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INLINE Fiberglass windows in Toronto Community Housing Corporation (TCHC) Project.

Time-tested durability Superior energy efficiency Residential and commercial applications Project: TCHC West Don Lands. Location: 589 King Street E, Toronto, ON. Architect: CORE Architect. Project Management: BLUESCAPE.

ARCHITECTS AND DESIGNERS FOR TORONTO COMMUNITY HOUSING’S WEST DON LANDS DEVELOPMENT project have incorporated Toronto’s goals to provide long term sustainable building systems that use less energy and lower carbon emissions. INLINE FIBERGLASS LTD. is a proud partner in helping Toronto achieve these goals.

CALL US TO DISCUSS YOUR NEXT PROJECT! lbidner@inlinefiberglass.com 24

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7 Resilient Design Resilence is the new sustainability, sponsored by the Canadian Precast/Prestressed Concrete Institute

SUMMER

17 2018 Canadian Green Building Awards The nine winning projects: - UBC Campus Energy Centre - Brock Common Tall Wood House - Langara College Science & Technology Building - Harvey Woods Lofts - Environmental Science and Chemistry Building - Okanagan College Child Care Centre - Ecology Action Centre Headquarters - Centre de Découverte - One York Street

ISSUE DON’T MISS NEXT FALL 2018 Passive House Supplement: Examples and details for super energy efficiency Continuing Education: Details for high-performance envelopes Design Practice: Building conservation for the low-carbon economy Top right: Our 2018 jury: Left to right: Heather Dubbeldam, Thomas Schweitzer and Lindsay Oster. Photo: Roy Grogan. Cover and middle right row: The nine winning projects of the 2018 Canadian Green Building Awards. Bottom: PassiveHouse-certified Salus Clementine Social Housing. SABMag - SUMMER 2018

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Photographer: Jesus Martin Ruiz Diamond Schmitt Architects Wilfrid Laurier University

Wood with no maintenance for contemporary architecture www.parklex.com

Partners with Engineered Assemblies Inc. www.engineeredassemblies.com

Tel: 1 866 591 7021 Email: info@engineeredassemblies.com

Uniting the house of design with the field of construction 4

SABMag - SUMMER 2018

Dedicated to high-performance building LEED EDUCATION PROVIDER

Member Canada Green Building Council

CELEBRATING THE 2018 CANADIAN GREEN BUILDING AWARDS

SABMag is a proud member and official media partner of the Canada Green Building Council.

The winning projects in this year’s awards program were selected from a strong and diverse field of entries that confirmed the breadth and depth of the green building industry in Canada.

VISIT www.sabmagazine.com

They ranged in scale and scope from the Ecology

PUBLISHER Don Griffith 800-520-6281, ext. 304, dgriffith@sabmagazine.com

Action Centre, the rehabilitation of a century-old residential building in Halifax, to One York Street,

EDITOR Jim Taggart, FRAIC 604-874-0195, architext@telus.net

a technologically sophisticated 35-storey office tower on the Toronto waterfront.

MARKETING MANAGER Denis Manseau photo: Roy Grogan

800-520-6281, ext. 303, dmanseau@sabmagazine.com SENIOR ACCOUNT MANAGER Patricia Abbas 416-438-7609, pabbas8@gmail.com

Many of the submissions reflected a renewed focus on energy conservation, with both the

Passive House certified Okanagan College Child Care Centre in Penticton, BC and the Environmental Science and Chemistry Building at the University of

GRAPHIC DESIGN Carine De Pauw cdepauw@sabmagazine.com

Toronto’s Scarborough campus being recognized in this regard. Life cycle considerations drove the choice of wood as the primary structural

Published by

material for the Brock Commons student residence and Campus Energy Centre

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at the University of British Columbia in Vancouver, as well as for the Centre de Découverte, located on an island in Boucherville, QC. Similar concerns dictated the conservation strategies in the conversion of a historic factory to create

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the Harvey Woods Lofts in Woodstock, ON.

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Occupant wellbeing was also a key consideration in many projects, with

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the Langara College Science and Technology Building in Vancouver being remarkable both for the handling of daylight in a deep plan building, as well as for the quality and diversity of its social spaces. We have many to thank for making the 2018 Canadian Green Building awards a success: all of those who prepared and entered a submission; our jury consisting of Heather Dubbeldam of Dubbeldam Architecture + Design in Toronto, Lindsay

ISSN 1911-4230 Copyright by Janam Publications Inc. All rights reserved. Contents may not be reprinted or reproduced without written permission. Views expressed are those of the authors exclusively.

Oster of Prairie Architects Inc. in Winnipeg and Thomas Schweitzer of Aedifica in Montreal who shared their expertise and insight in the careful evaluation of all the entries; and, of course, our sponsors as noted below, particularly our national sponsors Masonite Architectural and the Canadian Precast/Prestressed

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Concrete Institute. It is the support of our sponsors that makes this program possible.

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NEWS VANCOUVER ZERO EMISSIONS BUILDING CENTRE OF EXCELLENCE TO LAUNCH THIS SUMMER The Vancouver Regional Construction Association [VRCA], in partnership with the City of Vancouver, Passive House Canada and the Open Green Building Society, has announced that the Vancouver Zero Emissions Building Centre of Excellence [ZEBCoE] will open this summer. The mission of the Centre is to rapidly accelerate the capacity of local developers, designers and builders to deliver cost-effective, attractive, zero emissions new residential and commercial buildings in Vancouver. The Centre aspires to learn from both local and global leaders and to expand its mission to support zero emissions building across the province. “The development and launch of ZEBCoE aligns perfectly with our association’s strategic direction to foster an environment that encourages collaboration, innovation and continuous learning across the industry,” says VRCA President Fiona Famulak. An official launch of the Centre is planned for summer 2018. ffamulak@vrca.ca

BEST PRACTICE GUIDE: ARCHITECTURAL PRECAST CONCRETE WALLS The new Best Practice Guide from the Canadian Precast/ Prestressed Concrete Institute summarizes the most current best practices in architectural precast concrete design and construction, and illustrates recommended design details and site practices. Readers can request a copy online at: http://www.cpci.ca/en/resources/bestpractice_ archguide_offer/

LAFARGE TO USE RESIDUALS FROM WATER TREATMENT TO MAKE CEMENT Lafarge Canada Inc. and Metro Vancouver have reached a three-year agreement to use water treatment residuals from the Seymour Capilano Filtration Plant as material in cement manufacturing, and thus become part of the circular economy. The residuals are the solids removed during the drinking water filtration process, and and treatment chemicals [coagulants and polymers]. They contain a chemical profile that mimics that of red shale, a virgin aggregate input required as a raw material in cement manufacturing. The agreement means that fewer virgin materials would be needed to be mined, while residuals would be kept out of the landfill. jennifer.lewis@lafargeholcim.com

EVENTS October 11th 2018, the annual Green Building Festival, by Sustainable Buildings Canada, CaGBC Toronto Chapter, The Ontario Association of Architects, and the Toronto 2030 District, Toronto Marriott Downtown Eaton Centre Hotel. Speakers, networking and continuing education hours.

IS AN EXCELLENT CHOICE FOR ANY GREEN BUILDING PROJECT

Products certified to SFI are recognized by many leading green building rating programs around the world like Leadership in Energy and Environmental Design (LEED) and Green Globes. 6

SABMag - SUMMER 2018

Using wood products from responsibly managed forests is key to any green building project. Third-party forest certification standards, like the Sustainable Forestry Initiative® (SFI), are a proof-point that wood comes from responsibly managed forests that have been managed for multiple environmental, social and economic values — today and into the future. Architects and builders are turning to products certified to the SFI Standard to meet their green building needs. Learn more at: sfiprogram.org/green-building

CANADIAN PRECAST/PRESTRESSED CONCRE TE INSTITUTE

RESILIENT DESIGN RESILIENCE IS THE NEW SUSTAINABILITY

.ca .ca

RESILIENCY SABMag - SUMMER 2018

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RESILIENT DESIGN RESILIENCE IS THE NEW SUSTAINABILITY

After the catastrophic flooding in Moncton, Fredericton, Winnipeg, Ottawa, Calgary and the devastating wildfires in fort McMurray, Alberta, Canadians are realizing that climate change is one of the biggest challenges that the world faces. Tackling climate change is a top priority for all levels of government - at home and internationally.

RESILIENCY

Climate change has already had far-reaching impacts on infrastructure and has profound effect on sustained operation of the built environment. This trend is likely to accelerate in the coming decades. The main threats to infrastructure assets include damage or destruction caused by extreme weather events. Besides efforts to reduce climate change, decision makers need to prepare our infrastructure for the climate change that cannot be avoided. Building code requirements have an emphasis on life safety, i.e. allow major damage or total collapse providing the occupants can be evacuated prior to or during the event. Excessively damaged buildings have a slow recovery and may even prevent recovery for some neighbourhoods. But What Exactly is Resiliency? Resiliency can be defined as the adaptability of a system (communities) to maintain its function and structure in the face of turbulent internal and external change. The key attributes of enhanced structural resiliency are improvements in: • • • • • • •

Longevity (service life) Robustness Sustainability Life safety Durability Adaptability for reuse Resistance to disasters

Thoughtfully chosen, properly designed new construction can significantly improve both the resilience to natural and man-induced disasters and the long-term sustainability of modern urban environments in the 21st century. In particular precast concrete construction has the ability to provide extremely durable buildings at similar costs to traditional construction while also providing a more sustainable construction form, in terms of higher energy efficiency, lower embodied energy, safety, and a quicker recovery after a disaster. CPCI, NPCA, PCI and Members are the leading source of technical resources (Body of Knowledge (BOK)) for the precast concrete industry in North America. From this BOK, building codes, design guides, educational programs, certification, sustainability programs, and new research ideas are derived. This joint industry initiative develops, maintains, and disseminates the BOK necessary for designing, fabricating, and constructing sustainable and resilient precast concrete structures. 8

SABMag - SUMMER 2018

RESILIENCE IS THE NEW SUSTAINABILITY

CHAMPAGNE QUARRY PARK – FORMER INDUSTRIAL LANDS REJUVENATED AS SELF-CONTAINED COMMUNITIES Calgary, Alberta

Owner: Remington Development Corporation Architect: Gibbs Gage Architects Engineer: Kassian Dyck & Associates Contractor: Remington Development Corporation Precast Supplier: Lafarge Precast

Photos courtesy of Lafarge Precast

Champagne Quarry Park in Calgary is an example of what is happening in many parts of the country where former industrial lands along waterways and near city cores are being rejuvenated as self-contained communities. The project comprises five individual - four- and five-storey total precast buildings located on top of two levels of interconnected underground parking. The architecture is French provincial, which is supported with details such as natural stone and steep-pitched roof lines. It has balconies and large windows and arched detailing over the top windows. Colour palettes, construction materials and specifications differentiate this property from any other in Alberta. Precast Concrete is Safe Everybody knows that precast concrete does not burn! Not only is the structural stability maintained for longer periods, but precast concrete construction prevents the spread of fire from one building to another. SABMag - SUMMER 2018

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RESILIENCE IS THE NEW SUSTAINABILITY

ST. TERESA PLACE SUPPORTIVE LIVING FACILITY Calgary, Alberta

Owner: Covenant Care Architect: FWBA Architects Engineer: MPE Engineering Ltd. Contractor: Mansfield Construction Precast Supplier: Armtec Precast

Photos courtesy of Armtec Precast

St. Teresa Place facility, located in Calgary, Alberta, is a total precast concrete supportive living building. Located at 10 Redstone Place in Northeastern Calgary, this supportive living complex is four storeys in height, contains 250 units and has a gross building area of 19,000 square metres (205,000 square feet). The building was completed on a condensed installation schedule, without compromising the architectural design. This building method facilitated a fabrication and installation schedule of mere months – starting with precast production in June, precast installation starting in August and completion by the end of November. Total precast construction provides a state-of- the-art solution for continuing care needs by delivering a safe, fast, sustainable and resilient building. Precast Concrete is Tornado, Hurricane, and Wind Resistant Precast concrete is resistant to tornadoes, hurricanes, and wind. Debris driven by high winds presents the greatest hazard to occupants of homes, offices and commercial facilities during hurricanes and tornados. 10

SABMag - SUMMER 2018

RESILIENCE IS THE NEW SUSTAINABILITY

THE BARREL YARDS POINT TOWERS Waterloo, Ontario

A SWITCH TO PRECAST CONCRETE MID-PROJECT REDUCES THE CONSTRUCTION SCHEDULE BY ONE YEAR

Owner: Auburn Development Inc. Architect: Turner Fleischer Architects Inc. Engineer: HGS Limited Consulting Engineers Contractor: Stonerise Construction Precast Supplier: Stubbe’s Precast

Photos courtesy of Stubbe’s Precast

Point Towers, Phase 5 at The Barrel Yards in Waterloo consists of two 25-storey, 85-metre [279 feet] towers of 357 living units sitting on a two-storey podium with one level of underground parking. Total ground floor area is 41,877 square metres [450,290 square feet]. The Point Tower was originally designed as a cast-in- place concrete structure with precast concrete and window wall cladding, but during the design phase the client requested to change to a total precast building to shorten the construction schedule and reduce financing costs. In comparison to a similar building also under construction on the same property, but cast-in-place, the Barrel Yards precast concrete project started six months later and finished four months earlier, which greatly reduced construction and financing costs. Precast Concrete is Earthquake Resistant Precast concrete structures are designed to the seismic requirements of the National Building Code of Canada.

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RESILIENCE IS THE NEW SUSTAINABILITY

WILLIAM’S COURT

RESILIENCY

Kanata, Ontario

Owner: Groupe Lépine Architect: Alcaide Webster Architects (Buildings C, D and G) Engineer: CIMA+ Contractor: Groupe Lépine Precast Supplier: BPDL

Photos courtesy of BPDL

William’s Court - Groupe Lépine opted for precast concrete construction because of its fast construction, its durability, and for its lower cost made possible by the tightly controlled and relatively short production process. Groupe Lépine selected a white hammered finish and the precaster also used a brick form liner mould that was used to simulate a brick wall, which was then stained at various locations. The illusion is quite dazzling. Even natural stone was used in several locations, with some precast panels having over three different finishes or colours. Precast Concrete is Ecological Made of natural raw materials, locally available almost everywhere and in an enormous quantity, precast concrete minimizes the whole life cycle impact on the environment when compared with other construction materials.

PRECAST CONCRETE BUILDS ON… RESILIENCY 12

Canadian Precast/Prestressed Concrete Institute PO Box 24058, Hazeldean, Ottawa, Ontario Canada K2M 2C3 T: 613 232 2619 | TF: 877 937 2724 | E: info@cpci.ca | www.cpci.ca

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The Winning Projects >>

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>> Thank you to our sponsors and jury! >>

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THE NATIONAL PROGRAM BROUGHT TO YOU BY SUSTAINABLE ARCHITECTURE & BUILDING MAGAZINE

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JURY

Photo: Roy Grogan

Heather Dubbeldam, OAA, FRAIC, LEED AP Principal of Dubbeldam Architecture + Design, Toronto.

Thomas Schweitzer, OAQ, Director of Architecture, Ædifica, Montreal.

Lindsay Oster, MAA, SAA, OAA, MRAIC, LEED AP Principal of Prairie Architects Inc., Winnipeg.

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UBC CAMPUS ENERGY CENTRE Vancouver, BC COMMERCIAL/INDUSTRIAL [SMALL] AWARD Jury comments: This is a beautiful solution for a building type that has traditionally been tucked away from public view. The elegant way in which the building reveals its inner workings makes it not only a striking piece of architecture, but an important didactic tool for the University of British Columbia.

In 2007, The University of British Columbia [UBC] committed to reduce its greenhouse gas emissions by 33% from its baseline, by 2015. The Campus Energy Centre [CEC], certified LEED NC 2009 Gold, is an integral part of this reduction strategy. The CEC, a new high-efficiency hot water heating plant and district hot-water distribution loop, replaces UBC’s steam boiler plant constructed in 1925. It is a major contributor to UBC achieving its emission targets while simultaneously redefining public interaction with district energy infrastructure. The CEC serves over 130 buildings, or 110,000 m2 of campus development delivered through 14 km of underground insulated pipe. The 1,900m2 building houses all process equipment including three 15 MW boilers with capacity for expansion to a total output of 80 MW.

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PROJECT CREDITS OWNER/DEVELOPER University of British Columbia, Project Services ARCHITECT DIALOG STRUCTURAL ENGINEER Fast + Epp MECHANICAL ENGINEER FVB Energy Inc. ELECTRICAL ENGINEER Applied Engineering Services SUSTAINABILITY CONSULTANT Recollective Consulting COMMISSIONING AGENT CES Engineering ENVELOPE CONSULTANT Morrison Hershfield LIFE CYCLE ASSESSMENT Coldstream Consulting CIVIL ENGINEER Kerr Wood Leidal LANDSCAPE ARCHITECT Perry + Associates GENERAL CONTRACTOR LEDCOR PHOTOS Ema Peter / Martin Nielsen

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Hot water boil area Entrance lobby End of trip facilities Maintenance room Shower room Mechanical room Electrical room

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Mezzanine Living lab Control room Lunch room Office Stand by generator Boiler stacks Metal standing seam roof

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Natural ventilation

PROJECT PERFORMANCE Energy intensity [base building]= 123kWh/m2/year Energy intensity reduction relative to reference building under ASHRAE 90.1 [2007] = 63% Potable water consumption from municipal sources = 4391L/occupant/year Reduction in potable water consumption relative to reference building = 30.86 Recycled materials by value = 28.6% Regional materials [as defined by LEED] by value = 52% Construction materials diverted from landfill = 95% THE ZINC CLADDING UNIFIES THE ARCHITECTURAL EXPRESSION [1]. MEZZANINE LEVEL SHOWING EXPOSED GLULAM AND CLT ROOF STRUCTURE [2]. THE BOILERS PROVIDE DISTRICT HEAT TO MORE THAN 130 BUILDINGS ON THE UBC CAMPUS [3]. THE CEC FITS COMFORTABLY INTO ITS CONTEXT OF ACADEMIC BUILDINGS, WITH STREET LEVEL WINDOWS ENHANCING THE PEDESTRIAN EXPERIENCE [4 AND 5]. THE 20M HIGH BOILER BAY FEATURES A CLT AND GLULAM STRUCTURE, A RARITY IN AN INDUSTRIAL BUILDING [6]. THE ZINC ‘SHROUD’ IS RAISED TO GIVE PASSERS-BY VIEWS INTO THE BOILER BAY [7]. STAIRCASE TO OFFICE AREA [8].

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The major sustainable design strategies were to locate the facility in a pre-existing parking lot; establish a comprehensive storm-water management plan that included pervious paving, retention, detention equipment and rain gardens; harness the massing of the facility to drive natural ventilation; utilize as much structural engineered wood as possible to offset embodied carbon; and to design the building as a “living lab” that showcases and communicates the building systems. The CEC, with its elegant zinc cladding and expansive window openings, greatly enhances the experience of the public realm. The main street running along side the CEC now includes a generous sidewalk with planted rain gardens that treat the project’s storm water runoff, and striking views through the glazing of the 17-metre-tall exposed cross laminated timber [CLT] boiler bays. The use of exposed CLT and glulam engineered wood on the interior creates a warm, welcoming atmosphere while still achieving structural and practical requirements. A Life Cycle Analysis [LCA] was carried out using the ATHENA methodology to compare a steel and concrete reference building and the proposed glulam and CLT building. The LCA indicated an 18% global warming potential reduction by using engineered wood. The design of the plant incorporates significant daylight wherever

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possible, including the boiler bays and supporting district energy equipment areas, most often enclosed or in underground facilities. The equipment housed by the CEC emits significant amounts of residual heat into the interior space. Mechanically cooling this would

The CEC‘s encompassing zinc shroud acts as a mediator between

have required large amounts of energy. The design team saw this as

the educational occupancies surrounding it and the large, functional

an opportunity for significant energy reduction by using the large

infrastructure that is housed within. Along Agronomy Road, the

volume of the main plant space to drive natural ventilation using the

shroud descends to 3.7 metres above the sidewalk, becomes trans-

stack effect. The ventilation intake is supplied through louvres and

parent and creates an overhang - providing a human-scaled canopy

automatic dampers at ground level in the southeast elevation.

that invites visitors to the main entrance.

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BROCK COMMONS TALLWOOD HOUSE

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Vancouver, BC RESIDENTIAL

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Jury comments: We were impressed by the waste reduction that resulted from factory prefabrication, the speed of construction, the technical innovation, the holistic approach to sustainability – including carbon sequestration and life cycle issues. This is a building many people can learn from.

Completed in 2017, Brock Commons Tallwood House is an 18-storey, 404-bed student residence located at the University of British Columbia. With a height of 53 metres, Brock Commons is the world’s tallest mass timber tower. The LEED v4 Gold target project aspires to be a model for a future that features extraordinarily ordinary mass wood buildings that are quick, clean and cost effective to construct and that maximize carbon sequestration and the reduction of greenhouse gas emissions. The innovative project demonstrates that a mass wood building can be comparable in cost to a traditional concrete building. To be truly environmentally meaningful, mass wood structures must be incorporated into buildings of all types and sizes, from the audacious to the everyday, whether the wood structure is exposed or not. Using a “keep it simple” design approach, the innovative mass timber structural system proved to be economically viable, repeatable, and adaptable to other building types and uses. The project was delivered on time and on budget, demonstrating that encapsulated mass timber buildings can be constructed quickly and economically, while delivering significant environmental benefits. The wood used at Tallwood House was sourced from sustainably managed forests in British Columbia, where less than one third of one per cent of public forests are harvested annually, with a legal requirement to regenerate all harvested areas. Mass wood construction helps reduce greenhouse gas emissions created by the built environment since wood stores carbon and is less carbon intensive to produce than other building materials. With its 2,233m3 of wood, the building stores 1,753 metric tons of carbon dioxide.

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PROJECT CREDITS OWNER/DEVELOPER University of British Columbia ARCHITECT Acton Ostry Architects Inc. TALL WOOD ADVISOR Architekten Hermann Kaufmann ZT GmbH STRUCTURAL ENGINEER Fast + Epp FIRE SCIENCE & BUILDING CODE GHL Consultants Ltd. BUILDING ENVELOPE RDH Building Science MECHANICAL, ELECTRICAL & SUSTAINABILITY CONSULTANTS Stantec MASS WOOD ERECTION Seagate Structures MASS WOOD SUPPLIER Structurlam CONCRETE FORMWORK Whitewater Concrete Ltd. VIRTUAL MODELLING Cadmakers Inc. ENERGY MODELLING EnerSys Analytics Inc. ACOUSTICS RWDI LANDSCAPE ARCHITECT Hapa Collaborative CIVIL ENGINEER Kamps Engineering Limited GEOTECHNICAL ENGINEER Geopacific Consultants Inc. CONSTRUCTION MANAGER Urban One Builders DEVELOPMENT MANAGER UBC Properties Trust PHOTOGRAPHY Michael Elkan, Pollux Chung [3, 4] Mass timber structure

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The close attention paid to life cycle considerations on this project resulted in an exceptionally low carbon footprint, in both the embodied and operational life cycle stages. When using the ATHENA methodology to perform a 60-year cradleto-grave Life Cycle Analysis, Brock Commons demonstrates N

Typical floor plan

an exceptionally low embodied carbon intensity of 236 kg CO2-eq/m2 Global Warming Potential [GWP]. Compared to a similar, conventional concrete structure, Brock Commons achieved 43% savings on global warming potential, 60% on Ozone Depletion Potential, 47% on Eutrophication Potential and 35% on all other environmental indicators. The mass wood structure and facade were erected by a crew of nine workers in 66 days. There are 29 CLT panels per floor for a total of 464, with 78 glulam columns per floor for a total of 1,302. The use of prefabricated timber and steel construction components ensures flexibility of use and adaptability to other functions over the life of the building, after which demountability, repurposing, and recyclability of the components will be possible. The building has received considerable national and international attention, with over 1,300 people from around the world visiting the project during construction. Interest from government officials, design and construction professionals, forestry industry representatives, academics and students suggest that the impact of the project will be both profound and far-reaching.

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PROJECT PERFORMANCE Energy intensity [base building] = 135kWh/m2/year Energy intensity [process energy] = 5.7kWh/m2/year Energy intensity reduction relative to reference building under ASHRAE 90.1 [2007] = 42% Potable water consumption from municipal sources = 31,508L/occupant/year Reduction in potable water consumption relative to reference building = 52% indoor, 66% outdoor Recycled materials by value = 19% Regional materials [as defined by LEED] by value = 38% Reduction in waste generated compared to traditional construction = 76%

BROCK COMMONS AT DUSK [1]. THE STUDENT LOUNGE ON THE 18TH FLOOR FEATURES AN EXPOSED WOOD STRUCTURE AND SPECTACULAR VIEWS [2]. THE 17-STOREY MASS WOOD STRUCTURE WAS ERECTED IN OLNY 66 DAYS [3 AND 4]. A CLT CANOPY RUNS THE LENGTH OF THE BUILDING [5]. GROUND FLOOR STUDENT WORKSPACE. TACKABLE LINOLEUM WALL COVERINGS USE FORBO TACKBOARD [6].

This project was also published in the Winter 2017/18 issue of SABMag found at www.sabmagazine.com.

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2018

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LANGARA COLLEGE SCIENCE & TECHNOLOGY BUILDING Vancouver, BC

INSTITUTIONAL [LARGE] AWARD

Jury comments: This project is notable for its planning, with a six-storey atrium that functions not only as a light and ventilation well, but also as a social incubator that reinforces the academic program. The quality and quantity of natural light is extraordinary for a laboratory building of this type, and the energy performance is also exemplary. The project also creates a striking new landmark for the college.

1 This 14,600m2 Science & Technology building creates a strik-

As an architectural statement, cantilevering the laboratories and classrooms

ing new gateway into the Langara College campus in south

presents student activity as the face of the College, and makes a bold ges-

Vancouver, while creating a state-of-the-art home for its vari-

ture toward the nearby transit station. It also achieves a pragmatic solution

ous science programs. Science laboratories and classrooms

for a complex and constricted site, allowing a large program to be accom-

are located on the top three levels, which frame the main

modated on a limited footprint, which avoids disrupting the adjacent public

driveway with a bold cantilever. The lower levels consolidate

space, geothermal field and fire route.

essential student services and connect to adjacent lounges, study and meeting spaces.

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Wall construction section 1 2 3 4 5 6 7

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Roof 2-ply modified bitumen roof with high-albedo cap sheet Protection board 2 layers rigid insulation air vapour barrier Exterior gypsum sheathing Exterior corrugated metal wall Horizontal corrugated metal cladding Vertical galvanized hat channels/air space Breather membrane Mineral wool insulation Galvanized metal horizontal Z-girts on thermally insulated faรงade clips Sheathing board with integral air vapour barrier Metal stud framing Diagonal brace Exterior louvre system Supported on steel knife-plates anchored to structur through 13mm HDPE thermal spacers Oculus Structural silicone glazed system Continuous 8mm bent plates welded to HSS 127x76mm / 102x76mm structural cage Exterior sun shading louvre system Anoadized extruded aluminum louvres between vertical extuded aluminum supports @ 1680mm O.C. on 203mm vertical galvanized HSS 203x76 @ 1680mm O.C. Metal soffit Steel stud framing suspended from structure Galvanized hat channels, prefinished black Fire resistant aluminum composite material panel with knocked edges

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Floor plans

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Physics lab Storage Nursing classroom Vortex lounge Faculty offices Light well Debriefing room Community simulation Mini labs

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Existing libray beyond Cafetaria Meeting room Office Admission Records and graduation Continuing studies Admission Lobby Study

FRONTING WEST 49TH AVENUE, THE SCIENCE & TECHNOLOGY BUILDING IS THE NEW ‘GATEWAY’ TO THE LANGARA COLLEGE CAMPUS [1]. THE CANTILEVERED UPPER STOREYS ENABLE THE LARGE PROGRAM TO FIT ONTO A TIGHT SITE [2]. VIEW OF GROUND FLOOR STUDENT LOUNGE [3]. THE CENTRAL LIGHT WELL CONNECTS THE SOCIAL SPACES IN THE BUILDING VERTICALLY, WHILE GLASS PARTITIONS MAXIMIZE HORIZONTAL TRANSPARENCY AND VIEWS [4 AND 5]. THE LABORATORIES ALSO FEATURE HIGH LEVELS OF DAYLIGHT [6].

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PROJECT PERFORMANCE Energy intensity [building and process energy] = 138.7kWh/m2/year Energy intensity reduction relative to reference building under ASHRAE 90.1 [2007] = 63% Potable water consumption from municipal sources = 613.8L/occupant/year Reduction in potable water consumption relative to reference building = 44.3% Recycled materials by value = 14.88% Regional materials [as defined by LEED] by value = 8% Construction materials diverted from landfill = 90.6%

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Level 3

Inside and out, the spatial experience is defined by visual and physical interconnectivity designed to draw students together in a collaborative environment. Certified LEED Gold, the cost-effective design achieves exceptional efficiency through the integration of a high-performance envelope, thoughtfully deployed passive lighting and ventilation measures, and innovative locally developed energy management technology. The façade includes a custom louvre system on the upper floors, designed based on a sun path analysis, choreographing views to the campus and distant mountains, while maximizing useful natural light. On the lower floors a translucent polycarbonate wall-panel system provides diffuse lighting to balance glare mitigation and thermal performance. A six-storey lightwell brings light deep into the floorplate [and also facilitates natural stack effect

PROJECT CREDITS OWNER/DEVELOPER Langara College ARCHITECTS Teeple Architects Inc. ASSOCIATE ARCHITECT Proscenium Architecture + Interiors STRUCTURAL ENGINEER Weiler Smith Bower Consulting Structural Engineers MECHANICAL ENGINEER AME Group Consulting Professional Engineers THERMAL ENERGY SPECIALTY TC Thermenex Inc. ELEVATOR CONSULTANT Gunn Consultant Inc. ELECTRICAL ENGINEER Applied Engineering Solutions Ltd. SUSTAINABILITY CONSULTANT Zon Engineering COMMISSIONING AGENT MMM Group Limited CODE CONSULTANT LMDG Code Consultants Ltd. ENVELOPE CONSULTANT Read Jones Christoffersen Ltd. GEOTECHNICAL ENGINEER Geo Pacific Consultants Ltd. CIVIL ENGINEER Aplin Martin Consulting Ltd. LANDSCAPE ARCHITECT PFS Studio TRANSPORTATION CONSULTANT Bunt & Associates Ltd. GENERAL CONTRACTOR Bird Construction PHOTOS Andrew Latreille

ventilation]. Photocell sensors are installed in occupied perimeter spaces to reduce lighting when sufficient daylight is present.

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SABMag - SUMMER 2018

Exterior sunshades and cladding supplied by Engineered Assemblies.

Energy recovery and transfer

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Existing libray beyond Light well Kinesiology lab Biology lab Nursing classroom Classroom

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Biology storage Bathroom Chemistry lab Biology classroom Physics lab Office

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Workshop Administration Reception Continuing studies Lower lobby Lecture hall

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Sunlight Natural air path

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All circulation paths through the building, including the main atrium,

beyond traditional energy and carbon savings by ensuring no

multi-storey “Vortex Lounge” and fire stairs are highly visible. Animated by

fossil fuels are used for heating at the same time the building

views to other levels and teaching spaces, they integrate a variety of study

is rejecting heat with exhaust, relief air or the cooling tower.

and lounge spaces, naturally promoting interaction and encouraging

The building itself is the main source of heat. The application

movement through the building via stairs rather than elevators. The atrium

of “Thermenex in a Box” [TIAB] combined all the major com-

ties directly into the circulation spine of the adjacent library building,

ponents of the energy transfer in a single unit, manufactured

enhancing the college’s intuitively navigable indoor circulation network.

off-site and craned into place in two days. The project received

Heating loads were reduced by the building’s high-performance envelope,

18/19 energy points and is near net-zero carbon.

including a thermally-broken rainscreen system, while lighting loads were

With its bold architecture, creative planning and exemplary

reduced via extensive daylighting, mediated by insulated translucent

energy performance, the project helps to transform a parking-

assemblies and custom louvres.

focused commuter campus into an inspiring, vibrant and sus-

The mechanical system employs the locally developed innovative

tainable indoor-outdoor learning environment.

Thermenex energy management system. The Thermenex System goes

SABMag - SUMMER 2018

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2018

AWARDS

ING

C A NA D I

GRE E N B

LD UI

N A

HARVEY WOODS LOFTS Woodstock, ON

The project converted the vacant Harvey Woods Knitting Mill, a 1918 three-storey solid brick factory in downtown Woodstock ON, into 54 one-bedroom affordable

apartments.

The

existing

industrial structure and tight construction budget of $120,000/unit placed significant constraints on the design, which were resolved by creating long and narrow unit types. As a result, the centre of the building was carved out to create a three-storey covered atrium to bring natural daylight into the residential corridors.

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EXISTING BUILDING UPGRADE AWARD Jury comments: The retention and rehabilitation of existing buildings, particularly in the centre of small cities such as this, addresses sustainability issues of embodied energy as well as social and cultural continuity. We were impressed by how an atrium was created within the existing building as a community space, and by the improvements in energy performance – particularly in the context of a large social housing project.

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Building section Many of the original building features remain visible, including hardwood maple floors, wood columns, and steel beams. The historic brick facades were kept as-is, opting for interior insulation and large, high-performance INLINE Fiberglass windows that complete the daylighting strategy. Archival photos of women working in the factory were incorporated into the new curtain wall entrance, tying the renovation to the building’s storied past. The building’s energy efficiency strategy is completed with the addition of a geothermal well system and water-to-water heat pump for heating and cooling. Overall, the building’s energy intensity of 76 kWh/m2/year is a significant achievement in the conversion of this historic factory. The most important achievement, though, is creating 54 affordable apartments for the most vulnerable in this rural community. Given the pre-existing conditions of the building and its placement on the site, the key strategic decisions revolved around how to improve the access, circulation, and daylighting of the building. Working to preserve as much as possible of the original structure and to create the maximum number of units within the limited budget, the design team arrived at a perimeter layout, organized around a central atrium. Five different unit layouts [some deeper and narrower, some shorter and wider, accessible units] are grouped together to optimize circulation and maximize access to daylight and views.

FRONT ELEVATION: THE ENVELOPE WAS UPGRADED WITH NEW HIGH-PERFORMANCE INLINE FIBERGLASS WINDOWS, THE EXISTING MASONRY WAS RETAINED, WITH INTERIOR INSULATION ADDED TO IMPROVE THERMAL PERFORMANCE [1]. SITE DESIGN STRATEGIES INCLUDED MINIMIZING PARKING, INCREASING PERMEABLE LANDSCAPED AREAS AND RETAINING THE HISTORIC FACTORY CHIMNEY [2]. THE DESIGN APPROACH EMPHASIZED MAXIMUM RETENTION OF THE EXISTING BUILDING, CONSERVING THE EMBODIED ENERGY IN THE MASONRY AND THE SEQUESTERED CARBON IN THE WOOD FLOORS [3 AND 4].

SABMag - SUMMER 2018

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Where others saw a decaying property vacant for over 20 years, the non-profit developer saw the derelict factory as an opportunity: it was a well-known landmark in the downtown core, with transportation and other amenities nearby, and well suited to fulfill the affordable housing need for low-income residents.

The historic chimney

[only one of three left in the Woodstock area] was fully restored as a demonstration of community resilience. The project opted for an envelope-first approach towards energy conservation, retrofitting the existing masonry walls with interior spray foam insulation, and large, highperformance INLINE Fiberglass operable windows. These are fitted with double-pane argon-filled Insulated Glass Units [U- value of glass 0.25] and a Solar Heat Gain Coefficient of 0.34 for the south and west elevations, in order to reduce unwanted solar gains during the cooling season. The closed loop geothermal system [three intake wells + three recharge wells] and water-to-water heat pump cover 100% of the heating and cooling load for the building, excluding ventilation. Thanks to the adaptive reuse strategies, both the historic value and embodied energy of the Harvey Woods Lofts will be conserved, and the building will continue to serve its community for another 50 years or more.

5

PROJECT CREDITS OWNER/DEVELOPER Indwell Community Homes ARCHITECT Invizij Architects Inc. STRUCTURAL ENGINEER Schorn Consultants MECHANICAL/ ELECTRICAL ENGINEER R. Mancini and Associates CIVIL ENGINEER SPH Engineering GENERAL CONTRACTOR Sierra Construction Group Photos George Qua-Enoo PROJECT PERFORMANCE Energy intensity [building and process energy] = 75kWh/m2/year Energy intensity reduction relative to reference building under ASHRAE 90.1 [2007] = 37% Potable water consumption from municipal sources = 67,870L/occupant/year

THE DESIGN APPROACH EMPHASIZED MAXIMUM RETENTION OF THE EXISTING BUILDING, CONSERVING THE EMBODIED ENERGY IN THE MASONRY AND THE SEQUESTERED CARBON IN THE WOOD FLOORS [3 AND 4]. AN ATRIUM WAS INSERTED INTO THE CENTRE OF THE BUILDING BRINGING DAYLIGHT INTO THE COMMON AREAS [5].

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SABMag - SUMMER 2018

Keeping Good Roofs Good To Reduce Costs And Improve Facility Performance TTremco emc understands nde st nd d th thatt h having vi g a good g o roof o f starts t r with h kknowing o g tthat a

www.elkay.com

roof’ o ff’s ccondition. ndii io Th TThat’ a ’s w why hy our u solutions l i n are based a ed on o thorough ou h diagnostic da n i

C A NA D I

2018

evaluations. e a o s From F vegetative e e t e roofs oof and a d

B

AWARDS

ING

Environmental Science and Chemistry Building, U of T Scarborough, in the 2018 Canadian Green Building Awards.

N A

LD UI

Supplier of our ezH2O bottle filling stations to the winning project,

GRE E N

unique u q white wh e adhesive-based d i e a e built-up u t and d modified m d i d bitumen b u e roofs o fs to o a wide wd range a g off other t e energy-efficient energy e eg e efficient f e t roofi o fi fing ng g systems, y t ms , TTremco e o h hass the h solutions o u on architects hite h e t and nd building buildi d g ow owners e need eeed d to o lower w r the h costs o so of rrunning n i g new n wo or

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2018

AWARDS

ING

C A NA D I

GRE E N B

LD UI

N A

ENVIRONMENTAL SCIENCE AND CHEMISTRY BUILDING Scarborough, ON INSTITUTIONAL

[LARGE]

AWARD

Jury comments: This building has a particularly innovative approach to solar shading, creating a dynamic faรงade and animating interior spaces. This approach carries through to the other environmental systems which are exposed to view, not simply to celebrate the technology, but to monitor performance, facilitate research and identify potential improvements.

As befits a new building for the study of environmental sciences and chemistry, this facility, located on the Scarborough campus of the University of Toronto, is strongly rooted in sustainable design solutions. The facility features collaborative learning opportunities while providing flexible lab space that ensures adaptability for the ever-changing nature of research and teaching methods. The 10,000m2 building connects laboratories and academic offices around a sky-lit atrium designed to encourage collaboration and exchange. Thematically, the Environmental Sciences and Chemistry Building is inspired by nature to reflect not only the academic pursuits of these disciplines but also its setting on the edge of a wooded ravine. The building incorporates many unique and progressive systems that combine to achieve a significant reduction in energy consumption in a process-energy-driven facility. These include geo-thermal boreholes beneath the building and earth tubes. These systems are complemented by a high-performance building envelope including innovative solar shading. The project also features storm water capture and recycling, and a solar renewable-ready Tremco green roof. During design and construction, material selection and performance was approached as a collaborative effort to balance functionality and performance with sustainability. The design of the building envelope involved the architectural team, energy modeller, building science professional, material and system manufacturers and suppliers, as well as construction personnel in order to achieve the durability, thermal, and aesthetic performance targets for the project. This collaborative process resulted in a cladding system and innovative vertical solar shades that minimize thermal bridging through the vertical shading fins, allow for maintenance and replacement both for the fins and curtainwall, and ensure air and water tightness throughout.

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Ground floor plan N 1 Board room 2 Local program masters student group office 3 Catalyst centre 4 Multi-purpose room 5 Police office 6 Police support 7 Fumehood intensive 8 Teaching lab 9 Chem UG teaching lab support 10 Flammable + chemical storage

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Electrical closet Security closet Instrument room Tech office Material lift Tech office Earth tube glass floor display and green building kiosk Liquid nitrogen tank and enclosure

[1] THE SOUTH-WEST FACADE WITH EARTH TUBES. THE HIGH-PERFORMANCE BUILDING ENVELOPE INCLUDES VERTICAL SOLAR SHADES. [2 AND 3] A SKY-LIT FORUM AND CROSSROADS BETWEEN OFFICES AND LABS ENCOURAGE COLLABORATION.

3 PROJECT CREDITS OWNER/DEVELOPER University of Toronto Scarborough ARCHITECT Diamond Schmitt Architects STRUCTURAL ENGINEER RJC Engineers MECHANICAL/ELECTRICAL ENGINEER Smith + Anderson CIVIL ENGINEER WSP [formerly MMM] COMMISSIONING AGENT JLL [formerly HFM] ENERGY/ENVIRONMENTAL CONSULTANT Footprint LEED CONSULTANT/GENERAL CONTRACTOR EllisDon ACOUSTICS CONSULTANT HGC Engineering LANDSCAPE ARCHITECT Janet Rosenberg & Studio PHOTOS Tom Arban, Michael Muraz, Nithursan Elamuhilan

SABMag - SUMMER 2018

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Third floor plan N 1 Faculty office 2 Post doc/RA office 3 Grad office 4 Faculty/staff/lounge 5 Visitor office 6 Dry research support 7 TA/sessional meeting room 8 Dry research support 9 Primary dry research lab 10 Glasswash & sterilization

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Wet support lab Dry equipment room IT closet Electrical closet Librarian office Storage/freezers Janitor closet Wet chemistry lab Security closet

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East-west section 1 Atrium 2 Elevator shaft 3 Chem UG teaching lab support 4 Material lift 5 Teaching lab 6 Catalyst Centre 7 Primary dry research lab 8 Office 9 Fumehood intensive research lab 10 Flume lab THE VEGETATED ROOF USES A SYSTEM SUPPLIED BY TREMCO. WATER-CONSERVING PRODUCTS BY SLOAN, AND DRINKING WATER STATIONS BY ELKAY.

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SABMag - SUMMER 2018

The five-storey building connects laboratories and academic offices around a sky-lit forum and crossroads designed to encourage collaboration by providing gathering spaces in wide corridors, meeting rooms and white boards throughout. The building also embodies new thinking in laboratory design – open, transparent, flexible and adaptable, while providing a safe and secure work environment for students and researchers. As an active research and teaching laboratory, with nearly 120 fume hoods distributed in various labs throughout the laboratory wing, ventilation and make-up air posed a significant challenge to the design team. To improve energy efficiency, a series of earth tubes were designed to help temper incoming fresh air drawn from the adjacent courtyard before introducing it into the building.

Earth tubes and bore holes

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PROJECT PERFORMANCE ENERGY INTENSITY [BASE BUILDING] = 495KWh/m2/year ENERGY INTENSITY [PROCESS ENERGY] = 166KW/m2/YEAR

To optimize the efficiency of this system, a computational fluid dynamic [CFD] analysis was performed on the proposed design, and identified opportunities for improvement, specifically adding baffles and modify-

ENERGY INTENSITY REDUCTION RELATIVE TO REFERENCE BUILDING UNDER MNECB = 48%

ing their spacing throughout the tubes to reduce stratification, control

POTABLE WATER CONSUMPTION FROM MUNICIPAL SOURCES = 4,428L/occupant/year

static pressure, and achieve a uniform distribution across all six tubes.

REDUCTION IN POTABLE WATER CONSUMPTION RELATIVE TO REFERENCE BUILDING = 35% RECYCLED MATERIALS BY VALUE = 20%

As part of an integrated learning component, one of the earth tubes is translucent below the entrance vestibule, where an information kiosk explains the technology. A glass screen and floor opening permit stu-

REGIONAL MATERIALS [AS DEFINED BY LEED] BY VALUE = 32%

dents to see the earth tube in action; wind deflectors and coloured

CONSTRUCTION WASTE DIVERTED FROM LANDFILL = 67%

LEDs are integrated to illustrate the air movement within the tube and emphasize the heating and cooling these tubes extract from the latent energy of the soil.

[4] THE CENTRAL ATRIUM. [5] THE EARTH TUBES TEMPER INCOMING FRESH AIR TO IMPROVE ENERGY EFFICIENCY. [6] THE SOUTH-EAST FACADE.

SABMag - SUMMER 2018

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Heating and Cooling www.mitsubishielectric.ca Congratulations to Landform Architecture + Design Build For the 2018 Canadian Green Building Award for the Okanagan College Child Care Centre. We were proud to supply the energy efficient Mitsubishi Electric City Multi heat pump system for the project. This system provides room by room comfort control for both heating and cooling at the Centre.

Stay up-to-date about high-performance building, the Canadian Green Building Awards, and more. Sign up at dgriffith@sabmagazine.com

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AirOutshield WALL economical protection for walls. [CCMC listed]. AirOutshield ROOF for sloped roofs. Ideal for sloped, insulated roofs. SRP Tapes and Accessories The Ecology Action Centre Headquarters, a winning project of the 2018 Canadian Green Building Awards. [Photo: Acorn Art and Photography].

CONTACT US: 1.866.533.0233 info@srpcanada.ca www.srpcanada.ca 32

SABMag - SUMMER 2018

2018

AWARDS

ING

C A NA D I

GRE E N B

LD UI

N A

OKANAGAN COLLEGE CHILD CARE CENTRE Penticton, BC

INSTITUTIONAL

[SMALL] AWARD Jury comments: As a structure designed to the rigorous Passive House standard, this building is notable for the beauty and simplicity of its environmental systems. The building relies mostly on local materials and very economical passive design strategies, yet also addresses cross-cultural issues and creates a symbolic new gateway to the college campus.

The Okanagan College campus straddles the boundary between the City of Penticton and the Penticton Indian Reserve. The college and the En’owkin Centre, the cultural centre of the Syilx nation, are located directly across the river from one another. To acknowledge the cross-cultural nature of the community it serves, the Child Care Centre has bilingual signage, and each of the four Child Care spaces has been given the name and colour palette of one of the four traditional food staples [or ‘chiefs’] of the Okanagan people. EXTERIOR VIEW OF THE LANTERN [1].

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The site for the project is a previously developed area at the

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meadow area. Each of the four child care spaces within the

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building has its own contained outdoor play area, which is surrounded by tall native grasses.

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The physical form of the building was developed to maximize natural ventilation. South-facing windows have low operable air

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intake vents, and a double-height lantern at the centre of the building, with automatic opening clerestory windows to exhaust stale air. The lantern opens north to shield from summer heat

Site plan N 1 Entry 2 Foyer 3 Office 4 Janitor

gain, but also to capitalize on a venturi effect from prevailing

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Mechanical room Multi-purpose room Storage Nap

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Washroom Preschool, aftershool Observation room Three to five years old Infants

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winds. During the heating season, air is provided through a super-efficient heat recovery ventilator. A desire to connect indoor and outdoor spaces was at the core of the design model for the Child Care Centre. Each of the four Child Care rooms has a contained outdoor space equal to twice the area of the indoor space. The design of the rooms focuses on large windows and doors which provide constant visual and physical connection to the outdoor rooms. SABMag - SUMMER 2018

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PROJECT CREDITS OWNER/DEVELOPER Okanagan College ARCHITECT Landform Architecture STRUCTURAL ENGINEER Aspect Engineers MECHANICAL ENGINEER Butler Engineering ELECTRICAL ENGINEER Associated Engineering BUILDING ENVELOPE AND ENERGY CONSULTANTS BC Building Science PASSIVE HOUSE CONSULTANT Chris Snyder GENERAL CONTRACTOR Ritchie Custom Homes GEOTECHNICAL CONSULTANT Paul Glen PHOTOS Jon Adrian

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PROJECT PERFORMANCE The passive house requirement for space heating/cooling is 15 kWh/[m2a]. The PHPP model for the project shows 5.7. The requirement for Primary Energy Demand is 60 kWh/[m2a]. The PHPP model for the project shows 44.0. Energy intensity reduction relative to reference building = 46 %

Vapour retarding membrane + air barrier Intello Plus lapped and sealed with Tescon Vana

Double stud wall all joints in plywood taped insulation not shown for clarity

Concrete slab 150mm

Weather resistant barrier Solitex Mento 1000 lapped and taped w/ Tescon Vana

EPDM airsealing gasket Roflex Gasket around plumbing penetrations taped with Tescon Vana

Detail at slab to wall

Self adhered membrane Extoseal Encors Exterior plywood taped joints holes for vapor permeability Thermal barrier EPS Insulation 4 layers x 75mm

Air sealing tape Tescon Vana

Adhesive caulk Air barrier 10 mil polyethylene taped and sealed with Tescon Vana

Protective metal barrier Galvalume Flashing

Structural insulating formwork Insulspan EPS Foundation System

The outdoor spaces contain a mix of hard surface spaces

gy of super-insulation, airtight construction, and efficient mechanical systems

for wheeled toys, storytelling and wet weather play, rubber

to reduce energy consumption to less than 44 kWh/m2 annually. In addition,

mulched areas for active play, and natural areas including

the roof of the building has been oriented to the south and angled for opti-

berms, plantings, logs and water sources to allow unstruc-

mal photovoltaic performance. The material strategy for the building was a

tured learning. Large shade trees protect the play areas

regional one, selecting materials that were locally produced and materials

from the Okanagan sun. With the operable windows, acces-

appropriate to the Okanagan climate. This focus on local materials not only

sible transitions, and large doors, there is no clear distinc-

reduces transportation emissions, it fosters the development of a sustainable

tion between outdoor and indoor – rather, the entire child

regional economy. As the first Passive House Certified commercial building in

care space is a healthy, clean, safe island in the meadow. As

Canada, regular tours are being given to utility companies, elected officials,

a certified Passive House project, the building uses a strate-

and green building professionals.

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Heat pump Solar array Warm fresh air in/out Cool fresh air in/out Natural ventilation through space Super insulated building envelope Triple-glazed window

THE ENTRY CANOPY AND EXTERIOR WALLS WITH COMPOSITE CLADDING [2]. CONNECTION BETWEEN INDOOR AND OUTDOOR PLAY AREAS [3]. LARGE WINDOWS PROVIDE NATURAL LIGHT AND A VISUAL CONNECTION TO THE EXTERIOR [4]. THE LANTERN-LIT HALLWAY [5]. THE PROJECT USES A MITSUBISHI ELECTRIC CITY MULTI HEAT PUMP SYSTEM FOR ROOM BY ROOM HEATING AND COOLING.

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2018

AWARDS

ING

C A NA D I

GRE E N B

LD UI

N A

ECOLOGY ACTION CENTRE HEADQUARTERS Halifax, NS COMMERCIAL/INDUSTRIAL

In April 2016 the Ecology Action Centre [EAC] employees, 4,500 members, countless volunteers, and the public at large. Designed and constructed through a three-year community engagement process, this 480m2 building is a showcase for environmentally-sensitive renovation and densification in a tight urban setting. Located in Halifax’s North End, the project embodies the EAC’s values and goals, including exemplary energy performance and the creative use of salvaged and natural materials. Most importantly it is a welcoming and inspiring space for community and staff to connect, learn, and work together. The project demonstrates a commitment to increasing public and industry buy-in for sustainable redevelopment. Through the educational efforts of the owners and extensive community involvement, the project shows what can be achieved, even on a tight budget. The result is a fully renovated three-storey, century-old building that uses 50% less energy than the original two-storey structure, even though the floor area was increased by 50%. The EAC wanted to reinforce its connection with the community and, by lowering the western half of the main floor to sidewalk level, created a new accessible, 4-metre high community gallery and meeting space. Large windows reveal the activities within, and give the EAC an inviting street presence. From start to finish, the project was a true community effort. In addition to the hours dedicated to community consultation, there were over 1,400 hours of volunteer labour on the construction site – providing those involved with invaluable hands-on experience of sustainable building practice.

[1 AND 2] THE RENOVATED THREE-STOREY, CENTURYOLD BUILDING USES 50% LESS ENERGY THAN THE ORIGINAL TWO-STOREY STRUCTURE, EVEN THOUGH THE FLOOR AREA WAS INCREASED BY 50%. [3] CLADDING DETAILS.

1 SABMag - SUMMER 2018

AWARD

Jury comments: The fact the community was actively engaged in this project speaks to the often-overlooked issue of social and cultural sustainability. As such, it provides a reminder that successful community architecture is as much about process as it is about the final product. The energy performance and the creative use of salvaged materials were particularly impressive.

opened its revamped headquarters to its 40+

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[SMALL]

PROJECT PERFORMANCE Energy intensity [building and process energy] = 31.7kWh/m2/year 1

2

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Energy intensity reduction relative to reference building under MNECB 2011 = 63%

5

Potable water consumption from municipal sources = 3,150 L/occupant/year Reduction in potable water consumption relative to reference building = 33% 8 6

PROJECT CREDITS OWNER/DEVELOPER Ecology Action Centre

7

ARCHITECT Solterre Design CIVIL/STRUCTURAL ENGINEER Sherwood Enterprise

First floor

MECHANICAL ENGINEER Equilibrium Engineering GENERAL CONTRACTOR Tekton Design Build PHOTOS [1, 2, 3, 6] courtesy of Acorn Art Photography, [4] courtesy of EAC, 2

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Floor plans N 1 Kitchen 2 Bathroom 3 Accessible/flex 4 Administration 5 Copy room 6 Boardroom 7 Reception

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Volunteer Coastal/bec Meeting room Energy Breakout Directors Marine/food

Existing wall Demo wall 15 16 17 18 19

Transportation Phone Wilderness Membership/flex Finance

NEW AIROUTSHIELD AIRTIGHT EXTERIOR WEATHER BARRIER SUPPLIED BY SRP CANADA. WINDOWS AND DOORS, SUPPLIED BY KOHLTECH WINDOWS & ENTRANCE SYSTEMS, CONSIST OF SUPREME SINGLE HUNG AND SUPREME AWNING WINDOWS WITH ENERGY-EFFICIENT ENERGLAS GLASS, THREE DOORS WITH A HALF LITE KIT CONTAINING ENERGLAS, AND ANOTHER WITH A FULL LITE KIT CONTAINING ENERGLAS. KOHLTECH ALSO DELIVERED INSULATION SALVAGED FROM 400 DOOR CUT OUTS FROM OTHER PROJECTS TO HELP INSULATE THE BASEMENT FLOOR DURING RENOVATIONS, SAVING THOUSANDS OF DOLLARS IN RENOVATION COSTS. RESILIENT FLOORING IS FORBO MARMOLEUM.

Third floor

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Responsible urban densification was a key focus of the project. Building up increased the floor area without increasing the footprint or impacting existing green space. The renovation took advantage of the building’s orientation and elongated form to maximize daylight, views and natural ventilation strategies. Interior finishes are clay or milk paints and earth clay plasters. These finishes are VOC-free and help regulate occupant comfort through humidity control. The building was wrapped in a new airtight weather barrier and an exterior insulation package that improved the walls to R-32. A minimum of 600mm of cellulose insulation was added to the roof [R-75]. Insulated steel door cut-outs were diverted from the waste stream and the polyurethane foam component was used as sub-slab insulation [R- 16]. The project team salvaged an interesting array of materials including floorboards from the existing building which became a feature wall in the community gallery, beautiful oak doors from a recently demolished building, and high-density fibre cement panel off-cuts from another project. Existing walls, floors and roof saved 40 tonnes of wood, 3 tonnes of metal, 20 tonnes of "mixed waste", and 7 tonnes of drywall/plaster that might otherwise have gone to the landfill. The foundation reuse saved approximately, 90 tonnes of concrete. Together, this amounts to 527,208 MJ of embodied energy saved, equivalent to 9-1/2 years of operating energy. [4] THE BUILDING WAS WRAPPED IN A NEW AIRTIGHT WEATHER BARRIER SUPPLIED BY SRP CANADA AND EXTERIOR INSULATION. [5] INTERIOR FINISHES OF CLAY OR MILK PAINTS AND EARTH CLAY PLASTERS HELP REGULATE OCCUPANT COMFORT THROUGH HUMIDITY CONTROL. [6] SALVAGED FLOOR BOARDS USED IN THE BOARDROOM.

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The Centre de Découverte is located in the Parc National des Îles-de-Boucherville, a group of five islands in the St. Lawrence River, a few kilometres from Montreal. The building is both the main visitor centre for the park and a showcase for the SÉPAQ [National Parks of Quebec] network. Built entirely in wood, the Discovery Centre exemplifies an integrated approach to architecture that combines high performance, bright and inspiring interior spaces, and a respect for context.

CENTRE DE DÉCOUVERTE Boucherville, QC INSTITUTIONAL

[SMALL]

AWARD

Jury comments: This building was notable for its strong focus on sustainable strategies, implemented in a most elegant and beautifully detailed way. The use of natural ventilation and daylighting was particularly innovative. We also appreciated the multiple ways in which local wood was used.”

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Floor plan N 1 Main entrance 2 Information / Reception 3 Discovery area 4 Bistro 5 Shop & Troubleshooter 6 Sanitary 7 Employees' area 8 Office

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Storage Mechanical / electrical room Information / Rental Water sports storage Bike storage Camping equipment storage Promenade Terrace

Light Texture Assembled wood pieces Grey cedar

Water

Canopy

Natural cedar Mineral

PROJECT PERFORMANCE Energy intensity [building and process energy] = 142.7kWh/m2/year

White cedar

Energy intensity reduction [relative to reference building under MNECB] = 40% PROJECT CREDITS

Rock crib

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Transparency

OWNER/DEVELOPER SÉPAQ Reflection

ARCHITECT Smith Vigeant Architectes MECHANICAL/ELECTRICAL ENGINEER Bouthillette Parizeau CIVIL ENGINEER Groupe WSP LANDSCAPE ARCHITECT Groupe BC2 SPACE PROGRAMMING AND EXHIBITIONS Groupe GID Design

To improve access to the site and connection to the water, the program was divided into two volumes: one housing the interpretive centre, the other housing outdoor equipment rentals.

GENERAL CONTRACTOR Construction R. Bélanger

These two buildings define a public space that acts as a gather-

PHOTOS Adrien Williams

ing area and gateway to the park; conveying a sense of arrival and anticipation. Designed to introduce its many visitors to the natural world, the project both respects and reflects its environment. It was developed through an integrated design process, involving the client

[1] THE LOCATION AND FORM OF THE BUILDINGS WERE BASED ON SUN PATH ANALYSIS, WIND PATTERNS AND OTHER ECOLOGICAL CRITERIA. [2] A TRIPLEGLAZED CURTAIN WALL BRINGS IN NATURAL LIGHT, WHILE LOW-LEVEL VENTS ADMIT FRESH AIR THAT DRIVES THE NATURAL DISPLACEMENT VENTILATION SYSTEM, EXHAUSTING STALE AIR THROUGH VENTS AT THE TOP OF THE CENTRAL LIGHT WELL. [3] THE TWO BUILDINGS CONVEY A SENSE OF ARRIVAL TO THE PARK. WATER-FREE URINALS SUPPLIED BY SLOAN.

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and professionals from a wide spectrum of design disciplines. The building embodies the principles of bioclimatic design, with each gesture contributing to the aesthetics of the pavilion as well as to the overall sustainability of the project. Modelling of ventilation, daylight and energy systems was used to optimize building design and performance.

Bio-climatic section 1 Control of solar gain 2 Natural light 3 Durable materials structure and wood FSC 4 Natural ventilation / chimney effect 5 Energy: - Reduction in energy cost: 40% - Saving of energy: 175 GJ/year - Reduction of CO2: 3,737 kg - Use Led light only - Triple glazed windows 6 White roof membrane 7 Thermal comfort area 8 Radiant floor heating

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The location and form of the building were selected based on sun path analysis, wind patterns and a variety of ecological criteria. Environmental impact studies were carried out to ensure that the integrity of local ecosystems was preserved or enhanced. This included lighting design to minimize the impact on nocturnal and migratory animal and bird species, the collection and redistribution of rainwater to maintain hydrological cycles and plant health, and the careful shaping of the curvilinear building plan to preserve trees. This ecological agenda carries through to the specification of materials and finishes. The structure uses FSC [Forest Stewardship Council] certified wood; the cladding is locally-sourced eastern cedar and interior finishes have low or no VOC emissions.

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In addition to the sequestration of carbon, wood is low in embodied energy: construction of a wood stud wall results in 1.6x less greenhouse gas emissions than a steel wall, and 4.0x less than a concrete wall – contributing to superior life cycle performance. The interior of the Discovery Centre is bathed in natural light thanks to large expanses of triple-glazed curtain wall facing the park. Low level vents admit fresh air that drives the natural displacement ventilation system, exhausting stale air through vents at the top of the central light well. Wood louvres and overhangs protect the glazing from unwanted solar heat gain. The combination of a high-performance building envelope, careful implementation of bioclimatic design principles and efficient mechanical and electrical systems result in a building that uses 40% less energy than the reference building, with 100% of this energy supplied from hydroelectricity – a renewable source with a low environmental impact.

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www.sloan.com

Beyond Sustainability

Distributed by

Sustainability is the new baseline. We can help you incorporate it into project budgets, deadlines, building-specific requirements and develop programs to take it beyond opening.

CANADIAN DIRECTORY OF PRODUCTS AND SERVICES FOR SUSTAINABLE, HIGHPERFORMANCE BUILDING http://sabmagazine.com/directoryv4.html

www.greenreason.ca T 416-656-6606

SABMag's 2018 Directory is organized by Product Category and by LEED v4 Category, and is a quick reference for finding products and services for sustainable, high-performance building.

We are passionate about bringing our client’s vision to reality through creative and environmentally responsive design solutions.

University of Toronto Scarborough | Environmental Science and Chemistry Building | LEED® Gold

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and the Environmental Science and Chemistry Building, U of T Scarborough.

Let Green Reason show you how. . Sustainability Consulting . Project Management . Occupant Engagement . Commissioning

RJC Engineers

2018

AWARDS

... to three winning projects of the 2018 Canadian Green Building Awards: One York Tower, the Discovery Centre,

A truly sustainable building is more than meeting certification requirements.

Langara College Science & Technology Building | LEED® Registered

GRE E N B

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¢ Solis solar-powered flushometer ¢ Solis Optima Systems, EAF-275 ¢ Waterless urinals

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Supplier of water-conserving products:

Clareview Community Recreation Centre | LEED® Silver

rjc.ca

Contact dgriffith@sabmagazine.com to get your company listed. And, book your listing in the 2019 Directory for $595 to receive: ´ your 1/8-page listing [product photo and description] in the SABMag Winter 2018/19 print issue ´ same listing in the digital issue, and linked to your website ´ your listing in the web version of the Directory for 12 months, and linked to your website ´ your listing at the top of the SABMag Home Page and Facebook Page for one month ´ your listing linked to your website from a SABMag monthly e-News, and ´ your company named and linked from a fullpage ad in the print and digital issues of SABMag and the CaGBC FOCUS publications – 10 in total for 12 months

Reserve your listing now:

dgriffith@sabmagazine.com

2018

AWARDS

ONE YORK STREET

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COMMERCIAL/INDUSTRIAL AWARD

Toronto, ON [LARGE]

Jury comments: We were impressed that this tower incorporated so many innovative sustainable features, whether or not they would achieve credits on a check list. Things like individualized climate controls for office workers, and a public park rather than simply amenity space for building occupants, were notable examples of this approach.

The office building at One York Street is part of a 200,000m2 mixed-use development along the Central Waterfront in the new South Core of Toronto. One York is Toronto’s highest-scoring LEED Core+Shell certified office project to date – achieving Platinum certification at 89 points. Situated between Union Station and Lake Ontario, it occupies two-thirds of an entire city block at the foot of York Street between Lakeshore Boulevard and Harbour Street. The 35-storey office tower is one of three towers [two are residential] rising from a three-storey retail podium. The fourth floor of the podium provides public roof garden access, a shared food court and a significant health/fitness centre. Together, all connected components create a unique metropolis-like complex inspired by the Waldorf Astoria in NYC. Alan Murphy, project lead with sustainability consultant Green Reason writes: “With so much of the design focused on energy and water efficiency, it is critical to ensure that the building operates as designed and that occupants understand the design and remain engaged in ensuring that the operation balances with their needs.

As both owner and building manager,

Menkes understands the importance of continuous tracking, optimization and engagement with their own team and their tenants. Tenant engagement helps property managers build a better relationship with tenants in order to create positive behaviour change in the building environment. At One York a Green Team has been created, comprised of property management and tenant representatives. Having a Green Team is one of the most effective ways of delivering a tenant engagement program and provides a platform for effective communication and collaboration to accomplish One York’s sustainability goals. Green Reason’s role is facilitating Green Team meetings and related events.

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We are also tracking energy and water consumption information for One York in order to review actual energy and water use against design predictions. This not only allows the team to identify and address any issues with system operation but also supports the reporting requirement under the Province of Ontario’s Energy and Water

East-west building section 1 Lobby 2 Podium terrace shared amenity 3 Path connection 4 Residence lobby

Reporting Benchmarking regulation. This regulation is designed to help owners improve the energy and water efficiency of their building. Improving energy efficiency

Penthouse

is key to achieving the City’s greenhouse gas emissions reduction target of 80 per cent by 2050.” Beyond quantitative building performance, One York also focuses on human wellbeing. This meant maximizing access to fresh air, natural light, allowing personal control

Office tower

of one’s microclimate, and encouraging active transportation modes, all the while minimizing capital and operational costs, adverse environmental impacts and unnecessary resource consumption. One York is an elegant demonstration of how this can be done successfully.

This project was also published in the Spring 2018 issue of SABMag found at www.sabmagazine.com.

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PROJECT CREDITS OWNER/DEVELOPER Menkes Developments ARCHITECT Sweeny &Co Architects Inc. STRUCTURAL ENGINEER Stephenson Engineering Ltd. MECHANICAL ENGINEER The Mitchell Partnership ELECTRICAL ENGINEER AND LIGHTING DESIGNER Mulvey & Banani International [Commercial] LEED CONSULTANT Green Reason LANDSCAPE ARCHITECT NAK Design Strategies PHOTOS Doublespace Photography Water-conserving Solis solar-powered flushometer and Solis sensor faucets supplied by SLOAN. PROJECT PERFORMANCE ENERGY INTENSITY [BUILDING AND PROCESS ENERGY] = 171.4 kWh/m2/year REDUCTION IN ENERGY INTENSITY RELATIVE TO REFERENCE BUILDING = 46% [For Core and Shell with allowance for tenant consumption, and net of contribution from PV array] POTABLE WATER CONSUMPTION = 2,362 L/occupant/year REDUCTION IN POTABLE WATER CONSUMPTION RELATIVE TO REFERENCE BUILDING = 60% RECLAIMED AND RECYCLED MATERIAL CONTENT BY VALUE = 15% REGIONAL MATERIALS [AS DEFINED BY LEED] = 33% CONSTRUCTION WASTE DIVERTED FROM LANDFILL = 88% THE 35-STOREY OFFICE TOWER IS ONE OF THREE TOWERS [TWO ARE RESIDENTIAL] RISING FROM A THREE-STOREY RETAIL PODIUM [1]. SITUATED BETWEEN UNION STATION AND LAKE ONTARIO ON TWO-THIRDS OF A CITY BLOCK, ONE YORK IS TORONTO’S HIGHEST-SCORING LEED CORE+SHELL CERTIFIED OFFICE PROJECT TO DATE. [2]. THE UNDERFLOOR PRESSURIZED PLENUM IS SUPPLIED WITH CONDITIONED AIR EVENLY THROUGHOUT THE FLOOR, ALLOWING TENANTS TO INSTALL DIFFUSERS WHEREVER THEY ARE NEEDED [3]. SECTION PERSPECTIVE SHOWING THE RAISED FLOOR SYSTEM. CANTILEVERED FLOOR PLATES ALLOW FOR GREATER LIGHT PENETRATION, UNOBSTRUCTED VIEWS, AND AN UNINTERRUPTED, COLUMN-FREE PERIMETER [4]. THE ENTRY LOBBY OF ONE YORK STREET. ALONG WITH 150 OTHER BUILDINGS IN THE DOWNTOWN CORE, ONE YORK IS CONNECTED TO THE ENWAVE DEEP WATER COOLING SYSTEM [5].

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YOUR LEED V4 QUICK-REFERENCE

CANADIAN DIRECTORY OF PRODUCTS AND SERVICES FOR SUSTAINABLE, HIGH-PERFORMANCE BUILDING

Visit our on-line Directory to see hundreds of listings of companies which supply products and services for sustainable, high-performance building. Listings are organized by Product Category and by LEED v4 Category. Our LEED v4 Directory is created with the help of our partner:

OUR 2018 PARTNERS SITE | LANDSCAPING | RAINWATER HARVESTING

>Interface

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THERMAL & WINDOWS >Cascadia Windows & Doors >Eco Insulating Glass Inc.

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GREEN DESIGN SUPPORT + PROFESSIONALS

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INTERIOR FINISHES >CBR Products >Columbia Forest Products >Forbo Flooring Systems

Concrete Institute >Diamond Schmitt Architects >Efficiency Nova Scotia >FABRIQ architecture >Pomerleau >RJC Engineers

http://sabmagazine.com/directoryv4.html 46

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PRECAST CONCRETE BUILDS ON... RESILIENCY

The key attributes of enhanced architectural & structural resiliency are:

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Resistance to disasters Short-term recovery from a crisis Longevity (long service life) Life safety Durability Adaptability for reuse

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.ca Visit www.cpci.ca/publications to download your free copies of the Mitigate and Adapt Building our Communities in the Age of Climate Change brochure and the Structural Solutions technical publication.

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