Cara Ellis Portfolio Architecture 2015
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Transcript of Cara Ellis Portfolio Architecture 2015
CARA ELLISDESIGN PORTFOLIO
SANTA CLARA UNIVERSITY MASTER PLAN STUDY
SANTA CLARA UNIVERSITY
MASTERPLAN
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AB
Project Context• Executive Summary• Campus Facilities Masterplan Overview
Program Analysis• Course & Campus - Analysis Summary• Engineering Analysis• Sciences Analysis• Current & Notional Program• Options & Synergies
Master Planning• Options Summary• Option 1 - One Destination• Option 2 - Re-Group & Re-Create• Option 3 - A Whole New Place• Option 4 - Renovate & Regroup• Phasing
Appendices• A - Flexibility • B - Extended Data
Santa Clara University - Master Plan StudyProduced by Cannon Design 06-17-2013
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AB
Project Context• Executive Summary• Campus Facilities Masterplan Overview
Program Analysis• Course & Campus - Analysis Summary• Engineering Analysis• Sciences Analysis• Current & Notional Program• Options & Synergies
Master Planning• Options Summary• Option 1 - One Destination• Option 2 - Re-Group & Re-Create• Option 3 - A Whole New Place• Option 4 - Renovate & Regroup• Phasing
Appendices• A - Flexibility • B - Extended Data
Santa Clara University - Master Plan StudyProduced by Cannon Design 06-17-2013
CONCISE VERSION
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SANTA CLARA UNIVERSITY FACILITIES MASTER PLAN
• Law School - Demolish Heafey - Renovate Bannan - Vacate Bergin Hall - New Building on Heafey Site - 100,000 SF
Net Area Gain = 38,474 SF
• Engineering Campus - Demolish Bannan Labs - Renovate Mechanical Engineering - Renovate Bannan Engineering - Construct new facility - 70,000 SF
Net Area Gain = 52,035 SF
• Integrated Science Facility - Demolish Daly Science 100, 200, 300 - Construct new facility - 100,000 SF
Area Increase - 60,722 SFEXISTING SITE
Campus Facilities Masterplan OverviewSanta Clara University - Master Plan Study
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Engineering Campus
• Bannan Engineering bldg. - 3 stories - Gross Area = 44,338 SF - Net Area = 29,028 SF
• Mechanical Engineering bldg. - 2 stories - Gross Area = 27,689 SF - Net Area = 21,440 SF
• Bannan Labs bldg. - Gross Area = 12,954 SF - Net Area = 9,955 SF
Gross Area All 3 Existing Buildings = 84,981 SFNet Area All 3 Existing Buildings = 60,423 SF
Total Area Assumed for Enginnering with demolition of Bannan Labs, renovations and new contruction = 142,027 SF
Law School
• Bannan Hall - 3 stories - Gross Area = 49,600 SF - Net Area = 27,785 SF
• Heafey-Bergin bldg. - Gross Area = 65,000 SF
Gross Area of Existing Buildings = 114,600
Total Area Assumed for Law School with renovations and new contruction = 136,370 SF
Integrated Science Facility
• Daly Science bldgs. 100, 200, 300 - Gross Area = 54,713 SF
• Alumni Science bldg. - Gross Area = 52,326Gross Area of Existing Buildings = 107,039 SF
Total Area Assumed for Sciences with renovations and new contruction = 152,326 SF
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LECTURES
COURSES FOR ONE QUARTERGlobal Tech DevModlng & Cntrl of Rigd Bod DynSftwr Qlty Assrnc TstLogic Analysis & SynthesisParallel ThinkingHuman Interaction IGeologyIntro to Probability IDifferential EquationsLaw, Tech & Intell PropSemi-Cust Des W/Prog DevGender and EngineeringEngr Economics and BusinessComp Fluid Mech IAerospace StructuresNanotechnology and SocietyForms of NatureApplied Programming in CCommunication Sys L&LSoil-Structure InteractionAdv Logic DesignSecure Coding in C & C++Mechanics I: StaticsApplied Programming in CMultimedia Data Comp IEmag Fld Thry IDgtl Sgnl Proc IAdv Dynamics IIComputer NetworksCompilersPhase-Locked Lps IAcct & Cost Cntrl Project ManElectronic Circuits IProject Risk ManagementFinite Element Theory & ApplSemiconductor Dev I L&LSustainable Electric EnergyAdvanced ProgrammingMunicipal Engineering DesignMicrofab & Microfluid for BioeDes & Fabrication of PV CellsManag. in the Multicult EnvirnIc Assembly & Pkg Tech
Mech III:Strgth of Mtrls LabMech III:Strgth of Mtrls LabMech III:Strgth of Mtrls LabBioSignals and Processing LabReinforced Concrete Design LabReinforced Concrete Design LabWater Resources Design LabGeology LabGeology LabGeology LabMunicipal Engr Design LabMunicipal Engr Design LabElectric Circuits I LabElectric Circuits I LabElectric Circuits I LabElectric Circuits I LabElectric Circuits I LabElectric Circuits I LabElectric Circuits I LabMechatronics LabMechatronics LabElectronic Circuits I LabElectronic Circuits I LabModern Network Synth & Des LabIntro to Tissue Engineerng LabIntro to Power Electronics LabSemiconductor Devices LabCommunication Systems LabAdv Logic Design LabAdv Logic Design LabMechanical Vibrations LabMechanical Vibrations LabMechanical Vibrations LabHeat Transfer LabHeat Transfer LabHeat Transfer LabMdrn Instrument for Engrs-LabMdrn Instrument for Engrs-LabMdrn Instrument for Engrs-LabIntro to CNC IIIntro to CNC IIIntro to CNC IIIntro to Material Science Lab
Design Project IIDesign Project IIAdvanced Design II:Implementat
SeminarSolar Decathlon Workshop
LABS PROJECT WORKSHOP SEMINAR
75%57%
GRAD
23%1.3% .4% .3%
Cad for McrwvsApplied Math ILinear Algebra IITopics Comp EngrGuid & Cntrl IBiological Transport PhenomenaIntroduction to Biofuel EngrWater Resources DesignHeat TransferInt/Fml Lng Thy&CmplcnstEngr Project for the CommunityComp Perf EvalFund of Semiconductor PhysicsSoftware Eng. CapstoneEstimation TheoryLogic Design Using HDLVibrations IDsgn Cold-Frmd Steel Frame StrDifferential Equations:HonorsStructural Steel Des IIProbability & Statistics:HonorIntro to Nano-bioengineeringEffective Oral PresentationsFrac Mech & FatIgueIntro to CNC IIEffective Oral PresentationsDevelop of Construct DrawingsDevelop of Construct DrawingsTheory of WaveletsTopics Comp EngrParallel ProgrammingENGR ECON ADV CONCEPTS IITech Dev of New ProductsAdv. Engineering Math. IISys Conceptual DesPower SystemsSpec Top in Dynam & ContCont ProbNumerical Analysis IIFin Element Meth IIIntro to CommunicationVLSI Design IIGender and Engineering
Intro to Tissue EngineeringBioSignals and ProcessingEthics in TechnologyModern Network Synthesis & DesAdptv Sgnl Proc IIIntg Ckt Fab Proc IIRF Integ Cir DesignMaterials & Manufactur ProcessAnalog Integrated Circuits IAdvanced Mechatronics IIWeb UsabilityAdvanced ProgrammingElectric Circuits IIntro to Material ScienceMaterials & Manufactur ProcessReinforced Concrete DesignDesign Project IIComputer ArchitectureOO Analysis,Design,ProgrammingSoftware Dev Proc MgmtHigh Perf NtwrkgHigh Perf NtwrkgMachine Design IMechanical VibrationsManag. in the Multicult EnvirnMechanics II: DynamicsComputer NetworksMechanical VibrationsElectrical Engr Grad SeminarInformation Security MgmtDesign & Analysis: AlgorithmsSoftware EthicsIntro Altern Energy SysVLSI Design IMech III:Strength of MaterialsGraphical Comm in DesignSpecial Topics in CENGElectric Circuits IHeat TransferForm Spec & Adv Data StrucMechatronicsElectric Circuits IMech III:Strength of Materials
Construction EngineeringFormal Methods in Sw EngAdv. Proj. Mgmt & LeadershipMobile Application DevelopmentInformation TheoryHuman Resource DevIntro to Power ElectronicsComp. Aided Prj Mgmt SchLinear Algebra IDatabase SystemsNetwork ManagementTime Series AnalysisDifferential EquationsDifferential EquationsTheory of AlgorithmsBiomolecular Engineering IIMdrn Instrumentation for EngrsProbability & StatisticsHydraulic EngrProbability & StatisticsProbability & StatisticsDifferential EquationsDifferential EquationsNumerical MethodsEquilib ThermodynMedical Device Prod DevlopmentApplied Programming in MATLABApplied Programming in MATLABAdaptive Control IIDigital Image ProcessingTechnology EntrepreneurshipWireless & Mobile NetworksNanomaterialsIntro to Smart GridConv Heat Mass Tr IMdrn Instrumentation for EngrsInfrastructure Project MgmtElec Struct and Prop.Operating SystemsLinear Control SystemsEarthquake Engr IIGeologyIntro to Material Science
Intro to Material Science LabIntro to Material Science LabIntro to Material Science LabGraphical Comm in Design LabApplied Programming in C LabApplied Programming in C LabApplied Programming in C LabApplied Program in MATLAB LabApplied Program in MATLAB LabApplied Program in MATLAB LabApplied Program in MATLAB LabAdvanced Programming LabAdvanced Programming LabAdvanced Programming LabForm Spec & Adv Data Struc LabForm Spec & Adv Data Struc LabComputer Networks LabComputer Networks LabInt/Fml Lng Thy&Cmplcnst LabInt/Fml Lng Thy&Cmplcnst LabOO Analysis, Design, Prog LabWeb Usability LabGraphical Comm in Design Lab
GREEN TEXT NOTES COURSES WITH 30+ STUDENT ENROLLMENT
NO COURSES OVER 30 PEOPLE NO COURSES OVER 30 PEOPLE NO COURSES OVER 30 PEOPLEBLUE TEXT NOTES COURSES WITH 30+ STUDENT ENROLLMENT
How to Become an EngineerAnalysis
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2,126
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201
98
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ALUMNI SCIENCE = 11FINE ARTS BLDG. = 7ARTS AND SCI. = 85BANNAN HALL = 11CASA = 4DALY SCI. = 40ENG. = 2,126GRAHAM = 11KENNA = 201KENNEDY = 16LOYOLA = 2LUCAS HALL = 6MAYER THEATER = 3O’CONNOR HALL = 98SOBRATO HALL = 3
20% OF COURSES ARE NOT HELD IN
THE ENGINEERING BUILDINGS
N
Engineering Courses Campus Distribution - the Octopus EffectAnalysis
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Head of the ClassNumber of classes
# of
cla
sses
ove
r 4 y
ear p
erio
d
10 - 15Students
<10Students
16 - 30Students
31 - 45Students
46 - 60Students
61 - 75Students
75 - 99Students
100+Students
200
544455
1184
373
9 164
400
600
800
1000
1200
The number of courses in all engineering disciplines over a 4 year period of time, 2009 - 2013 illustrates the large number of classes within the 16 to 30 person range.
Additionally, the combined total of 999 classes in that same period with less than 16 students reveals the need for flexible small spaces versus large lecture spaces.
This graph does not differientiate between lecture, seminar or lab, but instead gives a glimpse into the general class size for engineering courses across the university.
Classes
Head of the Class - EngineeringAnalysis
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FALL
WINTER
10% 20% 30% 40% 50% 60% 70% 80%
SPRING
AVERAGE
AVERAGE
UNDERGRADUATE
GRADUATE
39%LECTURE
18% LAB
55%CAPACITY
FALL
WINTER
SPRING
10% 20% 30% 40% 50% 60% 70% 80%
14%LECTURE
6% LAB
47%CAPACITY
LAB UTILIZATION
LECTUREUTILIZATION
CAPACITY *CAPACITYAVERAGE ENROLLMENT OVERROOM CAPACITY (STUDENTS / SF)
*UTILIZATIONNUMBER OF HOURS/ WEEK ROOM HOSTS SCHEDULED COURSES OVER A 60 HOUR WEEK (12 HOURS/ DAY)
Where to Become an EngineerAnalysis
Our analysis of the courses held in the existing Engineering epicenter demonstates a higher demand for lecture space than specialized lab space.
The low utilization of lab space suggests hybridizing non-specialist labs to serve as both classroom and labs. (Non specialist labs far outnumber specialist labs, see appendix for detailed room by room analysis for 2012-2013).
Lecture rooms that can accomodate 16 to 30 students are in high demand.Large lecture spaces that seat over 50 students are chronically under capacity.
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The Future...Master Planning Summary
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Combined Science & Engineering The Law School
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Recommended Approach3 4
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PALM DRIVETH
E AL
AMED
A
Recommended Approach
*
* *
*
IntegratedSciecne and Engineering
Courtyard
Offices
Offices
SpecialtyLabs
Psychology +Classrooms
Classrooms +Library
Classrooms +Faculty Res. + Offices
CLABS +Offices
*Law SchoolCourtyard
* *
4 Renovate & Re-GroupMaster Planning
SITE PLAN CONCEPT
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• NEW CONSTRUCTION = 169,620 SF ENGINEERING & SCIENCE
• NEW CONSTRUCTION + BANNAN ENGINEERING RENOVATION + BANNAN MECHANICAL RENOVATION + BANNAN HALL RENOVATION =
• 291,247 SF (USING GROSS RENOV. AREAS)
• NEW CONSTRUCTION = 92,965 SF NEW LAW BUILDING
• NEW CONSTRUCTION + RENOVATION OF ALUMNI SCIENCE FOR LAW PROGRAMS = 145,291 SF GROSS
• NOTE: USES GROSS AREAS FOR ALUMNI RENOVATION, MAY BE CLOSER TO 136,370 SF REQUIRED ON FURTHER ANALYSIS OF ALUMNI NET USABLE AREAS
PERSPECTIVE
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Flexibility, Utilization & CollaborationAppendix A - Flexibility
A
B
MOBILE WORKSTATIONfabrication shop / heavy-use labsuite & multi-shop use
MOBILE WORKSTATIONcloud-enabled, suite & multiple room use & lecture use
MOBILE WORKSTATIONcloud enabled, everywhere use
MOBILE WORKSTATIONcloud enabled,everywhere use
IMMOBILE WORKSTATIONpotentially cloud-enabled, single room use
MOBILE WORKSTATIONpotentially cloud-enabled, suite or multipurpose room use
Technology Meets FlexibilityAppendix A - Flexibility
43
Downtown District Commercial Blocks as seen from the central roundabout transit hub.
Downtown Commercial Blocks
We designed the first two blocks of the Downtown Commercial District. Our major objective was to define the edge of the boulevard park with a “street-wall” of 10 story buildings. A continuous arcade shades the sidewalk and provides continuous shop fronts along the boulevard. Towers of various heights are set back behind the street-wall and establish a dynamic skyline.The incessant power of the sun dictates that all glass must be shaded and therefore we used a concrete exoskeleton that both shades the glass and allows for the movement of air along the facade. The Towers employ a system of external fins at various angles to the sun to protect the vision glass.
© SOM
94
selectARCHITECTURE
| PENCDowntown DistrictDowntown Commercial Blocks |
Previous Page: Aerial Perspective of the Downtown District Commercial Blocks. This Page: Aerial perspective of the icon tower.
98 99
Downtown District Commercial Blocks as seen from the central roundabout transit hub.
Downtown Commercial Blocks
We designed the first two blocks of the Downtown Commercial District. Our major objective was to define the edge of the boulevard park with a “street-wall” of 10 story buildings. A continuous arcade shades the sidewalk and provides continuous shop fronts along the boulevard. Towers of various heights are set back behind the street-wall and establish a dynamic skyline.The incessant power of the sun dictates that all glass must be shaded and therefore we used a concrete exoskeleton that both shades the glass and allows for the movement of air along the facade. The Towers employ a system of external fins at various angles to the sun to protect the vision glass.
© SOM
94
| PENCDowntown DistrictDowntown Commercial Blocks |
Previous Page: Aerial Perspective of the Downtown District Commercial Blocks. This Page: Aerial perspective of the icon tower.
98 99
Downtown District Commercial Blocks as seen from the central roundabout transit hub.
Downtown Commercial Blocks
We designed the first two blocks of the Downtown Commercial District. Our major objective was to define the edge of the boulevard park with a “street-wall” of 10 story buildings. A continuous arcade shades the sidewalk and provides continuous shop fronts along the boulevard. Towers of various heights are set back behind the street-wall and establish a dynamic skyline.The incessant power of the sun dictates that all glass must be shaded and therefore we used a concrete exoskeleton that both shades the glass and allows for the movement of air along the facade. The Towers employ a system of external fins at various angles to the sun to protect the vision glass.
© SOM
94
| PENCDowntown District
Structural Frame30% Shading
Rendering and details of the low-rise off building facades and shad-ing systems. The exposed structure in combination with horizontal and vertical louver systems shades the office glass while maintain view out to the boulevard beyond.
Structural Frame+ Horizontal Shade50% Shading
Structural Frame+ Horizontal Shade+ Vertical Fins95% Shading
Downtown Commercial Blocks |
Previous Page: Rendering and details of typical lowrise facade solutions. This Page: Rendered Detail of the Icon tower facade system. A series of fixed perforated metal louvers shades the tower glass from the sun while providing views out to the surrounding city.
100 101
| PENCDowntown DistrictDowntown Commercial Blocks |
Previous Page: Aerial Perspective of the Downtown District Commercial Blocks. This Page: Aerial perspective of the icon tower.
98 99
| PENCDowntown DistrictDowntown Residential Blocks |
Previous Page: Rendered plan of the Downtown District Residential Blocks. This Page: Massing Perspective showing unit mix.
3 BD UNITS
4 BD UNITS
4 BD UNITS
2 BD UNITS
CLUB
CORE
LEGEND
110 111
| PENCDowntown DistrictDowntown Residential Blocks |
Previous Page: Rendered plan of the Downtown District Residential Blocks. This Page: Massing Perspective showing unit mix.
3 BD UNITS
4 BD UNITS
4 BD UNITS
2 BD UNITS
CLUB
CORE
LEGEND
110 111
| PENCDowntown DistrictDowntown Residential Blocks |
Previous Page: Rendered plan of the Downtown District Residential Blocks. This Page: Massing Perspective showing unit mix.
3 BD UNITS
4 BD UNITS
4 BD UNITS
2 BD UNITS
CLUB
CORE
LEGEND
110 111
Perspective rendering of the Personal Floor Blocks fronting Formula 1 road.
Personal Floors Blocks
“Personal Floors” refers to large, luxurious apartments, around 4000 SF, where only two units share an elevator core. The site, long and thin, suggested two parallel rows of buildings of various heights, surrounding private gardens, raised one level above parking. Large balconies facing south are shaded by sliding wood screens.
© SOM
Perspective rendering of the Personal Floor Blocks fronting Formula 1 road.
Personal Floors Blocks
“Personal Floors” refers to large, luxurious apartments, around 4000 SF, where only two units share an elevator core. The site, long and thin, suggested two parallel rows of buildings of various heights, surrounding private gardens, raised one level above parking. Large balconies facing south are shaded by sliding wood screens.
© SOM
| PENCVilla District
DESIGN PRINCIPLES:• Place taller, higher density buildings facing the formula 1 circuit to provide higher values• Place lower buildings facing the Country Homes villas to the south to maintain the neighborhood scale• Create a strong street wall facing formula 1 by mixing tall towers with mid-rise buildings• Ensure a good mix of unit types to cater to a diverse market
CONTINUOUS EAST-WEST LINEAR
GARDEN TO CONNECT THE ENTIRE
NEIGHBORHOOD
ALL UNITS ARE ‘THROUGH’ UNITS TO CAPITALISE ON VIEWS
NORTH-SOUTH VIEW CORRIDORS AND PEDESTRIAN
CONNECTIONS BETWEEN THE KOUNTRY HOMES
AND FORMULA 1
Personal Floors Blocks |
Massing perspective looking towards the central downtown roundabout along Formula 1 road.
150 151
Perspective rendering of the Personal Floor Blocks fronting Formula 1 road.
Personal Floors Blocks
“Personal Floors” refers to large, luxurious apartments, around 4000 SF, where only two units share an elevator core. The site, long and thin, suggested two parallel rows of buildings of various heights, surrounding private gardens, raised one level above parking. Large balconies facing south are shaded by sliding wood screens.
© SOM
| PENCVilla District
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Rendered site plan for the
Personal Floor Blocks showing
interior courtyards.
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| PENCVilla District
148
Rendered site plan for the
Personal Floor Blocks showing
interior courtyards.
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148
149
Perspective rendering of the Personal Floor Blocks fronting Formula 1 road.
Personal Floors Blocks
“Personal Floors” refers to large, luxurious apartments, around 4000 SF, where only two units share an elevator core. The site, long and thin, suggested two parallel rows of buildings of various heights, surrounding private gardens, raised one level above parking. Large balconies facing south are shaded by sliding wood screens.
© SOM
12
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
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1111
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
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1
2
3
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5 66
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1111
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
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1
2
3
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5 66
7
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1111
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
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11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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3
4
5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
9
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
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5 66
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11
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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3
4
5 66
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1111
11
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
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1111
11
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
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5 66
7
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1111
11
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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3
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5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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4
5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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3
4
5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
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3
4
5 66
7
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
12
1
2
3
4
5 66
7
8
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10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
COMPETITION ENTRY UA STUDIO CHICAGO 2009
AMSTERDAM-NOORD BUIKSLOTERHAM FABRIEK RF : garden
L5 : restaurant
L4 : flex. lab / office
L3 : flex. lab / office
L2 : exhibit / lab
L1 : exhibit / lab
M : retail / cafe
GR : retail / cafe / gallery
RF : garden
RF : garden
400 m2
650 m2 600 m2
840 m2
240 m2
330 m2300 m2
500 m2
240 m2
330 m2300 m2
500 m2
650 m2 600 m2
400 m2
650 m2 600 m2
840 m2
650 m2
400 m2
650 m2 600 m2
840 m2
650 m2
1,250 m2
2,490 m2
1,370 m2
2,490 m2
1,370 m2
2,490 m2
1,680 m2 3,910 m2 3,000 m2 3,520 m2 12,110 m2
net usable area
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
RF : garden
L5 : restaurant
L4 : flex. lab / office
L3 : flex. lab / office
L2 : exhibit / lab
L1 : exhibit / lab
M : retail / cafe
GR : retail / cafe / gallery
RF : garden
RF : garden
400 m2
650 m2 600 m2
840 m2
240 m2
330 m2300 m2
500 m2
240 m2
330 m2300 m2
500 m2
650 m2 600 m2
400 m2
650 m2 600 m2
840 m2
650 m2
400 m2
650 m2 600 m2
840 m2
650 m2
1,250 m2
2,490 m2
1,370 m2
2,490 m2
1,370 m2
2,490 m2
1,680 m2 3,910 m2 3,000 m2 3,520 m2 12,110 m2
net usable area
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
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3
4
5 66
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11
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1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
UA STUDIO
12
1
2
3
4
5 66
7
8
9
10
1111
11
11
1_ bridge to neighbourhood
2_ town square
3_ parking ramp
4_ public quay
5_ wetlands park
6_ sluice gates
7_ waterside park
8_ bicycle path
9_ playing field
10_ marina
11_ views
12_ roof garden + wind turbines
perforated copper panel
stacked lumber brise - soleil
perforated zinc screen
perforated corten steel panel
BUIKSLOTERHAM FABRIEKOPEN F O R T 4 0 0
River Grove TowerHigh-Rise Residential Building S1
E1
E2
Stair 2
Stair 1
Trash
T/E
ServiceLobby
15'
18'
13'
11'
12'7'
13'
6'
K
T
BR-KLR/D
11'
17'
13'
6'
10'
13' 12'
7'
BR-Q
KLR/D
T
12'
11'BR-KBR-K 23
'13'
LR/D
7'
10'
T
13'
6'
K
T(2)
(3)
(1)
(2)
(3)
(2)
(3)
2BR 2BAType 1
984 RSF1 BR(K)Type 2
703 RSF
1 BR(Q)Type 3
604 RSF
Alternating
0' 2' 4' 8' 16'
Count
10 Units, 2 Elevator Plan
2 - 2BR. 2BA @ 984 RSF @ $1.50 $2952 $1,476.00
Gross/ Floor = 8,988 GSF
Ann. Gross Revenue $1,942,920 $2,252,377
Cap Rate - 7% Yr5 $30,550,971* - $212.56/ GSF*
4 - 1BR (K) @ 703 RSF @ $1.50 $4218 $1,054.50
Rentable/ Floor = 7,196 RSF
Occupancy (95%) $1,845,775 $2,139,758*
Cap Rate - 6% Yr5 $35,642,731* - $250.00/ GSF*
4 - 1BR (Q) @ 604 RSF @ $1.50 $3624 $904.50
Floor Effi ciency = 80%
Net Revenue (80%) $1,476,619 $1,711,806
Cap Rate - 5% Yr5 $42,771,360* - $297.58/ GSF*
10 Units 719 RSF Avg Av Per Unit $1,079.40
Total = 7,196 RSF Per Floor/ Per Mo $10,794.00
Type @ Size Rent Rate Rent (Each Unit)
Building Revenue/ Valuation*150 Units, 15 Floors + Lobby
5 yrs @1.03 Escalation
RICHTON PARK & RIVER GROVE TOWERS - TYPICAL FLOOR PLAN1/32” = 1’
* Residential only, excludes value of parking, land, infrastructure subsidy, & retail revenue.
Cost Anticipated + $200/ GSF
S1
E1
E2
Stair 2
Stair 1
Trash
T/E
ServiceLobby
15'
18'
13'
11'
12'7'
13'
6'
K
T
BR-KLR/D
11'
17'
13'
6'
10'
13' 12'
7'
BR-Q
KLR/D
T
12'
11'BR-KBR-K 23
'
13'
LR/D
7'
10'
T
13'
6'
K
T(2)
(3)
(1)
(2)
(3)
(2)
(3)
2BR 2BAType 1
984 RSF1 BR(K)Type 2
703 RSF
1 BR(Q)Type 3
604 RSF
Alternating
0' 2' 4' 8' 16'
Count
10 Units, 2 Elevator Plan
2 - 2BR. 2BA @ 984 RSF @ $1.50 $2952 $1,476.00
Gross/ Floor = 8,988 GSF
Ann. Gross Revenue $1,942,920 $2,252,377
Cap Rate - 7% Yr5 $30,550,971* - $212.56/ GSF*
4 - 1BR (K) @ 703 RSF @ $1.50 $4218 $1,054.50
Rentable/ Floor = 7,196 RSF
Occupancy (95%) $1,845,775 $2,139,758*
Cap Rate - 6% Yr5 $35,642,731* - $250.00/ GSF*
4 - 1BR (Q) @ 604 RSF @ $1.50 $3624 $904.50
Floor Effi ciency = 80%
Net Revenue (80%) $1,476,619 $1,711,806
Cap Rate - 5% Yr5 $42,771,360* - $297.58/ GSF*
10 Units 719 RSF Avg Av Per Unit $1,079.40
Total = 7,196 RSF Per Floor/ Per Mo $10,794.00
Type @ Size Rent Rate Rent (Each Unit)
Building Revenue/ Valuation*150 Units, 15 Floors + Lobby
5 yrs @1.03 Escalation
RICHTON PARK & RIVER GROVE TOWERS - TYPICAL FLOOR PLAN1/32” = 1’
* Residential only, excludes value of parking, land, infrastructure subsidy, & retail revenue.
Cost Anticipated + $200/ GSF
STUDIO PROJECT M. ARCH UNIT 5 FALL 2009
68 E. WACKER PLACE CHICAGO MOTOR CLUB HOTEL
2 0 0 9S A I C
Cara Ellis A6210_001_F09_cellis1_01
Mixed Use Commercial / Retail
Hotel
O�ce
Noteworthy Restaurants / Higher End Food
Hotel / Residential
Parking
Cultural
Vacant
Vehicular CirculationAt Street Level
Vehicular Circulation Below Grade
Service Circulation Below Grade
Ramp up to Grade (at Jackson)
Pedestrian Access Point to Below Grade
Service Accessible Zone Below Grade
Signi�cant Pedestrian Zone
1 2
3
4
1
2
3
4
Views to/ from Site: West Elevation, Most Prominent, Iconic
Views to/ from Site: East Elevation, Tighter Urban View, Michigan Corridor Context
Unsightly Back-of-House Facades, Parking + Mech. / Service - View Requires Occlusion
Proximity of Hotel 71 Facade Impacts Privacy - Solutions: Skin Design, Program Allocation
Site Analysis
Site Extents Existing Program Street Level
Existing Program Above Grade
Circulation Views Simple Sun Studies
Wacker Place
Mic
hig
an A
ven
ue
Wac
ker D
rive
Wab
ash
Str
eet
Cara Ellis A6210_001_F09_cellis1_01
Elevations
South Elevation
1’ = 1/32 “
West Elevation1’ = 1/64”
East Elevation North Elevation with Context
North Elevation minus Context
Chicago Motor Club HotelHotel Tower and Renovation
STUDIO PROJECT M. ARCH UNIT 5 FALL 2009
68 E. WACKER PLACE CHICAGO MOTOR CLUB HOTEL
2 0 0 9S A I C
Cara Ellis A6210_001_F09_cellis1_01
Mixed Use Commercial / Retail
Hotel
O�ce
Noteworthy Restaurants / Higher End Food
Hotel / Residential
Parking
Cultural
Vacant
Vehicular CirculationAt Street Level
Vehicular Circulation Below Grade
Service Circulation Below Grade
Ramp up to Grade (at Jackson)
Pedestrian Access Point to Below Grade
Service Accessible Zone Below Grade
Signi�cant Pedestrian Zone
1 2
3
4
1
2
3
4
Views to/ from Site: West Elevation, Most Prominent, Iconic
Views to/ from Site: East Elevation, Tighter Urban View, Michigan Corridor Context
Unsightly Back-of-House Facades, Parking + Mech. / Service - View Requires Occlusion
Proximity of Hotel 71 Facade Impacts Privacy - Solutions: Skin Design, Program Allocation
Site Analysis
Site Extents Existing Program Street Level
Existing Program Above Grade
Circulation Views Simple Sun Studies
Wacker Place
Mic
hig
an A
ven
ue
Wac
ker D
rive
Wab
ash
Str
eet
Cara Ellis A6210_001_F09_cellis1_01
Elevations
South Elevation
1’ = 1/32 “
West Elevation1’ = 1/64”
East Elevation North Elevation with Context
North Elevation minus Context
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
Buckminster Fuller has remained a vastly influential icon, not only for his optimistic vision of sustainable living, but also for his unique approach to architectural form. An early advocate of biomimickry, Fuller saw a fundamental, recurring geometry in nature that led him to understand shape as inherently derived from and dependent upon structure.
While Buckminster Fuller sought in nature the geometry of a pure sphere, I am interested in finding a structural basis for any irregular shape imaginable.
We differ not so much in content as in context: today, the term “parametric” can be applied to any idea-driven project; digital technology, combined with overwhelming access to information, has given rise to a plethora of formal possibilities… And still the inevitable question looms, how do we build it?
My work on the Digeotruss project is an attempt to tackle this question using the structural principles and economy of means exemplified in Buckminster Fuller’s Geodesic Dome:• Whereas a regular geodesic truss uses equilateral triangles to evenly distribute load, the Digeotruss system employs a flexible range of “close-to-equilateral” triangles - a kind of guided tesselation - that can approximate evenly distributed structures out of irregular, complexly curved forms.• Digeotruss is designed for ease of manufacture, employing only planar members with no custom joints or angled cuts. Made of multiple, non-homogenous components, a Digeotruss structure can be fabricated using only a laser-cutter or 3-axis milling machine.• Digeotruss is ultimately a method for dissecting complex NURBS surfaces into workable, structurally-based curve networks... which is to say, the possibilities of what it can be used for are vast and open to variation.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
PLANNTS
D I G E O T R U S SChicago • Milan • ZurichA NOVEL STRUCTURAL SYSTEM
GFRY / SAIC / iSalone Milan 2009
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
Buckminster Fuller has remained a vastly influential icon, not only for his optimistic vision of sustainable living, but also for his unique approach to architectural form. An early advocate of biomimickry, Fuller saw a fundamental, recurring geometry in nature that led him to understand shape as inherently derived from and dependent upon structure.
While Buckminster Fuller sought in nature the geometry of a pure sphere, I am interested in finding a structural basis for any irregular shape imaginable.
We differ not so much in content as in context: today, the term “parametric” can be applied to any idea-driven project; digital technology, combined with overwhelming access to information, has given rise to a plethora of formal possibilities… And still the inevitable question looms, how do we build it?
My work on the Digeotruss project is an attempt to tackle this question using the structural principles and economy of means exemplified in Buckminster Fuller’s Geodesic Dome:• Whereas a regular geodesic truss uses equilateral triangles to evenly distribute load, the Digeotruss system employs a flexible range of “close-to-equilateral” triangles - a kind of guided tesselation - that can approximate evenly distributed structures out of irregular, complexly curved forms.• Digeotruss is designed for ease of manufacture, employing only planar members with no custom joints or angled cuts. Made of multiple, non-homogenous components, a Digeotruss structure can be fabricated using only a laser-cutter or 3-axis milling machine.• Digeotruss is ultimately a method for dissecting complex NURBS surfaces into workable, structurally-based curve networks... which is to say, the possibilities of what it can be used for are vast and open to variation.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
PLANNTS
D I G E O T R U S SChicago • Milan • ZurichA NOVEL STRUCTURAL SYSTEM
GFRY / SAIC / iSalone Milan 2009
DIGEOTRUSSNOVEL STRUCTURAL SYSTEM
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
Buckminster Fuller has remained a vastly influential icon, not only for his optimistic vision of sustainable living, but also for his unique approach to architectural form. An early advocate of biomimickry, Fuller saw a fundamental, recurring geometry in nature that led him to understand shape as inherently derived from and dependent upon structure.
While Buckminster Fuller sought in nature the geometry of a pure sphere, I am interested in finding a structural basis for any irregular shape imaginable.
We differ not so much in content as in context: today, the term “parametric” can be applied to any idea-driven project; digital technology, combined with overwhelming access to information, has given rise to a plethora of formal possibilities… And still the inevitable question looms, how do we build it?
My work on the Digeotruss project is an attempt to tackle this question using the structural principles and economy of means exemplified in Buckminster Fuller’s Geodesic Dome:• Whereas a regular geodesic truss uses equilateral triangles to evenly distribute load, the Digeotruss system employs a flexible range of “close-to-equilateral” triangles - a kind of guided tesselation - that can approximate evenly distributed structures out of irregular, complexly curved forms.• Digeotruss is designed for ease of manufacture, employing only planar members with no custom joints or angled cuts. Made of multiple, non-homogenous components, a Digeotruss structure can be fabricated using only a laser-cutter or 3-axis milling machine.• Digeotruss is ultimately a method for dissecting complex NURBS surfaces into workable, structurally-based curve networks... which is to say, the possibilities of what it can be used for are vast and open to variation.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
ELEVATIONNTS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
Buckminster Fuller has remained a vastly influential icon, not only for his optimistic vision of sustainable living, but also for his unique approach to architectural form. An early advocate of biomimickry, Fuller saw a fundamental, recurring geometry in nature that led him to understand shape as inherently derived from and dependent upon structure.
While Buckminster Fuller sought in nature the geometry of a pure sphere, I am interested in finding a structural basis for any irregular shape imaginable.
We differ not so much in content as in context: today, the term “parametric” can be applied to any idea-driven project; digital technology, combined with overwhelming access to information, has given rise to a plethora of formal possibilities… And still the inevitable question looms, how do we build it?
My work on the Digeotruss project is an attempt to tackle this question using the structural principles and economy of means exemplified in Buckminster Fuller’s Geodesic Dome:• Whereas a regular geodesic truss uses equilateral triangles to evenly distribute load, the Digeotruss system employs a flexible range of “close-to-equilateral” triangles - a kind of guided tesselation - that can approximate evenly distributed structures out of irregular, complexly curved forms.• Digeotruss is designed for ease of manufacture, employing only planar members with no custom joints or angled cuts. Made of multiple, non-homogenous components, a Digeotruss structure can be fabricated using only a laser-cutter or 3-axis milling machine.• Digeotruss is ultimately a method for dissecting complex NURBS surfaces into workable, structurally-based curve networks... which is to say, the possibilities of what it can be used for are vast and open to variation.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
ELEVATIONNTS
I n h a b i t a t
http://www.inhabitat.com/2009/05/06/milan-2009-2000-watt-living-by-gfry-studio/
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The Digeotruss method employs geometry to produce inherently self-supporting structures out of complexly curved forms. Composed of planar members with no custom joints or angled cuts, Digeotruss can be flat-packed for shipping and assembled without power tools.
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. It has been exibited at the Fabbrica Del Vapore in Milan (Salone Internazionale del Mobile 2009), as well as in Chicago for SAIC•s �Making ModernÓ show (June 2009), and the �ACADIA (re)FormÓ Conference (October 2009).
PROJECT SYNOPSIS:
I n h a b i t a t
http://www.inhabitat.com/2009/05/06/milan-2009-2000-watt-living-by-gfry-studio/
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2 0 0 0 W A T TL I V I N GG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
The Digeotruss method employs geometry to produce inherently self-supporting structures out of complexly curved forms. Composed of planar members with no custom joints or angled cuts, Digeotruss can be flat-packed for shipping and assembled without power tools.
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. It has been exibited at the Fabbrica Del Vapore in Milan (Salone Internazionale del Mobile 2009), as well as in Chicago for SAIC•s �Making ModernÓ show (June 2009), and the �ACADIA (re)FormÓ Conference (October 2009).
PROJECT SYNOPSIS:
The GFRY Kiosk is the first full-scale prototype of a Digeotruss Structure. Constructed of birch plywood, steel tensioning cable, and minimal hardware, the kiosk was entirely fabricated in house at SAIC, and assembled here by the GFRY team.
2000 WATTLIVINGG F R Y 0 9
DIGEOTRUSS STRUCTURAL SYSTEM
CARA ELLIS
Making Modern
RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT
UNIVERSAL HEXAPANEL HARDWARE DESIGN
RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT
RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT
RESEARCH PROJECT M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
M. ARCH UNIT 4 SPRING 2008
SITE / PROJECT ANALYSIS
PERFORMANCE OBJECTIVE FOR INTERVENTION
PARAMETERS DEFINED
INITIAL DESIGN SHAPEBased on parameters and architectural / structural /
aesthetic judgement
ANALYSISEnvironmental software / physical
testing / formal judgementMANIPULATE TO OPTIMIZE
good?
RUN SCRIPT TO PANELIZE
MANIPULATE SCRIPTUsing built-in parameters
FURTHER PARAMETRIC MANIPULATION
Based on finer definition of panels (ex. aperture, thickness,
transparency, material...etc)
MANIPULATE SHAPETo improve panelization
DEFINE IN STANDARD ARCHITECTURAL DOCUMENTATION
Plan, section, elevation, detail, construction
COMPILE FOR 3D MASS-CUSTOMIZED MODULAR
CONSTRUCTIONDigital and drawing format, specifications model with
labled parts for manufacture / construction
PROPOSAL PRECIS:
A SCRIPT TOOL FOR GEODESIC TRANSLATION OF IRREGULAR SHAPES
The goal: to create a script/ tool capable of translating any simple or irregularly
curved surface/ shape into a set of tessellated (i.e. planar and non-overlapping)
triangles that:
1) Correspond as closely to the curvature of the surface/ shape as desired –
i.e. the density/number of triangles and the size of each triangle is defined by
steepness / extremeness of angle and the level of accuracy or min-max radius
range inputted.
2) The arrangement of triangles is constrained (unlike a render tessellation)
such that vertices only meet other vertices, making a vector-active structure.
3) The tessellation attempts to create modules as close to equilateral
triangles as possible (i.e. geodesic) within a given allowable range of variation
(in order to cope with irregular shapes). This entails working with points derived
from the surface that are not orthogonal but hexagonally arranged, i.e. 60-60-60
triangles rather than 45-45-90 triangles (as is usually outputted by UV surface
paneling tools).
4) The vertices of any triangles that meet are linked such that altering of one
also alters its neighbors – they are joined to behave as a single vertex or group of
vertices.
5) Each set of three triangular points defines the vertices of a triangular
plane that can be named and parametrically linked to a more complex physical
module, for example, a curtain-wall unit or a custom panel for a solar collecting
canopy. Altering of the simple plane will alter the shape of the externally linked
module.
6) The code-tool can accept any surface/shape by input / naming nodes,
allowing iteration (i.e. like a tool, “do this” to “this” surface/shape); the
advantage being that multiple iterations of a shape can be analyzed (using
software, Ectotect, Real Flow, Wind Tunnel…etc) for performance optimization,
and then re-run through the script without time-consuming manual manipulation.
EXTERIOR PLAN VIEW
ELEVATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
CLOSE-UP OF VERTEX PLATES
DOUBLE PANE GLASS WITH GAS-FILLED INSULATING TUBE
SPACE CAN BE FILLED WITH TRANSLUCENT FOAM INSULATION
EXTERIOR PLAN VIEW
INTERIOR PLAN VIEW
2 0 0 8S A I C
UNIVERSAL HEXAPANEL JOINT
ScientificworkflowProgramanalysis
Lab Space TransformationB1 / B30 Transition Strategic Planning
09 -12 -2013
Equi
pmen
t W
orkflowsDiscovery Translational
SciencesDevelopment
Therapeutic Themes
BasicNon-GLP
Human BiologyData Creation
GLP RequirementsStructured by People
+ Products
P2 + P3 Clinical TrialsRegulatory (GLP)
Amgen at a Glance: R&D Workflow
1
1
2
3
4
5
Introduction + Amgen at a Glance
Molecular Science + CB + IVD Structure & Workflow
Clinical Immunology Structure & Workflow
Pharmacokinetics + DMD Structure & Workflow
Lab Space Transformation Hypothesis
1
Contents Introduction
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MassSpec
Tissue Culture
FACS + Imaging
MicroArray
I S I S
Common Open LabShared Instrumentation
Short Term Sample Storage
BSM + Material Management
LABMolecular
ScienceIn Vitro
Diagnostics
Computational Biology
Clinical ImmunologyAssays
Increasing emphasis on time spent in office vs. lab environment:Data Analysis / Modeling / Interpretation
S
BSM + Material Management
Lab Work OfficeData Analysis
In Lab Samples
SI
Molecular Science + CB + IVD Structure & Workflow
S
= Instrumentation
= Support
I
2
MassSpec
Tissue Culture
FACS + Imaging
MicroArray
I S I S
Common Open LabShared Instrumentation
Short Term Sample Storage
BSM + Material Management
LABMolecular
ScienceIn Vitro
Diagnostics
Computational Biology
Clinical ImmunologyAssays
Increasing emphasis on time spent in office vs. lab environment:Data Analysis / Modeling / Interpretation
S
BSM + Material Management
Lab Work OfficeData Analysis
In Lab Samples
SI
Molecular Science + CB + IVD Structure & Workflow
S
= Instrumentation
= Support
I
2
IS
S
BSM + Material Management
Sample Prep Bench(Automation)
In Lab Samples
Suite approach to workflow:Emphasis on equipment, especially hoods.
I S
BioAssay
I S
Outsourcing
ResearchOps
I
CytometryServices
S
I S
Immuno Assay
I S
In Vitro Diagnostics
I S
MechanisticImmunology
Staff Reps. from
IA + BA + CS
+
CORE LAB
OFFICE STAFF / PERIPHERAL
LAB
Emphasis on consulting:
idea - generation /
process guidance;
use of outsourcing to augment
assay production
BSM + Material Management
MassSpec
Tissue Culture
Clinical Immunology Structure & Workflow
S
= Instrumentation
= Support
I
3
MassSpec
Tissue Culture
MassSpec
Pharmacokinetics + Discovery Metabolic Disorders Structure & Workflow
S
= Instrumentation
= Support
I 4
Small Molecule
I S
DMD
I S
I S
Large Molecule
Bio Analytical
LAB BIO ANALYTICAL
BSM + Material Management
SI
MassSpec
RadioLabel
Automa-tion
Cell Culture
BSM + Material ManagementResearch Groups
DMD
Sample Prep Sample Prep
SI
MassSpec
BSM + Material ManagementResearch Groups
Small Molecule
SIMSD
ELISA GYROS
BSM + Material ManagementResearch Groups
Large Molecule
Sample Prep
MassSpec
Tissue Culture
MassSpec
Pharmacokinetics + Discovery Metabolic Disorders Structure & Workflow
S
= Instrumentation
= Support
I 4
Small Molecule
I S
DMD
I S
I S
Large Molecule
Bio Analytical
LAB BIO ANALYTICAL
BSM + Material Management
SI
MassSpec
RadioLabel
Automa-tion
Cell Culture
BSM + Material ManagementResearch Groups
DMD
Sample Prep Sample Prep
SI
MassSpec
BSM + Material ManagementResearch Groups
Small Molecule
SIMSD
ELISA GYROS
BSM + Material ManagementResearch Groups
Large Molecule
Sample Prep
MassSpec
Tissue Culture
MassSpec
Pharmacokinetics + Discovery Metabolic Disorders Structure & Workflow
S
= Instrumentation
= Support
I 4
Small Molecule
I S
DMD
I S
I S
Large Molecule
Bio Analytical
LAB BIO ANALYTICAL
BSM + Material Management
SI
MassSpec
RadioLabel
Automa-tion
Cell Culture
BSM + Material ManagementResearch Groups
DMD
Sample Prep Sample Prep
SI
MassSpec
BSM + Material ManagementResearch Groups
Small Molecule
SIMSD
ELISA GYROS
BSM + Material ManagementResearch Groups
Large Molecule
Sample Prep
I S I S I S I S
MassSpec
Clinical Immunology
Tissue Culture
BA IA CS
OS RO
MII S I S I S
MassSpec
PKDM
Tissue Culture
MSDELISA
GYROS
LM SM DMBio Analytical
I S I S
Molecular Science + CB + IVD
MassSpec
Tissue Culture FACS
MicroArray
MS IVD CB
BSM + Material Management
Current State: “Continental Divide” 5
SElected art worksCollage • Painting • Animation& OTHER POST EARTH MUSINGS
2 0 1 0 - 2 0 1 4
SElected art worksCollage • Painting • Animation& OTHER POST EARTH MUSINGS
2 0 1 0 - 2 0 1 4
ABSTRACT + MoBILE ARTWORK