Master of Architecture - Segment II by Ross McKinnon

PORTFOLIO SEGMENT TWO

rossmckinnon

ROSS MCKINNON MASTER OF ARCHITECTURE BOSTON ARCHITECTURAL COLLEGE BOSTON, MASSACHUSETTS, USA ross.mckinnon@the-bac.edu 1(403)700-4370 Date of Submission: 12.15.2020

WO RK EMBARC STUDIO Designer - Boston, MA

E D UCATI O N 2020 - Present

BOSTON ARCHITECTURAL COLLEGE Master of Architecture

2018 - Present

+ 76 Ashford Street (Boston, MA) - Helped

+ The Master of Architecture is a first professional

+ Member of the American Institute of America

evolve the Conceptual Design and presentation packages for a 16 story residential tower in Allston, MA. 1558 Tremont Street (Boston, MA) - Organized the Unit Matrix to follow both Market and Compact Housing Models, while moving forward with conceptual design. 8 Delanson Circle (Wellesly, MA) Collaborated with the Landscape and Civil teams to develop directions for a complex site.

STANTEC ARCHITECTURE LTD. Architectural Designer - Boston, MA

2018 - 2020

+ Abiomed (Danvers, MA) - Worked through + + +

Contract Administration throughout various phases over the course of a year. 104 Canal (Boston, MA) - Assisted with the production of the final CD Set of a intricate brick boutique hotel in Boston’s West End Dot Block (Boston, MA) - Design Development and Construction Documents of a four-building development in Dorchester, Massachusetts. The BEAT (Boston, MA) - Responded to RFI’s and reviewed shop drawings during the CA phase of the re-purposing of the former Boston Globe headquarters. Built multiple models in preparation for Client Meetings.

P R O F I C I E N C Y : Revit, AutoCAD, Adobe Creative Suite (Illustrator, Photoshop, InDesign), SketchUp, Bluebeam, Lasercutter.

degree accredited by the National Architectural Accrediting Board (NAAB) that prepares students to earn licensure in as little as 2 years.

Students (AIAS) - BAC Chapter Cumulative GPA - 3.84

U N I V E R S I T Y O F C A L G A R Y 2012-2017 Bachelor of Arts - Urban Studies + Interdisciplinary program designed to provide an integrated understanding of the social, political, economic, environmental and cultural processes that shape urban life. + Member of the University of Calgary Men’s Baseball Team (2012-2017)

REFLECTIVE INTRODUCTION It has been close to two years since my last portfolio submission. Over those two years, I’ve had countless sleepless nights, dozens of coffee-fueled design crits, and a handful of self-treated injuries from late night model making adventures (all of this on top of the global pandemic we are all experiencing). I’m not typically a supporter of the ‘rite-of-passage’ mentality, however in this case I couldn’t be happier I’ve been able to experience what I have at the Boston Architectural College. The growth I’ve been able to experience over the last two years only has me more excited to continue along this path. This portfolio is a sample of both my academic and professional growth that I would have never known myself capable had it not been for the City of Boston. Beginning with Studio II, I was able to push forward a design in a city I was finally beginning to feel like a resident of and not a visitor. Studio III & IV pushed me even more to begin solving global and sociological problems through the City of Boston. My goal as an architect is to continue to challenge myself by seeing my work through the everchanging lens of humanity and sociology. This portfolio begins to address this intent through a combination of studio work, and additional coursework.

TABLE OF CONTENTS

Calumet Street Cider House

Cambridge Community Recreation Center

District Wharf Food Hall & Transportation Hub Building Systems

12 36

ARCHITECTURE STUDIO II: CALUMET STREET CIDER HOUSE INSTRUCTORS BILL BOXX â&#x20AC;¢ FALL 2019

Tucked into a small urban hillside in Mission Hill, Boston, the design of the Cider House draws a close parallel between the topography of the land and the gravitational process of cider making taking place inside. Through using organic materials like stone, concrete, timber and rusted steel, the design is intended to simplify the transition from the urban context of the site with the natural processes of cider making. A very intentional programming process allows for each space to stimulate their key characteristics and share them with not only the users but also the passers-by. 7

Site

Configuration

1. Basic program applied into a conceptual mass, shaped by the property line.

3. Deck structure is shaped allowing for seamless circulation for users at all points of the site. Key element of the Cider Production Facility retains its original shape to provide wayfinding for visitors.

2. Massing is shaped to match the natural topography of the existing site, giving the structure a more personal relationship with pedestrians at both the entrance and sidewalk.

4. Once occupied, the project allows for many modes of circulation all funneling through the central artery.

Documentation 10

8 2

1 Entry

2 Cafe

3 Production Room 4 Kitchen 5 Storage

Level 1

7 Production Room

8 Exhibition Space 9 Gallery

10 Community Space

6 Tap Room

11 Roof Deck

Level 2

Site Plan

Level 3

Tectonics

Used as a private retreat for community members, this space’s function is as versatile and adaptable as it’s design. Located in the back corner of the site, this space is intended to be a soft transition from the natural to built environment. The floating ceiling creates a built canopy, working along side the natural canopy of trees.

The perforated metal wall system wraps around the entire streetside façade of the project. An extremely versatile material, this system is intended to function as a light diffuser towards the production center and tap room, as well as serve an aesthetic purpose by appearing as a “glowing lantern” at night and enticing the public to peer into the space.

An elevated position above the fermentation tanks allows for a unique perspective into the intricate process of cider making. The slope of the roof structure allows for unique clerestory windows, increasing natural daylight intake into the production areas, as well as opening up views of the surrounding area. 10

ARCHITECTURE STUDIO III: DISTRICT WHARF - FOOD HALL & TRANSPORTATION HUB INSTRUCTORS TYLER HINCKLEY & ROB ADAMS â&#x20AC;¢ SPRING 2020 Team:

Almira

Akman,

Ross

McKinnon,

Janina

Piorowski

District Wharf is a reflection of the energy and vision inspired from within Bostonâ&#x20AC;&#x2122;s Seaport District. In an increasingly dense neighborhood, District Wharf strives to maintain a balance of natural and build infrastructure, in a rapidly expanding part of the city. By creating a combination of an extended landscape and biophilic facade, the public is given a building that uses the landscape to both protect the invaluable remaining green space while also giving a unique opportunity with an intimate connection with the daily tides. 13

Our site contains several key features which must remain undisturbed the design process - most prominently the continuation of the Harbor extension of Fan Pierâ&#x20AC;&#x2122;s Green Alley.

Although Fan Pier Park residents with nature, District and bring the

during Walk and

has flourished in their opportunity to connect Seaport it is District Wharf that will cut through the Seaport natural vibrancy of Fan Pier park deeper into the community.

2020 Median High Tide

2020 Extreme High Tide

2070 Extreme High Tide

2070 Storm Surge

Sea

Level

2020 + 6.67’ + 4.24’

Rise

EHT Median

High

Tide

2070 + 9.97’ EHT + Anticipated Level Rise

40”

Sea

2070 + 9.97’ EHT + 15’ Target Elevation for Storm Surge protection

Documentation 10'

30'

10'

30'

20' 10'

20'

30'

DO CK TO

WA TER

TA XI

20'

TO ROOF BRIDGE TO ICA

VENDOR

TICKET OFFICE

VENDOR VENDOR VENDOR

VENDOR ROOF DECK VENDOR

VENDOR

ROOFTOP BAR

TO ROOF VENDOR

VENDOR

VENDOR BAR STORAGE VENDOR

VENDOR

CENTER BAR

CO NFER ENCE

VENDOR

RO OM

VENDOR

ADMIN

Level One Plan

Level Two Plan

Roof Plan

The adaptable landscape is designed to give people a closer relationship with water, regardless of the level of tide or weather event. Although during storm surges water taxiâ&#x20AC;&#x2122;s will likely be non-operational, the intent is to still provide the public with a harbor walk that can be safely accessed and used.

Although high water levels will slow down water transportation, the public food hall will still be celebrated by Seaport residents and the Boston Public, as a resilient building and refuge for exchange, conversation, and public life.

ARCHITECTURE STUDIO IV: CAMBRIDGE COMMUNITY RECREATION CENTER INSTRUCTOR MICHAEL FERRARA â&#x20AC;¢ FALL 2020

Studio IV challenged us to progress from conceptual design to producing a true and realistic structure by identifying zoning and code constraints, construction and assembly types appropriate for the building proposal. A large emphasis placed on structural and mechanical systems selection, as well as material construction.

Analysis T

Zoning (Current) = OS L

S E IN A

RIVE

Includes, but is not limited to: + Art Galleries + Community Halls + Gymnasiums + Libraries + Indoor Tennis Courts C

Site Constraints H

60,000 SF Site 10,000 Maximum Footprint 120’-0” Maximum Height E

L K O

RLES

Assembly Group = A3

CHA

R L D G

RIA

Zoning (Buildable Area) = C3 P

Site

KLI

VER

Site 70’-0” 60’-0” 50’-0” 40’-0” 30’-0” 20’-0” 10’-0”

MAGAZINE BEACH

MEMORIAL DR

CHARLES RIVER

70’-0” 60’-0” 50’-0” 40’-0”

VIEW FROM MAGAZINE ST

30’-0” 20’-0” 10’-0”

MAGAZINE BEACH

MEMORIAL DR

CHARLES RIVER

VIEW FROM MAGAZINE ST

Analysis

One of the critical site constraints was its visual access from nearby neighborhoods. The Project Site was largely blocked by an array of trees.

Due to the visual constraint, what would become of the ‘void’ space created?

120’-0” 110’-0” 100’-0” 90’-0” 80’-0” 70’-0” 60’-0”

My solution: Build Tall

50’-0” 40’-0” 30’-0” 20’-0” 10’-0”

MAGAZINE BEACH CHARLES RIVER

MEMORIAL DR

VIEW FROM MAGAZINE ST

Program

Stacked

Program

SOCIAL

ACADEMIC ACTIVITY

ACCESS

SOCIAL

ACADEMIC

ACCESS

13’-3”

SOCIAL ACCESS

15’-0”

FLEX

Level 6 73’-3” Level 5 63’-3”

SQUASH

Level 4 43’-3” SPIN

Level 3 28’-3” Level 2 13’-3” Level 1 0’-0”

SOCIAL HUB OUT

LOBBY

ART STUDIO

15’-0” 15’-0”

ART STUDIO

Level 7 83’-3”

EDUCATION CENTRE

10’-0” 10’-0”

Level 8 98’-3”

EDUCATION CENTRE

Integration

YOGA

SQUASH

20’-0”

Level Roof 113’-3”

15’-0”

ACTIVITY

20’-0”

10’-0” 10’-0”

ACADEMIC

Architectural 15’-0”

Organization

15’-0”

Spatial

SOCIAL HUB IN

ELEV. LOBBY

FOOD KIOSK CAFE

15’-0”

ACTIVITY

13’-3”

Block

Massing

BUILDING CORE

Block

Level Roof 113’-3” Level 8 98’-3” Level 7 83’-3” Level 6 73’-3” Level 5 63’-3”

Level 4 43’-3” Level 3 28’-3” Level 2 13’-3” Level 1 0’-0”

EDUCATION CENTRE ART STUDIO FLEX

SQUASH

SPIN

SOCIAL HUB OUT

LOBBY

BUILDING CORE

Design

EDUCATION CENTRE ART STUDIO YOGA

SQUASH

SOCIAL HUB IN

ELEV. LOBBY

FOOD KIOSK CAFE

Statement

WHEN A TREE GROWS A NEW BRANCH, IT IS TAKING AN OPPORTUNITY TO CREATE MORE LIFE THROUGH AN EXTENSION OF ITSELF. THE CAMBRIDGE RECREATION CENTER IS FOLLOWING THIS MECHANISM BY BRANCHING OUT ITS LIMBS TO CREATE SMALL POCKETS OF LIFE SUSPENDED IN THE AIR. IN THESE MOMENTS, THE ARCHITECTURE INTENDS TO FRAME VIEWS, OFFER MOMENTS OF RELIEF, AND CREATE A WARM ENVIRONMENT FOR THE USER. ACTING AS A BEACON FROM THE EXTERIOR, THE INTERIOR ACTS AS A HIDEAWAY FROM THE EVERYDAY STRESSES OF LIFE.

32' - 5 1/2"

30' - 11 1/2"

30' - 7"

20' - 8 1/2"

Building

F 21' - 3"

---

Section

1 -

27' - 6"

---

READING ROOM

32' - 0"

STUDY ROOM -

3 18' - 2"

STUDY ROOM

30' - 3"

STUDY ROOM

STUDY ROOM -

---

STUDY ROOM

OPEN TO GALLERY BELOW STUDY ROOM

OPEN LOUNGE SPACE STUDY ROOM

---

STUDY ROOM

Gallery

Design

STUDY ROOM

ART STORAGE

ART STUDIO

GALLERY

YOGA STUDIO

LOBBY

SOCIAL HUB (INDOOR)

ENTRY & LOWER GALLERY

Structure The building is constructed of a simple steel & concrete structure. This allowed for the most freedom when making decisions on the form and flow of the structure. Thanks in large to the small footprint of the building, a fairly small amount of columns are actually carried all the way to the roof level.

Building

Details

Concrete

Slab

Steel

Deck

Rigid

Insulation

Steel

Beam

Wood Soffit & Cladding system

Mechanical

With a 2000 square foot mechanical room in the basement, we were able to host two (2) boilers, two (2) chillers, water pumps, and adequate equipment to support heating and cooling distribution throughout the building.

Source: The Architect Studioâ&#x20AC;&#x2122;s Companion, 5th Edition Allen and Iano: page 180181, 185

Source: The Architect Studioâ&#x20AC;&#x2122;s Companion, 5th Edition Allen and Iano: page 168-169

Basis of design - Single Duct, Variable Air Volume System (left)

Mechanical Due to the relatively small footprint of the building, a simple network of ductwork will provide ample heating and cooling all throughout the building. UP

CAFE (LOWER)

BOILER

MECHANICAL ROOM

WATER CHILLER WITH CONDENSATION TANK

1075L WATER TANK

Basement

Plan

Mechanical

Room

Level

Plan

The main entrance features two green roofs, which will also act as water catchment gardens. This trend of â&#x20AC;&#x153;small-scaleâ&#x20AC;? green roofs is continued throughout the rest of the project.

Water

Catchment

Water

Catchment

Grass w/ overflow capacities Modified Soil (filter)

Transition Layer coarse sand and gravel) Collection Pipe

To Water Storage Tank located in Mechanical Room in Basement

As seen for the

from Magazine Street, entire neighborhood.

this

community

center

will

act

beacon

The fourth floor terrace south. This moment is an

will offer tremendous natural light facing dueintegration of interior and exterior activities.

BUILDING SYSTEMS INSTRUCTOR JOHN PILLING • T.A. JOHN MAZZOCCHI • FALL 2020

We e k 1 2 - I n C l a s s A s s i g n m e n t

ROOF DETAIL

Building Envelope -

I c e , Wa te r , Va p o r B a r r i e r

Copper Cap Flashing

Lap and Seal Roof Flashing onto Water/Air Barrier Rainscreen Ventilated Airspace Continuous Rigid Insulation Water/Air Barrier

Sheathing EPDM Tapered Rigid Insulation Sheathing

Lap and Seal Roof Flashing onto Water/Air Barrier

Insulation Support

Interior Finish

Insect Screen

Rainscreen

Continuous Caulk with Backer Rod

Continuous Sealant with Backer Rod Copper Flashing

Water/Air Barrier

Ventilated Airspace Continuous Rigid Insulation Water/Air Barrier

20' - 0"

Official Course Desription: The concept of “Good Building” in the Western tradition began with the Roman architect and author Vitruvius. Its evolution to the present day requires students and practitioners of architecture to consider not only its ‘conditions’ (whose interpretation the instructor has borrowed from theorist Steve Mouzon): “Useful (adaptable / frugal), Durable and Lovable but the systems needed to be designed for it: Safety, Site, Services, Skin, Structure, and Sustainability.

Sheathing

10' - 0"

EPDM Tapered Rigid Insulation

15' - 0"

Sheathing

Insulation Support

Interior Finish Copper Cap Flashing Lap and Seal Roof Flashing onto Water/Air Barrier Rainscreen Ventilated Airspace Continuous Rigid Insulation Water/Air Barrier

Sheathing EPDM Tapered Rigid Insulation Sheathing

Insulation Support

Interior Finish

Insect Screen

Continuous Caulk with Backer Rod

Continuous Sealant with Backer Rod Copper Flashing

Water/Air Barrier

20' - 0"

Continuous Sealant with Backer Rod

10' - 0"

15' - 0"

Copper Flashing

Continuous Sealant with Backer Rod Copper Flashing

Continuous Sub-Grade Insulation Water Barrier Cover Board

Concrete Foundation Wall Filter Fabric Foundation Drainage

Sub-Grade Drainage Mat Capillary Break Foundation Drainage Concrete Foot with Rebar Dense Graded Agregate

The detail reveals the careful location of the air/water barrier in the wall and roof systems. Note: there is NO true vapor barrier employed in the wall so the system can dry in either direction as required by changing weather conditions.

Continuous Sub-Grade Insulation Water Barrier Cover Board

Concrete Foundation Wall Filter Fabric Foundation Drainage

Sub-Grade Drainage Mat Capillary Break Foundation Drainage Concrete Foot with Rebar Dense Graded Agregate

“Room 4” Nicholas Zartarian

TSM2002 - Building Systems - Fall 2020 |

Hunt Stehli

Monica

Elkomos

Marissa Mayo

Ross McKinnon

Safa Alazri

Insect Screen

Continuous Caulk with Backer Rod

ENETRATION Light

We e k 1 1 - I n C l a s s A s s i g n m e n t

We e k 1 1 - I n D C lA aY s sL A s sH i gTn m t ETRATION IG PeEnN

Building Envelope - Daylighting

A Window n a l yprovides s i ssufficient amount of daylighting for

most of the space. Supplemental lighting required for portion of room not near the window. Copper Cap Flashing Rainscreen

Ventilated Airspace

Continuous Rigid Insulation

Water/Air Barrier

Sheathing EPDM

Tapered Rigid Insulation

Sheathing

Insulation Support Interior Finish

Insect Screen

7' - 0"

10' - 0"

Continuous Caulk with Backer Rod

4' - 6"

7' - 6"

20' - 0"

3' - 0"

10' - 0"

Window provides sufficient amount of daylighting for the space. 15' - 0"

ENETRATION

We e k 1 1 - I n C l a s s A s s i g n m e n t Building Envelope - Daylighting Continuous Sealant with Backer Rod Copper Flashing

Continuous Sub-Grade Insulation

Window provides sufficient amount of daylighting for most of the space. Supplemental lighting required for portion of room not near the window Assuming the room is 20’ x 40’ (800 square feet), the window area required is approximately 200 square feet, making it about 28.5 feet long. Water Barrier

Cover Board

1. Window provide s sprovides u f f isufficient c i e amount nt a o u n tfor the o fspace. da y l i gthehroom ting Window of m daylighting Assuming required 40 square f o r m o s t o f t h e s pisa10’cxe15’.(150 S usquare p p lfeet), e mthe e window n t a larea l i g histapproximately ing r e q u i r e d f o r p o r t i o n o f r o o m n o t n e a rfeet,tmaking h e it wabout i n9dfeet o long. w A s s u m i n g t h e r o o m i s 2 0 ’ x 4 0 ’ ( 8 0 0 s q u a r e f e e , T S M 2 0 0 2 - B u i l d i n g S y s t e m s - F a l l 2 0t 2) 0 T S M 2 0 0 2 - B u i l d i n g S y s t e“ R moso -mF 4 a ”l l 2 0 2 0 the window area required is approximately 200 cnhoonl a |s Z Sa ar tf a a rA i al a n z r i| H u n ts Sqt u e hal ir e| f Me on c a, E lmk o Ro n nto n l |o nS g a f. a Alazri M o n i cWindow a E l k o mprovides os | Ma r i s s a amount Mayo |of daylighting R o s s M c KNi ni high ei t am k ois n |g Miatr i s saa bMoa yuot | 2 8 .s5s Mfc Kei e some in Concrete Foundation Wall Filter Fabric

Foundation Drainage

Sub-Grade Drainage Mat

3. |

Hunt Stehli

Capillary Break

Foundation Drainage

Concrete Foot with Rebar Dense Graded Agregate

the space. Supplemental lighting will be required.

Window provides sufficient amount of daylighting for areas close to the windows. Supplemental lighting required for inner portion of the space. Team:

Safa

2. Window provides sufficient amount of daylighting for the space. Assuming the room is 10’ x 15’ (150 square feet), the window area required is approximately 40 square feet, making it about 9 feet long. 3. Window provides some amount of daylighting high in the space. Assuming the room is 15’ x 20’ (300 square feet), the window area required is approximately 70 square feet, requiring that this narrow clerestory window be 23 feet long, longer than the room itself. If a clerestory is required by other circumstances, supplemental light will be required.

A l a z r i , Window M o nprovides i c a some E lamount k e mofodaylighting s , M ahigh r iinsthes space. a MAssuming a y o , theR o s s room is 15’ x 20’ (300 square feet), the window area required is approximately 70 square feet, requiring that this narrow clerestory window be 23 feet long, longer than the room itself. If a clerestory is required by other circumstances, supplemental light will be required.

TSM2002 - Building Systems - Fall 2020

McKinnon,

Hunt

Stehli,

Nick

Zartarian

*Image obtained through Climate Consultant 6.0 Software

The design strategies shown on this page are only a sample of the many methods we can use to achieve the goals of the 2030 challenge. The most important on our given site, is that of passive solar heating, and taking advantage of the sun path of our site.

*Images shown on this page were obtained through the Climate Consultant 6.0 Software, and are not my own.

*Image obtained through Climate Consultant 6.0 Software

â&#x20AC;&#x153;This software was developed by the UCLA Energy Design Tools Group, along with the Regents copyright notice. (...) The program was develped as a result of work sponsored by the California Energy Commission. It does not necessarily represent the views of the Energy Commission, its employees, or the State of California. The Energy Commission, the State of California, its employees, contractors, and subcontractors make no warranty, express or implied, and assume no legal liability for the information in this report; nor does any party represent that the use of this information will not infringe ypon provately owned rights.â&#x20AC;?

Code

Analysis

Our parcel on Magazine Beach has been designated as either a C-2 or C-3, which opens up the conversation to a world of possibilities.

Exhibition Halls occupant Concentrated (chairs only *

Square

(IBC

foot

2015)

per

occupant

load factor = 30 - not fixed) = 5

net* net*

Egress Minimum 3 means Maximum 200’-0” Maximum 250’-0” (IBC 2018)

of egress distance from distance from

eachother eachother

Plan

(w/o sprinkler) (w/ sprinkler)

44’-0”

35’-0”

THANK YOU FOR YOUR TIME