JOSH ROSENTHAL
PUBLIC
MIXED-USE
RECREATION
THE NEST: LANE COUNTY COURT _ 2
ZIPPER SPACE _ 12
EDISON ELEMENTARY SCHOOL_6
LENTS MARKET _14
URBAN ANALYSIS IN BARCELONA _ 25
INTERNSHIP WITH DLR GROUP_10
DOWNTOWN REDEVELOPMENT _ 18
TINY HOUSE_26
SHOP HOUSE _ 20
BALCONY SUNSPACE_27
Josh Rosenthal 1415 SW Alder St. Portland, OR 97205 rosenthalj1225@gmail.com 513-235-9788
BOATHOUSE _ 22
STUDIES TIMBER GRIDSHELL _ 24
THE NEST: LANE COUNTY COURTHOUSE Term: Fall 2017 Project Location: Eugene, Oregon Media: Rhino Derived from the parti of objects in space, the Nest consists of four stacked courtroom “eggs” surrounded by efficient office blocks. The design serves as a proposal by a team of four for the new Lane County Courthouse in downtown Eugene, Oregon. The structure of the building is almost entirely mass timber consisting of glulam columns and beams, CLT rocking walls and slabs, and curved CLT shear walls for the eggs. The office blocks surrounding the eggs include Court Administration to the east, state offices to the north, the DA to the west, and Jury Assembly to the south. Between these spaces are public and private atriums enclosed in semi-conditioned spaces. The public atrium contains a bioswale system. Other sustainable features of the project include maximum daylight potential, proper shading devices for each façade condition, and the use of double facades where necessary. The building is roughly 300k square feet.
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COURTROOM DAYLIGHT SECTION PERSPECTIVE
GROUND FLOOR PLAN
COURTROOM RENDER
2ND FLOOR PLAN
3
Finish Floor Over Plenum 12x12 Glu-lam Column Vertical Operable Louvers Horizontal Louvers GLULAM ROOF ASSEMBLY
6x12 Glu-lam Column
GLULAM COLUMNS + BEAMS
Shading Track/ Catwalk
Spider Joint
Metal Panal
Silicone
Finish Floor Over Plenum
Concrete Deck CLT Slab
Cable Wind Connection to Frame Louver
CLT FLOOR SLABS
Drop Ceiling
MASS TIMBER SYSTEMS
STRUCTURES DIAGRAM
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CLT SHEAR + ROCKING WALLS
East/West Facade 3/8” = 1’ - 0”
FACADE DETAIL
South Curtain W 3/8” = 1’ - 0”
FULL BUILDING MODEL: REDWOOD, CNC CUT PLYWOOD, COVER BOARD, CHIPBOARD, PLEXI
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EDISON ELEMENTARY SCHOOL Term: Winter 2018 Project Location: Eugene, Oregon Media: Rhino This design serves as a proposal by a team of three for a new K-6 school in South Eugene. The school is net-zero in design and is carefully tied to the surrounding context through the use of building orientation, gardens, and community spaces. The parti is two, east-west oriented bars connected by transparency axes. These bars are covered in a highly insulated, metal shell which is peeled away to reveal the warm wood interior of the building. The building is separated into public and private uses so that community functions can happen after hours while securing the classrooms. The central axis of the building is formed by the main hall and library. The gym, cafeteria, and music room are located west of the main axis and are tied together by a rain garden and transparency axis. The two level classroom bars are located east of the main axis and are tied together through a learning garden. Net zero attributes include a large PV rack, water collection, insulation, building orientation, and daylighting.
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2ND FLOOR PLAN
GYM SERVICES CAFETERIA LIBRARY ARTS AND MUSIC
GROUND FLOOR PLAN
ADMINISTRATION CLASSROOMS
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1 8
8
9
9
5
7
7
2
5
10 6
5
5
4
0’
8
3
10’
20’
50’
1. 2. 3. 4. 5.
Sun Angles for 44° Latitude Light Shelf Improves Daylighting Climate-Responsive Shell: R-43/R-62 Geothermal Wells Classrooms - Sidelit and Toplit
6. 7. 8. 9. 10.
Operable Windows and Shutters Light Tube for Bottom Classrooms Stack Vent for Peak Cooling Days Monocrystalline Solar Panels (1,200 kBtu/year) Learning Landscapes
BIOSWALES CISTERN
• INTEGRATED LEARNING • 5,000 SF LANDSCAPE
PV Rack
• 10,000 SF ROOF AREA • 317,730 GALLONS
Warm Wood Interior: 3-Pin arches isolate structure to the shell
Insulation Layer: R-50 Walls and R-60 Roofs of Sheeps Wool and Green Guard Insulation
Metal Exterior Cladding
RAIN GARDEN
GREEN ROOFS
• EVENT/DINING SPACE • 1,000 SF PLANTED AREA
• COVER 20% OF ROOF AREA • 5.3 INCHES DIVERTED
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INTERNSHIP AT DLR GROUP Term: Summer - Fall 2018 Location: Portland, Oregon Media: Revit, SketchUp, Cura, PhotoShop, Illustrator Work shown is the property of DLR Group and has been used with permission. Throughout my internship I worked on various tasks relating to an elementary school in Hillsboro, Oregon. My main task was the development of a series of 3D printed section models scaled at 1/8” = 1’ 0”. The models were exported from Revit to SketchUp to be sorted into printable pieces. These pieces would then be exported from SketchUp to Cura to program print settings. Following this, the pieces would be printed, glued together, and placed on a laser cut base. In addition to the models, I also helped with facade panel optimization on the school and made several renders for community presentations. While at DLR, I also worked in a team of three to develop booklets for two AIA award submissions in which I primarily worked on diagramming and other graphics. One submission was for the Oregon Youth Authority MacLaren Campus Cottages, a youth detention center with a focus on positive human development. This submission won honorable mention in the 2018 Seattle AIA Awards. Another submission was for the Beaverton School District prototype elementary schools.
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INDIVIDUALIZED USE
The Heart Creating a “heart” for every school is one of the district’s guiding principles. If equity starts with the caregivers, then the school must empower their behaviors. OYA SITEThe PLANheart consists of six critical program elements that operate individually and together as a whole.
OYA VISIBILITY DIAGRAMS
Gym GYM The gym accommodates performing arts and large events in addition to fitness and athletics.
Commons COMMONS The commons is located at the school center, and it is the hub for STRONG BASE BEAVERTON FLIP DIAGRAM all specialized program. 120
Foot Candles
Classrooms on the Kitchen KITCHEN second floor.
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100
is an integral90part of the Making the Food classrooms 80 work required a significant school day. amount of research. Working 70 with a sustainability expert 60 throughout the design process, 50 the building is modulated at 40 a variety ofMEDIA levels toCENTER achieve 30 quality daylight, views of Physical books are still important nature and optimal shape. 20
Media Center
for this age group.10
Outdoor Classroom OUTDOOR CLASSROOM
Outdoor learning happens throughout the school year.
Courtyard COURTYARD
The outdoor commons is safe and easy to supervise.
0
Design Elements Classroom size Ceiling height and shape Skylight location and size Exterior shading Interior shading
0’
5’
10’
15’
20’
25’
Sept. 21 Overcast Sky Daylighting Study
30’
35’
Classroom Depth
BEAVERTON DAYLIGHTING
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ZIPPER SPACE Term: Spring 2017 Project Location: Portland, Oregon Media: Grasshopper, Rhino As a submission for the Council on Tall Buildings and Urban Habitat Student Skyscraper Competition, Zipper Space takes on a problem plaguing many modern-day cities: diminishing urban lands. The problem is combated through the implementation of a vertical park housed inside a dense apartment tower. This concept allows for the continuation of development and densification in cities while preserving lost land. The tower was fully designed in Grasshopper starting with a highly flexible apartment unit. Once the units were stacked, parameters were set to open up a space for the park in the middle of the tower. Further parameters undulate the width of the opening to create wind tunnels for the placement of wind turbines. The park is not included on these floors. On each habitable floor, the park is divided into both a public park for the city and private areas for residences. The park includes seating areas to encourage interaction, places to play, and private spaces. A thick hanging vine acting as a vertical bioswale visually links the floors of the park, treating grey and rainwater. Other sustainable features include a double skin facade topped with a shading device designed through a radiation analysis.
0’
10’ 20’
12
20’
1
2
1: Rainwater is filtered for use 2: Greywater is treated through thick vines 3: Surface water is treated through basins
3
BASE CONDITION
A radiation diagram informs a shading device over the double skin facade. North-South daylight axis.
Holes have been opened in the mass for the purpose of wind passage to power turbines as well as openings for a park.
ELEVATED PARK
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LENTS MARKET: THESIS PREP Term: Fall 2018-Spring 2019 Project Location: Portland, Oregon Media: Rhino, PhotoShop, Illustrator, Excel This is the preliminary work for my thesis project that will be presented in June 2019. The focus of the project is adaptive reuse with a purpose of community betterment. The problem that I have decided to tackle is food deserts (areas more than two miles from the nearest grocery store) in East Portland, specifically in the Lents neighborhood. The solution that I have developed to this problem is a main food distribution center in Lents with satellite centers tailored to the communities in which they are located. The deliverable for the project will be the schematic design of the main distribution center with some design development and construction documents. A satellite facility may also be designed. The main facility, located in an old recycling plant in Lents, will not only be a distribution center but will also include a market hall, a food bank, mixed income housing, and pocket businesses. An economic model was developed with each of these elements in mind to make a fully functioning system. It is based on the community investment trust model in which community members invest in the theoretical Lents Market Group and make profit. The Lents Market Group is fueled by the rent from the market, housing, pocket businesses, and community donations. The market is supplied by the food bank and local farmers. The market and satellite facilities will also be supplied by urban farms on unused land in the surrounding neighborhoods. Though not a requirement of the thesis, I placed this economic model into a pro forma to develop specific programmatic requirements and square footages. The main facility will be just over 60,000 square feet, comfortably fitting in the existing recycling plant. A site analysis has been performed on the warehouse with existing plans obtained from the Portland Bureau of Development Services. Possible programmatic layouts have also been produced. In terms of design, I am interested in making the system of uses cohesive with as much mixing and overlap as possible to blur programmatic boundaries. Design aesthetic will be simple with localized complexities.
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MARKET RATE
LOW INCOME
POCKET BUSINESSES
LENTS MARKET GROUP
MARKET
LENTS
COMMUNITY INVESTORS
FOOD BANK
CASH INFLOW CASH OUTFLOW PRODUCE FLOW
FARMERS
URBAN FARM
MARKET HALL USE MARKET HALL PERMANENT STALL USE MARKET HALL MARKET HALL TEMPORARY STALL PERMANENT STALL USE USE DESIGNATED EATING AREA TEMPORARY STALL PERMANENT STALL PERMANENT STALL STALL COMMUNITY STAGE DESIGNATED EATING AREA TEMPORARY TEMPORARY STALL RESTROOMS (INCLUSIVE) COMMUNITY STAGE DESIGNATED EATING AREA DESIGNATEDKITCHEN EATING AREA COMMUNAL RESTROOMS (INCLUSIVE) COMMUNITY STAGE COMMUNITY STAGE STORAGE COMMUNAL RESTROOMSKITCHEN (INCLUSIVE) RESTROOMS (INCLUSIVE) MARKET OFFICE STORAGE COMMUNAL KITCHEN COMMUNAL KITCHEN CIRCULATION MARKET OFFICE STORAGE STORAGEOFFICE CIRCULATION MARKET MARKET OFFICE FOOD BANK CIRCULATION CIRCULATION USE FOOD BANK STORAGE USE FOOD BANK FOOD BANK COLD STORAGE USE STORAGE USE STORAGECENTER DISTRIBUTION COLD STORAGE STORAGE KITCHEN DISTRIBUTION COLD STORAGECENTER COLD STORAGE COMMUNITY DROP KITCHEN DISTRIBUTION CENTER DISTRIBUTION CENTER LOADING COMMUNITY DROP KITCHEN DOCK KITCHEN OFFICE LOADING DOCK COMMUNITY DROP COMMUNITY DROP BATHROOMS OFFICE LOADING DOCK LOADING DOCK BATHROOMS OFFICE OFFICE MIXED INCOME HOUSING BATHROOMS BATHROOMS USE MIXED INCOME HOUSING TOWNHOUSE USE MIXED INCOME HOUSING MIXED INCOME HOUSING SHOP TOWNHOUSE USE HOUSE USE 2SHOP BEDROOM HOUSE TOWNHOUSE TOWNHOUSE 12SHOP BEDROOM HOUSE HOUSE STUDIO 12SHOP BEDROOM 2 BEDROOM BEDROOM STUDIO 1OFFICE 1CIRCULATION BEDROOM OFFICE STUDIO STUDIO CIRCULATION OFFICE OFFICE POCKET BUSINESSES CIRCULATION CIRCULATION USE POCKET BUSINESSES SHOP HOUSE USE POCKET BUSINESSES POCKET BUSINESSES STAND ALONE SHOP USE HOUSE USE CIRCULATION STAND ALONE SHOP HOUSE SHOP CIRCULATION STANDHOUSE ALONE STAND ALONE CIRCULATION CIRCULATION
AREA (SQ. FT) AREA100 (SQ. FT) AREA100 (SQ. FT) AREA1200 (SQ. FT) 100 100 200 1200 100 100 400 200 1200 1200 600 400 200 200 500 600 400 400 200 500 600 600 4600 200 500 500 4600 200 200 4600 AREA4600 (SQ. FT) 11200 AREA (SQ. FT) 2800 11200 AREA (SQ. FT) AREA (SQ. FT) 300 2800 11200 11200 300 2800 2800 200 300 300 600 200 300 300 200 600 200 70 200 600 600 70 200 200 70 AREA 70 (SQ. FT) AREA1300 (SQ. FT) 850 AREA1300 (SQ. FT) AREA1300 (SQ. FT) 800 850 1300 600 800 850 850 350 600 800 800 300 350 600 600 5000 300 350 350 5000 300 300 5000 AREA5000 (SQ. FT) AREA425 (SQ. FT) 425 AREA500 (SQ. FT) AREA375 (SQ. FT) 500 425 425 375 500 500 375 375
COUNT 40 COUNT 40 COUNT COUNT 1 40 40 1 40 40 12 121 112 21 1 TOTAL: 11 TOTAL: 11 1 COUNT TOTAL: TOTAL: 1 COUNT 1 COUNT COUNT 1 11 11 11 11 211 TOTAL: 211 TOTAL: 21 2 COUNT TOTAL: TOTAL: 5 COUNT 5 COUNT COUNT 35 5435 6435 1364 146 TOTAL: 16 TOTAL: 11 1 COUNT TOTAL: TOTAL: 5 COUNT 10 5 COUNT COUNT 15 10 51 TOTAL: 10 10 TOTAL: 1 1 TOTAL: TOTAL:
TOTAL AREA (SQ. FT) 4000 (SQ. FT) TOTAL AREA 4000 (SQ. FT) TOTAL AREA TOTAL AREA 1200 4000 (SQ. FT) 4000 200 1200 4000 4000 800 200 1200 1200 600 800 200 200 500 600 800 800 200 500 600 600 4600 200 500 500 16100 4600 200 200 16100 4600 4600 (SQ. FT) TOTAL AREA 16100 16100 11200(SQ. FT) TOTAL AREA 2800 (SQ. FT) 11200 TOTAL AREA TOTAL AREA 300 (SQ. FT) 2800 11200 11200 300 2800 2800 200 300 300 600 200 300 300 200 600 200 140 200 600 600 15740 140 200 200 15740 140 140 (SQ. FT) TOTAL AREA 15740 15740 6500 (SQ. FT) TOTAL AREA 4250 6500 (SQ. FT) TOTAL AREA TOTAL AREA 2400 4250 6500 (SQ. FT) 6500 2400 4250 4250 2100 2400 2400 300 2100 2400 2400 5000 300 2100 2100 22950 5000 300 300 22950 5000 5000 (SQ. FT) TOTAL AREA 22950 22950 2125 (SQ. FT) TOTAL AREA 5000 2125 (SQ. FT) TOTAL AREA TOTAL AREA 375 (SQ. FT) 5000 2125 2125 7500 375 5000 5000 7500 375 375 7500 7500
URBAN FARM USE URBAN FARM USE URBAN FARM URBAN FARM USE USE
AREA (SQ. FT) AREA (SQ. FT) AREA (SQ. FT) AREA (SQ. FT)
COUNT COUNT COUNT COUNT
TOTAL AREA (SQ. FT) TOTAL AREA (SQ. FT) TOTAL AREA (SQ. FT) TOTAL AREA (SQ. FT)
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R5
R2a
EG2
TRAFFIC FLOW The site will be most heavily approached by cars and buses heading east on Foster Blvd from Downtown and I-205. Traffic will also approach on Foster heading west but to a lesser extent. Bike and pedestrian traffic will be heaviest from the south due to the Springwater Corridor.
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ZONING EG2: office and industry, manufacturing R2A: multi-dwelling; townhouse, duplex R5: single family, ADU, duplex
SOUND Neighboring industrial facilities to the east and south produce loud noise during business hours. Foster Blvd to the north is a high speed, busy street. SE 101st Ave is mainly used for freight traffic.
1
MARKET HALL
2
FOOD BANK
3
MIXED HOUSING
4
POCKET BUSINESS
2 3
4 1 1 4
OPTION A
2
3
OPTION B
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A preservation and activation of public space in response to the urban context of Downtown Eugene. A compact, affordable, and sustainable community.
DOWNTOWN REDEVELOPMENT Term: Fall 2016 Project Location: Eugene, Oregon Media: Revit Eugene, Oregon’s population is expected to drastically increase over the next decade. In order to prevent further expansion into the surrounding farmland, densification is necessary in the downtown core. This 13 floor, mixed-use tower is part of that densification process. The tower is located on a site commonly known as the Butterfly Lot and used to be part of Eugene’s four central park blocks. The site is the center of recent controversy as the founder of Eugene, Eugene Skinner, claimed the land as public space. Upon news of a land swap, a relative of Skinner filed a court case against the city. In response to the controversy, the project is designed to retain as much public space as possible on the site. Most of that space is utilized to create a permanent home for the Eugene Farmers Market. The project was designed as part of a highly realistic studio in which structure, code, economics, and sustainability had to be considered.
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HISTORICAL CONTINUITY
SOUND BUFFER
SETBACKS FOR VIEWS
PRESERVATION OF PUBLIC SPACE FOR FARMERS MARKET AND TO MAINTAIN HISTORIC DEED
DN
DN PENT 2.2
PENT DECKS
BUSINESS
STORAGE
STORAGE
3 BED GARAGE
UP
UP
UP
UP
UP
GARAGE
BIKE PARKING
DN
STORAGE
CORE
STORAGE
CORE
PENT 2.2
PENT 2.1 GARBAGE LOADING DOCK
BUSINESS
UP
UP
BUSINESS
OFFICE
STORAGE
STUDIO
TOWER LOBBY
CORE
PENT DECKS 1 BED
LOBBY BREEZEWAY
1 BED
PENTHOUSE FLOOR PLAN STUDIO
CORE
CORE
STUDIO
ALL RESIDENT DECK
3 BED
UP
STUDIO MECHANICAL
UP 2 BED STUDIO
1 BED
1 BED
2 BED
1 BED
STORAGE COURTYARD
MARKET COMMONS
1 BED
1 BED
CORE
BUSINESS
STORAGE
UP
STUDIO 1 BED
STUDIO
BUSINESS
CORE
STUDIO
CORE
CORE
STUDIO
STUDIO
3 BED
LOBBY
BUSINESS
BUSINESS
GROUND 1/64” = 1’0”
1 BED 1 BED
1 BED
LEVEL 2 3/64”=1’0”
1 BED
20’ 20’
GROUND FLOOR PLAN
SECOND FLOOR PLAN
ALL RESIDENT DECK
CORE
TYPICAL TOWER FLOOR PLAN
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SHOP HOUSE Term: Fall 2015 Project Location: Portland, Oregon Media: Rhino Division Street in Portland is currently undergoing major changes. A rapid revitalization process is occurring and infill projects are being constructed. This Shop House is an infill project located on the edge of the new and the old. An industrial neighborhood lies nearby to the west while a new commercial and high-density residential neighborhood lies directly to the east. The ground floor of the building contains a coffee bar and a book store in response to the local interests in Portland. The floor is orientated in a way to respond to the direction of people flow towards the site. The second floor contains two units and the third floor contains one as well as private and communal roof gardens. The coffee bar on the ground floor is directly connected to the unit above. A light well forms the central core of the building leading to a shade garden on the ground floor which acts as a transition from the shop plaza to the residential.
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SECOND FLOOR
THIRD FLOOR
GROUND FLOOR
SECTION DRAWING
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BOATHOUSE Term: Spring 2016 Project Location: Dexter Lake, Oregon Media: Rhino Every morning the University of Oregon’s rowing team practices on serene Dexter Lake, nestled in the foothills of the Cascade Mountains. The team’s current boathouse has fallen into a state of disrepair and more facilities are also desired. This project was designed not only to satisfy the needs of the rowers but to be as connected to the surrounding landscape and climate as possible. The parti of the boathouse is divided into three sections each having a relation to the course of regatta races along the lake. The west section, primarily for training, is aligned parallel to the race. The east section houses the boats and is parallel to the lake. An elevated bridge ties the two together and acts as public space for the community of Dexter Lake. The bridge is elevated to provide a direct path to the lake and boats for the rowers and to allow for water runoff to continue through the site. To the south, the two sides of the bridge face a covered bridge at the start of the race and the highest point in the area.
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Lock er R
Mec hanic al
oom
oom Lock er R
Up
Exerc
ise
GROUND FLOOR AND SITE
Repair
UO Rowing
SERC/OAR
SECOND FLOOR
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5-Point GRIDSHELL Term: Winter 2017 Media: Grasshopper, Karamba, Design-Build The 5-Point Gridshell is an advanced timber canopy designed to hold twenty people for varying event types. The canopy was the final design-build project of a mass timber class in which students learned about products, structural systems, and parametric design. For the project, I was part of a five person group in which I was responsible for some of the conceptual design, the majority of the grasshopper model creation, and the majority of the structural analysis of the project in Karamba. We chose the gridshell as the system can create large open spaces without the need for internal supports. The five support points are placed so that two create an entry condition while the other three house benches. The goal of structural analysis was to appropriately size the beams to prevent large amounts of deflection. Other members of the group, including engineering students from Oregon State University, designed the connections and picked fasteners to bring the design to fruition.
FULL SCALE FLEXIBILITY MOCK-UP
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URBAN ANALYSIS IN BARCELONA Term: Summer 2016 Project Location: Barcelona, Spain Media: Grasshopper, Rhino Barcelona is currently facing a major problem: too many tourists. Tourism, the driver for the city’s economy, is taking over city neighborhoods that once had a sense of community. In an effort to combat tourism, city planners have devised the concept of the Superilla, or Super Island. A Superilla is a three by three block super-block in which there is limited car access. The Superillas are currently in the process of being analyzed so designs can be applied specifically to each one based on the complex systems of data collected in order to benefit local communities. Grasshopper will then be used to assign design elements to each Superilla based on the data collected. In a group project including myself and one other student, we analyzed a single Superilla in terms of how effective it currently is in terms of community ownership. Factors analyzed included the ability to play, surveillance, and rest. Lodging locations were analyzed to detect the areas most marred by the presence of tourists. The end result was a tool for city planners to use in order to implement planning designs.
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DESIGN
TINY HOUSE Term: Spring 2018 Media: Rhino
STRUCTURE
SKIN
SYSTEMS
FINISHES
LONGITUDINAL SECTION Scale : 1/2” = 1’ - 0”
1
4’
4’
4’
4’
4’
2
Tiny House is an ADU designed to be constructed by the average person on a 8 1/2’ by 20’ trailer bed. The project, completed by a team of four people, required the design and construction documents for the ADU. Tiny House appears solid on approach. Upon opening the door, one is met with a wall of glass, which doubles as a sliding door, and open views to the exterior. The roof of the structure appears to float above a ring of clerestory. In terms of layout, the living room is located in the center of the main floor. The kitchen is located to the left upon entering while a foldable stair to the lofted bedroom is on the right. A fold-down porch is attached to 3 the sliding glass wall. A small bathroom is located underneath the loft. The structure, including the sheathing, is assembled through tenon and mortise joints. The structure is stuffed with fiber bat insulation. Insulated panels are then placed over the structure and windows are placed in. Facilities will be installed by a plumber and electrician. My role in this project included some layout design, some structural design, the design of the elevations, the electrical diagram, and the construction details.
11’ - 6” 6’ - 8” 3’
DESIGN LOFT FLOOR PLAN
Scale : 1/2” = 1’ - 0”
STRUCTURE 4’
SECTION
SKIN 4’
4’
20’
SYSTEMS 4’
FINISHES 4’
8’
STRUCTURE DIAGRAM DESIGN
STRUCTURE
SKIN
SYSTEMS
FINISHES
ELECTRICAL
5’ - 6”
8.5’
DESIGN
STRUCTURE
SKIN
SYSTEMS
FINISHES2’
FIRST FLOOR PLAN
Scale : 1/2” = 1’ - 0”
PV
8’
SECOND FLOOR PLAN
20’
Panel
5’
Switch
8.5’
Generator
Battery
Utility
AXON 3/8” - 1’
DESIGN ELECTRICAL DIAGRAM CORNER DETAIL 3” = 1’-0”
STRUCTURE
GROUND FLOOR PLAN SKIN SYSTEMS
FINISHES
20’
CORNER AND GUTTER DETAIL
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Detail Material Key 1 2 3 4 5 6
Wood Cladding, Rigid Insulation, Barriers, 5/8” Sheathing, Batt Insulation, 5/8” Sheathing Flashing Double Pane Window Metal Cladding, Rigid Insulation, Barriers, 5/8” Sheathing, Batt Insulation, 5/8” Sheathing Stud Gutter
operative temp. in sunspace/dwelling
BALCONY SUNSPACE section diagrams
- This graph is showing Term:the Winter 2018 Project operative temperatures in Location: both La Pine, Oregon Media: Energy Plus, Excel, SketchUp the sunspace as well as the dwelling, comparingThe theBalcony two, Sunspace to is a prototype sunspace designed by a team of two that can be applied to passively heat buildings in La Pine Oregon. see how they interact.
section diagrams SUNSPACE VS DWELLING TEMPERATURE GRAPH
This project is part of the Oregon Sustainable Cities Initiative. The design is a module that can be easily applied to a house and stacked over multiple It is clear through the datafloors without interfering with the modules below. The upper section diagrams is for maximum solar gain and the lower angle allows solar axis plotted that while theangle sunspace to other lower modules. A thermal mass absorbs the solar gain and standard window seat fluctuates in its temperature delays movement of heat to theplanter interiorbox of the space until nighttime. Movable insulation is applied to the space overnight so it can mainswings, the dwelling Section diagrams showing the variationsstays of configurations of our tain heat. insulation module. The lower portion of the sunspace exterior,This without glazing, is retracted completely during heating seaconsistently theorsame. son and can box. be turned into louvers during cooling season. The space may be used for either a seat, for a built-in planter Otherwise, it can remain open, as shown in our base module. This angle cooling season by propping open the glass candesign also be vented during allows for light to reach the module below. panels. The space was analyzed using Energy Plus over several days - Through our design we in March. Through Energy Plus, it was found that the space fluctuates have enabled the sunspace between 75to and 90 degrees between night and day while the interior a constant temperature of 72 degrees. My role in this study successfully heat themaintains dwelling included some site analysis, some design, the design of the movable when the window seat needed, and protect planter box insulation, and the Energy Plus analysis through Excel and SketchUp.
design
site section
standard
space form getting too hot as well.
Section diagrams showing the variations of configurations of our module. The lower portion of the sunspace exterior, without glazing, may be used for either a seat, or for a built-in planter box. Otherwise, it can remain open, as shown in our base design module. This angle allows for light to reach the module below.
design
graphs
standard
window seat
6/21 69º Section diagrams showing the variations of configurations of our module. The lower portion of the sunspace exterior, without glazing, may be used for either a seat, or for a built-in planter box. Otherwise, it can remain open, as shown in our base design module. This angle allows for light to reach the module below.
- The dwelling stays within a comfortable range of around 75 degrees Fahrenheit, while the sunspace swings from around planter box FLEXIBLE USES 73 up to 96 degrees.
Tree 15: 47’
Tree 16: 45’ Tree 5: 37’
12/21 22º
design Tilt: 40º
Site Section Looking East:
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