Jay C Henson II +Architecture Works +Washington State University
DESIGN PHILOSOPHY Designing is an ongoing evolutionary process and is often a non-linear process. It involves asking a series of questions to a client in order to understand their problems and concerns, to which one can then respond with multiple solutions. From this process, one can quickly answer a series of complex problems in order to come up with a response that will inevitably create beautiful and feasible design solutions.
PORTFOLIO CONTENTS
01 RESUME
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02 BRIDGING COMMUNITIES
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03 WHEAT INTORSION
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04 A BETTER USE OF SPACE
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05 FOLDED PAPER PAVILION
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01
SOFTWARE SKILLS
2-D REPRESENTATION AutoCad Illustrator CC InDesign CC Photoshop CC 3-D REPRESENTATION Grasshopper Revit Rhinoceros 5.0 Sketchup
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Jay C Henson II
10281 Horizon Lane SE Port Orchard, WA 98367
jay.henson@email.wsu.edu 360.649.3121
LEED® Green Associate
EDUCATION
CREDENTIALS
EXPERIENCE
AWARDS
Washington State University Pullman, WA Pursuing Master of Architecture Degree
05.2016
Washington State University Pullman, WA Bachelor of Science in Architectural Studies
05.2015
Olympic Community College Bremerton, WA Associate of Arts Degree
08.2011
LEED® Green Associate “LEED Green Associates have a documented, up-to-date understanding of the most current green building principles and practices, and are committed to their professional future.” -USGBC Website
11.2014
Pickard Construction Silverdale, WA General Laborer 930 IDP Supplemental Experience Credits Pickard Construction specializes in high-end residential architecture work that can be enjoyed throughout the greater Hood Canal region. Working under owner and general contractor, Jeff Pickard, I was exposed to valuable construction site experience.
2012-2014
Harmon & Silliman Presidential Scholarship WSU SDC Architecture ACM
04.2015
WSU SDC Accelerated Graduate Program Acceptance
03.2014 5
02 BRIDGING COMMUNITIES IDX Mass Timber Studio
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PROJECT DESCRIPTION Instructor: Colleagues: Completion: Location:
Darrin Griechen N/A Spring 2015 Spokane, WA, USA
A site located in Spokane, Washington was chosen for the opportunity to develop a connection, or bridge, between the downtown Spokane community and the WSU Spokane campus. To create the bridge, the location will be developed with the intention of fostering further growth within the established bond of urban life within the community, creating a cultural conflux. The cultural conflux will be achieved through the development of a key design aim: vertical circulation.
Programs Utilized +Revit +Rhinoceros 5.0 +Grasshopper +Adobe Illustrator CC +Adobe Photoshop CC
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FLOW ANALYSIS 02
A site location in downtown Spokane, Washington led to realization of the disconnect between the urban downtown and campus life. A flow analysis through Grasshopper, a plug-in for Rhinoceros, generated walking paths of pedestrians trying to navigate between the two differing contexts. A realization occurred that pedestrians do not always walk along the sidewalks and roadsthey take shortcuts. The new flow paths that were generated contained paths that cut through our site. The negative spaces between these paths were viewed as our zones of construction and should be looked upon for design development.
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GIVEN SITE
EXISTING FLOWS
GRIDDED SITE
FLOWS THROUGH SITE
DEVELOPMENT AREAS PHASE 01 A prime location for the studio aim of a 12-story CLT structure, this space will involve creating intermixing spaces of campus resource zones, student living, and community zones. PHASE 02 This phase emphasizes WSU capital planning’s expansion goals of a student academic center. PHASE 01
PHASE 03
PHASE 02
PHASE 04
PHASE 03 Creating spaces of interaction on the landscape will foster further growth between the two existing communities. PHASE 04 Recognizing the historic Jensen Byrd building next to our site and creating a blank canvas for adaptive reuse will establish a more cohesive design through contextual site development.
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EXPLORING RIGIDITY 02
When analyzing the most successful locations for points of entry, another flow analysis occurred. Paths from buildings within a ten-minute walk of our site were analyzed. Beginning from the existing building entrances and ending in the center of our site, locations of where paths crossed the building envelop were established as building entrances. Then, paths of travel from each entrance to another were analyzed and where multiple paths crossed, locations of vertical circulation and the main core were established.
PHASE 01 SITE
ENTRY POINTS MESH
CORE CIRCULATION
From the established location of vertical circulation, paths of horizontal circulation were established, including full circulation around the main core.
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FLOWS TO SITE CENTER
VERTICAL CIRCULATION
HORIZONTAL CIRCULATION
BUILDING GENERATION
MAX BUILDING VOLUME
VOLUMETRIC SHIFT A series of cuts to the overall building volume to account for sun shading on west and south facades, street perspectives, as well as cuts to exhibit the vertical circulation, created a dynamic genotype mold by which we could establish a resulting phenotype. Twelve splits were made to account for the twelve-story structure and resulted in twelvefoot high floors on every story.
SUMMER SOLSTICE AWARENESS
VERTICAL CIRCULATION CUT
FLOW ANALYSIS CUTS
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03 WHEAT INTORSION Digital Fabrication Studio
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PROJECT DESCRIPTION Instructor: Colleague: Completion: Location:
Mary Polites A. Miles Spring 2014 Exhibition Installation
This seminar focused on the development of a simple component which could be aggregated to form emergent qualities toward an architectural use. At the onset of this project, students were asked to define their aims: specific outcomes which we expected to achieve through the development, refinement, and implementation of our component and the system it forms in aggregation. Wheat Intorsion is focused on finding rigidity of a component.
Programs Utilized +AutoCad +Rhinoceros 5.0 +V-Ray +Grasshopper +Adobe Illustrator CC
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EXPLORING RIGIDITY 03
Moving forward, the aim was to find rigidity. Looking at any sheet material, when placed in the horizontal direction it is not rigid, but when folded in the vertical direction, it becomes quite rigid. With this exploration, model making continued to form a component that fit into these aims.
VERTICAL RIGIDITY BASELINE COMPONENT
COMPONENT FORCE APPLIED
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COMPONENT TORSION REACTION
HORIZONTAL CONTOUR APPLICATION
FABRICATION TECHNIQUES
VERTICAL RAIL NO TORSION TWIST
VERTICAL RAIL 15째 TORSION TWIST
VERTICAL RAIL TORSION TWIST
ABSTRACTED COLUMN GEOMETRY
ABSTRACTED COLUMN TWIST
VERTICAL RAIL ASSEMBLY
Now that the component was going to be populated in the vertical direction, focus then moved toward determining a fabrication technique. The idea cutting contours through the model was the first idea. Doing so would allow light to refract out from the structure as well as giving it a less dense structure. Soon it was realized that cutting the contours in the vertical direction instead of the traditional horizontal fashion, would also increase the components unique element of the vertical rigidity while also accentuating its 15 degree twist.
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Moving toward the global assembly, there was refinement to the fabrication of each component. To add strength to the vertical contour rails, the connection was changed to a simple dado connection that would CNC into the top and bottom chords of the component. This also eliminated the fabrication time and cost of a face connection using screws; and resulting in a more aesthetically pleasing, flowing global population.
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16.5”
GLOBAL REFINEMENT
15°
COMPONENT CORD PLAN
COMPONENT CORD AXON
VERTICAL RAILS APPLIED
15° TWIST APPLIED
COMPLETE COMPONENT
ADDITIONAL COMPONENT
MATERIAL RESEARCH LOCAL MATERIAL As to further tie back to the community it was decided to fabricate the column out of a locally-based material. The rolling hills of the Palouse are an iconic symbol of the Eastern Washington landscape. Thus, the wheat board material developed by Washington State University’s Composite Materials & Engineering Center (CMEC). SEPARATING WHEAT STRAW BALES
CHIPPING WHEAT STRAW IN MILL
FINAL WHEAT STRAW FIBERS
APPLYING RESIN TO WHEAT FIBERS
WHEAT FIBERS IN PANEL FORM
PRE-PRESSED WHEAT BOARD
MATERIAL DEVELOPMENT The opportunity to fabricate the wheat board material first-hand was given and was executed through a process that began with many wheat straw bales and ended with a 1/16”- thick wheat board panel.
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In an effort to tie the final installation of the component back to the community it was an idea to display “Welcome to the Palouse” in several different languages on every other vertical rail of the column structure. The above key allows visitors to locate their own language. The total number of languages that were represented in the column was seventy-seven, ranging from Afrikaans to Welsh.
Special Thank You to our Sponsors
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WELCOME TO THE PALOUSE
COMMUNITY TIES
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telugu (Telugu)
român (Romanian)
slovenský (Slovak)
katikati (Swahili) Svenska (Swedish)
khmer (Khmer)
Latine (Latin)
Melayu (Malay)
Latvijas (Latvian)
Malti (Maltese)
Lietuvos (Lithuanian)
Maori (Maori)
kreyòl ayisyen (Haitian Creole)
Hmoob (Hmong)
Igbo (Igbo)
Hausa (Hausa)
magyar (Hungarian)
Indonesia (Indonesian)
Icelandic (Icelandic)
Gaeilge (Irish) italiano (Italian)
English (English)
suomalainen (Finnish)
Georgian (Georgian)
Esperanto (Esperanto)
français (French)
Deutsch (German)
eesti (Estonian)
Galego (Galician)
Pilipino (Filipino) Afrikaans (Afrikaans) • • • • •
CMEC Inland Lighting Modern Millwork NVSD Woodworking Pomeroy Fairgrounds
shqiptar (Albanian)
Cebuano (Cebuano)
CLOSING ANALYSIS ENDING DISCOVERIES As we approached the end of our exploration, we realized the organic nature that the column’s interior produced. In plan view, produced a phyllotaxis condition which is a spiraling arrangement of leaves in some plants. This characteristic obeys as a number of subtle mathematical relationships that can inherently be seen in the column. We were unaware of this factor until final construction was complete. EXHIBITION OPENINGS The column was featured in multiple exhibitions located in Spokane, WA, Moscow, ID, and finally Pullman, WA.
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04 A BETTER USE OF SPACE Furniture Design
Body
Drawer
Base
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PROJECT DESCRIPTION Instructor: Colleagues: Completion: Status:
Mary Polites N/A Spring 2014 Constructed
The aim of this project was to break away from the traditional method of dedicating excessive area in the dresser created by an overlap between faces of the drawers. The sole purpose of the dresser is intended for storage, the concept of maximizing this capacity through side shelving was conceived and executed. In traditional furniture design, the faces of the drawer are over-set passed the functional space of the drawer. This creates a space that is wasted and defeats the overall purpose of the dresser as a space for storage. This wasted space will be looked upon to take advantage of through a new dresser design.
Programs Utilized +Revit +Adobe Illustrator CC +Traditional Woodworking Tools 21
DRESSER INTENTION
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DRESSER FOR CHILDREN The decision to proceed with a child’s dresser then provoked the notion to design the overall dimensions of the dresser to fit accordingly to an average size child who is four feet tall. The dimensions of the drawers were directly correlated with the dimensions of clothing for a child of that size. THE CONCEPT OF ‘FIT’ Items that fit within the context of the home are those that address the parameters necessary in order to become a successful accessory. If one thing were to change within the context, then the object itself may no longer fit. By acknowledging the items that will be stored on the interior of the dresser, as well as the user on the exterior, this dresser becomes an ideal furniture piece in a child’s room.
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REFINEMENT + EXECUTION TERRACING The overall geometry of the terrace is a playful form that will result in the culmination of organization and maximum storage capacity. The cautious decision to not exceed a height of thirty inches was in correlation with the chest height of the child in order to accommodate the limitations children have when trying to access clothing located in the top drawers. The depth of twenty inches allows the reach of a child to reach items located in the back of drawers.
DRAWER ASSEMBLY
DRAWER SLIDES
SIDE SHELVING
EASY-ACCESS PINNED TOP
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05 FOLDED PAPER PAVILION Parametric Design Studio
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PROJECT DESCRIPTION Instructor: Colleagues: Completion: Location:
Mary Polites S. Chimonas, E. Moneymaker, B. Zubiate Fall 2013 Moscow, ID, USA
The focus of the studio was to produce a surface system to act as a pavilion for the Moscow, Idaho Farmers Market. The intervention is defined as a material system which does not exceed a 500 square feet footprint. The design should be deployable and disassembled to address the 8-hour cycle of the market. The pavilion should address the flows and access points of the market and act as a generator for new programs. The material system will be structurally effective and produce, negotiate or intensify at least one environmental condition.
Programs Utilized +Rhinoceros 5.0 +Grasshopper +Adobe Illustrator CC +Traditional Woodworking Tools 25
COMPONENT
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The individual component that aggregates upon itself to form the overall pavilion utilizes a tab connection for ease of constructability. The tabs also allow space for eyelets to be inserted; which would be the main points of connection onto future components or canvas. The canvasing option allows the pedestrian traffic inhabiting the pavilion to escape the harsh Palouse summers.
Ceiling
6’
Horizontal Panel
HORIZONTAL PANEL Light-weight panels cause less stress on legs
1/4”
TAB EYELET
1/2”
TAB CONNECTION DETAIL
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4’
VERTICAL PANEL Provides support for roof
-Provides support for the Five components roofin a pentagon are
-Fivehorizontally components in a pentagon are then paneled horizontally Three in com-
-Five components in a pentagon are then paneled vertically Three in com-
-Three in complete assembly
-Three in complete assembly Allows arching
plete assembly
LANDSCAPE
4’
-Light-weight panels cause Five components less stress on legs in a pentagon are then panelled
Landscape
WALL
6’
8’
TAB CONNECTION
Wall
CEILING
then panelled
plete assembly
4’ Dodecahedron
DODECAHEDRON
for shelving and habitat-
-Provides stability for legs
weigh the structure down
-Bears the total load of pa-
30 total vilion components in dodecahedron
-30 total components Provides stability for legs decahedron
in do-
MATERIAL RESEARCH CARTON PAPER There are many benefits to the local economy, the local community, and the livelihoods of producers when products are manufactured and purchased locally. 34 miles from Moscow is a paper mill in Lewiston, Idaho.
FOLDED RIGIDITY OF PAPER
FOLDED RIGIDITY OF COMPONENT
Carton paper is used in the production of milk cartons and is a specially manufactured paper containing two laminations on either side to create a water-proof seal. When the mill gets towards the end of the paper roll, the lamination is no longer acceptable for milk carton production. Rather than the paper being wasted in a land fill, the paper is reused in component production.
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FABRICATION
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To avoid paper fraying and have the ability to mass-produce components, the carton paper was sandwiched between two 1/2� thick layers of medium-density fibreboard. A flexible moment of connection material was essential to assist in the program assembly process. Zip ties warranted these considerations and further aided the design process. Because the pavilion will not be able to be located in the same spot every week, the pavilion needed the ability to change every week to respond to the specific site conditions. The white zip ties represent the connections within each program. The black zip ties signify connections from one program to another, and when disassembling, are cut. The end result, when leaving the site after disassembly, is multiple ceiling, wall, and landscape programs that will then be constructed the next week in a new configuration with black zip ties.
CARTON PAPER+MDF
BOLT SECUREMENT
JIGSAW CUTOUT
EYELET GUIDELINES
COMPONENT CUTOUT
FOLDING TABS
COMPONENT FOLD
EYELET CLAMPING
COMPONENTS
ZIP TIE CONNECTION
2.5 Hrs
Template Tracing MDF/Paper Stacking
1 Hrs 1.5 Hrs
Template Cutting 1 Hrs
Drill Guidelines 3 Hrs
Component Folding 5.5 Hrs
Eyelet Clamping 0.5 Hrs 1.5 Hrs
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2-Man Crew
3-Man Crew
Sand Insertion Final Assembly
PAVILION TRANSLATION Due to the flexible design opportunities, the pavilion is always responsive in relation to the site conditions. In the optimal site setting, the assembly will feature an asymmetrical design that accommodates the flow of the farmers market’s pedestrian traffic. The large entrance areas create vibrant access points that open up to an easily habitable space for multiple people at one given time. The heavy base that supports a lighter ceiling allows for the creation of interesting shadows on the ground for individuals inhabiting the space as well as passerby that will be drawn into the structure. Each week, patrons will be eager to see where the pavilion is located and the corresponding form that arose from such site. Creating a more vibrant farmers market in Moscow, Idaho and giving back to the community that provided the material for such a possible assembly.
PAVILION PLAN VIEW
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Thank You