cody d storey | rhode island school of design
D Storey | Lost in the Desert: Las Vegas Field Research | Dossier 1/4
cody d storey
rhode island school of design Master of Architecture 2012
007 025 039 049 059
Detroit Redux
d3 Natural Systems Competition Elderly Housing+Campus Tiber Floods
School for the Digital Arts
MEDIUM 073 093 101
Concrete Frame House Theater
Elmwood Community Garden
SMALL 115 119 123 127
Coffee Table
Spindle Stool
Skrimp Lamp
Plywood Furn
Table of Contents | Cody D Storey
LARGE
LARGE
Spring 2011
Detroit Redux The Detroit Pistons’ new arena is sited along the waterfront of downtown Detroit. It is a beacon to regional fans as well as an example to be followed for future development. The roof of the arena becomes a site of occupancy where visual connections are made between paying fans, players and tailgaters on the outside. This is achieved through deep cuts and peeling in the roof plane. This peeling facilitates the insertion of program, geometry and the hard and soft surface that provide opportunities for different sports and activities. The exclusivity of the stadium is inverted and spilled out across the site; this gives fans a place to create their own competitions. The landscape is an extension of the stadium, forging connections to the greater area as an outdoor fitness park and place where fans without tickets can simply lean against the arena roof and see their team play.
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Detroit Warehouse ruin . juxtaposed . history . emptiness
LARGE: Detroit Redux | Cody D Storey
Detroit Warehouse poetry . rebirth . reoccupy . offering
LARGE: Detroit Redux | Cody D Storey
Renaissance Center parking lot . scale . Millennium Park
LARGE: Detroit Redux | Cody D Storey
Parking Lot asphalt . orchards . fitness park
Sketch Models light . beacon . cut . swell
LARGE: Detroit Redux | Cody D Storey
Hybrid Process above . ground . below . citizen . class
Downtown Detroit dequindre cut . chrystler freeway . people mover
Cody D Storey LARGE: Detroit| Redux Detroit| Arena Cody D Storey
Arena gather . density . hardscape . softscape
LARGE: Detroit Redux | Cody D Storey
Arena transparency . occupancy . outside(r)
LARGE: Detroit Redux | Cody D Storey
Pistons tailgaters . public views . inside(r)
Model respond . reveal . unify
LARGE: Detroit Redux | Cody D Storey
Model Detail fractured facade . landscape . public
LARGE
Summer 2011 | Collaboration 1+5
d3 Natural Systems Design Competition In the summer of 2011 I organized and lead a small design collaboration. We developed a basic business model, a way of working and submitted 3 competition proposals while maintaining regular contact with 2 advisors. This student based firm consisted of myself and 5 of my fellow graduate students. We collaborated from various parts of the country including UC Berkeley, Yale University, University of Utah and The Rhode Island School of Design. This is one of the resulting entries from that summer. This project was submitted to New York’s d3 Natural Systems competition. The project was published and exhibited later that year. What follows are the group’s competition boards and my contribution to the project.
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Team 1703 - 1 graphic . history . future . emptiness
LARGE: d3 Natural Systems | Cody D Storey
Detroit Re-imagined machine . society . learned behavior
Team 1703 - 2 densify . resources . deploy . berm
LARGE: d3 Natural Systems | Cody D Storey
Detroit Evolution neohuman . extension . survival . hope
Hybrid Process photograph . space . ruin porn
LARGE: d3 Natural Systems | Cody D Storey
Hybrid Process natural systems . relics . self awareness
LARGE: d3 Natural Systems | Cody D Storey
Density neighborhoods . void . resource(fulness)
LARGE: d3 Natural Systems | Cody D Storey
Density raw . material . interstitial
Abandon creation . destruction . memory
LARGE: d3 Natural Systems | Cody D Storey
Detroit Aware perpetuate . cycle . rediscovery
LARGE
Fall 2010
Elderly Housing + Campus This housing campus embraces the freedom of retirement while providing comfortable support facilities to aid the residents in their daily routines. By reacting to the three major local elements, the river, the hill to the east and Wickenden Street, the project is sculpted to embrace the local activity as well as the natural elements that it boarders. Taking advantage of river views, the housing levels rise to create a visual connection to the urban fabric while still maintaining porosity toward the landscape. Within the units themselves, residents have the option of supported living through open adjacent occupancy. This allows for kitchens and laundry rooms of two neighboring units to be shared giving residents the option to support one another by combining daily tasks with that of their neighbors. This concept is echoed throughout the program with communal moments of rest that grow in size as you move through the building. The weaving landscape aids in the support of relaxation by creating a series of secluded areas that slope into expanded open lawns within the courtyard. Below the triangular slopes rainwater is collect for various uses within the campus. The program includes exercise facilities, a small grocery store, cafe and a continuing education center.
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LARGE: Elderly Housing+Campus | Cody D Storey
3D Study Model aggregate . depth . access . light
LARGE: Elderly Housing+Campus | Cody D Storey
Unit Layout independent . shared . support
Massing Stack view . exterior
LARGE: Elderly Housing+Campus | Cody D Storey
Massing Corner urban . fabric . response
Circulation Models development . vertical access . massing
LARGE: Elderly Housing+Campus | Cody D Storey
Model courtyard . public . private
LARGE
Winter 2011
Tiber Floods The Tiber River and the city of Rome have a long and turbulent relationship. After the 1870 flood large embankment walls were constructed at great cost to the urban fabric of the city. Nearly 20% of the city was removed to facilitate these protective measures. The focus of this studio was to view the seasonal flooding with a contemporary lens. How much flooding can the city tolerate? What solutions can be offered to reconnect Rome with its hidden river? Centered around the Forum Boarium I began to reconnect not only the river with the city but the three ancient temples as well. An axial path was used to generate a piercing strategy. Traffic was diverted and a new landscape was created between the monuments and the river. The river platform releases part of its architecture to become a current driven ferry system. Similar systems can still be seen today in cities such as Basel. The site itself can be flooded in stages safely. In the case of a 100 year flood the pierced wall would be sealed by large flood gates housed within the wall itself. The duality of flooded to pedestrian space is explored around the temples themselves with anthropomorphic subtractions. The archway construction can be repeated to reinvigorate space all along the Tiber. Retail spaces can also be inserted to draw Rome back to the Tiber.
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Tiber Island ponte rotto . flood height . displacement
LARGE: Tiber Floods | Cody D Storey
The Wall derelict . pierce . cloaca . reconnect
Aqueduct Sketches (Top) water . origin . distal . connection
LARGE: Tiber Floods | Cody D Storey
Field Measurements (Bottom) water . result . separation . proximal
LARGE: Tiber Floods | Cody D Storey
LARGE: Tiber Floods | Cody D Storey
LARGE
Spring 2009
The New School for Digital Arts This new school considers our current educational system and challenges it. With access to stateof-the-art digital processing labs and flexible collaborative spaces students can receive an education based on a way of thinking rather than test scores. This development, located near the heart of downtown Salt Lake City, considers the concept of filtration and physical permeability. This conceptual framework creates the connective tissue that is so necessary for the school and its downtown community. This concept also allows the students and faculty to interact in a distraction free learning environment while other parts of the program welcome distraction as an impetus for creativity. Additionally, it explores the notion that students not only learn from their respective teachers but from the building itself. Revealing methods of construction , sources of energy and other concepts embedded with in the structure to the students as a way of architectural communication.
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The Edge of Density downtown . mall . rail yard . arena
LARGE: New School for Digital Arts | Cody D Storey
Shadow Study connectivity . public transit . energy
LARGE: New School for Digital Arts | Cody D Storey
Building as a Camera aperture . projection . permeability
Open Web Joist
Concrete Decking w/ Radiant Heat
W-Section (W21)
Wall Section structure . thermal mass . protrusion
LARGE: New School for Digital Arts | Cody D Storey
Glazing w/ Vertical Stiffeners
Stack Effect (Top) Possible Double Glazing Detail (Bottom) trombe wall . heat collection . ventilation
LARGE: New School for Digital Arts | Cody D Storey
HVAC Detail (Top) Cooling (Left) Heating (Right) radiant . return . supply . access
Wall Section Model structure . HVAC . radiant flooring
LARGE: New School for Digital Arts | Cody D Storey
Wall Section Detail south face . insulation . HVAC . performance
LARGE: New School for Digital Arts | Cody D Storey
Final Model LED projection . aperture . experience
MEDIUM
Fall 2011 | Collaboration 1+2
Concrete Frame House The concrete frame house is designed for a visiting music professor at the Brown School of Music. It has a focus on performance both on the systems from which it is comprised, and the space of performance which is built into its program. The concrete, both precast and cast-in-place, are used to enhance the acoustics, environmental systems, and spatial qualities of the house. The structural framework of the house is two large walls that divide a circulation space from living space, and operate as a fulcrum and counterweight to cantilever the 2nd floor sleeping areas over the performance space on the ground floor. The cantilever allows for a seamless transition from interior to exterior and connection to the surrounding context.
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eping areas over the performance space on the
ws for a seamless transition from interior to e
rounding context.
Early Conceptual Sketch balance . cantilever . continuity
MEDIUM: Concrete Frame House | Cody D Storey
2ND LEVEL CANTILEVER FRAME
FULCRUM
COUNTERWEIGHT
Concept Developed in Axon concrete . frame . cast
CONSTRUCTIONSEQUENCE SEQUENCE CONSTRUCTION PHASE 1: PHASE FOUNDATIONS/BASEMENT 1: FOUNDATIONS/BASEMENT 1: FOUNDATIONS/BASEMENT PHASEPHASE 1: FOUNDATIONS/BASEMENT
PHASE 2: PHASE SLAB ON 2: GRADE, SLAB ON GRADE, PHASE 2: ON SLAB ON GRADE, PHASECOLUMNS, 2: SLAB GRADE, PRIMARY FULCRUM & PRIMARY COLUMNS, FULCRUM & PRIMARY COLUMNS, FULCRUM & PRIMARY COLUMNS, FULCRUM & COUNTERWEIGHT COUNTERWEIGHT COUNTERWEIGHT COUNTERWEIGHT
PHASE 3: PHASE PRIMARY 3 3 PHASEPHASE 3: PRIM
UENCE EQUENCE EQUENCE UENCE
PHASE 3: PRIMARY FLOOR BEAMS HASE 3: PRIMARY FLOOR BEAMS PHASE 3: PRIMARY FLOOR BEAMS 3: PRIMARY FLOOR BEAMS PHASE 6: PHASE TOP PHASE TIE6:BEAMS TOP TIE BEAMS TOP TIE BEAMS PHASEPHASE 6: TOP6:TIE BEAMS
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PHASE FOUNDATIONS/BASEMENT PHASE 1: 1: FOUNDATIONS/BASEMENT PHASE 4: NORTH & SOUTH SIDE PHASE 4: NORTH & SOUTH SIDE TIE ROOF BEAM; AND SECONDARY WALL TIE BEAM; AND SECONDARY WALL PHASE 4: NORTH & SOUTH SIDE PHASE 4: NORTH & SOUTH SIDE PHASE 7: PHASE SECONDARY ROOF BEAMS 7: SECONDARY BEAMS STRUCTURE STRUCTURE TIE BEAM; SECONDARY WALL TIE BEAM; AND SECONDARY WALL PHASE 7: SECONDARY ROOF BEAMS PHASE 7:AND SECONDARY ROOF BEAMS STRUCTURE STRUCTURE
PHASE SLAB PHASE 2: 2: SLAB O PHASE 5: RADIANT PRIMARY COLU PRIMARY COLUM SECOND FLOOR C8 PHASE RADIAN COUNTERWEIG PHASE 8:5: FINAL W PHASE COUNTERWEIGHT SECOND FLOOR PHASEPHASE 8: FINA8
I N T E G18 R AT E D I LRDAT I NEGD SY ST S G SY S T E M S I NBT U EG BU I LEDMI N
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N TEEDG B RU ATI LED DI N BG U ISY L DSI N I N18 T E G RIAT T EGMSY S STEMS
PHASE 2: PHASE SLAB 2: ONSLAB GRADE, ON GRADE, PHASE 2: PHASE SLAB2:ON SLAB GRADE, ON GRADE, PRIMARY PRIMARY COLUMNS, COLUMNS, FULCRUM FULCRUM & & PHASE 5: RADIANT FLOOR SLABS; PRIMARY PRIMARY COLUMNS, COLUMNS, FULCRUM FULCRUM & & COUNTERWEIGHT PHASE 8:FLOOR FINAL WALLFLOOR BLOCKS HASE 8: FINAL WALLCOUNTERWEIGHT BLOCKS PHASE 5: RADIANT SLABS; SECOND COLUMNS COUNTERWEIGHT COUNTERWEIGHT PHASE 8: FINAL WALL BLOCKSSECOND PHASE FLOOR 8: FINAL WALL BLOCKS COLUMNS
PHASE 3: PRIMARY FLOOR BEAMS PHASE 3: PRIMARY FLOOR BEAMS PHASE 3: PHASE PRIMARY 3: PRIMARY FLOOR BEAMS FLOOR BEAMS PHASE TOP BEAMS PHASE 6: 6: TOP TIETIE BEAMS PHASE 9: ROOF SLABS PHASE 9: ROOF SLABS PHASE 9: ROOF SLABS
PHASE SECO PHASE 7: 7: SECON PHASE 10: COMPL PHASE 10: COMP
PHASE 9: ROOF SLABS
G SSY SM T ESM S 1818 I N TI NE GT ERGATREATDEBDUBI LUDI LI NDGI NSY TE
PHASE 7: SECONDARY ROOF BEAMS PHASE 7: SECONDARY ROOF BEAMS PHASE 7: PHASE SECONDARY 7: SECONDARY ROOF BEAMS ROOF BEAMS PHASE 10: COMPLETION PHASE 10: COMPLETION
PHASE 8: FINAL8:WALL PHASE FINALBLOCKS WALL BLOCKS PHASE 8: PHASE FINAL8:WALL FINALBLOCKS WALL BLOCKS
Construction Phasing order . placement
CONCRETE FRAME HOUSE CONCRETE FRAME HOUSE
19 19
MEDIUM: Concrete Frame House | Cody D Storey
Environmental Studies heat loss . heat gain . solar path
HEATING & COOLING: WINTER
DOCUMENTAT
: SECTIONS N: SECTIONS EAST SECTION A 1”= 32’
HOPE ST & BENEVOLENT ST, COLLEGE HILL
SECTION B 1”=32’
WEST
SECTION B
ELEVATION
EAST
NORTH
Elevations+Sections living . sleeping . access WEST
SOUTH
1”=16’
CONCRETE FRAME HOUSE
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TION: PLAN MEDIUM: Concrete Frame House | Cody D Storey
SECTION A
Plan axial . landscape . performance
I N G SY S T E M S
PRECAST ROOF PANEL WITH INSULATION
TEAK LOUVERS
GLAZING TROMBE WALL
STEEL CANTILEVERED STAIRS
MEMBRANE FOUNDATION
RIGID INSULATION RIGID INSULATION
DRAINAGE
GRAVEL MEMBRANE
South Wall Section heat gain . insulation . natural light
DETAILS: SOUTH WALL SECTION DETAILS: SOUTH WALL SECTION
CONCRETE
RIGID INSULATION RIGID INSULATION
PV ROOF TILES PV ROOF TILES
FLASHING FLASHING
UPPER LOUVER BRACKET UPPER LOUVER BRACKET
1-1/2”=1’
TEAK LOUVERS
1-1/2”=1’
TEAK LOUVERS
IN-SET STAIR WINDOWS
IN-SET STAIR WINDOWS
THERMAL BRIDGE BOLTS
THERMAL BRIDGE BOLTS (WARMS STAIRS) (WARMS STAIRS)
LOWER LOUVER BRACKET
LOWER LOUVER BRACKET
CONCRETE FRAME HOUSE
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CONCRETE FRAME HOUSE
1-1/2”=1’
1-1/2”=1’
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South Wall Details thermal bridge . surface temperature . roof detail
MEDIUM: Concrete Frame House | Cody D Storey
CONCRETE
12 I N T E G R AT E D B U I L D I N G SY S T E M S
DETAILS: NORTH WALL SECTION
METAL STUD WALL
FIBER CEMENT CONCRETE PANELING
CONCRETE FRAME
CONCRETE SLAB WITH RADIANT PIPING
OPERABLE GLASS DOOR WITH TEAK LOUVERS
North Wall Section
DETAILS: NORTH WALL SECTION cantilever . flexible performance space
DETAILS: NORTH WALL SECTION
EXPOSED CONCRETE SLAB
PV ROOF TILES
RIGID INSULATION 4” RIGID INSULATION FIBER CEMENT EXTERIOR PANELING IN METAL STUD WALL
EXPOSED CONCRETE SLAB
MOISTURE BARRIER FIBER CEMENT EXTERIOR PANELING
FLASHING
TYVEK RIGID INSULATION MOISTURE BARRIER
TYVEK RIGID INSULATION BLOCKING
WOOD FRAMING
UPPER LOUVER BRACKET
INSULATION BLOCKING
WOOD FRAMING GASKET
FIXED FRAME INSULATION 1-1/2”=1’
1-1/2”=1’
GASKET
MOVABLE FRAME TEAK LOUVERS FIXED FRAME 1-1/2”=1’ MOVABLE FRAME
DRAINAGE CHANNEL
SILICONE SEALANT DRAINAGE CHANNEL
IN-SET STAIR WINDOWS
RIGID INSULATION
THERMAL BRIDGE BOLTS (WARMS STAIRS)
DRYWALL
EXTERIOR SLAB SILICONE SEALANT
INTERIOR SLAB WITH RADIANT PIPING
EXTERIOR SLAB
INTERIOR SLAB WITH RADIANT PIPING
BLOCKING DRYWALL
WINDOW HEADER RIGID INSULATION
DOUBLE BLOCKING PANE GLASS
WINDOW HEADER
DOUBLE PANE GLASS
LOWER LOUVER BRACKET RIGID INSULATION
MOISTURE BARRIER RIGID INSULATION
SILL GRAVEL
CONCRETE FRAME HOUSE
C O N C R E T E FC RO AN MC E RHEOTU E SFER A M1E3H O U S E
1-1/2”=1’
MOISTURE BARRIER
SILL GRAVEL
1-1/2”=1’
1-1/2”=1’
1-1/2”=1’ 1-1/2”=1’
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North Wall Details water barrier . ground seam
MEDIUM: Concrete Frame House | Cody D Storey
4” RIGID INSULATION CONCRETE IN METAL STUD WALL
1
2
3
4
5
6
LS: WALL SECTION 1. Concrete Cladding 2. Vapor Barrier 3. Blocking 4. Insulation 5. Studs 6. Insulation 7. Concrete Frame 8. Slab & Joists
U I L D I N G SY S T E M S
Wall Construction Model half scale . concrete frame . glass . insulation
9. Acoustic Panels 10. Wood Frame 11. Blocking 12. Wood Frame 13. Fixed Window Frame 14. Operable Window Frame 15. Louvers 16. Glazing
9. Acousti 10. Wood F 11. Blockin 12. Wood F 13. Fixed W 14. Operab 15. Louver 16. Glazing
TION
MEDIUM: Concrete Frame House | Cody D Storey
1. Concrete Cladding 2. Vapor Barrier 3. Blocking 4. Insulation 5. Studs 6. Insulation 7. Concrete Frame 8 8. Slab & Joists
AILS: EXPLODED WALL SECTION
5
6
9. Acoustic Panels 10. Wood Frame 11. Blocking 12. Wood Frame 13. Fixed Window Frame 5 Window 6Frame 14. Operable 15. Louvers 16. Glazing 1 2
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7
10 11 12
13
8 7
9
14
3
4
5
6
7
15
9. Acoustic Panels 10. Wood Frame 11. Blocking 12. Wood Frame 13. Fixed Window Frame 14. Operable Window Frame 15. Louvers 16. Glazing
16 10 11 13
CONCRETE FRAME HOUSE
12
1. Concrete Cladding 2. Vapor Barrier 3. Blocking 14 4. Insulation 5. Studs 6. Insulation 7. Concrete Frame 16 8. Slab & Joists
15
17
9. Acoustic Panels 10. Wood Frame 11. Blocking 12. Wood Frame 13. Fixed Window Frame 14. Operable Window Frame 15. Louvers 16. Glazing CONCRETE FRAME HOUSE
Wall Construction Axon detail . bolt through frame . joint
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17
DETAILS: CLADDING
BLOCKING
CEMENT FIBER BOARD
LATERAL GASKET DRIP EDGE
CORNER PIN
CONCRETE FRAME HOUSE
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Cladding Detail fiber cement . pins . frame
PIN SLEEVE
MEDIUM: Concrete Frame House | Cody D Storey
EED LLD SSTTSEETM ETG GER RGAT AT DE B BU UBIIU NIG GN SY SYSY MESSM S R AT D IDLIIN D G
GLASS GLASS GLASS
LOUVER & & LOUVER LOUVER & SUPPORT STRUCTURE STRUCTURE SUPPORT SUPPORT STRUCTURE
STEEL FRAME FRAME STEEL STEEL FRAME
DOUBLE PANE PANE GLASS GLASS DOUBLE DOUBLE PANE GLASS
WINDOW GROOVE GROOVE WINDOW WINDOW GROOVE
20” THREADED THREADED ROD ROD 20” 20” THREADED ROD
BENT METAL METAL PLATE PLATE BENT BENT METAL PLATE IN-SITU CONCRETE CONCRETE IN-SITU IN-SITU CONCRETE COUNTER WEIGHT WEIGHT WALL WALL COUNTER COUNTER WEIGHT WALL
Counterweight Wall+Stair Detail thermal bridge . thermal mass
Water Collection landscape . site response
NDSCAPING MEDIUM: Concrete Frame House | Cody D Storey
T E G R AT E D B U I L D I N G SY S T E M S
Landscape south face . garden . office . deck
ACOUSTIC DIAGRAM: DOORS CLOSED
ACOUSTIC DIAGRAM: DOORS OPENED
Acoustic Studies closed . open . performance
MEDIUM: Concrete Frame House | Cody D Storey
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I N T E G R AT E D B U I L D I N G SY S T E M S
Performance Space closed . open . material
MEDIUM
Fall 2009
Theater Beginning with the most basic system, the knot, I investigated the various design possibilities that can evolve from that system. Moving from stage to stage via design charettes, I investigated ground, site, light, materiality and modular design. Warm toned wood is used to draw a gradient of light back through the crowd. The exterior walls are constructed with concrete modules. These modules contain the logic of the knot and give the building its porous appearance and illuminative permeability. The program of a 1.5 scale puppet theater gave me the opportunity to design based on the sidedness of the spectacle. Traditional indoor seating was created for a more intimate performance space while the outdoor seating provided for a dramatic view across a ravine. At night, the theater serves as a beacon to would be patrons. The performance casts its shadows on the surrounding trees and landscape, animating them with light.
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Module Differentiation fold . stack . aggregate
MEDIUM: Theater | Cody D Storey
Model+Drawn Studies transformation . transition . opacity
Model+Section views . audience . duality
MEDIUM: Theater | Cody D Storey
Spatial Configuration stage . behind . above . below
Cast Module section . strength . porosity
MEDIUM: Theater | Cody D Storey
Final Model aggregate . ground . building
MEDIUM
Spring 2010 | Collaboration 1+12
Elmwood Community Garden Elements: shaded area, perimeter fence, tool storage, planting beds, and pedestrian/truck access. These elements create zones of varied activity. Public areas such as tool storage and major pathways as well as the semi-private planting beds, provide new and unique opportunities for the people of Elmwood to connect with one another. The relationship between the planting areas can thus provide not only an efficient and usable space, but an opportunity to engage with the local community. We investigated this relationship by designing beds of different proportions and orientations. Spaces for kneeling, standing, and sitting are integrated throughout each of the four planting areas. This combination of differing bed types allows each member of the community garden to work where they are most comfortable. My role as co-designer, construction manager and coordinator of the modular installation can be seen throughout the following project.
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Site Panoramas opportunity . community
MEDIUM: Elmwood Community Garden | Cody D Storey
Site open . landscape
Perimeter Beds (Top) Interior Planting Beds (Bottom) ease of access . raised bed . kneeling bed
MEDIUM: Elmwood Community Garden | Cody D Storey
Final Model bed layout . variety . flexibility
MEDIUM: Elmwood Community Garden | Cody D Storey
Layout tool storage . beds . garden
Modular Design preparation . dry fit
MEDIUM: Elmwood Community Garden | Cody D Storey
Bed Frame compound angle . module
Module Installed section . irrigation . planting
MEDIUM: Elmwood Community Garden | Cody D Storey
Beds Installed and Connected path . raised bed . kneeling bed
MEDIUM: Elmwood Community Garden | Cody D Storey
SMALL
Fall 2010
Coffee Table Based on my interest in furniture design and a semester worth of research and practice I created a piece of my own. This table is designed around subtle functionality that contains a variety of volumes within. These volumes showcase objects of different scales. Made with the light-colored hardwood, European Beech, the table highlights the objects placed within it. The austere front of the table gives a small hint of depth which is prominent on the other side. Moving around the piece the sectional quality of the wrapping planes becomes dominant. The feet are made of mahogany. The rounded form and dark appearance allow them to disappear beneath the shadow of the table.
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SMALL: Coffee Table | Cody D Storey
SMALL
Winter 2012
Spindle Seat Made of recycled materials totaling $5, this project reimagines the use of those materials. The plastic tops were caps in a former life, the spindles and cones held thread. Connected together and splayed outward they have a collective strength. The nature of the cone ensures a secure press fit connection that can be reconfigured at any time. This allows for maximum flexibility of the base unit. This seat functions as a rocking chair, ottoman, storage for rolled drawings or as a stackable acoustic surface.
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SMALL: Spindle Seat | Cody D Storey
SMALL
Winter 2012
Skrimp Lamp Made from general purpose dust masks this hanging lamp filters light, changes shape and disperses heat generated by the bulb. Using the same construction logic as the dust mask I was able to create a free form hanging sculpture using only staples and the elastic head bands. The masks also form a protective cushion that allows the lamp to be shipped as is while protecting the large filament Edison bulb inside.
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SMALL: Skrimp Lamp | Cody D Storey
SMALL
Summer 2012
Plywood F端rn Series These tables were designed with a few simple concepts in mind, keep them simple, compact, and affordable. Made of birch plywood and steel pipe the connections are basic and strong. The dining table has adjustable screw type legs capped in white oak. Easily removable for transportation or to simply free up space around the house. The desk and side table both rely on gravity to lock the loose pipe into place. These are just as simple to breakdown but slightly more complicated to build. By giving the legs a splayed compound angle the weight of the tables forces the legs into fixed positions. If the weight is removed the legs simple fallout and the table can be stored flat or in a corner out of the way.
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SMALL: Dining Table | Cody D Storey
SMALL: Gravity Table | Cody D Storey
SMALL: Gravity Desk | Cody D Storey
D Storey | Lost in the Desert: Las Vegas Field Research | Dossier 1/4
cody d storey
website | www.codydstorey.com
contact | codydstorey@gmail.com