Engineering Look Book IED

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hok en g i n e e r ing

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CONT ENTS 01

HOK ENGINEERING

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PROJECTS BY MARKET TYPE

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HOK STREAM

Aviation + Transportation Corporate Healthcare Justice Science + Technology Sports + Recreation + Entertainment

Aviation + Transportation Healthcare Science + Technology

Sports + Recreation + Entertainment

04

SERVICES AND SPECIALTIES SUSTAINABILITY

MEP TECHNOLOGY

EXISTING BUILDINGS

Energy Modeling

Displacement Ventilation

Adaptive Reuse

Whole-Building Life-Cycle Analysis

Radiant Heating & Cooling

Renovation

Net Zero and LEED Platinum

Central Utility Plants Underfloor Air Systems

FACADE DESIGN AND ANALYSIS

SPECIALTY STRUCTURES Canopies

Enclosure Thermal Modeling

IT INNOVATION

Pedestrian Bridges

Daylight and Glare Simulation

Passive Optical Networks

Feature Stairs

IT Security Systems

Vibration Analysis

DESIGN COMPETITIONS Circadian Facades Stadiums

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HOK ENGINEERING

#1 A/E firm as ranked by ENR

#1

#1

A/E firm as ranked by Architectural Record

Green Building A/E firm as ranked by ENR

2019

One of Fast Company’s Most Innovative Design Firms


HOK’s culture is rooted in design and technical excellence. This is where great engineering lives. For over 50 years, we have delivered exceptional design with architects at HOK and those at other outstanding practices. We engineer HOK’s most complex projects, from the new Terminal B at LaGuardia, the largest P3 project in US history; to KAUST, a 6.5 million square-foot LEED Platinum Lab of the Year; to the first-of-its-kind Mercedes-Benz Stadium Halo Video Board. We thrive by finding creative, integrated solutions whether we are fine-tuning proven, cost-effective building systems, or exploring ambitious, unprecedented design. We want to be your engineers. We want to bring our experience across the spectrum of project type and size, supplemented by next-generation computational techniques developed by our team and sustainable excellence to your project. Let us help you deliver the best for your Client.

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ENGINEERING SERVICES STRUCTURAL

MECHANICAL

• Long-span & special structures

• Air distribution systems - VAV, constant

• Existing building assessments

volume, Demand Controlled Ventilation

• Foundation design

(DCV), displacement ventilation, underfloor air

• Linear and non-linear dynamic analysis

distribution (UFAD), dual facade

• Vibration analysis and design • Whole-building life-cycle analysis (WBLCA) • Renovation & retrofit design • Resilience based design • Seismic design • Structural modeling • Technical planning & conceptual studies

• Building automation systems-Integrated smart building systems • Central utility plants • Cooling condensate recovery systems • Energy recovery systems - Air, Water and Steam • Fuel containment systems • Geothermal systems and ground source heat pumps

ELECTRICAL

• Heating, ventilation, and air conditioning

• Emergency/Standby generator systems

• Hydronic distribution systems-building and

• Energy management and conservation analysis

campus; variable primary or primary/secondary/

• Fire alarm and smoke detection systems

tertiary

• Grounding systems

• Natural ventilation design

• Lighting / lighting control systems

• Radiant systems-chilled beam systems, radiant

• Lightning protection systems • Low-voltage power distribution (600V and below) • Medium voltage power distribution (4.16kV – 69kV) • Photovoltaic power systems • Power monitoring • Short circuit calculations, protective device coordination studies, and arc flash studies • Sustainable / LEED Design • Uninterruptible power supply systems

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ceilings, radiant floors, snow melting • Renewable Energy Systems-Solar thermal • Resilience Based design-Mission critical systems • Steam distribution systems-up to 250 psig • Variable Refrigerant Flow (VRF) systems


FACADES

PERFORMANCE MODELING

• Building enclosure design consulting

• Climate and micro-climate analysis

• Thermal performance analysis

• Computational Fluid Dynamics (CFD)

• Performance Specification

• Cost analysis

ENERGY MODELING

• Daylighting analysis • Life cycle cost analysis

• Energy Infrastructure Master Planning

• Multi-Criteria Performance Analysis

• Thermal Comfort Analysis

• Solar resource assessment and levelized cost of

• Whole Building Energy Analysis

IT & ES SERVICES • Integration of IT&ES into built environment design • Master Planning including IT systems, Security systems, Airport system, etc. • Passive & Active infrastructure (network and systems) design • Converged multi-service network design • Wireless LAN (WiFi) and DAS (distributed antenna system) design • Public Address and Digital Signage design • Command & Control Center design • Vulnerability & Threat Assessments • CPTED (Crime Prevention Through Environmental Design) • Access Control and Video Surveillance Systems • Parking Access Revenue Control Systems • Systems Integration planning and management

energy (LCOE) • Thermal comfort analysis

PLUMBING / FIRE PROTECTION • Fire pump/Secondary water storage tank • Gray/Rain Water retention and reuse system • Hot and Cold domestic water system • Medical/Process compressed air system • Medical/Process special gas systems • Medical/Process vacuum system • Mission critical systems • Natural Gas system • Purified water system • Sanitary waste/vent, grease waste/vent,

and process waste/vent systems

• Sprinklers and standpipe • Storm water and overflow systems • Vacuum waste systems

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Te s t i m o n i a l s “The HOK team delivered a resounding series of design solutions for the airport’s highprofile modernization project. Multiple

challenges

ranging

from complex existing conditions and attention to solutions that

maintain

uninterrupted

We’re honored to work with the best clients, designers, and construction firms in the industry. Here’s what a few of them have to say about our shared experiences.

operations, were achieved with talent, energy and enthusiasm, combined with a commanding understanding and use of the current modeling technologies.” Gary Summerlin, Senior Design

We are so grateful to the HOK structural team for their partnership on our project to renovate a factory in a state of disrepair for our headquarters. Our vision of a home for our staff and a thriving community space for our partners would not have been accomplished without the commitment of the structural team to build a strong foundation and backbone. They

always found

creative and effective solutions focused on our goal to create a space that would serve Missouri Foundation for Health well now and for many years to come.” Jill Nowak, CFO Missouri Foundation for Health (MFHH)

Manager, City of Atlanta Department of Aviation

“HOK Structural is an excellent collaborator and has been willing to provide us with a range of options that meet our ideas alongside the various constraints of our project. Their experience with large scale projects has truly been an asset for moving our project forward in an exciting and responsible manner.” Jason Dannenbring, AIA Associate, Snow Kreilich Architects

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“I had the pleasure of working with HOK’s IT&ES (Information Technology and Electronic Systems) team on the LaGuardia Airport Central Terminal Replacement Project. The team worked collaboratively with Skanska, La Guardia Gateway Partners, and the Port Authority of Y& NJ to develop and deliver innovative solutions to facilitate construction and achieve client goals.

Edward D’Angelo Director Information Technology, LaGuardia Gateway Partners


“HOK’s engineers contributed significantly to the success of our Phillips 66 Headquarters project and they were key to helping us set project aspirations that will serve us well in the future. They carefully listened to us and they asked us the right questions. They explored and presented us with design options early in the design process and helped guide us to zero in on solutions that were best suited for our needs. Their focused efforts on sustainable design and energy efficiency have resulted in our project achieving LEED Platinum status, Energy Star status and an ASHRAE Technology award. HOK’s engineers worked closely with our P66 team and the construction team in a very collaborative way to deliver a project that we are proud to call our home. My thanks for a job well done!” Jeff French , Director of Facilities Operations Phillips 66

“With knowledge, experience, communications and collaboration, HOK has helped us achieve our goal of having a facility that is consistent, safe and secure.” Capt. Johnny Reed, UDC Transition Team

“Our West Sacramento Headquarters symbolizes CalSTRS’ promise to sustainability while it provides our employees and visitors with a healthy, stimulating and supportive workplace. The 17 story, 409,000 square foot building has maintained its US Green Building LEED® Platinum certification since 2011. The energy efficient building features and the participation of our employees in “green” build-

strengthen and advance environmental responsibility in our community.” ing practices

-CalSTRS

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Engineering partners

Building a successful design team can be as challenging and critical to a project’s success as the design itself. We pride ourselves on being an experienced, collaborative member of any team. We appreciate what everyone brings to the table and enjoy working together to deliver the best for our clients.

“The St. Louis MLS Stadium project gave DMA the opportunity to work on an exciting local project with HOK

engineers

from coast to coast, each with unique experiences and backgrounds. The overall experience was a gainful collaboration for all involved.” Stephanie Spann PE, LEED AP Structural Project Manager David Mason + Associates

“Each time I have had the chance to speak directly with this team I have enjoyed their total focus, I have never felt as if they were in a hurry to get on with something else or had other matters of greater importance to attend to.

Steven Haynes Senior Commissioning Engineer Burns & McDonnell

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Over the past 5+ years, HOK and Sykes Consulting have collaborated successfully on the structural design of several projects totaling over $1B in construction cost. The project types and teaming arrangements have varied depending on project and client needs, and the teams have delivered consistently and successfully.

“The expertise of the HOK engineering team and familiarity of our DMA structural engineers with local construction methods and design criteria meshed well to benefit the overall project.” Kara Marfell, PE, SE Structural Project Manager David Mason + Associates

“HOK has been an outstanding partner of SYKES for several years. They continually demonstrate a commitment to team success and promote a shared vision of excellence. Their effective leadership style fosters a collaborative relationship that is built on trust and mutual respect. It is truly an honor and privilege to partner with HOK.” Darien Sykes President, SYKES Consulting

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Construction partners “Through our work at the HJAIA Landside Modernization Project, we had a

great

experience

collaborating

with HOK on the complex engineering requirements for the job. We had a shared focus on doing what is best for our client and delivering an iconic structure for the City of Atlanta. HOK’s design team was always responsive to the project needs and had a great ability to work within the design parameters to drive the project to incredible outcomes.“

Justis Brogan, LEED AP

Successful collaboration with our construction partners, from precon through commissioning, is critical to the projects’ success. We are proud to have strong relationships with some of the best construction firms in the world, developed over years on a range of project types and delivery methods, including Design-Build and CM delivery. We take great pride in our collaborative successes.

We enjoy working with HOK, because we have the same intensity in getting challenges met and we see things with a similar, cooperative attitude. We have been on many projects with HOK, and hope to do many more.

Hartsfield was a challenging project, and that’s precisely why HOK and Beck Steel ended up doing it together. Not just anyone could’ve accomplished that, especially in the timeframe we did...in the busiest airport in the world, at night, over an elevated 7-lane existing active roadway. HOK gets a lot of credit not only for enabling the project to go together, but where the project occurred and how it all came together is amazing.” John Beck, Jr. President and CEO, Beck Steel

Project Director | McCarthy Building Companies, Inc.

“HOK’s Structural group was creative, responsive, and provided some of the most accurate information during preconstruction of any team we have worked with. They have been, and continue to be, a valued design partner that we look forward to working with on future endeavors.” ERIKA WINTERS-DOWNEY Senior Engineering Manager,

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McCOWNGORDON


“I had the pleasure of working with HOK’s IT&ES (Information Technology and Electronic Systems) team on the LaGuardia Airport Central Terminal Replacement Project. The team worked collaboratively with

“The success of the Chicago Bears Halas Hall Addition and Renovation was the result of a true partnership between HOK and Mortenson. Having HOK’s structural engineering group as part of the team proved invaluable to the project. As the architect and structural engineer, HOK was able to coordinate closely to achieve the design vision and provide timely resolutions to questions and issues which were key to meeting the project’s challenging fast track schedule. Laura Sables Leber, Director of Design Phase Management, Mortenson

SkanskaWalsh JV, LaGuardia Gateway Partners, and the Port Authority of NY& NJ to develop and deliver sustainable and innovative system solutions to facilitate a complex phased construction and achieve client goals.” Ted Jadermark Project Director Skanska

“The Enclosures Team at HOK has been consistently responsive and effective in helping SWJV meet the challenges of the LaGuardia Terminal B Project. Our collaborative efforts have culminated in creating a new and beautiful state-of-the-art facility that will enhance the travel experience for generations of people who live in or travel through New York!“ Douglas C. Maines, Project Director Skanska Walsh Design-Build Joint Venture

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Integrating science and art To create the most imaginative design solutions, HOK blends engineering rigor and optimization strategies with architectural logic and poetry. Our engineers work across every major building typology and provide expert guidance across structural, mechanical, electrical, plumbing and fire-protection engineering as well as facades, information technology and building physics.

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Mercedes-Benz Stadium Halo

The Halo structure, if “unrolled,” would be taller than the Eiffel Tower. HOK Engineering’s design was finished in less than two months and earned the National Council of Structural Engineers Association’s coveted “Most Outstanding Project” award.

Salt Lake City International Airport

The energy-efficient airport meets demanding seismic criteria with steel moment frames and buckling restrained braced frames while maintaining long, clear spans for traveler movement and sweeping landscape views.

BP High-Performance Computing Center

Designed to accommodate “the world’s largest supercomputer for commercial research,” the facility reached a remarkable power usage effectiveness ratio of 1.35 while providing a highly wind-resistant structure protects the computer while providing serene daylit workspaces.

Sidney & Lois Eskenazi Hospital

Daylit interior spaces, green roofs, landscaped courtyards and massive cantilevers define this LEED-gold healthcare facility. The hospital is able to serve 20 percent more patients in less square footage than in the healthcare system’s previous space.

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MEET HOK LEADERS Claire Moore, PE, SE, LEED AP BD+C ENGINEERING PRACTICE LEADER

Claire’s work includes a wide range of experience in structural engineering design, project management and construction administration services. Her technical expertise encompasses both linear and nonlinear analysis, seismic evaluations and retrofits, structural design and BIM modeling. With completed projects ranging from large iconic buildings to small-scale art installations, she has experience in a variety of project types, including higher education, healthcare, justice and aviation. Claire sits on HOK’s Management Board and Technical Board.

Saad Dimachkieh, PE, CLEP, LEED AP ENGINEERING PRACTICE LEADER

An electrical engineer and engineering leader with nearly 40 years of experience, Saad works closely with owners, architects, consultants and contractors to integrate engineering design throughout all phases of project development. His expertise includes engineering management; design and documentation of lighting systems, power distribution systems and fire alarm systems; and coordination with consultants to design security and telecom systems. Saad sits on HOK’s Technical Board.

Gary Kuzma, PE, CEM, LEED AP, GBE ENGINEERING PRACTICE LEADER

Gary is a mechanical engineer with more than four decades of experience leading the mechanical engineering design for many of HOK’s most complex projects. He integrates innovative, highperformance engineering solutions into each building’s design. Gary leads teams in accommodating clients’ program requirements while ensuring system flexibility, reliability, maintainability and ease of operations. He has broad experience in value engineering and life cycle cost analysis, energy analysis and conservation, and sustainable design.

Matt Breidenthal, PE, SE, LEED AP ENGINEERING PRACTICE LEADER

Matt Breidenthal is a structural engineer responsible for delivering award-winning, complex and demanding multi-disciplinary projects. With a strong record of satisfied repeat clients, Matt brings a deep appreciation for interdisciplinary collaboration and is recognized for his ability to bring innovative and creative solutions. Matt has been lead engineer or Engineer of Record on over $10B of construction. He sits on HOK’s Marketing Board and Board of Directors.

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“We often find simple solutions

AND AN AWARDWINNING ENGINEERING

to complex problems through a collaborative team approach.”

TEAM “It’s fascinating to imagine what a new space looks like, how people experience a building and how the structure interacts with them.”

“We are partners in delivering great design.”

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P RO JECTS BY

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M AR K E T T Y P E

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AV IA HOK | 20


AT IO N + TRA N SPO RTAT I O N 21 | HOK


AVIATI ON + TRANS PO RTATION Around the globe, HOK engineers and designers are reenvisioning the way we think about transportation design. With decades of experience in aviation, from international hubs to regional and domestic airports, we understand the unique requirements of airport development. We take a hands-on approach to solving the systems, structural and technology design challenges that surround the complex airport environment — meeting the need for efficiency, sustainability and accommodating growth. From Hamad International Airport, consistently ranked as one of the world’s best, to major expansions at Salt Lake City, HartsfieldJackson, John F. Kennedy, LaGuardia, and Chicago O’Hare Airports, we think beyond single system design to develop ideas that work for the airport as a whole. We understand that high-performance design solutions start with effective planning. By integrating our engineering design process early on, we address how a functional layout, passenger comfort, energy use, fire and life safety issues, unique structural forms, network and security requirements can seamlessly come together to create an enjoyable environment.

"As part of the modernization of the world’s busiest airport, HOK delivered a structural and architectural icon." - STRUCTURE Magazine

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25

SELECT CLIENTS AND FACILITIES • Delta Airlines

bn

• Hamad International Airport

Over $25 billion in aviation projects delivered globally by HOK engineering

• Hartsfield-Jackson Atlanta International Airport • Chicago Department of Aviation

1

• Los Angeles International Airport

bn

• Salt Lake City International Airport

Over 1 billion passengers travel through HOK-designed facilities each year

• Port Authority of New York and New Jersey • John F. Kennedy International Airport • LaGuardia Airport

Best Airport + Transit Projects, Southeast: Hartsfield-Jackson Modernization

• Houston Airport System

ENGINEERING SERVICES • Structural Engineering

2020

• Energy Modeling and Analysis • Facade Design • IT Communications and Security Systems Design • Public Address & AV Systems Design • Mechanical Engineering • Electrical Engineering

2020

NCSEA Excellence in Structural Engineering Award LaGuardia Airport’s New Terminal B Pedestrian Bridge

• Plumbing and Fire Protection

AISC IDEAS National Award Canopies at Hartsfield Jackson Atlanta International Airport

2020 SKYTRAX World Airport Awards Hamad International Airport

• Sustainability

PROJECT TYPES • Air Traffic Control Towers

• Cargo Facilities

• Hangars

• Airport Cities

• Central Utility Plants

• Lounges

• Terminals and Concourses

• Concessions

• Automated People Movers (APM)

• FIS Facilities

• Concourse Extensions • Modernization • Parking Structures

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LAGUARDIA AIRPORT N E W T E R M I N AL B Façade Design Structural Engineering Plumbing and Fire Protection IT and Electronic Systems Design

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La G uard i a Ai r p or t New Term i n a l B N ew Yor k , New Yo r k 1. 3M s q. f t Th e H O K s tru ctu ra l t e a m ’s a i r y, icon i c bri dge s a nd c o n c o u rse s solved a l o n g- s tan d i n g c h a l l e n g e in ai r- s i de effi ci en c y, re c i evi n g a 2 02 0 N C S E A E xc e l l e n c e i n Structu ra l E n gi n ee r i n g Awa rd .

A challenging proposal set forth by a Port Authority public-private partnership challenged teams to envision replacing the existing airport with a sleek, efficient gateway to the city—without canceling a single flight. The key finding that islands, not peninsulas, would alleviate the greatest number of efficiency bottlenecks differed significantly from the rest of the design competition entries.

The geometry of the bridge trusses were optimized from thousands of possibilities using an optimization workflow developed by the engineering team (STREAM). The bridges merge seamlessly with the faceted long-span roofs of the concourses which allow uninterrupted sight-lines from the control tower as well as column-free day-lit circulation space for travelers below.

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The airport acheived LEED Gold, bolsterd by Life-Cycle Analysis indicating significant structural embodied carbon reduction as well as several systems innovations. A supplemental solar thermal domestic water heating system was engineered and installed to reduce the carbon footprint of the Terminal B buildings. Rain water is harvested from a large portion of the Terminal B headhouse building and stored underneath the headhouse for sitewide irrigation and non-potable water usage on-site. High-performance water-reducing plumbing fixtures were selected and installed within all Terminal B buildings.

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La G u a rdia Airport N ew Te r m inal B: Facades The new Terminal B is a collection of separate Head House, Central Hall, Concourses, and connecting bridges, all united by the consistent language of the enclosures. The sculpturally shaped elevations, with fluid rounded edges and corners, are defined by a taut rain-screen metal panel skin surrounding the curtain wall glazing. HOK’s façade group developed the conceptual approach to the modular unitized glazing and metal panel skin and collaborated with specialty manufacturers and suppliers and the Skanska-Walsh Joint Venture in a Design-Assist delivery process. The façade systems were all custom designed, with stringent requirements for security, thermal, acoustical, and structural performance tested in laboratory mock ups. The four systems used were cable wall, HSS ladder backup with veneer glazing, AESS steel fin mullion-supported gridded glazed frames and steel fin wall-supported ashlar-pattern glazing. The façade group guided and witnessed PMU tests and the extensive field testing conducted during Construction Administration.

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“The Enclosures Team at HOK has been consistently responsive and effective in helping SWJV meet the challenges of the LaGuardia Terminal B Project. Our collaborative efforts have culminated in creating a new and beautiful state-ofthe-art facility that will enhance the travel experience for generations of people who live in or travel through New York!” Douglas C. Maines Project Director Skanska Walsh DesignBuild Joint Venture

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The terminal is equipped with a single mode fiber communication infrastructure that supports both the fixed (wired) and mobile (wireless) communications requirements of terminal operator, airlines, travelers, first-responders, and other stakeholders. The first phase of construction included two new MDFs (Main Distribution Frame rooms) located in Concourse B and the Central Heating Refrigeration Plant. This enabled a high availability, converged, multi-service Passive Optical Network (PON) to be installed and interfaced with the legacy systems to facilitate operation of the new facilities with the existing facilities throughout construction.

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SALT LAKE CITY

I NT E RN AT I O N AL AI RPO RT Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

IT and Electronic Systems Design Façade Design

33 | HOK


SALT LAKE CIT Y INT ER NAT IONA L A I RPORT Salt Lake City, Utah 2.6M sq. ft.

Engineering strategies helped drive the design for 29 independent structures with rigorous seismic requirements and climatic challenges. Situated near the Wasatch Fault on the soft soil and high water table of the Great Salt Lake, the buildings need to meet rigorous earthquake safety standards. As the airport is in the high desert, the site experiences large thermal swings. Combining these challenges with large floor plates resulted in 29 structurally independent structures. HOK’s Structural Engineering solutions for the new Terminal and Concourse include steel moment frames and bucking restrained braced frames which allowed column-free circulation through security checkpoints and concourses. The climatic challenges were also met with customized MEP systems, striving for LEED Gold. Indirect / Direct Evaporative Cooling (IDEC) systems suit the dry climate of Salt Lake City and reduce overall mechanical cooling energy 80% from the ASHRAE 90.1 baseline. Displacement air systems are utilized in circulation spaces to reduce fan energy while increasing ventilation effectiveness. Displacement air diffusers are integrated in column covers and floor grilles to hide air outlets from view. The north plaza is served by a radiant floor for heating and cooling, to maintain a higher level of comfort than could be achieved by traditional air mixing systems.

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“One of the reasons we are

“To efficiently design 29

building a new airport is to bring

buildings simultaneously at Salt

it up to 21st Century seismic

Lake City International Airport,

standards, and knowing that we

we put in place lean processes:

will soon have facilities capable

pull planning, feedback loops,

of withstanding a 7.2 magnitude

and constraint logs. We also

earthquake is reassuring, and I

spent a lot of upfront time

am sure will also be welcomed

working out scripts and

by our passengers.”

workflows that made it possible to perform tasks that previously

-Bill Wyatt, Director of Airports,

required weeks in just hours.”

Salt Lake City -Claire Moore, Engineering Practice Leader

35 | HOK


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An elevated finned tube heater (shown as red line in right image) maintains comfort adjacent to the curtain wall.

Radiant heating and cooling slabs minimized air diffusers in the displacement ventilation system. The perimeter air diffusers were located between curtain wall vertical mullions and return air taken through concealed ceiling openings.

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HARTSFIELD JACKSON I N TE RNAT IO NA L A IRPO RT T ERM I NAL M O D E RNI ZATI O N Structural Engineering

39 | HOK


H A RTSFI E LD JACKSON I NT E RN ATI O N A L A IR PORT T E RM IN AL M ODER NIZATION Atlanta, Georgia 10,000 sq. ft.

To modernize the busiest airport in the world, HOK designed two soaring canopies to engage the curbside pick-up and drop-off areas and shelter travelers from the elements. Developing parametric optimization scripts to iterate through thousands of possibilities, HOK’s engineering team drove the design of elegant design 864’-long canopies feature curved HSS steel Vierendeel trusses, laterally braced by a lace-like diagrid.

This scheme dramatically minimized the impact to airport operations and passenger experience during

construction anticipated by the airport, far exceeding the client’s expectations. The structural team’s custom parametric scripts evaluated hundreds of possibilities, revealing the efficient form defining the structure’s geometry within a couple weeks. The group chose ETFE rather than glass to clad the canopies. As the weight of ETFE is ten percent that of traditional glazing, it allowed the total weight of the canopies, including structure, to decrease by half. The team conducted thorough analysis and onsite evaluation of the approximately 1M square foot existing structure to verifed the existing structure could support ETFE-clad canopies with minimal strengthening efforts. This avoided new columns, braces, and foundations atop curbside circulation space and the facilities below.

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While the truss chords appear to have gradually varying curvature, they are actually comprised of discrete constant-curvature sections, which are significantly less expensive to fabricate.

Bearing pads prevent lateral loads from being transferred to the existing terminal

The canopy’s form is driven completely by function: the diagrid’s shape allows it to transfer lateral forces away from the existing 40-yearold terminal.

“The HOK team delivered a resounding series of design solutions for the airport’s high-profile modernization project. Multiple challenges ranging from complex existing conditions and attention to solutions that maintain uninterrupted operations, were achieved with talent, energy and enthusiasm, combined with a commanding understanding and use of the current modeling technologies.” Gary Summerlin Senior Design Manager City of Atlanta Department of Aviation

41 | HOK


HAMAD INTERNATIONAL AIRPORT PASSE NG E R T ER MI NA L C O M P L EX Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 42


43 | HOK


H A M AD IN TE RNAT IONA L A IR PORT PASSE N GE R TER MINA L COMPLEX Doha, Qatar 6.46M sq. ft.

83 °F

This project is a testament to HOK’s ability to deliver a large, complex, fast track project anywhere in the world. The

78 °F

success and rapid growth of the national carrier, Qatar Airways led to the project more than doubling in size after construction had started. To create a thermally comfortable environment in an extreme climate, the minaret draws outdoor air into the mosque from far above the parking garage below.

74 °F

73 °F

To address extreme heat and solar loads at the perimeter spaces, computational fluid dynamics (CFD) analysis was used to validate and optimize the HVAC design.

Displacement air ventilation systems integrated into the mosque floor and walls create a comfortable space during hot and humid summer months and allows expansive roof skylights free from ductwork.

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While it doesn’t rain often in Qatar, when it rains, it pours. Rather than slope stormwater piping through the narrow soffit, a syphonic roof drainage system allows horizontal pipes to drain water from the roof of the 6.5m sqft structure, taking advantage of ideal drainage points created by the undulating roof.

Hanging a lap pool, enclosed by glass, was not only a structural feat, but also an innovative HVAC exercise to maintain a low humidity in the pool area and avoid condensation on glass. Dedicated dehumidification systems control humidity while specialized ductwork became part of the design aesthetic of the space.

45 | HOK


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CHICAGO O’HARE

I NT E R NAT I O N A L A IR PO RT T ERMI NAL 5 E XPANSI O N Structural Engineering IT and Electronic Systems Design

47 | HOK


C H I CAGO O ’HAR E INTER NAT IONA L AI RPORT T E RM IN AL 5 E X PA NSION Chicago, Illinois 260,000 sq. ft.

The terminal 5 expansion includes a new 1200 foot long, two story, 260,000 square foot concourse with 7 new gates and a dining area, and a two story, 100,000 square foot addition to the existing Headhouse which will house additional airline club, circulation, and baggage handling spaces. The concourse roof structure provides an expansive column-free interior space through the use of roof girders spanning from 70 to 150 feet. The long-span roof is split lengthwise by a clerestory at mid-span, requiring the use of a series of bent roof girders. Parametric modeling was used during the design process to achieve the dynamic roof form with a series of planar and single-curvature surfaces, reducing the structural complexity. The Headhouse addition is constructed atop a sub-grade portion of the existing terminal that extended beyond the above-ground building footprint, requiring a high level of coordination with the existing structure. Additionally, the expansion, which sits over the current and active Customs and Border Protection Arrivals Hall, was almost entirely supported by existing foundations with limited latent load-bearing capacity, requiring an efficient and lightweight structural design to minimize the new loads placed on the existing building. During the concept and schematic design phases, HOK worked with the broader design team to maximize the expansion potential of the existing building.

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The project includes converged multi-service PONs (Passive Optical Networks) that support airport, airline, and other stakeholder communications requirements. It will be the first airport where Customs Border and Protection (CBP) has agreed to allow PON to support CBP communications requirements. This was important because it allowed the elimination of 3 CBP strong rooms to house network equipments since PON is not subject to the 100 meter limitation that conventional Ethernet is. The PONs will be interfaced with existing airport and CBP networks to facilitate integrated operations of new and existing airport/ terminal facilities.

49 | HOK


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C O R PO RAT E 51 | HOK


CORPORATE + CULTURAL Listening to our clients and understanding their needs make HOK a trusted firm to provide engineering services for their projects from minor additions to iconic headquarters. Each corporate client has a unique approach to their operations – such as safety, security, and redundancy. We recognize these details in order to provide tailored engineering solutions to meet their specific needs. Our teams have been successfully delivering full-engineering services to several well-known corporations across business sectors. In many cases, we work with the consulting team to help our clients develop and maintain their corporate standards for their facilities. We have decades-long relationships with several clients due the value this relationship brings. With our strong technical knowledge and wide-range of experience, we are well equipped to take on inherent challenges of cultural projects, from preservation projects to one-of-a-kind structures. Typical or standard is not what we expect when working on this type of project. Innovative and integrated engineering solutions are often required to push the boundaries and produce sculptural and aesthetically stimulating structures. Budget allocation is one of the most critical aspects in this market sector. It is even more important for a capital investment of a corporation or a cultural project with a limited budget. With that in mind, we always work collaboratively with project teams to arrive with the most economical and optimal engineering solutions. Engineering systems of a building work most of the time behind the scene. Our goal is always to minimize the cost of these systems, so more budget can be spent to make the projects even more appealing.

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SELECT CLIENTS • Royal Caribbean Cruise Lines • Fluor Enterprises • Hines

9 mil

Square feet of high rise office buildings designed in the last 20 years.

5

Days of off-grid water supply for a resilient corporate campus

• LG North America • City of Houston • Visa USA, Inc. • Accenture • Centene • Honeywell ENGINEERING SERVICES • Structural Engineering • Energy Modeling and Analysis

2020

ASHRAE Region VIII Technology award, Phillips 66 Headquarters

• Façade Design • IT Communications and Security Systems Design • IT Electronics Systems • Mechanical Engineering • Electrical Engineering • Plumbing and Fire Protection

PROJECT TYPES • Corporate Headquarters

• Adaptive Reuse

• Corporate Campus

• Tenant Improvement

• High-rise Corporate Office

• Performance Space

• Museums

• Seismic Retrofit

• Libraries

• Stairs

• Renovation

• Existing Facility Assessment • Facade Replacement 53 | HOK


PHILLIPS 66

NEW COR PO RAT E CAM PUS Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 54


55 | HOK


P H I LLIPS 66 NEW COR PORATE CA MP US Houston, Texas 1.1M sq. ft. corporate headquarters; 1.1M sq. ft. parking garage The Project earned all 19 points for USGBC LEED credit EAc1 Optimize Energy Performance. A “Demand Based Management” philosophy was fundamental to all aspects of the building design. The chilled water plant uses variable speed chillers, pumps and cooling towers controlled by a plant optimization software to manage resources with the lowest possible electrical power needed. Total energy recovery wheels are used in conjunction with dedicated outdoor air systems to pre-condition outdoor air by transferring energy from the building exhaust. LED lighting throughout is controlled by a sophisticated system which operates based on occupancy and adjusts artificial light levels in response to natural light. Extensive sub-metering of cooling energy, heating energy and electric power provides real time and historical operating performance used to inform system management. Working closely with Phillips 66’s IT team, the team implemented data virtualization to reduce the on-site data center’s electrical power consumption.

Achieving LEED Platinum and an ASHRAE Region VIII Technology Award, the team’s design already addressed most of ASHRAE’s 2020 recommendations for a pandemic scenario.

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“When I asked Phillips 66 if there was anything I could do to assist them with a COVID-19 response, their reply was ‘Thank you! You already have.’” said Gary Kuzma, engineering practice leader in our Houston studio.

Heating, ventilating and air-conditioning (HVAC) for office floors include HOK’s next-generation underfloor air distribution (UFAD) that evolved from listening to past clients advice and experience with UFAD systems. The system is highly flexible and can be easily adapted to accommodate changes in heating and cooling loads and is easily re-configurable. Personal controls allow occupants to adjust temperature to control the environment around them. The team engineered steel framed office towers (14 story & 16 story) constructed integrally with the 6 story structural steel framed podium base. Office towers are connected with a pair of non-parallel chord, 10 story trusses located above the podium roof to allow connectivity between the two towers. Structural framing at podium roof was designed to accommodate an 18,500 sq. ft. organic, free-form skylight to allow natural light to filter into the floor levels below. The structural design also included an 8 story post-tensioned concrete parking structure, the roof of which provides an outdoor multi-purpose sports field and track.

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CA LS TR S HE ADQUARTERS Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

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Sacramento, California 620,000 sq. ft.

The tower’s Energy Star 94-100 rating and LEED Platinum efficiency “symbolizes CalSTRS’ promise to sustainability” -CalSTRS

The new headquarters for the California State Teachers’ Retirement System (CalSTRS) acheives LEED Platinum facility and includes 13 floors of office space and two floors of mechanical space above a 5 level podium structure. Energy modeling performed during the early design stages identified potential energy saving strategies. The glazing and interior space plan maximize daylight penetration and include high efficiency lighting fixtures and automatic lighting controls utilizing daylight sensors and occupant sensors. The building uses high efficiency chillers and an underfloor air distribution system, resulting in increased comfort, enhanced indoor air quality, and reduced energy use. In addition, the UFAD system allows up to 90% of the individuals on each tower floor to control the air flow to their personal work areas. Full building commissioning of all energy-related systems confirmed proper operation for energy efficiency and comfort. A direct digital control system was provided for control and monitoring of mechanical systems, with full trend logging capabilities.

59 | HOK


C ON FI D E N TIAL

NET-ZERO

ENERGY

C ORPO RATE CA MP US

Structural Engineering

South America

Electrical Engineering

Mechanical Engineering

115,000 sq. ft.

Plumbing and Fire Protection IT and Electronic Systems Design Façade Design

30-35 kbtu/sf EUI demand

30-35 kbtu/sf PV production

HOK delivered full-services for a paradigm-shifting net zero corporate campus in South America. The campus is comprised of two structural steel buildings and a service building which provide a cafeteria, fitness center, training center, laboratory, data center, and control room. Architecturally exposed structural steel (AESS) on both the interior and facade unifies the campus. Situated in a lush tropical region, HOK’s design focused on using systems that can be procured and installed by local construction personnel.

While Net Zero was not a programmatic requirement for this project, HOK was able to deliver this cutting-edge performance within the client’s budget, which was determined by an early life-cycle cost analysis. HOK’s engineers worked hand in hand with the architecture team during concept design to optimize the building footprint, orientation, shading devices and glazing percentages and minimize the energy demand, driving the EUI down from the ASHRAE 90.1 2010 baseline to an EUI entirely offset by the HOK-designed on-site power generation system, resulting in one of the first net-zero energy corporate complexes in South America.

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Energy conservation measures involved air-to-air energy recovery, variable refrigerant air conditioning system allowing localized control, high efficiency LED lighting, demand controlled ventilation for kitchen exhaust. On-site power generation will be accomplished through high-efficiency photovoltaic cells connected to the parking canopies complete with battery storage and 100% generator back-up. The engineering team’s analysis found that the payback period for the photovoltaic array will be less than 10 years. Further, due to unpredictible water resources, HOK provided a water collection, storage, and treatment system with which provides the added resilience of five-day off-grid water supply when needed.

61 | HOK


ROYAL CARIBBEAN CRUISE LINE HE A D Q UART E RS Façade Design Structural Engineering Energy Modeling

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63 | HOK


ROYAL CARI BBEA N CR UISE LINE H EADQ UARTE RS Miami, Florida 377,000 sq. ft.

The unique curvilinear floor lines project outward and inwards varying

This striking design requires that floor plate mass and stiffness geometrically varies from floor to floor, long cantilevers, floor beams subject to from floor to floor, mimicking a cruise liner about to embark.

high torsional moments and stresses and numerous transfer girders. The engineering team’s response to these challenges is a pan-joist framed floor supported on post-tensioned girders spanning from the exterior columns to the interior core walls and columns. Transfer girders are post-tensioned to minimize depth as prestressing forces increase their stiffness and reduce deflections. The exterior curved open floor areas support green roofs, blurirng the line between indoors and outdoors. While the entire building is framed with concrete, the roof was designed with structural steel to minimize weight while providing dramatic cantilevers.

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Due to the buildings’ proximity to the sea, the soft soil would settle significantly under sustained loads. Accordingly, the ground floor was designed as a structural floor supported on intermediate piles while the superstructure columns were supported on deep auger cast piles and concrete pile caps. The high wind loads are resisted by a lateral system of shear walls and the concrete frames in the longitudinal directions and shear walls and simply reinforced girders transverse to shallow floor plates. Completing the campus, the nine-level parking garage has long, clear spans with exterior spandrel beams designed to support an architectural fin similar to that at the office building and the fitness center. The long span beams and slab are designed to be post-tensioned. The roof of the garage supports a green space for sports, surrounded by a jogging track.

65 | HOK


LG

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LG NORTH AMERICA HE ADQ UARTE RS Facade Design

67 | HOK


LG HE ADQ UART ER S Englewood Cliffs, New Jersey 367,580 sq. ft.

Daylight

reaches

workspaces

in

deep

the

into

the

LEED-Platinum

buildings’ campus,

surrounded by 27 acres of scenic green space. Rooftop solar panels will generate approximately 1,500 megawatt hours of electrical power annually. Sustainable site strategies include restoration of five wetlands to increase native bird habitat.

A custom, glass-enclosed “cube” links the two buildings and features an open atrium and product galleries. The Cube atrium space enclosed in a custom Architectural Exposed Structural Steel facade system joins the two office bars. The offices are clad in customized unitized curtain wall.

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The HOK Facade Design group engineered the steel structural elements that lend the Cube its design language as well as structural and thermal perfomance. The team also quality control tested all enclosures on the facility.

69 | HOK


HOK | 70


811 MAIN Structural Engineering Architect: Pickard Chilton

71 | HOK


8 1 1 MAI N Houston, Texas 973,861 sq. ft.

Breathing new life into the Houston skyline, the tower at 811 Main reaches 47-stories in lightweight concrete by delivering load from exterior columns to interior shear walls via post-tensioned concrete girders. Developed by Hines Interests, the office tower sits atop a 10-story garage. In wind-prone Houston, a wind tunnel test was conducted which concluded that a building of this shape, which was architecturally advantageous for the office space within, would twist noticeably under an angular wind direction. HOK engineers determined that the shape would be feasible if this force was countered by post-tensioning the perimeter girders to increase their stiffness. With this system in place, the shear walls of the core can easily manage the balance of torsional behavior.

An eye-catching feature and design challenge, the cut-back in plan between levels 39 and 44 would traditionally require deep transfer girders at level 39 to span across the width of the building, supporting the inset columns from above. However, the architectural and MEP constraints did not allow for the higher floor to floor height a deep floor-framing system would require. To address this, a system of diagonal columns was devised by the structural team which begin at level 37 and extend two stories to the base of inset columns at level 39. At level 37, the girders at the base of each column were post-tensioned to act as a tension tie member. The adjacent floor areas were reinforced to support the additional tension load.

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73 | HOK


AF RI CAN AM E R ICA N LIB RA RY Houston, Texas 30,000 sq.

This adaptive reuse project is located in the historic “Freedman’s District” of Houston, the library showcases the African-American history of Houston both before and since that time. The building selected was an existing but unused historically African-American school, the exterior of which was to be left unchanged, with interior modifications for the library. Upon investigating the existing building, it was found that the exterior brick façade was load-bearing and was supported upon concrete walls and concrete footings along the exterior. The interior corridor was framed with a concrete slab supported on each side by continuous concrete beams and footings and the classrooms were framed with light wood joists and a wood deck. Any new floor and roof framing would have to be as light as the original. However, the load carrying capability and fire-rating requirements made it impossible to reframe the library with wood. The engineering team devised a solution: gut the deteriorating wood floors and roof, and at the same time provide temporary lateral bracing to the exterior walls for their full height. Then, frame the roof, the 2nd floor and the 1st floor with steel joists supporting a steel deck and concrete slab. The following key steps allowed the retrofit while preserving historic character: new strip footings between existing footings to support concrete pilasters, new cantilevered deep steel beams atop the pilasters to support three stories and high-strength pipe columns undetectably placed within new cross walls. Today, after years of use, there is no difference in elevation between the existing and the floors which were carefully offset by 1” at the time of construction to allow for settlement, just one indication of a successful historic retrofit.

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Structural Engineering Architect: Smith & Company

75 | HOK


ASIA SOCIETY Structural Engineering Architect: Taniguchi and Associates

HOK | 76


77 | HOK


ASI A SO CIE TY Houston, Texas 30,000 sq. ft.

The minimalist structure is intended to house Asian-American art, exhibitions, movies and performances, it is a 30,000 sq. ft., two-story building with display areas, an auditorium and roof garden with water fountain displays on the second floor. Renowned

Japanese

Architect,

Yoshio

Taniguchi engaged HOK to engineer a structure that would be as much art as the pieces it housed. The team delivered a sleek concrete flat slab floor framing system supported on high-strength concrete columns not more than 5” to 6” in diameter. The roof was framed with long span joists supported at exterior walls allowing a column-free interior. Key aesthetics driven by engineering ingenuity were stairs and cantilevered roof projections which appear to levitate. Roof cantilevers taper to a 4” thickness, evoking the horizontal lines of the Texas landscape.

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79 | HOK


SHELL WOODCREEK CAMPUS Structural Engineering

HOK | 80


81 | HOK


SH ELL O IL CAMPUS B UILDINGS & GARAG ES Houston, Texas 1.055M sq. ft.

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HOK was commissioned to masterplan and design a LEED Gold campus for Shell, for which three new 12-story office buildings and two garages were engineered by the HOK structural team. Since the buildings were in outlying areas of the city, they were subject to higher wind loads generated by the flat expanse of landscape which surrounds. The most economical structural system capable of supporting office floor loads, span from the exterior columns to the interior core and be of minimal depth was a cast-in-place concrete frame. The team used 16 inch deep joists at 6’ spacing to support a 4-inch thick lightweight concrete slab and spaced at 6’-0”. The lateral system used was a combination of concrete frames and shear walls around stairs and elevators. A feature stair was engineered to extremely tight deflection limits, appearing to float while allowing it to be clad in glass. 83 | HOK


HOK | 84


H E ALT H CARE 85 | HOK


HEALTHCARE HOK’s interdisciplinary healthcare teams design wellorganized, sustainable spaces to facilitate care and recovery. HOK Engineering is an experienced partner on projects for the healthcare environment. With experience ranging from new hospital campuses and patient care towers to existing building conversions and renovations, we are able to address the full range of challenges that surround these complex projects. Our engineers work with the entire project team from concept design onwards to design facilities that holistically deliver our healthcare clients’ requirements for operational efficiency and state-of-the-art patient treatment. We simultaneously address long span requirements with vibration control for critical areas such as operating rooms and imaging suites. We design to ensure dedicated pathways for operating and imaging equipment replacement. Our engineering team focuses on high-performance yet cost-effective structural solutions. As environmental health is integral to human health, our engineering team conducts life-cycle analyses to quantify carbon emissions, providing feedback to our clients on the environmental impacts of various design options and how to minimize them. We design with intention, always seeking opportunities to optimize the design, enhance the structure’s performance, and maximize its efficiency. Our clients benefit from workflows and custom parametric scripts HOK engineering has developed over years of healthcare projects to inform key design decisions in short periods of time. In addition, we bring expertise in specialized engineering requirements such as seismic design, security and blast design, as well as custom façades specifically for healthcare settings.

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SELECT CLIENTS AND PROJECTS • Duke University • The University of Michigan

60 ft

• Grady Health System • The University of Pittsburgh • Eskenazi Hospital • University of Missouri • Kaiser Permanente

10 %

• Stanford Children’s Hospital • New York Presbyterian Hospital

Girder span on Correll Pavilion above four levels of parking serving four levels of hospital services with vibration criteria up to VC-B Embodied carbon reductions on hospital projects utilizing lifecycle analysis Best Projects SE: Atlanta Hawks and Emory Sports Medicine Complex

• Rutgers Cancer Institute • Humana • Indiana University Health • Memorial Sloan-Kettering • South Nassau Communities Hospital • Department of Veterans Affairs

ENGINEERING SERVICES • Structural Engineering • Energy Modeling and Analysis • Façade Design • IT & Electronic Systems and Security Design

PROJECT TYPES

“Our vision of a home for our staff and a thriving community space for our partners would not have been accomplished without the commitment of the structural team to build a strong foundation and backbone. They always found creative and effective solutions focused on our goal to create a space that would serve Missouri Foundation for Health well now and for many years to come.” Jill Nowak, CFO Missouri Foundation for Health (MFHH)

• Health Sciences Facilities

• Academic Medical Centers

• Health + Wellness Centers

• Ambulatory Care / Outpatient Facilities

• Medical Office Buildings

• Behavioral Health Facilities

• Specialty Hospitals

• Community Hospitals

• Strategic Master Plans 87 | HOK


UPM C

U NI V E RSI T Y O F PI TTSBURG H M E DI CAL CE NT E R VI SI O N AND RE HABI LI TATI O N TOW E R AT U P M C M E RCY Structural Engineering

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89 | HOK


U N I V E RSITY OF PITTSB URGH MED I CAL C EN TER ( UP MC ) VI S I ON AN D REHA B ILITATION TOWER AT UP MC MERCY Pittsburgh, Pennsylvania 410,000 sq. ft.

Scheduled to open in 2022, the new facility is entirely dedicated to treating blindness and low vision conditions which will include leading-edge clinical spaces for research trials and interdisciplinary research. The structure of the facility consists primarily of a concrete flat slab supported by concrete columns and beams, with certain areas employing steel due to localized design requirements. The concrete floor plate manages the complex spatial variation of floor vibration requirements across use types, due to the significant amount of sensitive equipment used.

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In order to achieve the architectural vision and programing goals, a transition to steel structure in key areas was required. The most notable is the tower bridge which spans over the main entrance drive below. The trusses range in span from sixty-five to one hundred twenty feet and support levels four through eleven (roof). Another integration of the two structural materials occurred on the East side of the building to support the exterior collaboration stair. The glazed conduit was critical to the overall function of the building which provided casual interaction space for occupants of different disciplines.

Support of the enclosure required columns which extend over sixty feet in height, unbraced. Concrete filled steel tubes were used to maintain the sleek and minimal appearance of the glass enclosure. Other creative structural features of the project are the use Lastly, the two multi-story entrance atriums enclosed by glass were framed in steel.

of transfer beams, transfer walls, and walking columns to accommodate the loading dock and garage programing with the differing column grid of the clinical program above.HOK’s structural engineering team worked closely with the contractor to allow the foundation construction and fabrication of the steel transfer trusses to start ahead of the full construction documents being submitted, allowing the earliest construction completion date.

91 | HOK


SIDNEY & LOIS ESKENAZI HOSPITAL Structural Engineering

HOK | 92


93 | HOK


SI D N E Y & LO I S ESK ENA ZI HOSPITA L Indianapolis, Indiana 1.3M sq. ft.

After deeming the buildings on its nearly 150-year-old academic medical center beyond renovation, Eskenazi Health traded its outdated facilities for a large parcel of land just west of downtown Indianapolis. Strategically placed windows in patient rooms and visitor areas bring in sunshine and the natural environment, creating a bright, airy feeling. A highly efficient plan enables the new hospital to serve 20 percent more patients than in the old facility—in less square footage. The 37-acre campus, which is one of the world’s largest LEED Gold healthcare campuses, includes a 315-bed hospital, 100-bed emergency department, 275-room outpatient center and a faculty office building. In addition to setting a new standard for public hospitals, the architecture of the campus stands alongside that of the city’s libraries and museums and creates a new civic icon with lush public spaces and sweeping cantilevers.

HOK | 94


The structural team made these dramatic spans possible with story

The trusses support loads from floors 4 through 12, yet occupy relatively little space along the building perimeter. The cantlievered building spans a maximum of depth trusses between levels 4 and 5.

60 feet, creating a human-scale approach to the soaring hospital wing.

95 | HOK


GRADY HEALTH SYSTEM

COR R E L L PAV I L I ON FO R ADVANCE D S URG I CAL SE RVI C E S Structural Engineering

HOK | 96


97 | HOK


GRADY HE ALTH SYST EM C ORRE LL PAVILION FOR A DVA NCED S URG I CAL S ERVI C ES Atlanta, Georgia 232,000 sq. ft. surgical center over 348,000 sq. ft. parking

Keen to increase capacity and separate patient care areas by discipline, Grady Health System (GHS), Atlanta’s central community provider and Level One Trauma center engaged HOK’s structural and architectural teams to construct a major outpatient services center downtown. The Correll Pavilion is a new, free-standing ambulatory surgery and clinic center adjacent to GHS Main campus connected to the main hospital by a new pedestrian bridge. The state-of-the-art facility includes four levels of reinforced concrete outpatient medical facility and a mechanical penthouse above four levels of PT parking structure providing

The key structural features include an aggressive double cantilever at the main entry, enabling programmatic requirements and shading entrants to the lobby. Long-span girders of the parking structure support col600 parking spaces, and ground-level clinical space.

umns from the patient facility above, allowing a grid system change at level 5. HOK Structures frequently addresses the challenge of placing vibration-sensitive healthcare programming above parking and acheives it through a level of stiff transfer girders. The medical facility is designed to supply specific vibration performance to suit the intended use and equipment requirements of each floor, including operating rooms, imaging, and MRI rooms. The lateral system features a mix of concrete shear walls and moment frames to efficiently control drift while maintaining open space within the facility.

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99 | HOK


DUKE RALEIGH Structural Engineering

HOK | 100

BE D TOWE R


101 | HOK


D UKE RALE I GH B ED TOW ER Raleigh, North Carolina 202,000 sq. ft.

In the interest of modernizing and expanding the hospital’s services, Duke Health engaged HOK to design an addition that was both accessible to the public and integrated with the existing facility. The design covers 202,000 square feet of hospital space, including a bed tower addition and a 27,000 square foot operating wing. Nestled between the existing hospital and a medical office building, the layout of the new facility corresponds to the challenges involved in fitting the new structure onto a site with limited space availability.

New bed tower inserted amongst several existing facilities New operating wing, loading dock and additional patient entry

Expansion joints at existing structure interfaces Adjacent facilities operational during construction

Significant grade variation, underpinning at existing medical office building New connector to existing facility New feature entry with canopy

HOK | 102


Moment frames are the primary lateral force resisting system utilized to resist the seismic requirements of the area and critical nature of the facility. HOK engaged SidePlate for moment frame connections that saved interior space for programmatic flexibility and reduced erection time in the field. This system also helped limit deflections which minimized expansion joint sizes between the new and existing hospital buildings, key in maintaining smooth, wheel-friendly hallways. The structure of the South Pavilion includes provisions for construction of a future helipad at the roof. The design of the floors of the bed tower and OR are designed to minimize vibrations due to

occupancy and footfall. The project scope also includes the design of a new Central Energy Plant, replacing the existing, outdated system. HOK preemptively tackled design challenges by proactive coordination with in-house architectural design, early engagement with multiple disciplines, and an emphasis on precise BIM modeling. These approaches encouraged communication between the Owner, Engineer, and Contractor, and assisted in reducing unanticipated conditions in the field.

103 | HOK


HOK | 104


JU S T I C E 105 | HOK


JUSTICE HOK brings high-performance, integrated engineering solutions to the justice sector, with a focus on creating secure, sustainable and cost-effective facilities. Our team plans building systems that support security and safety, while integrating seamlessly with the architecture. We develop solutions that allow for maximum flexibility and enable effective planning for the future. Through application of high-performance engineering principles, we design with key objectives in mind — to support efficient operations, enhance the environment for occupants, reduce life cycle costs, incorporate sustainability and make the best use of the available budget. We design for a justice facility’s long service life and 24/7 operation with systems that are durable and efficient. We have also devised unique solutions for system maintenance areas to accommodate stringent security requirements. Our approach begins with a focus on client interaction to determine their requirements. We develop detailed design criteria accordingly to bring into the design process. Our design documents not only convey how to build the system but also tells the contractors about security procedures that affect their labor budget. Fear of the unknown in a bid process translates to money. Fully defining the process removes the unknown and thus unnecessary cost. Our team of designers has over 80 years of experience with security automation system design and we bring that experience to each new design opportunity. For the past 40 years, the mechanical and electrical services to each room in a correctional facility would come through a small triangular chase at the entryway accessed from within the housing unit. After Sheriffs and County maintenance staff raised security and operational concerns, HOK devised the rear chase, locating it outside the secure perimeter. The “horizontal service chase” concept creates service corridors behind the cells that are used to access ductwork, plumbing and electrical systems without entering the secure housing unit.

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SELECT CLIENTS

2013

Arnason Justice Center AIA Architecture for Justice Excellence Award

• Montgomery County, Ohio • Marion County, Indiana

Multiple AIA Justice Facilities Review Award Winners

• Bedrock Detroit • City of Indianapolis • County of San Mateo, California • Douglas County, Colorado • Hamilton County, Tennessee • Village of Oswego • Stanislaus County, California • Hays County, Texas • State of Utah • Pasco County, Florida

”HOK staff have ensured our needs have been met as we have moved through the construction process. They spent time talking and listening

to us from the start so they understood what we wanted and needed.. Through the process we have been in contact with them on a regular basis and never once have we got the impression we were a bother.” -Steve Turley, Division Director Institutional Operations, State of Utah

ENGINEERING SERVICES • Structural Engineering • Energy Modeling and Analysis • Façade Design • Security Consulting Design

PROJECT TYPES

• IT Electronics Systems Design

• Courthouses

• Sheriff Offices

• Mechanical Engineering

• Emergency Operations Centers

• Law Enforcement Facilities

• Electrical Engineering

• Forensic Labs

• Plumbing and Fire Protection

• Law Enforcement Offices

• Sustainability

• Correctional Facilities

107 | HOK


RI CHARD E. ARNASON JUS T I CE C E N T ER Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

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109 | HOK


RI C HARD E . AR NASON JUST ICE CE N TER Pittsburg, California 71,600 sq. ft.

This new courthouse building serves as a gateway to an emerging civic center in Pittsburg’s central business district. The daylit building was recognized in the AIA’s Justice Facilities Review 2013 which priased “the building’s warmth, sense of openness and the use of natural light throughout.” Sustainable features include extensive natural light and a green roof system that helps reduce runoff and cool the building. The new facility exceeds Title 24 energy use by 22.5% using energyefficient HVAC systems and high-efficiency lighting. Further, efficient plumbing fixtures reduced interior water use by 40%. The building is LEED Silver Certified. The building HVAC design employs the use of a built-up VAV system with frictionless compression chillers. The cooling tower uses chemical free water treatment. The courthouse also incorporates a full building automation system, with thermostats, CO2 sensors, occupancy sensors, and photo sensors to regulate the HVAC and electrical lighting demands. Building orientation, high performance glazing systems and shading devices all mitigate heat gain while maximizing natural light. Only energy-star-rated appliances were used in the building, and construction was completed in less than two years.

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111 | HOK


POT T ER COU NT Y DI STR ICT COURT B UILDING Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 112


Amarillo, Texas 145,000 sq. ft.

The mechanical systems in the Potter County District Court Building includes air cooled chilled water system, hot water heating system and multiple variable flow air handling systems.Design of building envelope and MEP systems were optimized to achieve high energy efficiency with favorable life cycle costing. Estimated site EUI (energy use intensity) is 37.0 kBtu/sf/yr, which is 20% more energy efficient compared to

the

adopted

2015

IECC energy code. High efficiency HVAC equipment are utilized, including high efficiency air cooled chillers and condensing boiler for both heating hot water and domestic water systems.

Hydronic distribution systems, including chilled water and heating hot water, are configured as variable primary flow pumping to reduce pumping energy. Airflow tracking is implemented on supply, return and exhaust air for all air handling systems to enhance building pressurization control. Demand control ventilation is applied in majority of spaces, including courtrooms, conference rooms and offices. Due the tornado hazard in this region, a safe room as defined by FEMA P-361 is required within the project. This safe room is strategically located in the record facility behind the court house. While the structural system of the main courthouse building is a structural steel frame with bracing frames, this one-story precast concrete record building is structurally separated from the courthouse. The exterior load-bearing precast panels comprise the lateral system for the one-story structure, and also serve as the hardened perimeter for the safe room.

113 | HOK


SAN M ATE O COUNT Y SHER IFF’S FO REN S I C S L A BO RATO RY AND CORONER ’S OFF I C E San Mateo, California 29,000 sq. ft. Mechanical Engineering Electrical Engineering

HOK | 114


In this one-story building, HOK designed a “living lab” for sustainability that set new performance standards for forensics laboratories. All regularly occupied areas of the building are daylit, and office areas have operable windows. The orientation of the building, large roof overhangs, north-facing clerestory windows, and canted windows on the southwest reduce glare while maximizing daylight. All the mechanical and electrical systems are exposed, making them easier to maintain. The sloped roof houses 1,418 rooftop-mounted, polycristalline silicon photovoltaic (PV) panels over an area of 22,000 SF. The team modeled energy use and peak loads at 50% less than California energy requirements. With a peak output of 202 kilowatts, the 22,000 square feet of photovoltaic panels produce enough power to accommodate all non-HVAC electrical requirements and to export energy back to the grid during offpeak daylight hours. In addition to the photovoltaic system, it features architectural sun control; daylight harvesting and advanced lighting controls with occupancy sensors and photocells (very little artificial lighting is necessary during the day); natural ventilation via operable windows in office areas; energy-efficient fume hoods and HVAC systems; and sustainable building materials such as lab casework made of certified wood with epoxy resin tops.

115 | HOK


WAY N E CO U N TY CONSOLIDAT ED J USTI CE FACI LIT Y Detroit, Michigan 1.1M sq. ft. Structural Engineering Mechanical Engineering Electrical Engineering IT & ES Design and Security Consulting Plumbing Engineering and Fire Protection Facade Design

The Wayne County Courthouse and justice complex is heated and cooled by chilled and heating water that are generated by an on-site HOKengineered Central Utility Plant (CUP) that is partially funded and operated by DTE Energy. Although the client did not pursue LEED certification, HOK incorporated many of its historically proven low-cost MEP design ideas to improve energy efficiency and occupancy comfort. Large outdoor custom air-handling units with walk-in vestibules, integrated controls, and piping are positioned on the roof of each building and are designed to automatically respond and adjust to demands for HVAC that result in optimum energy savings. Total energy wheels were used on some systems to recover energy from exhaust, pre-conditioning incoming outdoor air. Multiple structural systems were used for the six different buildings on this site. Four of the six buildings were constructed of composite steel floor framing supported on steel columns and two were constructed entirely of structural precast elements. The lateral systems consisted of braced frames, precast shear walls, or masonry shear walls. All buildings were supported on a shallow foundation system which consists of isolated and combined footings. There existed a weaker underlying layer of soil which required careful consideration for the more heavily loaded structures in order to not overload this layer, limiting settlement of soil under sustained loading. HOK’s Security and Technology team designed a security automation system, information transport system, court technology and audio visual systems including an IPTV distribution system. These modules are daisy chained with a single Cat 6 cable in groups of 8. This approach helped save the project millions of dollars in conduit infrastructure cost associated with the traditional approach of routing each device to an equipment room.

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117 | HOK


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S C IE N CE + T E C H N O LO GY 119 | HOK


SCIENCE + TECHNOLOGY HOK’s multidisciplinary engineering team’s cutting edge research and high performance designs foster, efficiency, reliability, maintainability and flexibility for changing program needs. HOK brings high-performance engineering solutions to the design of science, research and technology environments for academic, corporate, government and other clients. Through our collaborative approach, we develop solutions to meet the hi-tech requirements unique to the research environment — from ventilation and air flow to specialized fume hoods to alternative heating and cooling systems to data technology solutions. We work with our clients to create right-size systems for their specific needs, focusing on sufficient and reliable power, while maximizing energy efficiency. Through plumbing design, we provide for specialty gases and high purity water design. In addition, our deep understanding of IT, security and other electronic systems enables us to design technology infrastructure and systems that support current, emerging and anticipated future business needs. Structural solutions address vibration control for research spaces and specialty equipment, seismic design, as well as detailing for interior collaboration and public spaces. HOK has extensive experience in the design and optimization of new and existing laboratory and research facilities for project-specific vibration criteria. We use finite element models and modal analysis in tandem with traditional prescriptive methods in order to more accurately determine vibration performance and optimize for it. HOK has also developed STREAM, a proprietary parametric tool that links architectural design options with engineering analysis software. It allows us to rapidly generate and analyze a large number of design options, including area-specific velocity and acceleration limits.

HOK | 120


SELECT CLIENTS • Emory University • BP • Stanford Univeristy

2M ⁺ sq. ft.

LEED Platinum Science + Technology facilities designed by HOK Engineering

50M⁺

Science + Technology space programmed, planned and designed by HOK in the past 10 years

• Rice University • Colgate Palmolive • AstraZeneca • King Abdullah University of Science and Technology

sq. ft.

• University of California - Davis • State University of New York • Georgia Board of Regents • The Pennsylvania State University

ENGINEERING SERVICES

PROJECT TYPES

• Structural Engineering

• Academic Research Facilities

• Pharmaceutical + Biotech

• Energy Modeling and Analysis

• Allied Health Facilities

• Plant + Agricultural Sciences

• Façade Design

• Alternative Energy Research

• Public Health Research

• Audio Visual & Public Address

• Biomedical Research

• Research + Development

• IT Electronics Systems + Security

• Engineering + Physical Sciences

• Science Facility Renovations

• Mechanical Engineering

• Higher Education Science

• STEM Education Facilities

• Electrical Engineering

• Interdisciplinary Research

• Translational Research

• Plumbing and Fire Protection

• Medical Education

• Staging and Phasing

• High-Performance Computing

121 | HOK


ASTRAZENECA

SOUTH SAN FRANCI SCO L A B Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 122


123 | HOK


AST RAZE N E CA SOUTH SA N F RAN CISCO LAB San Francisco, California 145,000 sq. ft.

The Astra Zeneca lab renovation project required the installation of the abatement system for the exhaust treatment of effluent gases in the pharmaceutical processes to meet high environmental standards. The abatement system as well as other equipment and lab uses required a large volume of liquid nitrogen and the existing facility infrastructure was not adequate to support all new loads. The challenge was supporting all lab equipment in a small existing mechanical room and service yard. The design team looked into multiple options such as a nitrogen cylinder/dewar farm, nitrogen generator, reduced abatement running time, and bulk liquid nitrogen (LN2) tank. Per the team’s calculations, bulk LN2 was the most feasible but the challenge was where to house the tank, ultimately solved by an outbuilding the size of a couple parking spots. Additional electrical and mechanical building infrastructure upgrades were undertaken to support the project operational requirements. The shell building standby generator fuel tanks were enlarged and the standby power circuiting was augmented to allow the laboratory spaces to operate for days without interruption. Through intelligent space planning and HVAC design, the shell building heating and cooling plant, air handling

Minor piping and ductwork interconnections provide N+1 redundancy for all of the major mechanical systems at minimal additional cost to the project. units, and laboratory exhaust fans were reconfigured.

HOK | 124


125 | HOK


BP HIGH PERFORMANCE CO MPU T I N G C EN T ER Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 126


127 | HOK


BP HI GH PE RFOR MA NCE COMP UTI N G C EN TE R Houston, Texas 110,000 sq. ft.

HOK was commissioned to design and engineer a new High-Performance Computing (HPC) facility at BP’s west Houston campus. The three-story, stand-alone building housing all functions and equipment associated with state-of-the-art HPC technology requirements, including “the world’s largest supercomputer for commercial research” and global operations offices spaces. The fully glazed, undulating north facade captures attention while welcoming visitors with an approachable scale. Servers and mechanical systems are oriented to the south and encased in the opaque, precast concrete shell.

Optimal solar orientation and highperformance mechanical and electrical systems provide a power usage effectiveness (PUE) well below the typical data center average. When an The fully glazed office spaces are located to the north.

ideal power usage effectiveness (PUE) is 1.0, typical data centers average is 1.8. Yet, the facility reached a remarkable PUE of 1.35 of the total energy.

Designed to resist winds of up to 130 mph, the facade is the building’s first line of defense. Inside, reinforced CMU walls define the data center and protect the computers. Computing spaces are equipped with a steeper roof slope, ensuring that water drains away from the equipment. In the case of a water outage, an underground reservoir can assist with cooling the space and equipment.

HOK | 128


129 | HOK


EMORY UNIVERSITY HSRB II Structural Engineering HOK | 130


131 | HOK


E M ORY U N IVE RSITY H EALTH SCIE NCE R ESEA RCH B UIL D I N G H RS B - I I Atlanta, Georgia 350,000 sq. ft.

This new biomedical research facility includes office and laboratory space for translational researchers in neuroscience and cancer research, amongst other disciplines. The project has high sustainability goals, and interfaces with an existing facility with tight floorto-floor spacing that might have made achieving those goals a challenge due to limited space for intra-floor services required to achieve high energy efficiency

HOK’s Structural team helped lead integrated design strategies to address this and other key challenges such as providing a 5-10% embodied carbon reduction. targets.

HOK | 132


The floor framing system is designed to meet tight vibration limits in several laboratory areas. The structural team led a series of multi-parameter optimization studies to arrive at the appropriate balance of structural depth, services depth, location-specific vibration performance that met the project goals within the floor-to-floor height limitation.

The structural team proposed a system that addressed a fundamental challenge at the beginning of design: the project included three large programmatic elements which required different column arrangements. The structural and architecture teams worked together to streamline the program and structure such that the building could employ a single transfer level with a framing layout optimized for both constructability and minimal depth.

The design includes several feature structural elements in the large six-story central atrium, including dual sculpted pedestrian bridges, a multi-tiered cantilever stair, and a prominent full-height façade supported by a concealed truss at roof level.

133 | HOK


KI NG ABDULLAH UNIVERSITY S CI E NC E AN D T E C H NO LO GY Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

HOK | 134

OF


135 | HOK


KI NG ABDU LLAH UNIV ER SIT Y OF SC I E N CE AN D T ECHNOLOGY ( K AUS T) Thuwal, Saudi Arabia 5.5M sq. ft.

The largest LEED-Platinum project in the world at the time it was built, KAUST was delivered by HOK design and engineering teams in just three years.

King Abdullah University of Science and Technology’s (KAUST) is a highly acclaimed world class research university located on the Red Sea coast in Thuwal, Saudi Arabia. It was born from the late King Abdullah’s vision and is a lasting legacy. KAUST consists of 27 buildings totaling 5.5 million square feet, including two million square feet of lab space spread across four 500,000 square foot buildings. Despite the many challenges of building the campus in Saudi Arabia’s harsh climate, KAUST became the world’s largest LEED Platinum project at the time of its certification and was able to realize substantial reductions in water and energy use. The engineering team integrated many passive design solutions combined with numerous innovative engineering strategies for energy-efficient MEP systems, such as: chilled beams, total energy recovery wheels, underfloor air distribution, smart lighting controls, variable frequency drives and low-friction loss duct and piped design.

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The highly reconfigurable state-of-the-art lab spaces provided by the mechanical team garnered R&D Magazine’s Lab of the Year in 2011. R&D Magazine noted that the campus “contains just about every modern lab concept known today.” This includes interchangeable lab neighborhoods, flexible lab support zones, grid planning, kit-of-parts furniture and MEP, walkable interstitial space, collaboration spaces, large circulation spines, high-height pilot areas, lab daylighting and of course the engineering infrastructure to allow this unprecedented level of flexibility. Further, HOK mechanical worked with KAUST reserchers to deliver a solar-powered desalination pilot plant and continue to provide the university with engineering services when needed to support their ever-evolving cutting edge research.

1 Passive ventilation 2 Local evaporative cooling 3 Recycled condensate 4 High-performance glazing 5 Integrated shading

6 Reflective roofing 7 Rainwater collection 8 PV and solar thermal panels 9 Filtered daylighting

Vast arrays consisting of thousands of solar PV and solar thermal panels cover the innovative roof system, which spans across buildings to block the sun on facades while sheltering outdoor pedestrian spaces. Solar PV harvests nearly 8 percent of the total estimated energy consumption. Highly interactive direct digital controls optimize MEP system operation while continuously monitoring and reporting system performance, energy harvested, energy recovered, and energy used to ensure long term energy management.

137 | HOK


KAU ST

One of the most significant project challenges of the $15B project was the extremely aggressive schedule: only 3 years to design and construct. HOK’s MEP and structural engineers rose to the challenge by leading multiple engineering design teams consisting of hundreds of engineers from multiple HOK offices and outside consulting engineering firms on parallel design paths while at the same time working closely with the construction team to deliver early packages for fast track construction.

The structural design included drilling 42,000 stone columns into the ground to ensure the soil could support the weight of the buildings.

HOK | 138


On the western end of the four lab buildings, concrete trusses create a 55-foot cantilever. Several other buildings incorporate shear walls for smaller cantilevers.

139 | HOK


RI C E U N IVE RSIT Y SPACE SCI E N CE A ND T ECHNOLOGY B UI L D I N G Houston, Texas 75,000 sq. ft. Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

This project included a total replacement of the mechanical, electrical, plumbing, communications, audiovisual and security systems to modernize the Space Science and Technology Building to 21st century standards. The lab space was designed to be modular and easily adaptable for changing research needs by using modular utility connections and building in functionality to reconfigure utilities such as exhausts where required.

Locating the cleanroom in the basement posed its own set of unique challenges due to limited floor to floor height, vibration, and noise mitigation due to the cleanroom’s adjacency to the main mechanical room. The design allowed routing of utilities from the basement to the roof for proper exhaust and connecting the cleanroom to the campus and building chilled, heating and steam systems while maintaining the required N+1 redundancy to keep the cleanroom operational. HOK’s electrical engineers and interior designers teamed to provide an average lighting power density of 0.4 watts per square foot by using high efficiency LED lighting throughout the building. Setting targets far beyond the code, this achieved a lighting power density less than half that allowed by ASHRAE-90.1-2013.

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Compartmented laser laboratory

The next generation of nano-molecular and biological researches rely heavily on experimentation with lasers to split particles. The laser laboratories required temperature control within 0.5 degrees F, and humidity control within 5 percent relative humidity. HOK was able to provide the tight tolerances required by the researchers by using localized, dedicated air handling equipment.

141 | HOK


HOK | 142


STANFORD CENTER FOR ACADEMIC MEDICINE Structural Engineering Mechanical Engineering Electrical Engineering Plumbing and Fire Protection

143 | HOK


STA N FO RD CENT ER FOR ACA DEM I C MED I C I N E Stanford, California 170,000 sq. ft.

The Stanford School of Medicine’s clinical faculty and staff did not have an office space away from the hospital where they could come together to work and collaborate with colleagues, so HOK designed a new building to allow those chance encounters and cross-pollination of ideas to flourish. The large volume glass lobby was provided with a radiant cooled and heated floor for enhanced comfort and energy savings. The initial aspiration was that the center be an entirely naturally ventilated space. A multitude of mechanical systems were evaluated using a Life Cycle Cost Analysis including natural ventilation, solar chimneys, radiant systems and high volume low speed (HVLS) ceiling fans which would make this possible. While concerns regarding pest control in the wooded surroundings ultimately led the client away from 100% natural ventilation, the very high efficiency of the Stanford central energy facility allowed a traditional VAV system to provide the overall best life cycle cost assessment. The large volume glass lobby was delivered with a radiant cooled and heated floor for enhanced comfort and energy savings and AHUs were selected with low face velocities to provide fan energy savings.

HOK | 144


Solar PV & Solar Thermal

Rainwater collection Energy Recovery

Green roofs

Radiant slabs vs. UFAD Passive ventilation

Biophilic design

Evaporative cooling

Stormwater Collection & Treatment

Irrigation

Thermal massing

145 | HOK


STA N FO RD CENT ER FOR ACA DE M IC M EDICINE

Several significant structural elements were utilized to create the dramatic approach to the building. Four steel trusses at the roof cantilever out to support the floors below creating a dramatic column free overhang at the entrance corner of the building. The terrace suspended from the trusses offers sweeping views of the hills beyond campus. At the ends of the building wings facing the arboretum, the terraces are cantilevered to allow column-free views. The exterior corridor along one wing of the building is hung from the roof to allow more column-free space at the courtyard adjacent to the auditorium. Two pedestrian bridges link the narrow wings of the building, one hung from the structure above the other rising up out of the landscaped plaza. The bridges allow the narrow building wings to embrace courtyards, while connecting the building occupants to one another. The building provides diverse settings for collaboration near the woods and in plazas, balconies, walkways, porches and terraces. The heavily landscaped plaza conceals a 3-story below-grade parking garage under the building and courtyards. Buckling restrained braced frames comprised the above grade building lateral force resisting system and concrete shear walls in the parking garage portion of the building. The building is designed to meet Stanford’s Seismic Design Guidelines and reviewed via their Peer Review process. A nonlinear analysis was performed to demonstrate the building seismic performance.

HOK | 146


147 | HOK


HOK | 148


UNIVERSITY OF GEORGIA I N T E R D I S C I P L I N A RY STE M RES E A RC H BU I L D I N G Structural Engineering Structural Engineering

149 | HOK


U N I V E RSITY OF GEORGIA I NT E RDI SCI PL INA RY STEM R ESEA RC H B UI L D I N G Atlanta, Georgia 350,000 sq. ft.

The University of Georgia Interdisciplinary STEM research building brings Chemistry and Engineering together for a collaborative research experience. It is a four-story, 100,000 sq ft laboratory building over three floors of parking designed to accommodate a future four-story laboratory building. Specialty laboratory equipment in the facility includes mass spectrometry, electron microscopy, engineering instrumentation prototyping and system, and chemistry instrumentation and labs.

An extensive vibration study was performed to optimize the structural bay layout to allow the use of a concrete moment frame and eliminate any concrete shear walls that would intrude on laboratory and parking spaces. Close collaboration with the vibration consultant validated results and helped optimize the structure to reduce selfweight and material cost.

HOK | 150


To encourage collaboration within the space, a monumental communicating steel stair case connects Levels 2 and 3 and brings light into the core through a light well. Between Phase 1 and Phase 2 laboratory buildings, a multi-story connector structure is anticipated to bridge between the East and West laboratories and contain additional teamwork space.

HOK has extensive experience in the design of structural laboratory facilities, including optimization of the structures’ vibration and natural frequency to meet stringent user requirements while reducing construction cost.

The structural group often designs for future use scenarios to accommodate potential expansion and growth options. The successful collaboration of both of these elements allowed the delivery of a Phase 1 parking garage and laboratory that can readily accommodate the Phase 2 laboratory and connector.

151 | HOK


U N I V E RSITY OF CA LIFOR NIA DAV IS VE T E RIN ARY MEDICINE R ESEA RCH FAC I L I TY Davis, California 118,000 sq. ft.

As laboratory space is typically an energy-intensive use-type, the engineering and architecture team saw this as an opportunity to design labs that minimized mechanical energy use and maximized day-lighting. Individual offi ces have smart HVAC controls that shuts off ventilation and water to radiant panels when it senses that a window is open. CFD and lighting analysis was used to determine overhead radiant panel location for both occupant comfort and offi ce daylighting. A centralized stair with operable penthouse louvers provides natural ventilation at the ground floor lobby. The stack effect fostered allows hot air from the lobby to rise and escape through the roof, drawing in colder air from orifices below to ventilate the lobby. On days when natural ventilation is not possible, the lobby can rely on efficient radiant floor heating and cooling.

HOK | 152


Campus chilled water and steam provides the heating and cooling for the rest of the building as well as steam for sterilization of lab equipment. Further, to save energy, offices and labs are each provided their own AHUs. The office AHUs serve chilled beams that are part of a two-pipe changeover system. The labs are also served by chilled beams, however these AHUs contain a run-around coil to pre-heat/pre-cool outside air to reduce energy cost with the added benefit of delivering 100% fresh outside air to the occupants. Level 4 houses a BSL-3 lab with dedicated exhaust fans that have been carefully selected to meet strict plume height requirements.

153 | HOK


@ 4240 L A BORATORY AND OFF I C E BU I L D I N G Structural Engineering

HOK | 154


183,000 sq. ft. St. Louis, Missouri Housing nearly 500 high-tech jobs, @4240 anchors the Cortex Innovation Community, an urban research district in midtown St. Louis. HOK redesigned the three-story building, providing large floor plates and highly adaptable mechanical systems to support tenants ranging from small startups to established research organizations. HOK’s design for the LEED Platinumcertified project includes extensive use of renewable building materials and energy efficient measures, including a 50kV photovoltaic array. The team worked within historic guidelines to restore the building’s deteriorating brick facade and upgrade the industrial windows with historically accurate, insulated replacement glazing.

When the best new building is no new building: the structural team delivered a LEED-Platinum urban-revival research district via adaptive reuse of a 1948 factory The structural group cut expansive floor openings along the middle of the building allow skylights to illuminate lab and work spaces across floors as well as an interior courtyard. The team engineered a cantilevering multi-story connecting stair and exterior canopy.

155 | HOK


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SPORTS + R E C R E AT I O N + ENT E RTAI N M E N T 157 | HOK


SPORTS + RECREATION + ENTERTAINMENT HOK’s engineering team brings world-class experience and cutting-edge integrated design technology to create elegant and inspiring solutions. HOK’s award-winning engineering team has experience on a range of sports, recreation, and entertainment facilities. Using our expertise in multiple specialties, including the technology of building enclosures, we design for seismicity, security/blast, wind, energy performance and other factors. Our team has expertise in long-span structures and design for acoustic and vibration isolation. We have developed proprietary design technology, HOK STREAM, that dramatically enhances the design process, including optimization for vibration performance and minimizing cost. Fast Company cited our Engineering team’s work in recognizing HOK as one of its Most Innovative Design Companies. With our development and advanced use of STREAM and other proprietary design tools, we work as part of an integrated team to deliver creative options and optimized structures, which save substantial amounts of construction time and cost, as well as delivering better buildings for HOK’s clients.

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SELECT CLIENTS

Excellence in Structural Engineering Most Outstanding Project: Mercedes-Benz Halo

• Allied eSports • Atlanta Falcons • Atlanta Hawks • Chicago Bears • City of Houston

Most Innovative Design Firm

• Emory University • Equinox Fitness • Ohio State University • St. Louis City SC

”The success of the Chicago Bears

• University of California System

Halas Hall Addition and Renovation was the result of a true partnership

ENGINEERING SERVICES

Having HOK’s structural engineering group as part of the team proved invaluable to the project." between HOK and Mortenson.

• Structural Engineering • Energy Modeling and Analysis • Façade Design

• IT and Electronics Systems and Security Systems

Laura Sables Leber

• Mechanical Engineering

Director of Design Phase Management Mortenson

• Electrical Engineering • Plumbing and Fire Protection Design

PROJECT TYPES

• Arenas • Entertainment Venues + Districts • Mixed-use Developments

• Training + Practice Facilities • Vibration and Noise Isolation

• Recreation + Wellness Facilities

• eSports Venues

• Special Structures

• Athletic Facility Renovations

159 | HOK


MAJOR LEAGUE SOCCER S T. LO U I S S TA D I U M

Structural Engineering

HOK | 160


161 | HOK


ST. LO U I S MA JOR LEAGUE SOC C E R S TADI UM St. Louis, Missouri 22,500 seats

A major part of St. Louis’ excitement about their new team and 22,500-seat stadium is its location in Downtown West. This urban site presented numerous challenges, including access constraints, varying perimeter retaining wall conditions, and relatively high seismic design parameters. The design intent is to have a clean, transparent structure that is as open to the surrounding community as possible. Perimeter braced frames, which are typically seen in large, long-span structures would have conflicted with this need. HOK’s engineering team therefore designed the stadium in a way that made the stadium’s lateral system effectively disappear.

HOK | 162


The 120’-wide canopy structure

Although the canopy profile is rela-

HOK engineered all connections

is supported by circular columns

tively uniform around all four sides,

on the project, often implementing

spaced only 25’ apart. This system

the supporting conditions below vary

finite element models to optimize

provides stability for the canopy

substantially due to varying program.

key conditions, and worked closely

by relying on a combination of

The engineering team worked intensely

with the CM team on preferences and

moment frame action and the

with the architectural team to optimize

implementation, from design through

inherent rigidity of the precast

spatial efficiency.

construction.

seating bowl.

163 | HOK


MERCEDES BENZ S TAD I UM HALO Structural Engineering

HOK | 164


165 | HOK


M ERCE DE S BENZ STA DIUM HA LO Atlanta, Georgia 71,000 seats At 56 feet tall and 1,100 feet in circumference, the Halo is the largest video

scoreboard

in

the

United

States. Named an NCSEA “Most Outstanding Project”, the Halo board support structure contains as much steel as a 150,000 square foot office building, and is supported by a long span roof structure that expands and contracts by several inches under service load conditions. The structure needed to support the loads from the video board, while not weighing more than 550 tons, remain isolated from the differential movement

of

the

primary

roof

structure to which it connected at 200 points. The data points associated with the support locations ran into the hundreds of thousands, and the time available for design and documentation was only two months

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The Halo supports were required to align within 1”

The structural team created a parametric model to optimize

upon completion of construction to acheive video

the geometry, members and generate the Revit model. This

system tolerances. Thus the connections were

process accelerated the design period by a factor of three and

designed such that they could be flipped in order

allowed for modifications to key dimensions midway through

to align with various potential field conditions. The

the design process; changes that would have typically caused

structural team also created a custom survey data

a multi-week delay were fully accommodated within hours.

visualization tool to quickly evaluate vast amounts of survey data from the field during construction.

167 | HOK


AT LA N TA H AWKS AND E MO RY H EALT H CA RE

SPORTS MED ICINE COMPLEX Structural Engineering

HOK | 168


169 | HOK


AT L ANTA HAW KS A ND E M ORY SPO RTS MEDICINE COMPL E X Atlanta, Georgia 90,000 sq. ft. Winner of the Engineering News Record Southeast Award of Merit, the 90,000 sq. ft. Atlanta Hawks Practice Facility and Emory Sports Medicine Complex is an unprecedented building typology. The Hawks’ new practice facility is the NBA’s first to be located within a sports medicine center allowing for immediate treatment and on-site access to high-tech equipment such as the 3 Tesla MRI scanner, which provides fast, high quality diagnoses for soft tissue and bone bruise injuries.

A core of concentric braced frames frees up the building perimeter for expansive glazing, allowing natural light to filter through the complex. The training facility includes customized structure for therapy pools, video rooms, and the central practice courts. The medical facilities feature equipment specific vibration design, including an MRI machine room located on the second floor and supported by structural steel framing.

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“We were able to deliver a world-class training facility weeks ahead of schedule and 2% under budget.” Thad Sheely Chief Operating Officer, Atlanta Hawks

Located just outside of downtown Atlanta in Brookhaven, the facility was designed and constructed in less than 24 months. HOK’s structural engineering team provided phased deliverables with weekly packages issued for steel and concrete trades. The coordination of the structural deliverables with the field schedule allowed the fast-track delivery of the foundations and building structure to keep the project on schedule.

171 | HOK


HALAS HALL EXPANSION CH I CAG O BEARS

Structural Engineering

HOK | 172


173 | HOK


C HI CAG O B EA RS H ALAS HALL EX PA NSION Chicago, Illinois 195,000 sq. ft.

HOK | 174


HOK’s structural design accommodates specialty training equipment including hydrotherapy pools, a three-story, vibrationally isolated weight room, an indoor turf classroom, elevated outdoor patios, and custom exposed steel trusses and canopies. The existing facility renovation includes enclosing two elevated outdoor patios, installing an elevator, and a 28’x5’ feature video board. The additional space also includes a learning center for staff training and professional development, a nutrition center, an expanded sports medicine space, a helmet-fitting room, and wellness rooms. HOK collaborated closely with the specialty equipment manufacturers and MEP to meet strict produc-driven t vibration and deflection requirements.

Through a close collaboration between HOK and Mortenson, in August 2019 the Chicago Bears expanded their existing training facility, Halas Hall, with a 165,000 ft2 addition, and a 30,000 ft2 renovation. The addition consists of a partial floor basement, with cantilevered concrete retaining walls, and up to four levels of elevated steel framing. The addition connects to the existing structure on two floors.

Constructed in only 17 months, the HOK structural team worked closely with Mortenson to identify critical submittals and hot RFIs to keep the project on schedule.

175 | HOK


LE VI NE FR I CKE SOFTBA LL FACIL I T Y University of California, Berkeley 11,000 sq. ft. / 1,525 seats

HOK’s structural team was tasked with providing a new facility for the UC Berkeley Womens Softball team a mere 800 feet away from the Hayward fault. The Levine Fricke stadium will enclose approximately 11,000 square feet and have 1,525 seats. HOK’s integrated architecture, structural engineering, and landscape design services proved key in delivering a seismically-resilient and functional stadium design.

The site in Strawberry Canyon is tightly constrained, which requires inserting the building program and batting cages beneath the concourse and seating. The structure consists of a steel gravity frame and concrete shear walls. Long span girders over the batting cage area were design to provide enough space to have infield practice indoors during inclement weather. Due to the proximity of the project site to the Hayward Fault, the structure has been reviewed by the University Seismic Review Committee.

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Accommodating all components of the site program required pushing the building in to the hillside which necessitates excavation at one end. The team designed a permanent, tiedback shoring wall to solve the retention challenge and save cost. Additionally, the site soils are undocumented fill, which required deep drilled piers which rest upon bedrock. Lastly, the “Big Inch” culvert runs under the site which provides drainage for the uphill portion of the canyon and requires spanning the foundation over the culvert to not disturb its flow. The result is a scenic stadium which belies its hard-working structural system of concrete shear walls managing multiple environmental challenges at once.

Concrete shear wall analysis, stress contours

177 | HOK


U N I VE RSI TY OF CA LIFOR NIA MERC ED WE LLN E SS CENT ER Merced, California 31,000 sq. ft.

It is a compact two-story structure that joins the Aquatic center locker room facility with a Sports Medicine program. Several structural systems were considered in conjunction with input from the P3 consortium for which the HOK structural group conducted a thorough cost comparison.

The UC Merced wellness center was part of a forward-thinking P3 development that doubles the built space of the UC Merced campus. HOK worked closely with the univeristy to provide a design tailored to the needs of the institution and student body. These facilities included new athletics fields, competition aquatics center and Wellness building.

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Narrowing down the options to bucklingrestrained braces and special concentricallybraced frames, the structural team identified the latter as the most cost-effective while meeting the University Seismic Design Requirements. Due to the seismic demands of the site, the structural design was approved via the University Peer Review process.

179 | HOK


EQ U I N OX New York, New York Multiple projects

Seeking an architecturally-stimulating environment to house their new gym, Equinox engaged HOK to transform a Brooks Brothers warehouse into a gym, the Bond Equinox. The adaptive reuse project required significant structural input as the centrury-old wooded structure had seen extensive use. The structural group thoroughly examined the existing conditions, drawing attention to the distressed floor timbers. To restore the building and increase the floor’s load-carrying capacity the group designed aesthetically exposed steel plate reinforcement for the heavy timber joists. Further, to control vibration under exercise loading, the structural group put forth a system of neoprene pads under poured concrete which liminted the vibrations transmitted to the original wood floor structure below. Finally, a key structural element of a feature stair penetrates the floor plates and responds to the exposed, historic industrial aesthetic of the interior.

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HO K ST R E AM


03

The fut ure of b uild ing d e sig n is here

HOK STREAM optimization scripts accelerate the design process, saving time, materials, carbon emissions and cost

+

Optimization algorithms help explore hundreds of design possibilities in the first few weeks of a project

+

Standard engineering design processes are automated, accommodating unexpected design changes in hours, not weeks

+

Estimated material quantities during concept design often within 5% of as-built quantities

+

Complex architectural geometry is rationalized into elegant framing schemes, easy to fabricate, erect, and adjust in the field

183 | HOK


S T REA M

Av i a t ion + Tra nsp or t at ion

HOK structures’ STREAM parametric engineering workflow has revolutionized some of the country’s largest airports. STREAM embeds long-span deflection analysis and member selection into an automated optimization routine. For LaGuardia airport, the HOK competition team came to the paradigm-shifting conclusion that islands, not peninsulas, would dramatically increase efficiency and trim two years from the construction schedule, and the viability of the scheme hinged upon whether the bridges could work structurally, which needed to be determined within weeks.

HOK | 184


To answer, the HOK structural team developed custom parametric engineering algorithms to rapidly assess the feasibility of dozens of variations of the 450 ft-long bridge structures. An envelope of sight-lines from the existing control tower skims the surface of the proposed bridges, limiting their height, and the largest possible aircraft predicted to travel the taxiway below limits their depth. Optimization algorithms in HOK scripts used deflection performance to narrow the results, feeding into a finite-element vibration analysis model. The engineers were able to present the optimal design within weeks, both winning the competition and delivering unparalleled air-side efficiency. The accuracy of HOK’s STREAM parametric workflow resulted in as-built tonnage of Pedestrian Bridge B within 5% of the tonnage calculated during the competition phase.

185 | HOK


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In three weeks between hand-sketches and client acceptance of the design, parametric structural models optimized performance and minimized load applied to existing structures. During construction, the team’s animations and 3d prints conveyed the macro behavior of slide bearings during erection.

STRE A M

Aviat ion + Tran spor t at ion 187 | HOK


Aviat ion + Transpor t at ion

S TR E AM

WIth experience on two dozen airports, the HOK structural team has developed automated scripts to deliver complex, long span roof structures in a manner that simplifies construction. STREAM parametric scripts were essential to rationalize the complex roof geometry at the O’Hare Terminal 5 Expansion, reconciling it with a constrained column layout, into the most efficient framing scheme.

HOK | 188


Developed in-house, the scripts projected framing geometry onto faceted roof planes and relayed information between finite-element programs and custom optimization algorithms to minimize structural weight and simplify erection in the field.

189 | HOK


Sp o r t s + Rec reati o n

S TR E AM

HOK STREAM can shorten structural design processes from months to weeks, with scripts ranging from architectural bowl-builders, set up to solve common challenges at the outset of design, to structural design scripts which seek out the optimal design for challenging long-span conditions. Further, during construction administration, custom survey data visualization tools can quickly evaluate vast amounts of field data to identify issues and assist in any required adjustments.

As part of the incredibly fast design and construction process for the Atlanta Hawks’ new practice facility, HOK conducted a series of optimization studies for the long span roof trusses over the practice courts. This study included glulam options and helped the design and construction team quickly decide on a design that worked best for cost and schedule.

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The Video Halo Board at Mercedes-Benz Stadium is a unique structure designed and built using innovative technology at unprecedented speed. At 56 feet tall and 1,100 feet in circumference, it is the largest video scoreboard in the United States. HOK created a set of parametric scripts that automatically generated the structural geometry with respect to support nodes and their associated stiffnesses and movements, avoided hanger location conflicts with gusset, stair, and video board attachment locations, optimized steel members and generated the Revit model. This process accelerated the design period by a factor of three and allowed for modifications to key dimensions that occurred midway through the design: changes that would have typically caused a multi-week delay were fully accommodated within hours.

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HOK | 192

STRE AM E m b o d i e d + Ope ra t i o n a l C ar bo n


An integration of custom scripts developed by HOK structural, MEP and sustainability groups allows the minimization of carbon emissions associated with structural/facade materials (embodied) and those emitted by heating, cooling and lighting systems (operational). With design for strength, deflection, and climate control embedded in the parametric script alongside life-cycle impact assessment, the tool provides the client and design team a clear visualization of the path to net-zero embodied and operational carbon at concept design.

193 | HOK


HOK has extensive experience in the design and optimization of hospitals, surgical centers, and imaging facilities for project-specific vibration criteria. We use finite element models and modal analysis in tandem with traditional prescriptive methods in order to more accurately determine vibration performance and optimize for it. HOK STREAM is a proprietary parametric tool that links architectural design options with engineering analysis software. It allows us to rapidly generate and analyze a large number of design options, including area-specific velocity and acceleration limits. This allows for relative valuations of interdisciplinary design decisions, and accelerated design iterations based on those decisions: structural costs associated with any design option can be quickly evaluated to determine the option that best aligns with the project goals. STREAM is a substantial differentiator for HOK and our clients: we can develop more optimized solutions faster and more efficiently, including analysis and optimization for Embodied Carbon reduction. Fast Company cited HOK Engineering’s development and

ST REAM

H e a l t h c a re

implementation of STREAM in recognizing HOK as one of its Most Innovative Companies.

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Corridor


Operating rooms

Patient rooms

195 | HOK


HOK has extensive experience in the design and optimization of new and existing laboratory and research facilities for project-specific vibration criteria. We use finite element models and modal analysis in tandem with traditional prescriptive methods in order to more accurately determine vibration performance and optimize for it. HOK STREAM is a proprietary parametric tool that links architectural design options with engineering analysis software. It allows us to rapidly generate and analyze a large number of design

ST REAM

S c i e n c e + Te ch n o l o gy

options, including area-specific velocity and acceleration limits. This allows for relative

HOK | 196

valuations of interdisciplinary design decisions, and accelerated design iterations based on those decisions: structural costs associated with any design option can be quickly evaluated to determine the option that best aligns with the project goals. STREAM is a substantial differentiator for HOK and our clients: we can develop more optimized solutions faster and more efficiently, including analysis and optimization for Embodied Carbon reduction. Fast Company cited HOK Engineering’s development and implementation of STREAM in recognizing HOK as one of its Most Innovative Companies.

Corridor


Offices

Lab space Vibration criteria VC-A

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SER VI C E S AN D SPE C I ALT I E S

HOK | 198


04

A few of our favor it e t hing s

+HOK’s Engineering team has experience on a wide array of diverse topics, many of which are included in this section. From pedestrian bridges to passive optical networks, from design competitions to displacement ventilation… please reach out if you’re interested to learn more.

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SPECIALTIES Energy modeling

Energy modeling is an interdisciplinary effort at HOK, requiring close collaboration between the sustainability, MEP, facade design, and structural teams. The process starts at the macro-scale to determine orientation and form for passive climate control and becomes more detailed when MEP system selection, facade condensation analysis and thermal bridging studies come to the forefront during schematic design and design development.

HOK | 200


87% wind ow-to-

50% window-to-

87% window-to-wall

wall ratio, Royal

wall ratio (WWR)

ratio + extended slab

Caribbean HQ

edges = energy performance of 50% WWR

201 | HOK


Embodied carbon is CO 2 emitted by raw materials extraction, materials processing, constructi on, repair, and endof-service life (landfill, re-use

S P E C I ALT I ES Li fe- c ycl e a na lysis

or recycling) scenarios.

HOK | 202

Unlike operational carbon associated with heating, cooling and lighting, embodied carbon is emitted almost entirely at the beginning of a building project. Quantifying these emissions informs design decisions, resulting in a lower carbon footprint at each stage of the design process.

Cement replacements, sourcing local materials, and multipurpose structural systems are key components of the carbon reduction process. While 5%-10% reductions will earn the project additional LEED credits, HOK aims much higher, making net-zero embodied carbon within reach.


Transport

You ca n o n ly imp rove wh a t you me a sure

End of use

U n ders ta n d em bo died CO 2 by

As a signatory to the SE 2050 challenge targeting

life-c yc le s ta ge

net-zero structura l carbon emissions by 2050, HOK structures quantifies the embodied emissions of every building project’s structure and enclosure by conducting Whole Building Life Cycle Assessment (WBLCA). This allows clients and designers to make informed design decisions which minimize building embodied carbon over the course of the design process.

Pinpoint sources of CO 2 emissions by building system...

Materials

Repair

...and by material Polymers

Windows

Glass

Slabs

Exterior walls

Shallow foundations

Steel

Concrete

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N et - ze ro a nd LE E D Pl a t i num

S PECI A LTI E S HOK | 204

To achieve a Net Zero Energy Building, HOK has developed the 6-Step process to Integrated Performance Design: Discovery & Definition – Our process kicks-off with a sustainability charrette, where our integrated HOK team will work with you to define roles and responsibilities, set targets for energy, water and waste, identify energy benchmarks, Energy Use Intensity (EUI) targets, financial parameters and alternative financing solutions, and potential solutions and incentives for the project. Climate & Place – The next step is to perform a site and climate analysis for the site to understand external loads, resources and challenges. The analysis should look at topography, geology, biology, and hydrology in addition to context clues, such as cultural norms and systems that are geographically appropriate. The design team will look for opportunities to harvest free water and energy from the site, including rainwater, condensate, natural ventilation, passive solar heating and convection. Load Reduction – The most cost-effective way to reach net zero is to reduce overall building energy loads before designing a renewable energy system to provide sufficient energy for the building. Load reduction will minimize the renewable energy investment by reducing the size of the photovoltaic array or other renewable energy sources. Load reduction may be achieved and through programming and space requirements reduction, site planning, massing and orientation, building envelope optimization, high efficiency HVAC systems and plug load control. The load reduction will be demonstrated through energy modeling and other analytical tools. Integrated Solutions – We use design tools to optimize the building envelope, daylight and thermal comfort. We evaluate MEP and structural systems, site and landscape to minimize energy and water resource use that meet the program requirements set by the client and end users.


Renewable Systems – After building energy demand has been reduced through load reduction and efficient systems, the project can employ renewable energy systems to make up the balance of demand. As each project has it’s own challenges, HOK engineers can help determine the correct renewable energy system for each project. Occupancy – Once the building has been designed to achieve Net Zero Energy over the course of a year, it will be important to monitor, measure and optimize building performance, as well as engage occupants in energy conservation and plug load reduction activities. Building optimization for Net Zero performance is a process rather than a destination.

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S P EC IA LTI ES Facade design an d an alysis


Th e HOK Fac ades t e a m provide s s uppo r t t o t h e d e s i g n pro c e s s in ea c h pro je c t p hase, id e n t ifyin g a p prop ri a te syst ems and m a t e ria ls t o achieve ae s th et ic objectives.

A b e autif ul and high-p er fo r m a nce b ui ldi ng skin is sc ru tin ized ea r ly in t he p ro cess for three key rea s o ns : t o calculate the weighted avera g e U-va lue of the assem b ly, t o d e t erm i ne the risk of c o nd ens a t io n, a nd to e nsure c onstru ct ib ilit y a nd

p ro je ct b udget, perform an ce cri ter ia, and ae st h e tic i ntentions. a li g nm e nt with the

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SP ECIA LT I E S

Facade thermal performance

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Of fset mullio n a t

St a nd a rd m u l l i o n

O f fs e t mu l l i o n a t

St a n da rd mu l l i o n a t

span drel

a t s p a nd re l

vi s i o n gl a s s

vi s i o n gl a s s

D e s ign

+

Sc ienc e

The facade design team blends art and science seam lessly to design facade assemblies, analyzing the conduction,

convection

and

radiation

that

controls

the

location of the dew point temperature for each facadestructure condition in the building. Boundary conditions based upon extensive climate data are gleaned from the NFRC and ASHRAE 90.1 to simulate the behavior of the system in research-grade programs such as THERM.

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HOK | 210

SPE CIA LT IES Sys te m & M at er ial Selec t io n


Precast

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SPECIALTIES Fac ade dayligh t in g per for man ce

Minimize glare

Annual Solar Irradiation

HOK | 212

Optimize Daylighting


Ext er io r

Optimize the for a +

Co mfo r t able , Ef f ic ient , Pro duc t ive Int er io r

Simulation Solemma

of

Space

daylighting

Climate

Studio

with helps

evaluate the trade off between view and natural light to minimize heat gain and glare. HOK facades works with the design team to asses options as early in the process as possible to find optimal and

economical

solutions

that

lead to comfortable and productive spaces

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SPE CIA LT IES Sys te m & M at er ial Selec t io n

Brick & Stone Veneer

Metal Panel Rain Screen

Cassette Curtain Wall on AESS

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Precast

GFRC Rain Screen


Unitized Curtain Wall System

Stick-Built Curtain Wall System

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S P EC IA LTI ES Facade in n ovat io n


CIRCADIAN FACADE HOK Facades and WSP Built Ecology developed a concept based on the Gartner/Permasteelisa Closed Cav ity system, curved lites to facilitate automated shading allowing indirect natural light and views at all ti mes. Potential savings

25%

operational

compared

to

energy

convention -

al building. Structural glass saves 4,000 tons of embodied carbon by reducing need for aluminum in the mullion framing.

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Facade in n ovat io n

S P EC IA LTI ES HOK | 218

CIRCADIAN FACADE Metals In Construction Design Competition for a Facade fostering Wellness 2018. Published in Bldg Des & Construction, Azure Magazine, Window and Facade Magazine India, & several other publications Presented: •

Greenbuild 2019

Facade Tectonics World Congress 2020

Zak Facades Conference, 2020


CIRCAD IAN FAÇADE

CONVENT IONAL F LAT FACADE

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S PECIALT I ES

Fa c ade In n ovat ion

STRUCTURAL EXTERIOR ENCLOSURE This design for a megapanel cladding system which provides lateral stiffness to the primary structural frame of a high-rise tower was a collaboration between the structural and facades teams.

th e claddin g con ce pt re d u ces the tower’s Embodie d Carbon sign ifican tly by su pplem e n ti ng co re dri ft co ntrol with a steel braced panel system that supports a shallow Designed and analysed to meet code performance criteria,

glazing system, in place of a conventional aluminum curtainwall.

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S PECI A LT I E S De s ig n c o m p e titio ns

HOK | 222


Le t e n g in e e r i ng be t h e d i f fe re nc e i n your wi nni ng c omp e t i t i on d e s i g n

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SP ECI ALT I E S

Des ign co mp e t i t i o ns

Do n’t limit you rse l f: l e t u s p rov id e yo u w it h opt i ons you d i dn’ t know we re p os s i b l e

HOK | 224


The tension and compression in a bicycle wheel illustra tes the concept enabling the vast span.

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D esi g n co m p e t i t i o ns

S PECI A LTI E S HOK | 226

U npa ra lleled ac c ura c y a t t h e co m pet i t i o n ph a se:

let our S TREAM wo r kf l ow h el p yo u ge t a h e a d st a r t


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Existing buildings

SPE C I ALT IE S HOK | 228

This is an existing 32 story office building in downtown Houston. It is framed with structural steel and served as the offices for El Paso Energy. Since the entire tower was to be upgraded, it was necessary to upgrade the structure as well to bring it up to date with the occupancy. Over the years, significant changes have been made to the wind code, the wind speeds and wind forces had been revised to be much greater than those at the time the tower was

The challenge was how to strengthen and stiffen the existing structure to bring it into compliance with the new wind codes. An designed.

extensive structural analysis was done using the stiffness of the existing masonry core walls. Since these were interior walls and not reinforced with rebar and not grouted, a detail analysis was done taking the reductions in the stiffness of these existing walls. Fortunately, there were sufficient such walls and even with the taken reductions provided sufficient stiffness to meet the code required wind forces.


S PE C IA LT I ES

Renovation

HOK’s structural team renovated an abandoned thirty-yearold former Sysco Distribution center to become a new home of the Houston Food Bank. This 308,000-sf warehouse building allows HFB to improve their logistic and expand community services. Several existing post-tensioned tilt-up wall panels were cut and removed to create the welcome center and main entrance of the facility from nothing but a

Since most of the wall panels were load-bearing elements, modifying them required special care. To ensure the safety of construction, long line of existing loading docks.

our structural engineer worked closely with the general contractor to develop step-by-step construction procedure in several critical areas such as where the new monumental stair was added.

229 | HOK


S P E C IALT I ES

Renovation

600 Travis, also known as JPMorgan Chase Tower, is Houston’s tallest building. The original main lobby featured a 5-story tall vertical curtain wall which are being replaced by a new curtain wall system with a pyramid shape. This renovation allows the lobby depth to be expanded and promotes the circulation and the utilization of the lobby area. It also improved the connectivity of the lobby and the outdoor plaza area. To maintain the operations of the building loading dock and several retails in the basement under the lobby, the new curtain wall frame was designed to be primarily suspended from two existing concrete columns at level 6 which minimized the structural strengthening required on the underside

The boundary conditions of the framing system were strategically designed to maximize the structural efficiency and constructability. of the ground floor slab.

Besides the pyramid curtain wall, the structural team also worked closely with the landscape team to add several site structures and modified landscape profile of the plaza. The design was coordinated to minimize the required structural modification and keep the project under the budget.

HOK | 230


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Ad ap t ive reu s e an d ren ovat i o n

S PECIA LTIES

M I SS OU R I F OU N DATION F OR H E A LT H

HOK | 232

St. Louis, Missouri


We are so grateful to the HOK structural team for their partnership on our project to renovate a factory in a state of disrepair for our headquarters. Our vision of a home for our staff and a thriving community space for our partners would not have been accomplished without the commitment of the structural team to build a strong foundation and backbone. They always found creative and effective solutions focused on our goal to create a space that would serve Missouri Foundation for Health well now and for many years to come.” -Jill Nowak, CFO, Missouri Foundation for Health (MFHH) 233 | HOK


Ad a p t i ve reu s e an d ren ovat i o n

TYSON FOOD S EMMA AVENUE OFFI CE Springdale, Arkansas

This renovation and addition to Tyson Foods’ original

SP EC IALTIE S

1940s headquarters and Brown’s Hatchery provides

HOK | 234

space for 400 IT employees while revitalizing a downtown Springdale landmark.


“This project was especially rewarding to participate in due to the historical significance and the adaptive reuse of two existing buildings. Tyson’s desire was to give back to the community by bringing some of their employees back to downtown Springdale to initiate new economic development in the area.” Steven Crang, Regional Leader of Engineering

235 | HOK


Ad ap t ive re u s e an d ren ovat i o n

SP E CIALTIES

T YSON FOOD S E MMA AV E N U E OF F IC E Springdale, Arkansas

HOK | 236


outside, additional window openings were constructed at the east elevation of the Original HQ’s building. The Brown Hatchery building was originally constructed with a basement and the first elevated floor was wood framed. The original wood members supporting the first floor were found to be structurally compromised prior to the renovation. Due to the limited height of the basement and the deteriorated condition of first floor framing, HOK recommended infilling the basement and reconstructing the first floor with a reinforced concrete slab on grade. The structural team utilized an interior structural steel frame to brace the existing brick masonry walls and to support new structural steel roof framing. All column foundations utilized The Emma Avenue Office is one of several projects for which Tyson Foods has partnered with HOK over the past couple decades. In this project, HOK’s design pays homage to the place where family-owned Tyson got its start. A new light-filled central lobby links the

cantilevered grade beams constructed integrally with spread footing foundations.

This configuration allowed footings to

be placed safely away from existing masonry wall foundations and allow wide flange steel columns to be supported in close proximity to existing masonry walls

two historic buildings and provides employees and guests with a place to collaborate. There were minimal existing openings in the original brick masonry walls with the exception of the two north facing storefronts.

The HOK Structures

team evaluated the existing brick masonry walls to accommodate multiple new openings and detailed exposed structural steel lintels and jamb reinforcing steel to achieve this vision. Additionally, to allow ample daylight into the interior of building and views to the

237 | HOK


S P E C I A LT I E S C a nop ie s

Delivering iconic, long-span structures while ensuring continuous airport operations is core to HOK’s engineering for aviation practice. As part of the modernization of the world’s busiest airport, HOK delivered a structural and architectural icon for Hartsfield-Jackson Atlanta International. Dual 864’ long structural steel canopies clad in ETFE flank the existing terminal and suspend new pedestrian bridges over the existing roadways, with complex existing conditions at each end of the span.

HOK | 238


While the truss chords appear to consist of a consistently varying curvature, they are actually comprised of discrete constant-curvature sections, significantly less expensive to fabricate. The truss splice connections were designed with internal bolts erected during a midnight-to-5am schedule to minimize lane closures, concealed with welded cover plates afterwards. This innovative design process delivered what the airport General Manager deemed “iconic architectural landmarks for the City of Atlanta.”

To make this possible, HOK structural engineers generated parametric structural models integrated with the architectural models to verify viability, performance, and minimize load applied to the existing structures. This provided continual feedback to the design team and shortened the design process from months to three weeks. Geometric optimization and lightweight ETFE cladding decreased the weight of the structure enough to allow it to rest upon the existing building without additional columns. The sweeping form of the diagrid canopy emerged from the most efficient structural load path found by the team’s algorithm, finessed by creative decisions to simplify construction.

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SPECIALTIES Pedestrian bridges

HOK | 240


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HOK | 242


of green space near downtown Houston. Two separate branches of this bridge draw pedestrians over Memorial parkway and the river before adjoining together into a descending loop at the sculpture park on the opposite side. The bridge belongs to a family of five recreational structures featuring long spans and dramatic cantilevers designed by the structural group to create spaces for outdoor performance, relaxation and river sports.

Rosemount Bridge, Buffalo Bayou Park, Houston TX

S P ECI A LTI ES Pe de st rian br idge s

The Buffalo Bayou river winds through 160 acres

243 | HOK


SPECIALTIES Stairs

HOK | 244


Stairs become sculptural centerpieces encouranging interaction between programs, people, and spaces. HOK engineers stairs that appear to float while conforming to deflection and vibration criteria so stringent, they can be clad in glass (and covered by its warranty).

245 | HOK


SPE CIA LT IES Sta irs HOK | 246

The HOK structural team collaborated with the interiors group to deliver a striking feature staircase for the Norfolk Southern Headquarters project in downtown Atlanta. While the shape of the stair is a set of concentric spirals from levels 2-4, the shape unravels into a surrealist, sculptural ribbon.To support the Corian cladding and shape, curved steel plates were used to form the stair stringers as well as the hand rail supports. This improves the structural ef ficiency by increasing the cross-section moment of inertia.


Ribbon below the stair is a made up of a series of frames linked together by curved steel edge members and joins seamlessly with the steel plate stair at level 2. For this to be successful, an iterative process bet ween the interiors and structural design was imperative. Further, cam ber was applied to counter the un-raveling effect gravity loads wield on spiral geometry.

247 | HOK


SP ECI A LT I E S

Vi b ra t i o n a na l ysi s

Successful, proven strategies for addressing structural vibration performance and cutting unnecessary project costs.

The archi tecture and engineering team developing options on an integrated approach for the structural framing and mechanical distribution. This system in creased p lenum depth by 20%, dramatically increasing energy performance while maintaining desired ceiling height and a wide array of location-specific vibration criteria.

HOK | 248


Vibration criteria can be major drivers of project cost when addressed in an overly conservative way, or a major source of risk if they were to not be addressed sufficiently.

HOK’s Engineering team has

extensive experience in designing cost-effective structures for strict vibration performance on a wide range of structural systems and types, including laboratories, healthcare facilities, stadia, training centers, bridges, stairs, and renovations. We use advanced analysis techniques to accurately model and optimize structural systems for location-specific vibration criteria and forcing functions, for occupants and for equipment.

We work with the design team

to develop integrated systems solutions that deliver structural performance while maintaining sufficient space for services distribution.

249 | HOK


SP ECI ALT I E S

Dis placement ve nt i l a t i o n

Displacement air systems take advantage of ther mal stratification to move air through the space at very low velocities. The cooler supply air is introduced low in the space and is attracted to the warmer surfaces throughout the space. As the air being supplied is warmed a natural draft is cre ated as air is collected and removed at the ceiling level. This design approach lowers the quantity of airflow needed to condition only the occupied zone of the space. Because supply air is introduced into the space at an elevated temperature when compared to traditional overhead HVAC systems displacement air systems increase the hours that airside econo mizer cycles can be used to effectively provide free cooling and reduce HVAC cooling energy. Ventilation effectiveness is increased with displacement air systems by supplying air directly to the occupied zone with less mixing than a traditional overhead system thus improving indoor air quality and occupant comfort. HOK’s engineering team has implemented displacement air systems in projects with large vol ume spaces where conditioning the entire volume of the space would not be efficient, as well as projects where the design teams goal was to mini mize or hide the appearance of the HVAC system by integrating it into architectural features. On some projects, like the Salt Lake City Internation al Airport, displacement air systems were coupled with evaporative cooling systems to further increase the hours that do not require mechanical cooling.

HOK | 250


SPE C I ALT I E S

Radiant heating a nd co o l i ng

Radiant heating and cooling systems can improve occupant comfort and increase energy savings versus traditional HVAC strategies through better control over operative tem perature of the space and the lower transport energy inherent to waterbased systems. High mass radiant systems can store energy that can be re-charged during off hours to offset operational cost. HOK’s mechanical engineering team has extensive experience with ra diant heating and cooling systems through our work on past projects in Aviation, Science and Technology and Corporate markets. HOK’s radiant system designs have utilized both in-slab, panel systems and chilled beams. On some projects, like the Salt Lake City International Airport, the radiant systems were coupled with displacement air systems to maximize energy savings. Through HOK’s collaborative team approach and close integration with our fellow architectural and structural engineering team members radiant floor slabs are designed to optimize appearance, performance and cost.

251 | HOK


SPE C I A LT IE S C e nt ra l u til i ty plan t s HOK | 252

The Cummins concrete cooling towers, the NASA B-48 CUP and the BP High Performance Commuting Center CUP. The Cummins cooling tower was a collaboration with the s tructural team. HOK designed CUPs have served everything from NASA’s mission control, data centers, universities, laboratories, airports, justice complexes, manufacturing facilities, office buildings and various other type of mission critical spaces.


Central Utility Plants (CUPs) are the beating heart of heating and cooling systems in buildings as CUPs provide chilled water, heating water and/or steam to buildings and campuses. We focus on issues like future expansion, operational flexibility, cost, controllability, simplicity, energy-efficiency, plant optimization, turndown, resiliency, uninterruptable operation, fail-safe operation, continuity of building operations, maintainability and serviceability. Pulling from our vast and extensive experience allows us to efficiently tailor designs to Project specific requirements while providing coordinated and multi-discipline solutions to common issues such as maintainability, serviceability and resiliency. HOK designed CUPs have incorporated a variety of technologies to meet the varying project needs including thermal ice storage, field-fabricated custom cooling towers, low temperature condenser water operation, commercialgrade DDC controls, industrial-grade PLC controls, central plant optimization software and make-up water storage.

253 | HOK


SP ECI A LT I E S

U nd e r fl o o r a i r syst e m s AIR-COOLED WHITE SPACE

2020 Rice Oil & Gas HPC Workshop

March 3, 2020 I Page 6

Hellmuth, Obata + Kassabaum

Displacement Ventilation systems are able to save energy in a number of ways. While they use air for cooling and heating like VAV systems, they usually only need to supply about 60% as much air to provide the same amount of cooling, which reduces the fan energy. The systems are designed to cool the occupied space only, so space heat loads from items at the ceiling (like lighting) do not necessarily need to be cooled, also saving energy.

HOK | 254


Supplying air at about 68°F/19°C instead of 58°F/14°C can affect the energy both ways – it depends on the climate and what sort of recovery systems are used at the central plant. But in very cold climates or climates with high humidity, this may actually increase energy consumption.

UNDERFLOOR RESULTS 2020 Rice Oil & Gas HPC Workshop

2020 Rice Oil & Gas HPC Workshop

March 3, 2020 I Page 15

March 3, 2020 I Page 16

Hellmuth, Obata + Kassabaum

Hellmuth, Obata + Kassabaum

255 | HOK


SP ECI A LT I E S

Pa ssi ve o p t i ca l ne t wo r ks

New network technologies enable designers to create buildings that support communications requirements with less space, power, cooling and infrastructure. Passive optical networks (PONs) use fiber optic cables that transmit signals more effectively than traditional copper cable-based networks . For the past several years, PON technology has been used to deliver phone, data and television services into homes. Today, PON equipment is being repackaged into devices appro priate for installation in many building types. Integrating PONs into a building design can generate signifi cant first-cost and long-term operational savings.

HOK | 256


Intermediate Distribution Frame (IDF) for a Traditional LAN: Power required: 6-8 kVA for active network equipment Dedicated HVAC required Approximate room area: 120 sf per every 10,000 sf

IDF for a Passive Optical LAN : No power requirements or cooling equipment for passive equipment Approximate Room area: 28sf per every 10,000sf

257 | HOK


SP E C I A LT I E S

A i r po r t Ter m inal IT& ES Int egrat io n

HOK has developed innovative strategies to seamlessly integrate the IT&ES (information technology and electronic systems) and infrastructure required to support current emerging and future passenger processing technologies and amenities into airport terminals. At the new LaGuardia Terminal B, Single Mode Fiber Optic Cable infrastructure is used for both backbone and horizontal cabling instead of a combination of conventional copper, coaxial and multi-mode fiber cabling. Single Mode Fiber can transmit signals much further than conventional copper, coaxial and multi-mode fiber cabling this allowed the number of IDFs to be reduced and provided greater flexibility in where they are located. Wireless Access Points (WAPs) for WiFi and Distributed Antenna System (DAS) antennas are located

H e a t m a ps we re u se d to confirm that c overage requ i re m e n t s a re m e t . Th i s a l l owe d t h ese sys tems to be insta lled a nd te st e d befo re t h e ce i l i n gs we re co m pl e ted . Additionally, since the devices are above the ceilings in public areas, a lot of detailed coordination above ceiling tiles and behind panels that are transparent to RF signals.

both in design and construction was eliminated, leading to schedule and construction cost savings.

HOK | 258


PSLS Transceiver connected to two head-ends for high availability

Hung ceiling

Another advantage of the Fiber to the antenna solution deployed at LaGuardia is that it requires less the ½ the power that conventional systems required. This is because the transceivers are located at the antennas as opposed to remotely in IDFs and MDFs. This reduces/eliminates the signal losses inherent it coaxial cable based systems. Locating antennas and WAPs above the ceiling enables ubiquitous PSLS Radio, Cellular DAS and WiFi coverage without cluttering highly finished public spaces with less attractive devices – the technology is invisible.

259 | HOK


S PE C I A LT IE S

Com m uni ca t i ng w i t h Pa sse ng e rs HOK IT&ES designers strategically locate EVIDS (Electronic Visual Information Display System) displays and Public Address System (PAS) speakers to provide travelers and other stake holders with information when and where they need it. Interface Control Documents (ICDs) processes are used to develop, test, and prove interfaces between EVIDS and PAS (as well as other systems) during design, in pre-production facility, and finally in situ.

The ICD develop -

ment process documents how each interface works and facilitates testing and commission -

Th i s a l l ows t h e sch edu l e t o be co m presse d a n d de - r i sks pro j e ct s by en a bl i n g i n t er fa ces t o be t est ed a n d proven w h i l e t h e bu i l di n g i s be i n g bu i l t a s o ppo sed t o af t e r i t i s co n st r u ct ed. ing of each interface.

At LaGuardia both the EVIDS and PAS are interfaced with each other and with the Airport Operational Data Base (AODB) so that information displayed on EVIDS is always consistent with PAS announcements. When the AODB receives updates to arrival and/or departure times, this information is automatically shared with the EVIDS and PAS to keep passengers and other stakeholders informed. To take the guesswork out of PAS design, Enhanced

Acoustic

Simulator

for

Engineers

(EASE) software is used to confirm coverage EASE Study Confirming Public Address Coverage at Security Screening Check Point

prior to construction.

Departures Hall and Security Screening Check Point

and

George

Houston, TX.

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Following are repre-

sentative images from an EASE Study for the Bush

Intercontinental

in


EASE Study Confirming Public Address Coverage in Departures Hall

Audibility, intelligibility, and costs are optimized thru selection of a combination of conventional ceiling mou nted speakers and larger linear array speakers. Linear array speakers cost more than conventional ceiling speakers but cover much greater areas so total cost of installation can be re duced. Another advantage of linear array speakers is that they are mounted to walls, columns or posts. This means that they can be instal led, tested and commissioned while ceilings are installed (long before ceiling speakers could be installed, tested and commissioned). The AODB can also be interfaced with airport terminal website to provide travelers with real time information about flight status and what is happening at the terminal. This information is accessible from home, hotel, taxi and any other location with access to the Internet. Providing accurate real time information improves the travel experience from the time one leave from home until one returns.

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SP ECI A LTI E S IT secu r it y syst ems


The security automation systems for justice complexes is an innovative design process, minimizing the number and use of traditional control rooms.

Campusus often include a

dedicated security LAN that centralizes the video security system in a single area, making it easier to manage. The security system LAN includes an array of edge, aggregation and core Ethernet switching appliances that provide recording and playback functionality throughout the campus.

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