Jaspall (Jay) Gill Architecture Portfolio

17 Dafoe Crescent Brampton | 647.717.9429 | [email protected]

JASPALL GILL

ARCHITECTURE

PORTFOLIO

Curriculum Vitae Community Center 1Student Residence

1 Curriculum Vitae

Thesis

Beach Chair InstallationLookout TowerCommunity Center 2 Chinese Spa

Professional ExperienceEducation

Snyder Architects Inc. 8 Months, 2012-2013St.Mary Catholic Elementary School Assistant Construction Manager (9 Million) Responsible for contract administration, interior design, SI’s, CO’s, and coordination of shop drawings,

Milton 5 Catholic Elementary School Draftsman (14 Million)Responsible for detailing, annotating construction drawings, and Revit modeling Various Reno’s on Toronto Catholic SchoolsAssistant Construction Manager (Approx 1 Million each)Responsible for interior design, SI’s, coordination of shop drawings, and contract administration

Everstrong Construction Ltd. 4 Months, 2014Milton 7 Catholic Elementary School Project Coordinator (10 Million)Responsible for compiling information, issuing contracts and proposing change orders

Milton 5 Catholic Elementary School Project Coordinator (14 Million)Responsible for compiling information, directing contractors and occasional site visits (I worked on this project both on the architect’s and contractor’s side) Tiger Jeet Elementary School AdditionProject Coordinator (1 Million)Responsible for compiling information, issuing contracts and proposing change orders, gathering quotes`

Atelier Small Pte. Ltd. 4 Months, 2015ILight Marina Bay Festival DesignerResponsible creating design proposals, including drawings and renders.

Nathan Place CondoDesignerResponsible creating design proposals, including drawings and renders. Istanbul Community Market CompetitionDesignerResponsible creating design proposals, including drawings and renders.

Master of Architecture University of Waterloo 2016

Bachelor of Architectural ScienceRyerson University 2015 LEED Green AssociateCaGBC 2012

Fundamentals of University TeachingUniversity of Waterloo 2016

Abroad Study in ChinaSoochow University 2014

JASPALL GILLUniversity of Waterloo, Master of Architecture Ryerson University, Bachelor of Architectural ScienceLEED Green [email protected]

Specialties Skills Volunteer Work Aspiring Goals

Project ManagementMost of my experience takes place during the construction phase for most of the projects I have worked on. I have managed construction as both while employed by contractor and project manager

Institutional DesignI have a full year of experience dealing with K-12 public schools. For a school in Milton I was employed at an Architecture firm during the Design and CD phase and then sought employment at the GC company that managed its construction and worked on the project from conception to delivery.

Revit CollaborationDuring our third year in school our team was tasked with creating a full set of construction drawings. This included everything from schedules, details, wall sections and annotated plans to industry level standards for a commercial building. I lead the team in setting up the file and teaching the members how use annotations, and create advanced completely linked schedules

Residential DesignI have experience dealing with clients requesting custom home designs in Singapore.

Design VisualizationEvery render in this portfolio, including those done in a collaborative setting, have been done my me.

FabricationLaser Cutting3D Printing Wood CNC Routing

SoftwareRevitAutoCADAdvanced AcrobatPhotoshopInDesignIllustratorLumion (animations)Rhino + VRayGrasshopperSketchup

OtherSketchingHand DraftingLightingPhotographyPublic SpeakingClassroom DesignProduct ResearchArduino programming

325 Magazine Position: Sponsorship Coordinator. A volunteer club to promote Ryerson Architecture by producing a magazine featuring student work

CANstruction A charity competition to design a sculpture out of cans to be donated

AIAS RyersonPosition: Event Coordinator. A club meant to foster an architecture community within Ryerson in collaboration with the AIAS network in the states.

AIAS Mentorship ProgramA initiative to mentor first year students to help guild them.

Spec Writing I feel it gives you a new level of control and confidence in the design and cost management of the project.

Energy Modeling I feel this will be a very necessary skill with the environment increasingly driving economics

Real World Design With Digital FabricationI have a lot of knowledge on how to laser cut and CNC items but I don’t know how to efficiently implement it into any design.

Estimating Project Costs

NCARB Certificate

LEED AP

JASPALL GILL

.

FitnessPhotography Dancing

Project Coordina n

Revit Architecture Design

Ins tu al Design

Design

Industrial Design

4 2015 JUNIOR DESIGNERDesigning residen�al renova�ons, designing compe��on submissions, residen�al interior design, 3D visualisa�on, furniture design, and landscape design.

ATELIER | SMALL PTE. LTD. (Architecture Firm in Singapore)

4 2014 PROJECT COORDINATORCoordina�ng informa�on between sub trades and consultants, reviewing shop drawings, issuing purchase orders and resolving conflicts between various par�es.

EVERSTRONG CONSTRUCTION LTD. (Construc�on Company in Milton)

82013 & 2012 INTERNDra�ing Construc�on drawings, designing various building components, aiding in construc�on management, and construc�on administra�on.

SNYDER ARCHITECTS INC. (Architecture Firm in Toronto)

WORK EXPERIENCE (months) SPECIALTIES

)

, Canada)cience

)

2014Soochow University (Suzhou, China Study Abroad in China

EDUCATION

2015 Ryerson University (Toronto Bachelor of Architectural S

2016 University of Waterloo (Waterloo, Canada Master of Architecture (Expected)

GrasshopperAdobe IllistratorAdobe Indesign

Public SpeakingClassroom Design

Research Autodesk AutoCAD

Adobe PhotoshopRhino 3D + Vray

SKILLS

HOBBIES

Seoul (1.5 weeks)

Suzhou (2.5 weeks)

Beijing (2 weeks)

Singapore (4 months)Kuala Lumpur (1 month)

Shanghai (2.5 weeks)Toronto (22 years)

Montreal (3 weeks)

Georgia (3 weeks)

Phoenix (2 weeks)

Chicago (3.5 weeks)

PAST TRAVEL EXPERIENCE JASPALL SINGH GILL

[email protected]

[email protected]

+1 647 717 942917 Dafoe CrescentBrampton, Ontario,

Canada L6Y2L1

M.Arch., B.Arch.Sc., LEED Green Assoc. Jaspall Gill is a Master of Architecture graduate from the University of Waterloo also holding an undergraduate degree in architecture from Ryerson University. He is a LEED Green Associate with over a year of experience in a series of construc�on/architecture firms.The majority of his experience lies in ins�tu�onal design and construc�on. His strongest skills are visualiza�on, construc�on management and building science.His current goal is to gain employment in a large firm and accumulate his hours to become a licensed architect.

ThesisIndividualThis thesis explores a design of a colony in outer space able to comfortably sustain a dense growing population of 1 million inhabitants. This visionary colony, will exist in the Moon-Earth Lagrange Point 1 and aims to take advantage of the unique physical, phenomenological, and technological aspects of space while providing a level of comfort on par with that of a first world city. This paper engages the practice of architecture by exploring past our current ability of habitation, enabled by being surrounded in an outer space context, ultimately trying to answer the question of ‘what sequence of events will allow for self-sustaining, expanding, city in space and what type of life may we lead within?’ The major axioms in this thesis will revolve primarily around four categories: the potential technology required, the abstract mechanics of how various systems would interact to support life, the timeline that would require a space colony to be built and the urban design that a city of the sky should enjoy. The goal is to synthesize these three areas and ultimately determine the schematic design approach of a space colony. To this end topics relating to, energy production, mining, ecological footprint, modern scenes of fantasy, mechanical and structural engineering, alternative housing, linear cities and political governing will be explored topics of study. The overarching goal of all of this is to discover how we can to build a habitat in orbital space based on our current and projected technology and to explore the emerging field of space urbanism.

.

FitnessPhotography Dancing

Project Coordina n

Revit Architecture Design

Ins tu al Design

Design

Industrial Design

4 2015 JUNIOR DESIGNERDesigning residen�al renova�ons, designing compe��on submissions, residen�al interior design, 3D visualisa�on, furniture design, and landscape design.

ATELIER | SMALL PTE. LTD. (Architecture Firm in Singapore)

4 2014 PROJECT COORDINATORCoordina�ng informa�on between sub trades and consultants, reviewing shop drawings, issuing purchase orders and resolving conflicts between various par�es.

EVERSTRONG CONSTRUCTION LTD. (Construc�on Company in Milton)

82013 & 2012 INTERNDra�ing Construc�on drawings, designing various building components, aiding in construc�on management, and construc�on administra�on.

SNYDER ARCHITECTS INC. (Architecture Firm in Toronto)

WORK EXPERIENCE (months) SPECIALTIES

)

, Canada)cience

)

2014Soochow University (Suzhou, China Study Abroad in China

EDUCATION

2015 Ryerson University (Toronto Bachelor of Architectural S

2016 University of Waterloo (Waterloo, Canada Master of Architecture (Expected)

GrasshopperAdobe IllistratorAdobe Indesign

Public SpeakingClassroom Design

Research Autodesk AutoCAD

Adobe PhotoshopRhino 3D + Vray

SKILLS

HOBBIES

Seoul (1.5 weeks)

Suzhou (2.5 weeks)

Beijing (2 weeks)

Singapore (4 months)Kuala Lumpur (1 month)

Shanghai (2.5 weeks)Toronto (22 years)

Montreal (3 weeks)

Georgia (3 weeks)

Phoenix (2 weeks)

Chicago (3.5 weeks)

PAST TRAVEL EXPERIENCE JASPALL SINGH GILL

[email protected]

[email protected]

+1 647 717 942917 Dafoe CrescentBrampton, Ontario,

Canada L6Y2L1

M.Arch., B.Arch.Sc., LEED Green Assoc. Jaspall Gill is a Master of Architecture graduate from the University of Waterloo also holding an undergraduate degree in architecture from Ryerson University. He is a LEED Green Associate with over a year of experience in a series of construc�on/architecture firms.The majority of his experience lies in ins�tu�onal design and construc�on. His strongest skills are visualiza�on, construc�on management and building science.His current goal is to gain employment in a large firm and accumulate his hours to become a licensed architect.

Initial habitation modules. This will grow into a double helix. The two modules need to be made in pairs in order to maintain complete balance.

This image illustrates how each module will grow continuously but never conflict with each other. The solid colour illustrates the habitation modules

and the clear illustrates the agricultural modules.

Initial habitation modules with the added modules for agriculture. The colony as a whole when the agriculture is added will grow as a quadruple helix to form a cylinder. The two agricultural modules also need to be made in pairs

in order to maintain complete balance. They do not need to match the mass of the habitation modules.

The completion stage, that includes the agricultural areas and the habitation areas. All the modules line up to form a cylinder

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Population Density of the

agriculture mods

Service Population

Module Division 8

Population of all Agriculture

Modules

Population of all Service Modules


Modules per ring


per ring

Overall Population

Agriculture Space Population

Division 9

Space between ducts

Housing Stacks Required

Population Per Ring

Number of Rings For Agriculture 3

Housing Stacks Required Per

Module

Housing Stack Cluster Required

People per Housing Stack

Housing Stack Share 12

Housing Stack Space Required

Per Module


per Module

Number of Modules 4

Housing Stacks in a Cluster 29

Open Area per Cluster


per Ring

People Per Cluster

Total Area of Housing Stack

Cluster


per Module


Housing Stacks Required per

Ring

Total Space Required

Space left for other things

Area per Module

Land available

Land available

Space left for other things Per

Module


Land available

Population Density of the service mods

Length of each Module 5

Linear Width of Colony 6

m2 per Tree

Length of each ring

Ducts running Widthwise

Ducts running lengthwise

Space between ducts

Ducts running Heightwise



Number of Ducts required

Height of Enclosure 7

Desired Duct Cross Section

Desired Air Speed (m/s)

Flow Rate (m3/s)

Force Created by the Fan

Desired Air Speed (km/h) 45

Energy use by the fan per day W

Energy use by the fan per day kWh

per mod

Total energy used per service

module per day

Amount of Helium 3 required per mod per day

Total energy used per Service

module Watts

Total energy used per Service mod

per year

kWh per day per service module

Energy Use Per Service Module

per day

Population of one Service Module

Energy Use Per Person per day

47

Food Generated Per Service Mod

Water Usage Per module per day

Oxygen Used Per mod

Water Usage Per Person per day

48

Water Usage Per Agricultural

module per day

kWh per day per agricultural

moduleWater USe per

day

Peanut Carbohydrate

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Land Use

Crop land needed

Crop land needed

Mass Needed

Total Land needed

Land Use

Land Use

Land Use

Land Use

Land Use

Mass Needed

Oats Carbohydrate

Total Amount required

Carbohydrate

Carbohydrates Mass Generated

Per Mod


Carbohydrate


Carbohydrate


Carbohydrate


Carbohydrate


Carbohydrate

Consumption Age bracket 30 to



module per dayTotal Amount

required Carbohydrate

Soy bean Carbohydrate

Ground Beef Carbohydrate

Potato Carbohydrate

Brown Rice Carbohydrate

Peanut Carbohydrate

Flax Seed Carbohydrate

Coconut Oil Carbohydrate

Ground Chicken Carbohydrate

Mass Needed

Land Use

Mass Needed

Total Food Generated for the

Colony

Protein Mass Generated Per

mod

Fat Mass Generated Per

mod

Food Generated Per Agriculture

Mod

Number of Rings For People 2

Total Helium 3 Required for the

colony

Volume of the total habitation

space

Surface area of the Colony (capped)

Volume of the total Colony

Volume of a Ring

Volume of the total Agriculture

space

Volume of a Module

Radius of colony

Flow Rate

Flow Rate

Flow Rate (L/s)

Air changes per hour

Air changes per week 43

Flow Rate (m3/s)

Flow Rate (L/s)










per mod

Total energy used per Agricultural module per day


Total energy used per Agricultural module Watts

Total energy used per Agricultural

mod per year

Energy Use Per Agricultural

Module per day

Amount of Helium 3 required per mod per year

Share of Energy Generated

Through Fusion

Helium 3 Fusion YeildArea of solar

panels needed per module

Total energy used per Service rings

per year


Through Solar

Efficiency of solar panels 50

Area of solar panels needed

per module

Desired Duct Diameter 44

Linear Velocity Required for 1g

Surface area of one module (not

capped)

Surface area due to Mirrors

Surface area of side always

pointing towards sun Total Radiation

gain from the sun

Energy output from the to the

average distance from the sun

(same distance as earth)

Total Radiation gain from the sun

in kWh


Total Radiation gain

Energy needed to be radiated out to

equalize temp

Radiation Conductivity 42

Energy lost through radiation per module per

day

Watts lost through radiation

per module

Average Temp

Temperature min (at night) 40

Surface area of one ring

Seconds Per Rotation

Rotations Per Min.


Mass Needed

Mass Needed

Protein

Land Use

Ground Beef Protein

Total Amount required Protein

Soy bean Protein

Ground Chicken Protein

Potato Protein

Peanut Protein

Flax Seed Protein

Coconut Oil Protein









Live stock land needed Live stock land

needed

Land Use

Total Land needed

Increase in yeild

Levels of Land Required

Crop land needed


Distance between levels

Mass Needed

Mass Needed

Mass Needed

Water USe per day

Peanut Fat

Total Amount required Fat








Ground Beef Fat

Potato Fat

Brown Rice Fat

Oats Fat

Flax Seed Fat

Coconut Oil Fat

Ground Chicken Fat

Soy bean Fat

Consumption Age bracket 80+

Age bracket 80+

Consumption Age bracket 70 to 79

Age bracket 70 to 79














Age bracket 0 to 9

Waste Per Food Eaten


Live stock land needed


kWh per litre 49

Minimum vegitation Required

Oxygen Used Per Person

Total Daily production of

Oxygen

Production per 1m2 of grass

Tree Production of oxygen per mod per day

Production of oxygen per tree

per day

Trees per mod

Total energy used per Service Mod per year Watts


Land Used

Land for water Ponds

Land Available

Land Left for Other things



Land for Offices

Land for Residential

Reduction of Land available due to

infrastructure 11


Land for Offices


Per ModuleTotal Space

Required Per Module

Office Space Required

Total Area of Office Cluster

Office Cluster Required

Office Cluster Required per

Module


Offices Required


People Per Cluster

Open Area to Office footprint

37

Office Footprint M2

Office Units Per Floor 34

Average Office Size 33

People Per Office Unit 32

People per Office

Floors Per Office 35

Total Height of Office

Height Per Floor 38

Population Density Per

Cluster (people/ m2)

Office Required Per Module

Office Share 39

Office Space Required Per

Module

Width of Pond from the edge 24

Land for Offices

Land Used per Module

Land in mod available for

farming



Total Space Required Per

Module


Module




Housing Stack Footprint M2

Housing Stack Units Per Floor

27

Average Housing Stack Size M2 26

Open Area to Housing Stack footprint 30

Floors Per Housing Stack

28

People Per Housing Stack

Unit 25

Total Height of Housing Stack

Height Per Floor 31

Population Density of the

agriculture mods

Service Population

Module Division 8


Modules



Modules per ring


per ring

Overall Population

Agriculture Space Population

Division 9

Space between ducts

Housing Stacks Required

Population Per Ring

Number of Rings For Agriculture 3


Module


People per Housing Stack



Per Module


per Module

Number of Modules 4




per Ring

People Per Cluster

Total Area of Housing Stack

Cluster


per Module


Housing Stacks Required per

Ring



Area per Module

Land available

Land available

Space left for other things Per

Module


Land available


Length of each Module 5

Linear Width of Colony 6

m2 per Tree

Length of each ring



Space between ducts





Height of Enclosure 7



Flow Rate (m3/s)





per mod


module per day


Total energy used per Service

module Watts

Total energy used per Service mod

per year

kWh per day per service module

Energy Use Per Service Module

per day

Population of one Service Module

Energy Use Per Person per day

47

Food Generated Per Service Mod

Water Usage Per module per day

Oxygen Used Per mod

Water Usage Per Person per day

48

Water Usage Per Agricultural

module per day

kWh per day per agricultural

moduleWater USe per

day

Peanut Carbohydrate

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Water USe per day

Land Use

Crop land needed

Crop land needed

Mass Needed

Total Land needed

Land Use

Land Use

Land Use

Land Use

Land Use

Mass Needed

Oats Carbohydrate


Carbohydrate

Carbohydrates Mass Generated

Per Mod


Carbohydrate


Carbohydrate


Carbohydrate


Carbohydrate


Carbohydrate

Consumption Age bracket 30 to



module per dayTotal Amount

required Carbohydrate

Soy bean Carbohydrate

Ground Beef Carbohydrate

Potato Carbohydrate

Brown Rice Carbohydrate

Peanut Carbohydrate

Flax Seed Carbohydrate

Coconut Oil Carbohydrate

Ground Chicken Carbohydrate

Mass Needed

Land Use

Mass Needed

Total Food Generated for the

Colony

Protein Mass Generated Per

mod

Fat Mass Generated Per

mod

Food Generated Per Agriculture

Mod

Number of Rings For People 2

Total Helium 3 Required for the

colony

Volume of the total habitation

space

Surface area of the Colony (capped)

Volume of the total Colony

Volume of a Ring

Volume of the total Agriculture

space

Volume of a Module

Radius of colony

Flow Rate

Flow Rate

Flow Rate (L/s)



Flow Rate (m3/s)

Flow Rate (L/s)










per mod

Total energy used per Agricultural module per day


Total energy used per Agricultural module Watts

Total energy used per Agricultural

mod per year

Energy Use Per Agricultural

Module per day



Through Fusion

Helium 3 Fusion YeildArea of solar

panels needed per module

Total energy used per Service rings

per year


Through Solar

Efficiency of solar panels 50

Area of solar panels needed

per module


Linear Velocity Required for 1g

Surface area of one module (not

capped)


Surface area of side always

pointing towards sun Total Radiation

gain from the sun

Energy output from the to the

average distance from the sun

(same distance as earth)

Total Radiation gain from the sun

in kWh


Total Radiation gain

Energy needed to be radiated out to

equalize temp

Radiation Conductivity 42

Energy lost through radiation per module per

day

Watts lost through radiation

per module

Average Temp

Temperature min (at night) 40

Surface area of one ring

Seconds Per Rotation

Rotations Per Min.


Mass Needed

Mass Needed

Protein

Land Use

Ground Beef Protein


Soy bean Protein

Ground Chicken Protein

Potato Protein

Peanut Protein

Flax Seed Protein

Coconut Oil Protein









Live stock land needed Live stock land

needed

Land Use

Total Land needed

Increase in yeild


Crop land needed



Mass Needed

Mass Needed

Mass Needed

Water USe per day

Peanut Fat









Ground Beef Fat

Potato Fat

Brown Rice Fat

Oats Fat

Flax Seed Fat

Coconut Oil Fat

Ground Chicken Fat

Soy bean Fat

Consumption Age bracket 80+

Age bracket 80+
















Age bracket 0 to 9

Waste Per Food Eaten


Live stock land needed


kWh per litre 49

Minimum vegitation Required

Oxygen Used Per Person

Total Daily production of

Oxygen

Production per 1m2 of grass

Tree Production of oxygen per mod per day

Production of oxygen per tree

per day

Trees per mod

Total energy used per Service Mod per year Watts


Land Used


Land Available




Land for Offices


Reduction of Land available due to

infrastructure 11


Land for Offices


Per ModuleTotal Space

Required Per Module

Office Space Required

Total Area of Office Cluster

Office Cluster Required

Office Cluster Required per

Module


Offices Required


People Per Cluster

Open Area to Office footprint

37

Office Footprint M2

Office Units Per Floor 34

Average Office Size 33

People Per Office Unit 32

People per Office

Floors Per Office 35

Total Height of Office

Height Per Floor 38



Office Required Per Module

Office Share 39

Office Space Required Per

Module

Width of Pond from the edge 24

Land for Offices

Land Used per Module

Land in mod available for

farming



Total Space Required Per

Module


Module




Housing Stack Footprint M2

Housing Stack Units Per Floor

27

Average Housing Stack Size M2 26

Open Area to Housing Stack footprint 30

Floors Per Housing Stack

28

People Per Housing Stack

Unit 25

Total Height of Housing Stack

Height Per Floor 31

FULL HUMAN

MODULE INTERIOR

Coriolis e� ect 0%Population Density +167%Energy Required -55%Radiation Exposure -65%Population Di� erence per mod +8418

INTERIORMODULE

HUMANFULLCoriolis e� ect -29%Population Density -50%Energy Required +113%Radiation Exposure +117%Population Di� erence per mod 0

FULL HUMAN

MODULE INTERIOR

Coriolis e� ect -43%Population Density +120%Energy Required -19%Radiation Exposure -35%Population Di� erence per mod +4261

FULL HUMAN

MODULE INTERIOR

Iteration One

Visualization Of A Parametric Energy Model Built From Scratch in Excel

Iteration Two Iteration Three Final Design

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Tensile Members act like bike spokes to support the floor of the colony. Tensile Members also support a tension Mesh. High density housing blocks are supported on the tension ring. Buildings appear to

float.

The structure of the individual units will be 3D printed out of concrete and steel. They can be customized to any degree so long as there is a central structural member going through its center of gravity. Housing modules are transported via train to the tensile building structure. Housing modules are hoisted up via a mechanical pulley to be attached to tensile ring. Multiple

modules are built one under another to form a grape vine of housing.

Earth Orbit 365 Days

Moon Orbit 27 Days

MoonLagrange Point 1

Earth

Concept art of the interior

Location Exploded Massing

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Concept art of the interior

Concept art of the interiorConcept art of the interior

Mixed Use Student Residence IndividualStanding as a multi-unit student residential project featuring office space down below, this intervention strives to introduce Ryerson’s Digital Media initiatives to the rest of the university by using a bridge to connect the public areas to the private office space. The ground floor lobby features several gathering spaces that look down on to the Digital Media Zone’s new. This idea of the bridge is also taken up to the residential floors with west end of every other floor featuring an open to below section allowing for visual communication for the student residents between floors.

Given the property on Younge Street directly adjacent to the new student learning center.

Perforations were made in the ground floor to connect the offices with the lobby. This served to create dedicated congregation zones with the remaining floor space on the lobby. The vast degree of the floor space removed also visually connects the two spaces advertising for the Digital Media Zone and providing for views to the users

The program calls for one floor to be dedicated office space to the Digital Media Zone, another for the lobby and a the remaining upper floors for student residents

On the residential side, to maximize the amount of sunlight that can enter the building ‘gills’ were extruded from the side.

The office for the Digital Media Zone was dedicated to basement floor

The Younge street facade became fully glazed to allow the residents of each atrium to have a full view of the street.

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Younge St.

Victoria St.

Gould St.

Younge St.

Victoria St.

Gould St.

Younge St.

Victoria St.

Gould St.

Younge St.

Victoria St.

Gould St.

Younge St.

Victoria St.

Gould St.

Younge St.

Victoria St.

Gould St.

Younge Street Entrance3rd Space LoungeGould Street EntranceLoadingWashroomTriple UnitDouble UnitSingle UnitMarried UnitMeeting RoomLobby Digital Media Zone

01.02.03.04.05.06.07.08.09.10.11.12.

UP

DN

UP

DN

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Loadingzone

First Floor Plan

First Floor

01.02.

03.

04.

05.

12.11.

UP DN

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UP

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Group Study

Third And Fifth Floor Plan

06.

07.08. 08.

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First Floor

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Soffit Detail

Media Zone Floor Plan

Perspective Section

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Community Center 1IndividualCurrently the sounding context is sandwiched between the entertainment district to the north and a quickly developing high rise condominium area to the south. On paper the area is well served with many amenities that are included in the high rise condominiums, but these areas are tend to be exclusive and often included as an afterthought for marketing purposes. The solution, build a community center with a marvel to compete with the sounding urban context. The idea came from a desire to combine the organic aspects two parks directly adjacent with the linear and more rigid form that most of the city assumes, what results is a faceted organic form. The spacial organization was then modeled around a tree, again as tribute to the parks with each of the programs being the branches that all stem from the trunk that is the atrium.

Beginning with a large site on Wellington between two parks

Incorporate an atrium that will draw the users into a central location and have each program feed off it.

Add a hierarchy that makes each higher floor incorporating increasing activity. This allows for users to be more comfortable, grouped with people of a similar physical strength.

Bring the overall aesthetic of the tree into the building by incorporating it into the structure. Add more prominence to the atrium by allowing it to be the central circulatory corridor on 2nd floor by adding a bridge.

Derive an aesthetic based on the combination of the natural and organic with the man made and linear to arrive at a faceted organic form.

Apply the faceted form the both the exterior and interior of the building to create an intervention stands out in its environment.

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Increasing Intensity of

activity

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Steel Truss with OWSJ Across

Custom Steel HSS

Concrete Columns

Cast in place Concrete Floor

Cast in place Concrete Walls

Concrete Columns

Retaining Wall With FootingsFirst Floor Entrance

AtriumPoolBowling AlleyLibraryRestaurantsSquashGymnasiumTennis CourtMixed UseStorageClassroomTrack CardioWorkout Area

01.02.03.04.05.06.07.08.09.10.11.12.13.14.

1 2 3 5

B

C

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Pool

Atrium

Rest

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Library

BowlingAlley

AdminOffice

LunchRoom

Storage

BoysChangeRoom

BowlingOffice

Storage

Life GaurdOffice

GirlsChangeRoom

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Second Floor Bridge

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Gymnasium

Classroom Storage

Mixed UseMixed Use

Classroom

Stor

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Squash Squash Squash

Storage

Boys

WR

Girl

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TennisCourt

Storage

Mixed Use

Atrium

Open ToBelow

Open ToBelow

Open ToBelow

Open ToBelow

Open ToBelow

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01.02.03.04.05.06.07.08.09.10.11.12.13.14.

Multi-Use Rooms

Pool

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Community Center 2In collaboration with Charles Bennett.This community center is centered around the desire to connect the busyness of King Street with the quite cove of Wellington Street in tandem with creating a center to the parks to the north, east and west. This is done by reinforcing a lane-way connection between the two streets by landscaping and including all of the main entryways on the path. The building is centered around verticality ordered by increasing privacy as the user ascends using vertical wood fins in varying density to block and allow sightliness. The mass is separated into five volumes with each space forming an atrium where all the vertical circulation occurs. This also forms a chimney effect allowing for the building to naturally ventilate itself.

BUILDABLE ENVELOPE MATCH HEIGHTS EXPAND LANEWAY SERVICE ENTERANCE

PERPENDICULAR CIRCULATION LANEWAY

OPEN TO LANEWAY

PERPENDICULAR CIRCULATION PARK

SOLID STRUCTURES

CREATE VOIDS

VOID STRUCTURE

PUSH TO REVEAL ENTERANCE

MERGE STRUCTURES

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Gymnasium Court.

Entrance

DN

UP

DN

UP UP

UP

DN

DN

Second Floor Plan

07.

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13.

UP

UP

DN

UP

UP

UP

First Floor Plan

01.

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03.04.

05.

CafeGalleryLobbyGymBike StorageArt StudioClass RoomYouth RoomMixed UseWeight LiftingLibraryDance

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Ground Floor

Lobby

DN

UP

DN

DN

UP

UP

DN

Third Floor Plan

07.08.09.

10.

DN

DN

UP

Fourth Floor Plan

11.11.12.09.CafeGalleryLobbyGymBike StorageArt StudioClass RoomYouth RoomMixed UseWeight LiftingLibraryDance

01.02.03.04.05.06.07.08.09.10.11.12.

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EXPERIENTIAL SECTION

Sectional Perspective

WATER RETENTION SYSTEM

SOLAR CHIMNEYS + STACK EFFECT

VEGETATIVE ROOF

LIGHT WELLS CONTROLED LIGHTING

NATURAL VENTALATION

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Solar Chimney Diagram

Plan Section Interior

Looking to Skyline

Lookout TowerIndividualThe design engages the site through submersion, hiding among the foliage, with its staircase shaft cloaked in 2 way mirrored glass. The resultant is a floating box, eying the Toronto skyline allowing for users to admire its beauty in a calming natural setting. This is further reinforced by its reliance on the sun for lighting, including openings in the roof to create rays of light that move with the sun. The tower accommodates the communal aspect of the island providing spaces that can be engaged in a shared manner by both able bodied and disabled users. The plan is primarily a raised open terrace with seating available including a view directed towards the city and back towards the park.

Siding Axonometric

Steel Bracket

Concealed Steel Splice

2x10 Wood Stud

Hidden Steel Angle

Wood Cant

2x10 Roof Stud

CLT Floor Slab

4x4 Wood Stud

Steel Spider Connection

Glass With 2-Way Mirror Film

CLT to Stud Spider Connection Detail

2x10 Wood Stud

Steel Bracket

CLT Floor Slab

Interior View of 2-Way Mirrored Glass

Look

out T

ower

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Concealed Steel Plate

Wood Beam

Parasol Membrane

Parasol Canopy Structure

Parasol Wood Column

Wood Chair

Life Guard Stand

Wood Anchor System

1/2” plywood for Seating

Wood Column

Wood 2x4

Concealed Splice Bracket

Concealed Splice DetailParasol Anchor DetailParasol Attachment Detail

Exploded Axonometric`

Exterior View

Beach Chair InstallationIn collaboration with Kenan ElsässerThe design process started with the question of what we expect to see at the beach in summer and how to incorporate those familiar elements in winter.The beach chair and umbrella was determined to be the most iconic representation.The theme of humour was selected and this was done through a simple play of the scale. The result would intrigue and shock the viewer by providing a very unorthodox form that they could interact with.

Concealed Steel Plate

Wood Beam

Transparency

Child Play

Seating

Wind Mitigation

Steel Cap

Column Bracket

Wood 2x4

SectionParasol Detail Program Axonometric

Play of Scale DiagramLooking out from the Chair

Beach

Chair

Insta

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Chinese SpaBuilding designed Individually. Site designed in collaboration with Ting Ting, Mahan Navabi, Jiapei Li, and Jin Sun. A need displayed by the lack of recreational buildings, an abundance of hotels, and an up and coming community for young professionals this Spa designed in the new style aims to provide revenue for the park, create an magnet attracting people to the site and provide a series of much needed facilities.

A spa, needing an entrance, a pool, a hot tub, massage area and relaxation area

Fitting in with the wandering theme of the rest of the park, there was to be no directed experiential route by providing a central circulation space where everything could originate from the center

A form of spacial organization was loosely derived from the Chinese concept of elements. The belief is that all matter was composed of various amounts of wind, water fire and earth and when they come together they form energy.

Various forms were explored keeping in mind how this would fit in with the Hefei context. The new Hui style was researched and their additive style of building was incorporated into the design in the form of overlaps

The central circulatory area needed its own theme was to represent the energy and to set itself aside from the programing areas. A meeting space with its own contrasting geometry was employed

The building was also developed in section to highlight this area. The roofs sloped down towards the main circulation path.

This was done in tandem with the knowledge of the Hefei region, which itself is surrounded by mountains.

The resultant form needed to have an exterior that relayed the notation of the strong, towering, wall. The design sought to reflect this by minimizing the amount of windows on each facade and taking a very monolithic approach.

These overlaps allowed for new spaces with different identities to be explored. Areas that came together could now have a new theme born as a result of the combination of the two themes.

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Entrance

Massage - Earth

Deep End PoolOfficeLounge AreaSteam BathTea Hot BathSaunaBody MassageFoot MassageMud Bath Shallow End PoolMain Entrance Pool UndersideChange RoomMechanical Room

01.02.03.04.05.06.07.08.09.10.11.12.13.14.

01.

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04.

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First Floor Plan

05.

06.

07.

08.

09.

10.

11.

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CAP SHEETBASE SHEET13mm FIBER BOARDVAPOR RETARDER200mm CAST IN PLACE CONCRETE75mm RIGID INSULATION25mm AIR SPACE70mm PRECAST CONCRETE PANEL

CANT

13mm PLYWOOD

ALUMINUM PARAPET CAP

STEEL ANCHOR BOLT

BALLASTROOF MEMBRANE

13mm FIBER BOARD100mm RIGID INSULATION

VAPOR RETARDER13mm PLYWOOD

CAST IN PLACE CONCRETE

WOOD BLOCKING

13mm PLYWOOD

WOOD BLOCKING

Water - Pool

Tea Baths - Fire

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METAL FLASHING

WOOD NAILER

ALUMINUM BENT PLATE

SEALANT AND DUALBACKER ROD

VAPOR RETARDER TIEDINTO WINDOW

SPRAY INSULATION CANT

100mm SALVAGED BRICK MASONRY200mm CAST IN PLACE CONCRETEVAPOR RETARDER75mm RIGID INSULATION25mm AIR SPACE70mm CONCRETE PANEL

CAP SHEETBASE SHEET13mm FIBER BOARDVAPOR RETARDER200mm CAST IN PLACE CONCRETE75mm RIGID INSULATION25mm AIR SPACE70mm PRECAST CONCRETE PANEL

CANT

13mm PLYWOOD

ALUMINUM PARAPET CAP

STEEL ANCHOR BOLT

BALLASTROOF MEMBRANE

13mm FIBER BOARD100mm RIGID INSULATION

VAPOR RETARDER13mm PLYWOOD

CAST IN PLACE CONCRETE

WOOD BLOCKING

13mm PLYWOOD

WOOD BLOCKING

100mm SALVAGED BRICK200mm CAST IN PLACE CONCRETEVAPOR RETARDER75mm RIGID INSULATION25mm AIR SPACE70mm CONCRETE PANEL

SEALANT AND DUAL BACKER ROD

STEEL DOWEL

METAL FLASHING @3PANEL O.C.

SPRAY INSULATION

STEELCOMPRESSIONFASTENERSTEELFACADEPANELFASTENER

STEEL LINTEL

SEALANT ANDDUAL BACKER

ROD

METAL FLASHING

WEEP HOLES @ 900mm O.C.

SEALANT AND BACKER ROD

Wind - Lounge

Front Elevation Side Elevation

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Site Plan

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Documents

Jaspall (Jay) Gill Architecture Portfolio