rodinných domů včetně dopravní a technické infrastruktury.

objekt:

SO 03 - RODINNÝ DŮM TYPU C1 PŮDORYS 1. NADZEMNÍHO PODLAŽÍ

P2 – ŽB PŘEKLAD 240x250

120

±0,000 [m.n.m.]

SO 03 - RD C1

obsah:

DP-PUR L.80MM

LEGENDA OKEN A DVEŘÍ OZN.

stupeň:

PDSP

změna PDSP č. 1 část: datum: měřítko: kopie

stavebn 5/2019 1 : 50

č.výkresu

D.C1.02

POD HUMNY RESIDENTIAL AREA 2019 CO-AUTHOR DAVIDKOVA GROUP ODOLENA VODA, CZECHIA