Polina V. Portfolio

P O L I N A VOROBYEVA

A R C H I T E C T

P O R T F O L I O

Education

Work experience

Computer skills

Languages

...and More

Architectural Association (London, UK)

Moscow Architectural Institute (Russia)

Sept 2012 - March 2014 Master of Architecture in Sustainable Environmental Design

2006-2010 Bachelor of Architecture

Junior architect

Free-lance architect

Architectural assistant

2011 - 2012

company of Roman Leonidov

in Ecosistema Urbano, Madrid Collaboration during the project for Voronezh city (Russia) 2015

2010-2012 Specialist of Architecture

in Architectural

Oct 2009 - April 2011

Drawing and modelling

Simulation software

Editing and publishing

Advanced: SketchUp, ArchiCad, Artlantis, Revit

Advanced: Ecotect, EDSL Tas, Energy Plus, Radiance, WinAir Basic: Envi-met

Adobe Photoshop Adobe InDesign Adobe Illustrator Microsoft Office

Russian

English

French, Spanish

Native speaker

Advanced IELTS 6.5

Beginner

Hard working Quick study person Dependable Trustworthy

Cooperative Success motivated Energetic

Calm and determined under pressure Tactful and patient communicator

Basic: MicroStation, Vectorworks, AutoCad

Polina Vorobyeva e-mail: apx.polina@gmail.com mob. phone: Moscow +7 926 173 22 73 London +44 7423 838 431

I was born in July 1989 in Moscow, where I had my first education as an architect. At the age of 17 I was sure that all I wanted was to enter the Moscow Architectural Institute and I did it. In addition I received a grant to study there. My responsibility, punctuality and accuracy helped me to be selected as a leader of the group and stayed there during my whole education. I started to work as an architect when I was on my fourth year, because I definitely wanted to get more practice. I joined a well-known company as an assistant and after two years of working there I started to run different kinds of projects on my own, and this experience helped me to decide in which area I wanted to specialize after graduation. I gained good practice, valuable computer graphic skills, the ability to work within a group and enriched my knowledge. Also, my colleagues always considered me as a very careful and reliable person who is able to work with short deadlines and under pressure. I have always believed that architecture should never forget its commitment to both the environment and society. I wanted to learn how to design comfort environments integrating passive strategies involving the climate and the architectural context in order to reduce the overall energy consumption and create sustainable buildings. Therefore I decided to carry on with my education at the Master programme on Sustainable Environmental Design in Architectural Association in London. After that, I took part in several competitions and joined spanish architectural company to work together on the project in Russia.

Я родилась в июле 1989 года в Москве. В 17 лет я поступила в МАрхИ и через 6 лет обучения получила диплом специалиста в архитектуре. Благодаря моей ответственности, пунктуальности и внимательности, я была выбрана старостой группы и оставалась ей на протяжении всего периода обучения. На 4 курсе МАрхИ, я устроилась на работу, так как хотела получить больше практических навыков. Я начинала как помощник-чертежник, а спустя 2 года работы в компании я была частью команды архитекторов, и у меня уже были собственные проекты. Этот опыт помог мне понять, в какой отрасли архитектуры я бы хотела работать в дальнейшем. Также я обрела практические знания и хорошие навыки работы в команде, с проектной документацией и компьютерными программами. По словам моих коллег, я очень работоспособна, внимательна к деталям и на меня можно положиться. Кроме того, я стрессоустойчивый сотрудник и всегда сдаю работу вовремя. Я всегда верила, что архитектура должна быть напрямую связана с обществом и окружающей средой. Я хотела понять, как проектировать комфортные для использования здания, опираясь на пассивный дизайн, особенности климата и окружение, чтобы снизить энергозатраты проекта и сделать его экологичным. Поэтому я решила продолжить мое обучение, поступив на магистратуру в Architectural Association в Лондон на программу Устойчивого Проектирования (Sustainable Environmental Design). После окончания я принимала участие в нескольких конкурсах, а затем начала работать в испанской архитектурной компании над проектом в России.

Waterproof separation WoodenWooden decking decking Waterproof separation Деревянный настил membrane Деревянный настил membrane Водонепроницаемая Водонепроницаемая разделительная разделительная пленка пленка

Macrophytes Macrophytes Макрофиты Макрофиты

Pedestrian path Pedestrian path Пешеходный Пешеходный мостик мостик

ConcreteConcrete rings rings Бетонные Бетонные кольца кольца

ACTION_1 Natural swimming pools. Strategic location of Public bathing areas equipped with systems to purify and control the quality of water, both in the urban context and the natural reservoir environment.

Wooden decking Waterproof separation Деревянный настил membrane Водонепроницаемая разделительная пленка

Macrophytes Макрофиты

ACTION_2 Eco-pathPedestrian path

Пешеходный мостик

The northern area of theVoronezh Sea presents a landscape of great ecological richness due to the natural formation of wetlands. Landscape and urban regeneration of the reservoir Concrete rings banks intended to improve the interplay between the water Бетонные surface andкольца its natural and/or urban context.

Gravel bed Слой гравия Floating macrophytes Плавающие макрофиты Drainage pipe Дренажная система

Rainwater Ливневые стоки Irrigation needs or discharge to the reservoir Для полива либо сброс воды в водохранилище

The aim of this project is to develop a strategy for the renovation of the Voronezh Reservoir and it`s city. Today the main problem is the water pollution and city`s detachment from the water. The vision for the Voronezh reservoir has 3 targets: to eliminate the sources of pollution with specific solutions for each one of them, to improve the quality of the reservoir water through the use of natural systems and mobile cleaning elements, and finally to incorporate urban proposals to the landscape facilitating new uses of urban land to reconnect the city with the water.

VORONEZH CITY REVITALIZATION Russia Ecosistema Urbano 2014 1st PRIZE

01

WIND TURBINES ВЕТРОГЕНЕРАТОРЫ RAINWATER AND SURFACE WATER RUNOFF ДОЖДЕВАЯ ВОДА И ПОВЕРХНОСТНЫЕ СТОКИ

macrophyte pond пруд с макрофитами

AERATORS АЭРАТОР

macro wind turbines мини ветрогенераторы

GREEN AREAS ЗЕЛЕНЫЕ НАСАЖДЕНИЯ

permeable pipe перфорированная труба

ACTION_3 New development The area will present an urban character, including mixeduse zone with residential, office, commercial and cultural spaces. This must be a pilot experience incorporating all the current sustainable technologies and good practices in water management.

THE FLOATING MACROPHYTES ARE THE BEST SOLUTION TO CONSIDERABLY IMPROVE THE WATER QUALITY IN SHALLOW AREAS ИСПОЛЬЗОВАНИЕ ПЛАВАЮЩИХ МАКРОФИТОВ - ОДИН ИЗ САМЫХ ЭФФЕКТИВНЫХ СПОСОБОВ УЛУЧШЕНИЯ КАЧЕСТВА ВОДЫ НА МЕЛКОВОДНЫХ УЧАСТКАХ

ACTION_4 Macrophytes Islands Creation of Laboratory-Islands of natural purification using floating systems in the shallower parts of the reservoir, in order to stop the proliferation of aquatic plants. These places will become infrastructures for the progressive improvement of water quality, but they will also house educational projects linked to new research techniques for the regeneration of water.

BY CROSSING THESE ISLANDS, FOLLOWING THE DIRECTION OF THE FLOW AND WITH THE HELP OF PUMPS, THE WATER WILL GET CLEAN ВОДА ОЧИЩАЕТСЯ, ПРОХОДЯ ЧЕРЕЗ ЭТИ ОСТРОВКИ ЕСТЕСТВЕННЫМ ПУТЕМ ИЛИ ЧЕРЕЗ НАСОСНУЮ УСТАНОВКУ

pH CONTROLL КОНТРОЛЬ pH

WATER AERATOR СИСТЕМА АЭРАЦИИ

ALUM TANK БАК С КВАСЦЕМ

TREATED WATER OUTFLOW WITH FILTER ВЫПУСК ОЧИЩЕННОЙ ВОДЫ ЧЕРЕЗ ФИЛЬТР

+

SLUDGE DRAWOFF PIPE ВЫПУСК ОСАДКА

SLUDGE STORAGE

FLOATING ACTIVITIES

MONITORING

РАЗВЛЕЧЕНИЯ НА ПЛАВУЧИХ ПЛАТФОРМАХ

МОНИТОРИНГ

WATER CLEANINGРЕЗЕРВУАР ДЛЯ TECHNOLOGY ОСАДКА ТЕХНОЛОГИЯ ОЧИСТКИ ВОДЫ

=

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ACTION_5 Mobile creaning Infrustructure

=

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+ WATER CLEANING TECHNOLOGY

FLOATING ACTIVITIES

MONITORING

ТЕХНОЛОГИЯ ОЧИСТКИ ВОДЫ

РАЗВЛЕЧЕНИЯ НА ПЛАВУЧИХ ПЛАТФОРМАХ

МОНИТОРИНГ

CLEANING MOBILE INFRASTRUCTURES МОБИЛЬНАЯ ОЧИЩАЮЩАЯ ПЛАТФОРМА С ИНФРАСТРУКТУРОЙ

This ‘customized’ barges will navigate the lake, controlling the eutrophication of the water through tanks with alum filters. The ‘plug in’ boats incorporate different programs and becoming mobile urban equipment that can be connected to different parts of the city, as required. At the same time, the barges and its water monitoring systems generates maps of water quality that can be accessed in real time through a web platform.

ПРОГРАММЫ ПО ОЧИСТКЕ И КОРРЕКТИРОВАТЬ ЕЕ ПРИ НЕОБХОДИМОСТИ.

30%

! temperature O2 contaminants % overall water quality

ACTION_6 Monitoring system - Digital layer Mobile app allows citizent and departments to access the changes of the water quality, evaluating the treatment effectiveness and adapt it, if necessary. The information about the water quality is recieved from the monitoring devices placed on the cleaning mobile infrustructures and on the buoys. Mobile app should unite all the facilities avaliable in the city: bikelines, public events, current exibitions, markets, etc.

ACTION_7 Leisure Island The idea is to turn the existing Pridachenskaya dam into a Leisure Island with different activities, becoming a new infrastructure for the city incorporating swimming areas.

10 ACTIONS towards city revitalization 1_RESERVA BIOVERSIDAD [banco de San Miguel]

2_FRENTE FLUVIAL [Costanera]

3_PARQUE BICENTENARIO [Costanera]

4_COSTERO VERDE ACTIVO [Costanera]

5_REVITALIZATION CHACARITA ALTA

6_CORREDORES ECOLOGICOS [centro historico]

TÍTULO:

PLANO GEN Plan director NUMERO:

P.11.1

Plan Maestro

AS Labo A

DOCUMENTA

Dirección: ecosistema urb arquitectos SLP

REVITALISATION OF THE HISTORICAL CENTER OF ASUNCION 7_CORREDORES CIVICOS [centro historico]

8_CATALIZADORES URBANOS [centro historico]

9_CORREDORES DINAMICOS [centro historico]

10_PUERTO VIVO [puerto de Asuncion]

Ecosistema Urbano 2015 In an effort to raise awareness and reconcile the city with its environment and natural heritage, our proposal aims to integrate sustainable urban development as a crosssectoral approach applied to all of the actions. We propose the creation of a series of dynamic, green and ecological corridors, connected by urban catalysts: buildings with hybrid, mixed-use, and flexible programming. The regeneration and consolidation of Upper Chacarita will follow in the footsteps of the revitalization process already begun in San Jeronimo neighborhood. The creation of a “coastal active green” (floodable park) will respect the existing topography and become the lungs of the city, using natural processes to facilitate air and water purification. A dense and compact urban waterfront will serve as both an urban façade and a gateway to the Bahia. It will also enable the spontaneous development of creative economies and new enterprises. Environmental initiatives – such as the establishment of a nature reserve – will be implemented in Banco de San Miguel and Bicentennial Park. Meanwhile, the cultural, social and economic character of Asuncion´s seaport will be reactivated.

ASU LAB

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Assembly process Prefab SIP wall panels

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3 17 1. Fiber cement board (15mm) 2. timber posts (40x60mm) 3. SIP wall panel: OSB (10mm)+insulation (100mm)+OSB (10mm) 4. SIP floor panel: OSB (12mm)+insulation (156mm)+OSB (12mm) 5. Field installed panel bottom plate (30x100mm) 6. Field installed panel edge plate (60x180mm) 7. Treated sill plate 8. Sill sealer 9. Termite shield 10. Foundation wall (200x160x150 mm) 11. Metal sheet roof 12. Waterproof layer 13. Timber joists (30x30mm) 14. SIP roof panel: OSB (10mm) + insulation (100mm) + OSB (10mm) 15. hidden metal gutter 16. Field installed special panel edge plate 17. Sliding doors 18. Shutters

Fiber cement boards

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TEMPORARY SUMMER UNIT FOR A HOSTEL IN ST.PETERSBURG Competition 2014

03 summer-autumn period <200 000 Rub

easy to transport WARM WEATHER

COLD WEATHER

max 9 m2

1200 m2

300 m2

900 m2

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300 m2

Wh

300 m2

600 m

2

June 6 p.m.

March 6 p.m. June 9 a.m.

March 9 a.m.

300 m2

300 m2

300 m2

300 m2

open-plan layout + meeting rooms teamwork spaces concenrtation rooms individual offices for head department

December 3:30 p.m. (sunset)

December 9:30 a.m. (sunrise)

Comparison of incident solar radiation on the facade with and without voids during the winter (01 Dec-28 Feb) 10.00-16.00, average daily values, Wh.

400+ 367 334 301 268 235 202 169 136 105 70

Winter

OFFICE BUILDING in Moscow

Despite the continuous growth of the Russian office-building sector, current designs are still far away from the environmental standards that contemporary architecture should fulfill. The result is a fully glazed and wide “box� with high levels of energy consumption and small response to modern working activities and spatial requirements. Consequently, the environmental quality of office spaces within this particular climate is an architectural challenge worth pursuing.

Summer

AA Architectural Association MArch Dissertation project 2013-2014

04

Most of part of Russia is located within a continental climate zone characterized by extremely cold winters and hot summers. Therefore, adaptive strategies must be implemented to maintain both visual and thermal comfort in indoor environments throughout the year, while simultaneously and substantially reducing energy consumption.

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Cold period

Diffuse light

Direct sun

Plantroom air recirculation

Skin

Shading + Shutters

Construction

Plantroom air recirculation

air supply

air supply

Warm period

air supply

The skin consists of three layers: an inner layer with doubleglazed floor-to-ceiling windows, night shutters and shading, and an outer layer with pivoting single-glazed panels. This system comprises a corridor-type double-skin facade that is partitioned per storey. The maintenance catwalks are set into the cavity and act as a shading device. Also, the skin has been designed to stop the spread of fire and smoke in case of an emergency. Every level consists of four panels: upper and lower panels are designed to be completely open during the warm period. When they are closed it is essential for the skin to maintain a high degree of air tightness; in winter this provides additional insulation and reduces heat loss.

air supply

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The inclined roof of the atrium was designed tilted to one side. That allows low winter sun to penetrate through the clear vertical glazing on the south side, while more coated glazed panels on the pitched part reflect high direct sun angles. Also, the shape of the roof helps snow to roll down, without covering the atrium.

One of the aims of the project has been to bypass the use of natural ventilation through external windows for several reasons. Therefore, ventilation strategies are based on ventilation provided through the atrium. During the cold period it is essential the air recirculation is provided since the greatest heat loss occurs through the ventilation. 90% of the air is recovered in the plant room and only 10% of the air is taken from outside. In cold period the atrium roof is closed; the exhausted air then goes up to the top floor where it is collected in the plant room for further recirculation. In the warm period the panels on the roof of the atrium are opened to create a stuck effect.

Warm period

Cold period, nighttime

Summer. South facade

Cold period, working hours when dark outside

Winter. South facade

maintenance catwalk

opaque insulating panel glazed panel

Sky-court

Sky-court

Office space

Office space

The office building has different public areas: skycourts and atriums can be used in cold period, while big courtyard creates pleasant environment in summer. Sky courts provide social areas that can be used as coffee spots, break-out areas and places for interaction. Also, they improve daylight penetration into the building. Ten metre deep atrium is enough to provide the minimum required daylight for the ground level of the building.

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Global Radia6on (W) North Office Temp.

Diffuse Radia6on (W) Terrace Temp.

External Temperature (°C) Atrium Temp.

South Office Temp. Working hours

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Construction detail. Section through the South facade.

glazed panel

shutters, 20 mm wood drive for shutters

maintenance catwalk

air inlet heating

insulation panel motor for louvres air extractor

ANNUAL AIR TEMPERATURE FRENQUENCY DISTRIBUTION

(occupied hours - 10 toduring 19) Annual temperature frequency distribution the working hours. 700

comfort

heating deficit

600

Hours of Occurrence

500

cooling deficit

88.6%

7.2%

As a result of the applied strategies, the project achieves a comfort temperature in the office space for 88% of the occupancy hours throughout the year. The monthly heating demand in the coldest month was reduced to 2.0 kWh/m2, and the cooling in the warmest month to 1.3 kWh/m2. A combination of office trends and a program for design strategies has given rise to new working environments that provide occupants with different activities and create thermal and visual comfort.

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Global Radia5on (W) a5on (W) Diffuse Radia5on (W) mperature (°C) South Office Temp. External Temperature (°C) e Temp with air recovery South system Office Temp with air recovery system

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External Thours emperature (°C) Diffuse R adia5on (W) Working ffice Temp with air recovery system South OSouth ffice TO emp.

GABRIEL`S WHARF AA Architectural Association MArch team project 2012

05

Wind and solar studies Today old temporary market is situated on the South bank in central area of London. This project, based on the area demand, proposed programme focuses on organizing the mixed use space mainly for young couples, families and young professionals. First, massing process based on solar access, wind conditions and solar distribution over the faรงade and ground was done. Main aim was to provide thermal and visual comfort for living and working spaces following the lifestyle and daily activities of occupants. Also, some of the targets were to save the iconic wall of the market and make a link between the square, park and Queen`s Walk.

Office block

Coupling open plan space with shared offices, a unit volume with a mezzanine was defined. Analysis of the effects of different glazing to floor ratio on the daylight and temperature was made; one side and cross ventilation strategies were proposed.

cellular offices 1-2 person

Indoor temperature simulations based on TAS resuls

open plan shared space

A: Buffer balcony + more insulation for exposed floor

B: Closed corridor

C: Night shutters U-value 1.47 w/m2K

Family flat

The family flats are designed for young couples with a child. Duplex typology was chosen to have more separated and flexible areas. Different conditions and WWR were simulated to achieve the best result in terms of daylight and comfort temperature through the whole year. March 17:00 Sky illuminance 3 600 lux

!

!

Overview of the Project

61

Estimating the viability of using renewable energy sources to meet the residual energy demand is one target of the project. The estimated* annual total heating energy demand of the entire development (excluding the market) are 146.1 MWh for hot water heating and 22.4 MWh for space heating, of which 67% is from the family and couple flats (marked in cyan) and another 33% from the offices and shared flats (marked in orange). As 67% of the hot water demand is from the family and couple flats, 142 panels will be installed on their rooftop and the rest 70 on the other block to minimize heat loss along the pipework.

Renewable energy

Dog Kennel Hill (London) is a 3-storey apartment building with two levels in each flat, which was chosen for Term 1 project on Sustainable Environmental Design Master programme in AA. First step was to observe the site, take some spot measurements and talk to the people around the building for better understanding its performance. Outside measurements were reviewed and analysed for further investigations of the outdoor environmental conditions and comfort. Then indoor analysis was done: questionnaires, data loggers and different simulations helped to understand building performance and propose some improvements.

Problem findings

Daylight level calculations

U-Values and heat loss calculations

Data-loggers analysis

Spot measurements. Moisture problem

Solar radiation analysis

Wind simulations

DOG KENNEL HILL Building Studies CURRENT HEATING LOAD

NEW HEATING LOAD

25.4 kW/m2

18.7 kW/m2

heating 24h at 21oC

heating 24h at 21oC

AA Architectural Association MArch team project 2012

06

PROVIDE MECHANICAL VENTILATION inlet on the sliding door - to increase ventilation in the kitchen - to deal with moisture problem

VOID ADD INSULATION on the North wall

-add adjustable blinds to reduce overlighting in living room - improve mechanical ventilation to control smells from the kitchen - maintain double-high view - better ventilation in summer

- reduce heat load - filling with aerogel does not reduce much illuminance - maintain daylight level

CLADDING PERFORMANCE

LOUVRES on the North wall

-to control excessive solar gain through the south facade in summer - low impact on solar radiation and daylight in winter

- reduce overheating from direct sun in summer - control excess of brightness in the bedroom

SOUTH WINDOWS - effective in terms of solar gains - perform better with cladding - reducing its area (-30%, -60%) don`t lead to significant decrease of heating demand

PRIVATE HOUSE

Key responsobilities: - working with plans, facades and sections - selection of materials - interior and exterior design - preparing technical drawings and project documentation - meetings with clients and architectural supervision

Architectural company of Roman Leonidov

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This house was designed for for a big family on a site 30 km away from Moscow. It has 4 levels and the total rooms area is about 500 m2. The feature of this house are huge glued wooden beams, which lean on the concrete construction.

PRIVATE HOUSE Architectural company of Roman Leonidov 2011

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This building consists of 3 main volumes that are connected with galleries. Simple shapes and natural materials make the house organically fit into surrounding area. Deep-set glazing on the main South-oriented facade protects from direct sun in summer and allows solar rays to heat rooms in winter.

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10

7

6

5

4

3

2

1

4

8 x 0.150 = 1.200 m

F

11 x 0.150 = 1.650 m

F

F

E

E

E

D

D

5

5

4

3

2

1

12 x 0.150 = 1.800 m 8 x 0.150 = 1.200 m

22 x 0.150 = 3.300 m

8 x 0.150 = 1.200 m 11 x 0.150 = 1.650 m

E

4

3

12 x 0.150 = 1.800 m

22 x 0.150 = 3.300 m

8 x 0.150 = 1.200 m

F

11

1

G

5

4

3

2

1

G

2

G

G

10

6

7

5

6

H

4

5

3

9

2

8

H

1

3

4

8

3

7

2

6

1

D

D 8 x 0.150 = 1.200 m

8 x 0.150 = 1.200 m 7

6

5

4

3

2

1

7

6

5

4

3

2

1

8 x 0.150 = 1.200 m

8 x 0.150 = 1.200 m

C

7

6

5

4

3

2

1

7

6

5

4

3

2

1

C

C

C

B

B

B

B

9 x 0.050 = 0.450 m

9 x 0.050 = 0.450 m

A

A

A

A

1

2

1

3

2

3

4

5

4

6

1

5

6

2

1

3

2

3

4

5

4

6

5

6

P O L I N A VOROBYEVA M

o

s

c

o

w

+7 926 173 22 73 L

o

n

d

o

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+44 7423 838 431 apx.polina@gmail.com