51.0486° N, 114.0708° W
Undergraduate Portfolio Austen Goodman
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About Growing up on the West Coast of Canada founded my passion for sustainability and the inter relationship of design and natural processes. My goal is to harness my creative abilities to design sustainable solutions without sacrifice of comforts, convenience and aesthetics. To articulate these design solutions, I am developing skills in utilizing computational programs to articulate successful sustainable design. Due to the increasing intensity of natural disasters, architecture can provide adaptable solutions to respond to these challenges. Studying architecture in the hurricane and flood zones of Savannah, Georgia has allowed me to recognize and apply the thinking that responsive and adaptive architecture is a facet of sustainable design. I intend to apply design to tackle the technical, social and environmental challenges of our time.
Contents
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Studio M Studio IV
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Latvian Hiking Cabin
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Boulder Creek Outpost
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Fallout
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Pneumatic Structure
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Tune Up
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Floodgate
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Spectorium
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Modeling
Independent Project
Studio II
Studio I
Studio III
Independent Project
Independent Project
Studio III
Independent projects and work experience
Studio M Pittsburgh Pennsylvania Studio IV Duration: 10 weeks The purpose Studio M was to design a building to promote sustainability and wellness, and be a template for future sustainable projects in Pittsburgh, Pennsylvania. The city is reshaping its image in America, moving away from industrial development and into more sustainable design. Once a coal and steel city, it is now a center of technology and sustainable industry. Studio M seeks to exemplify this in its design. The Shou
Sugi Ban facade of the building speaks to the coal industry’s past and the buildings that were coated with ash and soot in the 80’s. The interior contrasts this with large ceilings and bright CLT wood walls, beams and columns. Studio M also promotes many sustainable solutions and displays them in a way that hopefully inspires other developers to use similar practices. The placement of the bioswales and design of the constructed wetland as
an educational space are designed to show all elements of sustainability Additional sustainability components include: - Onsite water treatment and collection facility - System of greenroofs and PV panels to generate solar energy -Geometric volumes are shifted towards the sun to maximize solar gain - Double facade system -Parametrically defined louvre system
Residential Maker Space Integrated Space Open Retail
Extrude Long narrow mass to maximize cross ventilation. Tall narrow top mass to implement ventilation from double facade and maximize lighting.
Rotate Re-orient main building volumes to increase southern exposure and increase passive heating.
Interpret Translate programs into volumes. Isolated Residential space, semi secluded maker space, open retail space.
Lift
Ventilation
Greenscape
Elevate central building floor to minimize building footprint, as site is in a flood zone, creating a covered courtyard space.
Using flow design the masses are oriented to block winter winds, in the courtyard and cool the solar exposed facades.
Implementing a system of bioswales and green roofs that filter water allow the site to manage over 188% percent of water that is brought onsite.
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ALLEGHENY RIVER
David McCullough Bridge
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Veterans Bridge
“Three Sisters”
Rachel Carson Bridge
Andy Warhol Bridge
Roberto Clemente Bridge
MONONGAHELA Fort Duquesne Bridge
Ft. Pitt Bridge
Smithfield Street Bridge
Panhandle Bridge
Liberty Bridge
Bridges + High Volume city access roads
Phillip Murray Bridge
Birmingham Bridge
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Maker Based Retail Shops Tech Health Foods Botique Shopping Maker Shops Coffee Shops
Demographics S O M
Site Mapping
Visual representation of Pittsburgh Pennsylvania
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Greenspaces S O M
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Urban Development
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Green Roof
Water and Toilets
Bio Swale / Site Water Collection
Grey Water Cistern
Black Water Cistern
Shou Sugi Ban Facade
Long life, essentially fire proof and UV resistant charred wood is applied to the facade and used to provide and extra factor of heat absorption to the building in the cold winter months.
Solar Greenhouse
The top service floor includes a greenhouse that uses HVAC heating and solar gain that heats the building. The floor and walls are solid and roof and exterior walls arei formed with triple wall glazing.
Cross Ventilation
The long narrow design of the central mass allows cross ventilation from breezes.
Double Skin Facade
The double skin facade is equipped with adaptive louvers and an exterior mesh that acts as a twin face system to both heat and cool the building.
Geothermal
The building masses harness geothermal energy accumulated from the ground. The energy is utilized in the VRF and HVAC system.
Greenroof and Water Collection
The roof is equipped with a green roof that acts as a insulator for the building as well as a filtration system for the rainwater collection. It also sits underneath solar panels and acts as small air conditioner for the panel in the summer and insulator for the panels in winter.
Constructed Wetland
Triple Paned Zola Windows
Photovoltaics
CLT Construction
It is proposed that all water is dealt with on site. A grey and black water system collects water from bioswales and rooftop collection points. All black water and excess grey water is sent to the constructed wetland. for filtering.
PV panels have been implemented in the largest areas of solar gain and harness solar energy for electricity and heating.
The building uses triple paned Zola Windows to maximize heat retention and integrate durability.
CLT allows the use of sequestered carbon, so dead trees that have been ravaged by the pine beetle can now be used for mass timber construction.
28,389 Metric Tons of Carbon Reduced
Integrating over 34 acres of greenspace and wetland for flood mitigation offsets 28,389 Metric Tons of carbon
Proposed Greenscape Plan
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Urban Renewal Pittsburgh’s current storm water and sewage system operates using the same pipe system. This means that during periods of severe rainfall, untreated sewage and storm water can run directly into local rivers. To mitigate this, a protocol has been designed to deal with all building and site waste water on location. In addition, land around Smallman Street should be greenscaped - this will result in better handling of waste water and flooding from the Allegheny river. Three systems have been designed to manage the building and site’s waster water Bioswales will filter rain runoff and excess water to be collected in
Allegheny Flood Zone Rainfall
Rainfall
a large containment tank under the site that contains black water. Filtered waste water will be pumped to a constructed wetland treatment system across the street. The then purified water will be reintroduced into the Allegheny river. A secondary system has been implemented to deal with grey water. The rooftop is equipped with a greenroof that filters rainwater to be collected in a grey water cistern. The grey water is then redistributed to plants and toilets as needed. Excess cleaned grey water is sent offsite with treated black water and reintroduced to the river in the case of an oversupply of water.
Rainfall
Water Treatment & Constructed Wetland
485,334
188%
1010%
Gallons collected annually
Water managed onsite
Water managed including constructed wetland
Water Circulates wetland - cleansed by wetlands plants and gravel.
Roof Water Collection
1. Building Site
Site run off and building black water
2. Constructed Wetland
3. Allegheny Reintroduction
Morning Commute
Designing With Timber
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US and Canadian Forests grow 145,690 ft² of Timber in 1 minute - renewable resource
980 Metric tons of carbon benefit
Years - Green roof
145,690 ft² of Timber - Carbon Benefits
Flashing Batt Fill Cavity Insulation Continuous GMS channel (w. Drip Edge)
Ballast - Gravel 2” semi rigid Insulation Support Panel Drainage Layer Growing Medium
Equivalent to:
188 Cars of the road for a year Triple paned Zola ZNC insulating glass
310 Metric tons of carbon stored in the wood
Energy to operate 84 homes for a year *WoodWorks Carbon estimator
50 Years - Timber Structure
Designing For Energy Passive Energy Potential
PV Output
Constructed Wetland I
Residential PV array
292,599 KWH/YR
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44468 KWH Commercial PV array
Insulating Glass Unit Batt Insulation Metal Back Pan Continuous Formed Metal Membrane 1.5” Semi Rigid Insulation
83935 KWH Constructed Wetland II
Years - Zola Windows
The space can be passively managed 48.7% of the year and exist within the thermal comfort levels.
Treated Wood Nailer Horizontal Mullion Mineral Wool Firestop Spandrel Panel (Fritted Glass)
78413 KWH
85783 KWH
48.7%
Light Shelf/Laminated Tempered Glass floor Steel Outrigger
Carpet .25” Acoustic Underlay
*Ladybug Photovoltaics Component
.325’ 3 layer CLT Panel .043’ two-ply plywood .325’ 3 layer CLT Panel
Energy Use Intensity
Carbon Cycle
.554’ 5 layer CLT Panel 1.5” Semi Rigid insulation Glulam Beam - Dimensions Range
292,599 KWH/YR Total Potential Mass Timber Carbon Benefit 980 Metric Tons of Carbon Dioxide
PV Array
*WoodWorks Carbon estimator
*Construction Carbon Calculator
130,189 KWH/YR
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422,788 KWH/YR EUI Per Year *Revit Insight
Bio Swale in Motion
Years - Shou Sugi Bahn Cladding
Approximate net embodied Carbon Dioxide 11,679 Metric Tons of Carbon Dioxide
(2) 2x6 top plate (2) 2x4 1.5” Shou Sugi Bahn Sheathing Batt Insulation 5/8” Gyp Board Metal Panel Vapor Barrier
1/10” = 1’ AA
Vegetation Analysis 8%
Bioswale
72%
Greenscaped
22%
42%
28%
Green Roof
Building Pad
Constructed Wetland
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2nd Floor
3rd Floor
4th Floor
5th-8th Floor
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Amber Road Trekking Cabin Amber Road, Latvia Independent Project Duration: 10 weeks Collaboration with Stephany Knize
Workflow Collaboration Breakdown Rhinoceros
Conceptualization
Collaborative -
Photoshop
3DS Max Lighting + Rendering
Visualization
Illustrator Diagrams + Details
Collaborative -
Independent
Dual users on all files
Dual users on all files
The Amber road is an extensive trading network through Latvia and along it’s coastline. The purpose of this build project was to design a cabin that could be placed for hikers traveling the amber road.
The cabin components are designed for simple assembly:
The cabin’s form was derived from imagery and geometries of an amber stone that can be found along the trail. The natural geometries of the amber stone were interpreted and reflected in the structure, plan and section. The cabin was designed to function off the grid with simplicity and practicality in mind.
Frame can be assembled on-site
Foundation is precast piles that can be placed and leveled quickly to accommodate ground contours
The walls panels can be pre-fabricated off-site and plugged into the frame allowing for rapid assembly and easy on-site build experience. Cabin innovations for energy efficiency and comfort: 02
Large sloping roof collects rainwater which is stored and can be heated using solar water heaters. The water is made accessible through gravity fed faucets in both the sink and shower. Single hung floor-to-ceiling window wall that can be raised or lowered manually Large roof skylight with shading apertures that can be manually operated. The toilet is net zero and organically decomposes waste without odor solar panels support low E light bulbs.
Human Centered Design The cabin is equipped with handles and cranks that allow the user to operate the cabin and interact with it using only human power. Louvered glass skylights can be completely closed and sealed during cabin vacancy to protect from storm damage. They can be opened using a crank and allow the viewers to gaze at the night sky as well as enjoy natural daylight. The single hung floor-to-ceiling window wall can be raised or lowered depending upon the needs of the user and allows a large amount of natural light into the space.
Double functioning door and window wall
Hydraulic operated hand crank
Constructivist Joints Bolted Bracket
Bolted Bracket
Hardfoam Insulation Walls Sheathing Timber Cladding
Column, Girder, Pier Pin Connection
Precast + Reinforced Concrete Piers
The frame can be assembled on site, on the simple, easy level concrete piers. Prefabricated panels can be transported to location and plugged into the frame requiring minimal construction time and skill.
A central hearth is the main source of heat for the cabin and allows for food preparation and place to dry wet hiking gear. The chimney extends up through the sleeping quarters providing a source of heat for that area.
The roof is fitted with louvres and a glass sky lit roof to offer extra lighting and minimizing the need for electric lighting.
The louvre system is quickly adjusted using hand cranks. In storms or overly bright conditions the building can be completely sealed.
Standard configuration includes four beds and a hammock for two people. The living room bench can be turned into additional sleeping space for two people making the cabin comfortable for eight hikers.
Exploded Axonometric Axonometric showing structure and mechanical innovations.
The precast piers can not only be quickly placed and leveled, they also lift the building off the ground to protect from flooding due to the extreme precipitation and close proximity to the ocean affected by winter storms.
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Ground Floor 1. Kitchen Area 2. Hearth 3. Living Room 4. Fold Out Bed/Bench 5. Bathroom 6. Shower
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Second Floor 1. Hammock 2. Beds 3. Gear Cubbies 4. Hot Water Storage 5. Cold Water Storage
Water Conservation System
Passive Solar Water Heater
Gravity Fed Shower
Gravity Fed Sink Faucet
Dry Flush Chemical Free Odorless - Waterless Toilet Hot Water Collection Tank Cold Water Collection
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Kit of Parts 1.
Flooring framing (floor joists, inner floor joists)
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3x12” timber shading panels
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Concrete piles
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OSB Cubbies
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8x16” 8’ height timber columns (8 total)
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Stacked panels
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Second level beams
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Paneling with timber cladding
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8x2” studs for panel framing
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Door framing and system
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Hardware
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Utilities including water collector tubes, water storage units, plumbing, faucets, decomposing toilet
Boulder Garage Boulder, Colorado Studio II Duration: 10 weeks Set in Boulder Colorado, next to Boulder Creek near the foothills of the Flat Iron Mountains. The unique nature of the site of steep sloping terrain leading to the river, a large flood plain area, wildfires, multi-modal pathways, and adjacencies to an urban center created several design challenges. The building was designed to meet the LBC (Living Building Challenge) guidelines and meet the standards set out by the seven petals. Place, Water, Energy, Health and Happiness, Materials, Equity, and equality. These were all defining factors in the design of the building effected the design, sustainability, and aesthetics.
The project included a threshold of 10,000 SF. Since the building was designed around outdoor use, I chose to design a smaller building, conistsing of 5,000 SF of interior space, while maximizing outdoor program. This mitigated cost and made meeting the living building challenge more achievable.
The shape evolved by converging three masses into one form, then manipulated using BIM variables which helped determine the most efficient design.
Solar conditions were also integral to the design, with the main form being oriented on an EW axis and then rotated to maximize sunlight and solar Boulder Garage is organized mass efficiency. in a radial organizational parti and has a cohesive design that allows for a Equally important to the design seamless travel from interior to exterior were site considerations. A large berm spaces. The form was inspired by site was created to mitigate the cold of the lines in conjunction with eddies that northern space, and a green roof was broke on the river beside the site. built as accessible space to encourage users to enjoy the building envelope. 03
e t iv tra nis mi d A l tai Re ation e cr Re
Program The priority of the studio was to better understand program and site. The first step of the process involved breaking down the form into its programmatic elements.
Thermal Mass and Earth Sheltering A berm was added to the cold and windy North side. Making the space usable year round by insulating the building, reducing heating and cooling loads.
Bend The building was placed on an EW axis, the goal was still to have a point of convergence but to separate the spaces into their respective programmatic elements.
Passive Heating and Cooling An accessible greenroof acts as a passive heating and cooling system for the rooftop panels.
Anchor After working out program details an axial anchor was placed in the form of a boulder that was both interactive and also centering to the three programmatic elements.
Solar Gain Due to Boulders temperate climate zone, a PV array was proposed for the elevated roof area.
Earth Sheltering, a berm is added to insulate the building and reduce heating and cooling loads. It also minimizes cold outdoor spaces and protects from outdoor extremes.
Green Roof, generates an evaporative cooling system for PV panels and reduces air born pollutants increasing PV panel efficiency. The roof also acts as an insulator for the building.
The building footprint is placed on an East - West orientation with a glazed southern facade to maximize solar gain.
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The roof is optimized for PV panel performance with the potential to offset 19 tons of Carbon per year. Performance is also enhanced by the greenroofs added insulating effects.
Triple Paned Zola Windows boasting a U value of 0.123 minimizes winter heat loss further reducing cooling and heating loads.
Thermal Mass, the South facade is glazed which allows heat to transfer to concrete floors and walls - absorbed heat is then released at night.
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5 1. Change Rooms 2. Storage 3. Merchandise and Apparel 4. Bouldering rock 5. Bathrooms 6. Conference room 7. Office Space 8. Office Storage 9. Climbing Wall
1. Kitchen 2. Snack Bar 3. Hammocks 4. Climbing Wall 5. Outdoor Seating
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Ground Floor
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Second Floor
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East West orientation with glazed southern facade to
Green Roof, generates evaporative cooling system for PV panels and
Roof is optimized for PV panel performance and performance is
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Fallout Lacoste France Studio I Duration: 8 weeks
Fallout is a utopic community that is driven by the desire to explore the unknown. Centered underground in a crevasse, this utopian society suggests that the outside world is dystopian in nature, and one must look inward to find utopia. Inspired by fallout shelters of the mid to late 1900’s, this utopia has a focus on subterranean living and exploration. The dynamic geometry of the mass above communicates movement, representing the community ideal that is focused on adventure and pushing physical limits. The main building will have a steel truss system fastened into the bedrock with concrete piers. The underground bunkers in the base camp are carved using a boring machine and left as they are in their raw form. The shell of the form uses Glass Fibre Reinforced Concrete (GFRC) and Glass Fibre Reinforced Polyester (GFRP). It is reinforced with a steel framing system and left uninsulated.
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20’
Pneumatic Structural Exploration Siteless
Studio III Duration: 1 weeks
Workflow Collaboration Breakdown
Rhinoceros
Collaboration with Andrea Ortiz, Vero Paulon, Tofu Chen
Hand Cutting
Conceptualization
Assembly
Independent
Collaborative Team Assembly
Building the Pneumatic structure was an introduction exercise to my third studio project which focused on structure. The intent was to learn about site-less architecture, that immediately questions the consideration of structure. The inflatable architecture concept challenges our pre-conceived notion of building envelope, wall, structure, construction, and poche. My project team wanted to find an element in nature and then replicate and abstract it in a more constructivist sense.
The Pneumatic structure was inspired by the dynamism of the wave, and the way it creates a unique and natural interior space. We wanted to address the form of the wave as well as the juxtaposition of space and light within the project. A tight interior entry way is contrasted by a large and open interior space. A design was projected onto the outer shell of the structure to create a more compelling visual experience as well as project a unique pattern on the interior. 05
One side is open and light, while the other side starts very light and progressively becomes darker with the overlap of tape. I used Rhino as a visualization tool for this project, flattening the outline and plotting it as a pattern. The polyethylene plastic was then cut out using the pattern I had created and assembled to spec by the entire group. Using the rhino model we were also able to calculate the volume of the structure and determine Interior pressure
Tune Up Calgary, Alberta Independent Collaboration Duration: 3 Weeks Collaboration with photographer Natasha Palmer
Working in Collaboration with Natasha Palmer, photographer and student of ACAD I was asked to help on a project for her current photography studio. The project brief was very open in its instruction with the only specific requirement being a 30X30 box to fit into the urban context of downtown Calgary and programmatically contribute to the wellbeing of its occupants. We determined that a meditation and sound therapy space could be a very positive addition to the city’s downtown core. The idea I presented was to bring in elements from Alberta’s natural landscape and use them to inform the interior form. Using Natasha’s photography as a template, and my knowledge of the area through extensive hiking and exploration, I was able to shape the interior to match the photography of my partner. Workflow and Collaboration Breakdown
Collaborative Dual users on PS files
Rhinoceros
TSplines
Conceptualization
Interior Sculpting
Vray
Photoshop
Lighting + Rendering
Visualization
Grasshopper
Site + Structure
Independent
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Illustrator
Diagrams + Details
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Parameters
Precedent
The program brief required that the design be contained in a 30X30 box with a 20’ height maximum. No other restrictions were applied except that it would be situated somewhere within the urban landscape of downtown Calgary.
Outside Calgary along the route to the Rockies is a cove that many locals enjoy in both the winter and summer months. This cove is used as a Nexus for all things Calgary, and was used to create the form and define the entire precedent of the interior space.
Erosion
Refinement
The cove was formed over time through a process of erosion. Topography lines from the cove were projected onto the walls of the interior and then manipulated to reveal the same qualities of the inspiring form.
Using Tsplines, the form was then molded to create a seating area and a directionality which guides the eye to a large skylight. The intent is for viewers to look up which is a stark contrast to a day spent looking down at a screen.
Fabrication
Program
Two main materials were used - Steel and Wood. The structure is comprised of a steel building frame, and a CNC milled glulam frame. Cedar planks are then steamed, pressed and bowed onto the frame, creating a seamless and flowing interior space, design much like a cedar strip canoe.
The final plan invokes a strong directionality and guides the occupant to the interior meditation space. Emphasis is placed on the interior to be both inviting and minimal, allowing the occupant to focus on centering themselves.
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Kananaskis Park - Valley
Carve
Mount Temple - Peak
Extrude
Marble Canyon - Rift
Fracture
Floodgate Miami Coastline Independent Collaboration Duration: 2 Weeks Collaboration with Philip Singer and Stephany Knize
In 2020 one quarter of Florida was underwater due to storm surge and ocean levels rising. The tremendous amount of causalities and damage to property inspired the implementation of storm surge barriers. Aptly named floodgate these net positive structures use tidal power to create a barrier during hurricanes. One of the main causes of hurricane damage in the eastern USA is from resultant storm surge. Strom surge is caused by the rising of the sea level due to low pressure, high winds and waves. When these waves make landfall, these causes significant flooding costing a significant loss of life and damage to the existing coastline. Floodgate uses adaptive response mechanics, harnessing tidal energy to create an impenetrable storm surge wall. The low profile of the walls only effects detrimental hurricane waves and allows existing ocean ecology to move uninhibited in the depths below.
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450M ABS Steel Wall
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LED Beacon Panel
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5,720 kW Pistons
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Helicopter Pad
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Hydro-Power Gener-
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Multi-Axis Turbine
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Semi-Permeable Turbine Cover
Independent Module Exploded Axonometric
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Powerhouse
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Jet Drive Turbines
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ABS Steel Rudder
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Carbon Fibre Ribbing + Shock Absorbent Vertebrae
Polysemic Drawing - Floodgate Test Sequence
Unfolding Sequence
Stratosphere Spectorium Talmadge Piers, Savannah Ga Studio III Duration: 9 weeks
Stratosphere is a global surveillance center and modern bunker that operates on a threefold defense and surveillance system and is anchored to a concrete pier. The pier was preexisting to the site and the premise of the studio was to create a Spectorium that could fasten to the pier.
Underground Entry
Using Adaptive response mechanics, this form appropriately responds to incoming information. Signals are received from the top satellite dishes and are then dispersed throughout the structure. Critically important, international information is transmitted to the top deck. National information and less pressing issues are transmitted to the second deck. Local news and other information is sent to the inner core of the center. The information is then processed, and a response is formulated and transmitted as appropriate. In times of turmoil the structure has the ability to close to become impenetrable and only accessible through underground passages. In less tumultuous times, the form responds by opening in a language that mimics a satellite. The program was derived from early WWII bunker typologies and cold war surveillance towers and submarine capsules. The dimensions that run throughout the form hold true to WWII and Cold War programing. However, they have been advanced and modified to maximize program capabilities and increase security in the event of crisis. 1'2' 3'4'5'6'7'8'9' 10'11'12'
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Lag Shield
Base Plate
Lag Bolt Rigid Clamp
1 Thick steel plate
Primary Deck Secondary Deck
50 Span Draw Bridge Steel Mesh Grating Gusset Plate W16 x 50 I beam
North Elevation North Elevation
Unfolding Sequence
Unfolding Sequence
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Modeling 3D Printing and Wood Work Over the course of my undergraduate studies I have dedicated time to both hand modeling, 3D printing, and wood working. I can operate a laser cutter, and often help students in the shop by cutting extra projects for them. I also have experience in the wood shop and I do many side projects as I have a real passion for wood working. During the summer and fall of 2016, I was assigned the task of 3D printing EOG Resource’s state-of-the-art hydrocarbon dew point control plant. The purpose of this was to build a scale model to train operating engineers in facility processes. 09
Austen Goodman austen.goodman@gmail.com 682 301 0878