Architecture portfolio by harshad shitole

ARCHFOLIO H A R S H A D

S H I T O L E

31, Prof Telderslaan, 2628VW,Delft, NL harshad.shida@gmail.com +31 654357456 www.shida.in Date of birth : 23rd March,â&#x20AC;&#x2122;86 Nationality: Indian Licensed Architect (IN): # CA/2009/44788 Council of Architecture, India Marital status : Single

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Personal Profile

A recent graduate from Technische Universiteit, Delft with masters in Building Technology and specialization in Facade Engineering. I am self-motivated, creative, ambitious and hardworking person with an ability to adapt to different situations. I am extremely meticulous in technical drawings and documentation supported by good visualization skills and keen interest in building physics and building structures.

Education 2010-2012 MSc in Building Technology, Specialization in Facade Engineering Faculty of Architecture, TU Delft, NL Thesis: Feasibility and application of NEXT Active Facade.

2003-2008 Bachelor of Architecture, Sir J J College of Architecture, University of Mumbai, India Thesis: Aviopolis - Centre for Aviation studies and aerospace Museum.

Work Experience Dec 2011 -Present

Assistant at Free-D Geometries Amsterdam, NL

May 2008 June 2010 Dec 2007 April 2008 July 2006- Present

Architect at Malik Architecture, Mumbai, IN Trainee at Malik Architecture, Mumbai, IN Freelance Architect and as cofounder of SHIDA Mumbai, IN

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NEXT active facade Graduation thesis, TU Delft Project title - Detailed application of NEXT Active Facade.

NEXT is a collaborative platform of facade industry experts

Mentors - Dipl.-Ing. Tillmann Klein Dipl.-Ing. Eric van den Ham

not a product but an idea. It is an open system or a tool box

Time span - Nov 2011 - June 2012

There were previous attempts by different companies to go

This thesis is performed as the finalization of the master degree of the masters in Building Technology, track Faรงade De-

sign at the faculty of Architecture. The topic is about the NEXT Active faรงade and its detailed application. The main objective

of my thesis was to understand the feasibility of NEXT concept in a given condition and working out a detailed application for the system.

Alcoa, TROX, Somfy, Delta Netherlands, Hurks, Cepezed and TU Delft. NEXT deals in decentralized ventilation system. It is like desktop computers with several modules we can choose

from depending on the requirement of the building or client.

for a facade integrated services solutions but the main advantage of NEXT over others is its modular setup. Communication between the players involved in the facade construction

e.g - architects, contractors, advisors, system suppliers etc. becomes very important when it comes to time and cost of construction. A toolbox developed by NEXT as a design tool is a first step to optimise the communication.

cepezed

NEXT ACTIVE FACADE

Harshad Shitole_TU Delft _ Building Technology International Faรงade Masters _ 4121570

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centalized climate system Image courtesy - NEXT

decentalized climate system *Comapny logos are used only for academic purpose

NEXT ACTIVE FACADE

Harshad Shitole_TU Delft _ Building Technology International FaĂ§ade Masters _ 4121570

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NEXT ACTIVE FACADE

Harshad Shitole_TU Delft _ Faculty of Architecture_ Department of Building Technology

Service Integrated Responsive FaĂ§ade

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To understand the applicability of the NEXT concept

two examples were studied as refurbishment proposals. First one was ‘de-Studio’ in Amsterdam and the

second one ‘Polaris’ in Groningen. Different climate

concepts and placement options were derived using NEXT system demonstrating the design flexibility of

the system. Further the energy consumption comparison was carried out between existing building,

building with default refurbishment with centralized climate system and building with NEXT which proved that NEXT system is very energy efficient. In the last

part the detailed product placement layouts were worked out.

PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

Existing column (420x360mm)

L brackets (50x50) 200x200x12 fixing Bracket 75 mm thk soft insulation

Bracket fixing assembly

2 mm thk Aluminium sheet TROX unit (FSL-B-ZUS type)

125mm thk composite panel

ALCOA 2500 PG Unitwall (50x150) (Kawneer)

Harshad Shitole/ TUD / Graduati

The New Kuip : Enfolding 24X7 XXL Workshop, TU Delft Project - Designing the â&#x20AC;&#x2DC;The New Kuipâ&#x20AC;&#x2122; stadium in Rotterdam.

The New Kuip, permeable from all sides yet covered from

Studio coordinator - Michela Turrin

diums which exploit mainly the peripheral functional volumes

Tutors - Prof Ir. K. Oosterhuis, Dr. Ir Joop Paul, Dr. Ir H H Bier, Ir. Jelle Feringa, Ir. A. Borgart, Ir. T. Klein, Ir. S Mulders, Ir. P Nourian, Dr. Ir. A. van Timmeren, Prof. Dr. Ing P. Teuffel, Prof. Ir F. Heinzelmann

Time span - Feb 2011 - April 2011

above, contributes to the city a protected plaza, where everything can take place. In contrary to current examples of stafor supporting public and commercial functions on a no-match

day, the future stadiums explores the potential of adapting the arena for introducing various functions and events that provides the platform for everyday urban activity. Considering the fact that a stadium of 65.000 people is infrequently used for

hosting football matches, filling up the functional time line in order to generate revenue and blend the colossal structure in the urban fabric is one of the biggest challenges faced.

This group project was performed in collaboration with E. Calle, P.Sakkas, T. Bristogiannis. I was responsible for initial

Architectural conceptulization along with all other group members and the structural design of the building

The New Kuip: Enfolding 24/7

FORM STRATEGY PROGRAMME

The New Kuip: Enfolding 24/7 The New Kuip: Enfolding 24/7

The New Kuip: Enfolding 24/7

The New

TU Delft _ Faculty of Architecture _ AR0025 _ XXL Workshop (2010-2011 Q3) Team 5: Bristogianni Telesilla _ Calle Eduardo _ Sakkas Panos _ Shitole Harshad

6. Sustainable design Sustainable design recognizes the interdependence of the built and natural environments; seeks to harness natural energy from biological processes and eliminate reliance on fossil fuels and toxic materials; and seeks to imThe New Kuip: Enfolding 24/7 LEVEL 1 The New Kuip: Enfolding 24/7 SURYH UHVRXUFH HIÂżFLHQF\ The New Kuip: Enfolding 24/7 LEVEL 2

As designers and builders it is our responsibility to create buildings which protect and potentially enhance the enYLURQPHQW SK\VLFDOO\ DQG LQ DQ\ RWKHU SRVVLEOH ZD\ %XLOGLQJV FKDQJH WKH Ă&#x20AC;RZ RI HQHUJ\ DQG PDWWHU WKURXJK XUEDQ HFRV\VWHPV RIWHQ FDXVLQJ HQYLURQPHQWDOSUREOHPV 7KHVH SUREOHPV FDQ EH SDUWLDOO\ PLWLJDWHG E\ DOWHULQJ WKH EXLOGLQJVÂś VXUÂżFLDO SURSHUWLHV In our proposal for the New Kuip aiming for a sustainable construction is our main goal and itâ&#x20AC;&#x2122;s closely integrated LQ WKH GHVLJQ FRQFHSW 6SHFLDO FDUH LV JLYHQ WR WKH XVH RI PDWHULDOV WKURXJKRXW WKH VWUXFWXUH EHLQJ Lightness the RQH ZLWK D VWURQJHVW VLJQLÂżFDQFH DQG GHÂżQLQJ WKH PDWHULDOLW\ DQG YLVXDO DSSHDUDQFH RI WKH DUFKLWHFWXUDO REMHFW Moreover, energy production based on renewable sources, in this case the sun, is also an important part of the VWUDWHJ\ LEVEL 4

LEVEL 5

OVERALL STRATEGIES Energy production by inteJUDWLQJ Ă&#x20AC;H[LEOH PV panels

Light weight tensile surface structure for facade construction Light weight tensile roof structure and cladding

Inner volume of the arena naturally ventilated though JURXQG Ă&#x20AC;RRU JDS DQG IDFDGH openings Green slopes and roofs Reducing urban heat island effects

Earth and ground shaped to form stadium bowl which will be lower in the ground, reducing building costs and the movement of vehicles importing and removing materials 0 materials: Using materials from renewable sources (wooden deck), bulk materials or recycled materials as much DV SRVVLEOH

The textile wrapping of the building is a unifying gesture for the functions such as hotel, community school, sports education

Structure

centre, medical facilities, commercial hospitality and entertainment functions and all the supporting stadium utilities for a foot-

ball match. The intense use of peripheral spaces is achieved by adaptable re configuration of functions with similar functional volumes e.g. VIP boxes can convert to Hotel rooms, the FIFA meeting rooms to school classrooms, and the press and media rooms

to supporting areas of the conference centre, quickly and without requiring excess effort.

TU Delft _ Faculty of Architecture _ AR0025 _ XXL Workshop (2010-2011 Q3) TU Delft _ Faculty of Architecture _ AR0025 _ XXL Workshop (2010-2011 Q3) Team 5: Bristogianni Telesilla _ Calle Eduardo _ Sakkas Panos _ Shitole Harshad Team 5: Bristogianni Telesilla _ Calle Eduardo _ Sakkas Panos _ Shitole Harshad

The New Kuip: Enfolding 24/7 The New Kuip: Enfolding 24/7

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Structural Design

The materialization of facade and roof and the roof structure was result of the demand to merge the building in surrounding instead

of making a â&#x20AC;&#x2DC;Big white elephantâ&#x20AC;&#x2122; in the urban fabric. The most logical step to reduce the building height was to go for the anticlastic

tensile roof structure from which the roof fabric skin was suspended. The modulations of wrapping of the skin was result of the light studies done using Ecotect.

44 44

Structural Design Structural Design

The New Kuip: Enfolding 24/7

Skin

Cladding

e New Kuip: Enfolding 24/7

adding

TU Delft _ Faculty of Architecture _ AR0025 _ XXL Workshop (2010-2011 Q3) Team 5:

Bristogianni T. _ Calle E. _ Sakkas Panos / 4120639 _ Shitole H.

Team 5:

Bristogianni T. _ Calle E. _ Sakkas Panos / 4120639 _ Shitole H

Cladding

TU Delft _ Faculty of Architecture _ AR0025 _ XXL Workshop (2010-2011 Q3)

level, the space grid of points was not longer necessary. In fact, the creation of interpolate curves based

Adaptability

in a collection of points would create a curve of multiple parabolic fragments that would act as a multi-hinged arch, thus as an unstable mechanism. Hence, the curves should be produced having as reference points only their endpoints, to ensure their function as a continuous arch, pinned on its ends.

5.13. Plan showing the functions introduced in the arena during the week and 3D aspects of the reconﬁguration of the interior

Nevertheless, new points of reference emerged on the ring level and the beginning of the 2nd level stands. Soon it was made clear that the ring, as being the boundary curve of an anticlastic surface, would implicate the rolling of the strips and, therefore, a secondary horizontal ring needed to be introduced, at a lower level. The update of the structural design worked in favor of the stability of the structure as the intermediate level reduced the buckling of the previously slender columns. The positioning level of the ring differed in each of the 4 wings of the stadium and was parametrically deﬁned until more information was obtained on the height of the mechanism in its rolled conﬁguration. All in all, the later 3D model was important for visualising the application of the strips elements in space and setting the goals that would guide the computational analysis.

5.2.4.3. Deﬁning the shape of the structural elements The next focus of the research was the optimal curved shape the airbeams would obtain in the 1st, large span conﬁguration. Consultation of relevant literature pointed out the parabola and the catenary curve as the most optimal formations. Although these curves have an almost similar representation, the catenary curve was selected in the end, as it would guarantee the equal distribution of stresses along the airbeam and zero bending moments in each internal section. Taking into account that the catenary curve is also the basis that generates minimal surfaces, the above choice would positively affect further stages of the design that would deal with the optimal shape of the covering membranes. To understand the behavior of the curves, the online application “Active Statics” provided by MIT was used. Using this tool, the relationship between form and reaction forces was established and a set of constraints was formulated to ensure that the produced curves would result to the minimum value of reaction forces. Digital Design and Computation

The maximum use of the stadium will not be achieved unless

the adaptability of the arena is addressed by introducing smaller scale events and activities. A system of inflatable beams and

textile covering enables the division of space into smaller cells

to achieve number of different configurations. Adaptability is approached through the conversion of the peripheral functions and lightweight system of interior partitions rather than displacing the

heavy parts of the structure like the roof or stands. Such an approach is a key factor towards an energy efficient building along with the use of an economical and light material for the building

envelope. Furthermore, taking advantage of extensive surface area of the roof, we introduce lightweight flexible PV panels with south orientation to support the energy needs of the building.

Light

Research Institute: Performance driven design Building design and engineering studio, TU Delft Project: To design a performance driven building for a research institute in The Hague, NL

This project was a result of a collaborative effort with Mar Mu-

Studio coordinator - Ir. Henk Mihl Tutors - Ir. Henk Mihl, Dr. Ir Joop Paul, Ir. A. Borgart, Ir. Ragina Bokel, Ir. M Mijs

ent climatic requirements. Light played the major role in de-

Time span - April 2011 - June 2011

noz Catalina and Prashanth Raghunath. Conceptulization of

the building form was a result of the optimization of the differfining the volumetric characteristics specially the orientation of the central atrium. Parametric approach helped define the most light efficient atrium orientation.

The daylight has been the main driver in the design of our building. Our initial approach was done

from the point of view of daylight and energy saving which was developed in a performance-driven

design. Daylight does not only provide buildings of

a more comfortable environment but it also reduces the energy consumption. This is particularly relevant in winter, when buildings of this type spend 20% of their energy in heating and 30% in lighting.

The illuminance values in winter are around five times lower than in the summer and that is why the focus was more on the winter scenario.

To find the optimized shape and orientation

of the atrium to get maximum amount of light parametrical analysis was carried out using Grasshopper+Geco+ecotect.

Structure :

Climate :

The design for the structural system revolved around the hyper-

The main approach for the climate design of the project was find-

focus from architectural point of view. Due to the complex form of

visual, and qualitative experience of the occupants become the fo-

boloid geometry of atrium structure, which was one of our main the hyperboloid, it almost became a necessity for us to analyse the

structure on GSA . Manual calculations could be limited to stability checks, some basic axial forces and design of details. But to

understand if and how any forces are being transferred through

the hyperbolide, GSA was necessary. The comflor deck system not only reduced the thickness of the floor slab but also allowed the integration of building services in structure.

winter_3 days

winter_1 week

ing climate mitigation systems which make the thermal, acoustic,

cus of the undertaking. In addition, solutions which were sought attempted to reduce the energy consumption and ecological footprint

of the building overall. The approach was therefore grounded in

finding natural solutions that would give better air quality, reduce

the need for mechanical systems, and find more sustainable solutions that would take advantage of conditions existing on the site

and those generated by the use of the building itself. The computer program Capsol was used to simulate the heat flows.

winter_3 months

summer from 11th June_1 week

wooden plank

A' coronation plate

aluminum frame

perforated aluminum sheet (wrapped around frame)

PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

fixed connection insulation

damp proof layer

top I profile of inverted truss (to increase exhibition space floor height)

mortar layer for slope (3%)

tube profile interior welding

north fac a de referenc e drawing

U profile to embrace mullion window mullion sandwich panel

gravel

PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

bottom I profile of inverted truss

additional connection to reduce span

suspended ceiling

PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

decking sheet

north fac a de roof detail_1/5

engineered wood bamboo (floor finish)

insulation

leveling layer

edge box steel profile ventilation box using radiant heat through plates to treat air in winter

capilary floor heating damp proof layer

steel H beam

decking sheet and poured contrete

edge I steel profile aluminum frame perforated aluminum sheet (wrapped around frame) connection with horizontal and vertical tolerance

fixed connection thermal break

sandwich panel

tube profile interior welding U profile to embrace mullion

window mullion

suspended luminaire

suspended ceiling_acoustical gypsum panel

north fac a de ty p ic a l detail_1/5 PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

NORTH FACADE DETAILS

GROUP D__Diana Roitman / 41120213 __ Prashanth Raghunath / 4129253 __ Harshad Shitole / 4121570 __ Mar Mu単oz Catalina / 4116194

SOUTH FACADE DETAILS

PRODUCED PRODUCED BY BY AN AN AUTODESK AUTODESK EDUCATIONAL EDUCATIONAL PRODUCT PRODUCT

wooden plank plank wooden

A A'

coronation plate plate coronation sandwich panel panel (1side (1side cladded) cladded) sandwich PRODUCED BY AN AUTODESK EDUCATIONAL PRODUCT

insulation insulation fixed connection connection for for cladding cladding fixed damp damp proof proof layer layer fixed perforated perforated aluminum aluminum panel panel on on aluminum aluminum frame frame fixed top top II profile profile of of inverted inverted truss truss (to (to increase increase exhibition space space floor floor height) height) exhibition

gravel gravel

o uth fac s a de referenc e drawing

mortar layer layer for for slope slope (3%) (3%) mortar

Facade : The variation in the facade typology for all 4

directions of the building is a reaction to the climate and context. South facade needed the maximum protection from harsh sun which

resulted in the perforated metal second skin, which was not necessary for other facades. Concrete core heating was supported by the

bottom bottom II profile profile of of inverted inverted truss truss

DUCATIONAL PRODUCT

suspended ceiling ceiling suspended

additional additional connection connection to to avoid avoid buckling buckling

window window mullion mullion

decking sheet sheet decking

o uth fac s a de roof detail_1/5

ventilation ventilation box box support support

plate plate connected connected to to the the II profile profile web web (tolerance (tolerance connection) connection)

insulation insulation

engineered engineered wood wood bamboo bamboo (floor (floor finish) finish)

ventilation box box using using radiant radiant heat heat through through ventilation plates to to treat treat air air in in winter winter plates

capilary capilary floor floor heating heating

leveling leveling layer layer

steel steel H H beam beam

damp damp proof proof layer layer

edge edge II steel steel profile profile

decking decking sheet sheet and and poured poured contrete contrete

grille grille

fixed fixed connection connection through through steel steel profile profile aluminum tube tube profile profile (5mm) (5mm) aluminum

aluminum C C profile profile (5mm) (5mm) aluminum

perforated aluminum aluminum sheet sheet perforated

sandwich panel panel sandwich thermal thermal break break sliding panel panel sliding

sandwich sandwich panel panel tube tube profile profile interior welding interior welding U U profile profile to to embrace embrace mullion mullion

steel plate plate welded welded to to main main beam beam steel

opening window window with with opening aluminum frame frame aluminum

suspended suspended ceiling_acoustical ceiling_acoustical gypsum gypsum panel panel

suspended suspended luminaire luminaire

steel steel strip strip to to avoid avoid deflection deflection of of cantilever cantilever beam beam

sliding mechanism mechanism sliding

aluminum aluminum mullion mullion

fixed fixed panel panel

PRODUCED PRODUCED BY BY AN AN AUTODESK AUTODESK EDUCATIONAL EDUCATIONAL PRODUCT PRODUCT

heating and cooling boxes integrated in facade.

VRXWK IDFDGH W\SLFDO ÀRRU GHWDLOB PRODUCED BY BY AN AN AUTODESK AUTODESK EDUCATIONAL EDUCATIONAL PRODUCT PRODUCT PRODUCED

GROUP D__Diana Roitman / 41120213 __ Prashanth Raghunath / 4129253 __ Harshad Shitole / 4121570 __ Mar Muñoz Catalina / 4116194

Flex cavity facade : Innovative facade prototype Bucky Lab, TU Delft Project: To design, develop and build a innovative facade prototype for a building.

The assignment was to design an innovative building facade

Studio coordinator - Ir. K J Vollers, Ir. P. M. J

terialized and developed to the level of final design. The final

van Swieten Tutors - Prof. Dr. Ir. M. Eekhout, Ir. A. Borgart, Ir. Ragina Bokel, Dr. Ir. F. Veer, Kees Baardolf

for a 10 storey office building. The project started with the design of the architectural facade concept, which will be matest was the realization of a full scale prototype of a part of the facade. This project was carried out in collaboration with dipl. Arch. Lauris Birznieks.

The Flex cavity facade is a symbiosis between classical

facade requirements such as durability and thermo efficiency, aspects of contemporary significance like sustainability and individual challenge of reaching desired

aesthetical quality. After extensive research about building skin especially the second skin in context of building physics the concept of a flex facade was developed which can respond to the exterior environmental factors

such as air temperatures, wind, sun, rain etc. and also

the disadvantages of the conventional double skin facade such as over heating in the cavity etc.

MediaTecture - In and Out Future Facade Studio, TU Delft Project: To develope a innovative future facade concept.

In this ‘Future Facade Studio’ I tried to explore the effects,

Studio coordinator / Tutor - Ir. Tillmann Klein

facade into a ‘Media Facade’ which can be interactive from

Time span - July 2011 - August 2011

possibilities and limitations of future media facades. I have

tried to integrate all functional and aesthetical functions of a outside to the public and also from inside to the user simul-

taneously. I have tried to explore possible options to make it duel interactive using present and upcoming technologies. OLEDs was the focus of research

mirror

Curtain/ Sunscreen

Operable window

mirror

Curtain/ Sunscreen

Operable window

Books Soft board Books Soft board Computer

Radiator

Mediatecture - ‘In and Out’ Mediatecture - ‘In and Out’ Interactive and Intelligent building skin

Harshad Shitole_TU Delft _ AR3B420_Future Facade Design Harshad Shitole_TU Delft _ AR3B420_Future Facade Design

Interactive and Intelligent building skin

Radiator

Computer

2. Initial concept

Initial concept

There were two pints of departures for the concept, Initial concept first one developed while questioning the very existResult in of size 2.ence Initial concept of the equipments and elements my constraint house Result of size constraint Thereme. were two(2) pints of departures for room the concept, around Fig. shows interior of my with + Ventilation first one developed while questioning the very operexistmany physical objects such as mirror, curtain, + Ventilation enceand of the equipments and elements in my house able transparent window, radiator, Option 1ventilator, Option 1 around me.softboard, Fig. (2) shows offimy room with computer, books,interior lighting xtures etc. manyof physical objects such as mirror, curtain, operMost them are not dependent of others existence able andof transparent window, radiator,if ventilator, in terms its function. For example, I am closing computer, softboard, books, xtures the curtains I really don’t carelighting whats fithe viewetc. outside Most are not of others existence or if I of amthem opening the dependent window it doesn’t matter if my Option 2 in terms is ofon its or function. example, radiator not or ifFor I am working myclosing computer Optionifon 2I am the curtains I really don’tmy care whats the view outside it doesn’t matter where mirror is placed. I use the or if Ifiam opening thenight window it doesn’t if my light xtures only at when there is matter no natural radiator on orthe notday or iftime I amthese working on my light, so is during fixtures or computer equip-

it doesn’t where my mirror is placed. use the ments justmatter occupy the physical space of my Iroom. If xtures only at night when there natural Ilight am fisleeping on my bed, existence of isallno the things light, sohas during the day time fixtures or equipabove no meaning in thethese physical space of my + PV ments How just occupy theofphysical space of my room. If room. to get rid the physical + PVelements with no I am sleeping my bed, of allisthe things in functional use on at that pointexistence of time? This possible above has world no meaning theinphysical space the virtual but diffiin cult physical world.ofIt my could Option 3

2. Interior Photo -311, Roland Holstlaan, Delft

Option 3 room. How to get could rid of blur the physical elements with no be possible if we the boundaries between functional two worlds.use at that point of time? This is possible in the virtual world but difﬁcult in physical world. It could 5 be possible if we could blur the boundaries between two worlds.

2. Interior Photo -311, Roland Holstlaan, Delft

PLAN PLAN

PV PV

PV PV PV PV

SECTION SECTION

43 43

17 17

Transparent heating

The very existence of the equipment and elements in any living

Unitized system - While developing an unitized system the integra-

many physical objects such as mirror, curtain, operable and transpar-

Photovoltiac, sunscreening and suffi cient amount of insulation need

space can be questioned. Picture shows interior of my room with ent window, radiator, ventilator, computer, softboard, books, lighting fixtures etc. Most of them are not dependent of others existence in

terms of its function. For example, if I am closing the curtains I really

don’t care whats the view outside or if I am opening the window it doesn’t matter if my radiator is on or not or if I am working on my computer it doesn’t matter where my mirror is placed. How to get rid of the

physical elements with no functional use at that point of time? This is

possible in the virtual world but difficult in physical world. It could be possible if we could blur the boundaries between two worlds. One of

the ways to do it in future if we could integrated the virtual capabilities of OLED or similar technologies in the rigid nature of our building facades.

tion of functional characteristics like Heating, cooling,ventilation,

to be considered. To incorporate ventilation, simple mechanism like

sliding or opening the OLED can be considered. It becomes tricky when it comes to integration of photovoltiacs. Usually sun light falling on the facade is never perpendicular but at some angle, vertically and also horizontally (in plan and section). One of the ways to make

utilize the maximum sunlight falling on the facade is to making the

part of the facade face upwards and sidewards. Geometrically combining both plan and section we get a surface made out of 4 rhombus geometries. After combining and repeating the rhombus geometry we

get a 3 dimensional Tessellated surface. To make a unitized system, it was divided in square grid, which in turn gave 11 faced geometry.

EVOLO : Project IndoStar Competition | SHIDA ‘Project: INDOSTAR’ freestands on the principles of emer-

architecture of Indostar is paradoxically the assemblage of

treads on a dangerous play field, the thin zone of blur between

ules, where all the intelligent systems of the vertical commu-

gence & perpetuates on the demands of variable change. It the naiveté of the digital avant garde, the loosest tethers of

engineering physics &the profit oriented Real Estate. The site is a nondescript village in India, off a metropolis. Sprouting

from ‘Kepler conjecture’ (ca.1611) on the highest achievable density in packing of spheres, the

complex VOIDs… voids between spherical habitable modnity run through, including the structural prototypes; their logic

evoking a techno-optimism from a certain filmic imagery. Each

‘void-structural’ prototype is proposed to be used-on-site for roughly 30 years, being replaced & recycled.

Based on FCC packing, layers of prefab spherical units are

livelihoods causing the single most drasticchanges within a

coding 12 unique plug coordinates, allowing instant installa-

to diplomatically spearhead the near-future urbanisms that

plugged-in-place (PIP) around the voids, facilitated by bartion & dismantling. 50 or so ‘Build-Bots’ patrol in & around

the structure as they install custom-fabricated units, repair the damaged & dismantle the deserted units making Indostar an

architecture in perpetual state of ‘building’, continuously ‘Reforming’ as per it’s site demands (local weather, structural integrity, lateral forces, optimal harvesting of solarpower & rainwater etc.). Individual units with its thick greenery facing the

exterior form loosely clustered garden-houses recalling the

mythical Babylonian towers. An estimated period for a single sphere is around 15-20 years, the socio-biological time a kid requires to grow independent & leave home to pursue their

typical nuclear family structure in India. Indostar is imagined ‘could’ be. An Architecture in, by & for an emergent India…

that is healing the wounds of the last centuries promisingly well as if they were urban fables, while wearing its morality light yet firm. One where the dramatically heroic aggrades

out of zillion mundanes, almost unnoticeable, humming of its inaudible clanking; best serving the happily single & 24X7online, ‘disposable generations’ to come, that will never again need to know how to stitchup a loose button.

Residence at Alibag I, IN Malik Architecture

(www.malikarchitecture.com)

Project: Private residence for Mr. Ashok Kapur

The site for this home is a hill in Alibag (India), one which en-

Project team - Ar. Arjun Malik (Project Architect), Ar. Jigar Mehta, Ar. Ganesh Kugaji, Ar. Harshad Shitole

ing it, but of the sea and the skyline of Mumbai in the distance.

Responsibility - In the initial phase of design I assisted in architectural design and later in detail drawings, consultant

coordination and site supervision over the span of 18 months.

joys a stunning view, not only of the rolling contours surroundConceptually, the design of the home is a departure from the “stepped terrace` typology that one would conventionally

employ on a heavily contoured site. Instead, chose to deconstruct a cuboid that is tilted and suspended over the ground

and appears to simultaneously ‘float’ and ‘flow’ down the hill. The creation of singular sensory experiences has been the

primary organizing and sculpting vector. Numerous geometric inflections and articulations are designed to engage the senses in unconventional ways.

Residence at Alibag II, IN Malik Architecture

(www.malikarchitecture.com)

Project: Private residence for Mr. Ashok Kapur

The sister house to the previous one is under construction.

Project team - Ar. Arjun Malik (Project Architect), Ar. Jigar Mehta, Ar. Suzanna Machado, Ar. Harshad Shitole

slopes, it is submerged in the ground enough to explore the

Responsibility - In the initial phase of design I assisted

in concept development by visualization and maodel making.

I was also part of the team which worked out the detail drawings for construction.

Unlike the first house which seems to be floating on the hill

stunning views of the marvellous landscape around and not to

block the privileged views of the first house. Unconventional

volumetric spaces framed by inclined concrete walls compliments the â&#x20AC;&#x2DC;motionâ&#x20AC;&#x2122; characteristic of the first house.

Private residence, IN Personal project / SHIDA

Project: Private residence for Mr. Ahuja

The client brief rendered the changing definition of joint Indi-

Project team - Ar. Harshad Shitole, Ar. Kingshuk Datta

and their respective families who wanted to stay like a joint

Responsibility - Everything. From finding the clients to convincing them to build an unconventional house to designing, drawings, site supervision and at some point dirtying my

hands to show the unskilled workers how to build. Founding

partner of SHIDA Ar. Kingshuk Datta also gave some important architectural inputs.

an family structure. This house was designed for two brothers

family but without compromising their private family space.

The common courtyard framed by the two inclined â&#x20AC;&#x2DC;deadâ&#x20AC;&#x2122; con-

crete walls depicts the interdependency of the families but respecting the privacy. Because of some financial problems completion of this project is delayed.

Photography

Gateway to the changing immortality of coincidental compositions.