The Architect’s Role in Sustainable Design (and How to Use Technology & Innovation to Advance Our Green Agenda) #ilmaBlog #green #design #architecture

Background

In the design and construction field, there are two major categories of resources: renewable and non-renewable. As opposed to non-renewable resources, which are depleted with their constant use, renewable resources are not. If not managed properly Non-renewable resources might become non-existent when the rate at which they are used is much higher than the rate at which they are replaced. Renewable resources include water, geothermal energy and wind energy. Non-renewable resources include coal, natural gas and oil.  The demand for new construction is on the rise as the world’s population increases and the demand for newer, more efficient modern buildings also increase.

Architect’s Role

Because buildings account for so much energy to build and maintain, architects and designers have become very conscious about our role in minimizing our environmental footprint when we design buildings.  The American Institute of Architects, the largest organization of architects world-wide has a committee called the Committee on the Environment (COTE), which works to advance, disseminate, and advocate—to the profession, the building industry, the academy, and the public—design practices that integrate built and natural systems and enhance both the design quality and environmental performance of the built environment. COTE serves as the community and voice on behalf of AIA architects regarding sustainable design and building science and performance.

Bamboo

Renewable Resources

In green construction processes, there is an emphasis on the use of renewable resources. In many cases, this natural source becomes depleted much faster than it is able to replenish itself, therefore, it has become important that buildings make use of alternative water sources for heating, hot water and sewerage disposal throughout their life cycles, to reduce use and conserve water supplies.

Architects and designers specify rapidly renewable materials are those that regenerate more quickly than their level of demand. Our goal is to reduce the use and depletion of finite raw materials and long-cycle renewable materials by replacing them with rapidly renewable ones.  Some commonly specified rapidly renewable materials include cork, bamboo, cotton batt insulation, linoleum flooring, sunflower seed board panels, wheat-board cabinetry, wool carpeting, cork flooring, bio-based paints, geotextile fabrics such as coir and jute, soy-based insulation and form-release agent and straw bales. Some green building materials products are made of a merger of rapidly renewable materials and recycled content such as newsprint, cotton, soy-based materials, seed husks, etc.

Check out this ILMA article about “Materiality and Green Architecture: The Effect of Building Materials on Sustainability and Design” for more information on this topic.

Responsibility of Architects

Architects and designers who align with AIA’s COTE objectives, (1) recognize the value of their role in environmental leadership to advance the importance of sustainable design to the general public while incorporating sustainable design into their daily practice, (2) influence the direction of architectural education to place more emphasis on ecological literacy, sustainable design and building science, (3) communicate the AIA’s environmental and energy-related concerns to the public and private sectors and influence the decisions of the public, professionals, clients, and public officials on the impact of their environmental and energy-related decisions, (4) educate other architects on regulatory, performance, technical and building science issues and how those issues influence architecture, (5) educate the architectural profession on programming, designing, and managing building performance, (6) investigate and disseminate information regarding building performance best practices, criteria, measurement methods, planning tools, occupant-comfort, heat/air/moisture interfaces between the interior and exterior of buildings, (7) promote a more integrated practice in order to achieve environmentally and economically efficient buildings. One of the tools we will plan to promote to achieve this integration is Building Information Technology (BIM).

Smart-Building

The Role of Technology & Innovation – A Case Study (“The Edge”)

PLP Architecture and the Developer OVG Real Estate, built “The Edge” is a 430,556 SF (40,000m²) office building in the Zuidas business district in Amsterdam. It was designed for the global financial firm and main tenant, Deloitte. The project aimed to consolidate Deloitte’s employees from multiple buildings throughout the city into a single environment, and to create a ‘smart building’ to act as a catalyst for Deloitte’s transition into the digital age.

They key features of this building include the following innovations which address the environmental impact of building such a large edifice:

  • Each facade is uniquely detailed according to its orientation and purpose.
    • Load bearing walls to the south, east and west have smaller openings to provide thermal mass and shading, and solid openable panels for ventilation.
    • Louvers on the south facades are designed according to sun angles and provide additional shading for the office spaces, reducing solar heat gain.
    • Solar panels on the south facade provide enough sustainable electricity to power all smartphones, laptops and electric cars.
    • The North facades are highly transparent and use thicker glass to dampen noise from the motorway.
    • The Atrium façade is totally transparent, allowing views out over the dyke, and steady north light in.
  • The building’s Ethernet-powered LED lighting system is integrated with 30,000 sensors to continuously measure occupancy, movement, lighting levels, humidity and temperature, allowing it to automatically adjust energy use.
  • 65,000 SF of solar panels are located on the facades and roof, and remotely on the roofs of buildings of the University of Amsterdam – thereby making use of neighborhood level energy sourcing.
  • The atrium acts as a buffer between the workspace and the external environment. Excess ventilation air from the offices is used again to air condition the atrium space. The air is then ventilated back out through the top of the atrium where it passes through a heat exchanger to make use of any warmth.
  • Rain water is collected on the roof and used to flush toilets and irrigate the green terraces in the atrium and other garden areas surrounding the building.
  • Two thermal energy wells reach down to an aquifer, allowing thermal energy differentials to be stored deep underground.
  • In The Edge a new LED-lighting system has been co-developed with Philips. The Light over Ethernet (LoE) LED system is powered by Ethernet and 100% IP based. This makes the system (i.e. each luminaire individually) computer controllable, so that changes can be implemented quickly and easily without opening suspended ceilings. The luminaires are furthermore equipped with Philips’ ‘coded-light’ system allowing for a highly precise localization via smartphone down to 8 inches (20 cm) accuracy, much more precise than known WiFi or beacon systems.
  • Around 6,000 of these luminaires were placed in The Edge with every second luminaire being equipped with an additional multi-sensor to detect movement, light, infrared and temperature.
  • The Philips LoE LED system was used in all office spaces to reduce the energy requirement by around 50% compared to conventional TL-5 Lighting. Via the LoE system daily building use can be monitored. This data is fed to facility managers via the BMS allowing:
    • Remote insight into the presence of people in the building (anonymous). Heating, cooling, fresh air and lighting are fully IoT (Internet of Things) integrated and BMS controlled per 200 sqft based on occupancy – with zero occupancy there is next-to-zero energy use.
    • Predictions of occupancy at lunchtime based on real time historical data and traffic and weather information to avoid food-waste.
    • Unused rooms to be skipped for cleaning.
    • Managers to be alerted to lights that need replacing.
    • Notification of printers needing paper.
  • Every employee is connected to the building via an app on their smartphone. Using the app they can find parking spaces, free desks or other colleagues, report issues to the facilities team, or even navigate within the building.
  • Employees can customize the temperature and light levels anywhere they choose to work in the building via the mobile app. The app remembers how they like their coffee, and tracks their energy use so they’re aware of it.
  • The vast amount of data generated by the building’s digital systems and the mobile app on everything from energy use to working patterns, has huge potential for informing not only Deloitte’s own operations, but also our understanding of working environments as a whole. Discussions are currently ongoing regarding the future of this data and its use for research and knowledge transfer.
  • The green space that separates the building from the nearby motorway acts as an ecological corridor, allowing animals and insects cross the site safely.

Conclusion

Because buildings account for nearly 40 percent of global energy consumption, architects and designers have been working to impact the built environment in a positive way.  Although not every project can be as green as The Edge, by selecting materials that are renewable while reducing energy are two big contributions we can make to help ease the increasing demand for construction.

Technology can play a big part in our role to design more sustainable buildings through the use of building information modeling, energy management software, building management software, online sustainability calculators, energy modeling software, new lighting innovations, new techniques to capture and deliver energy and clean water while reducing waste, and mobile applications utilizing IoT.

Sources:

We would love to hear from you about what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends.

Feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook

 


Prototyping Future Worlds with Futurist Architect Filmmaker @Liam_Young featured on Mind & Machine Podcast with Host @AugustBradley #Technology #Art #Film #ilmaBlog

Earlier this week I heard a great podcast on Mind & Machine, hosted by August Bradley I wanted to share with you.
MIND & MACHINE: Future Technology, Futurist Ideas (Published on Apr 9, 2018)

Liam Young, Speculative Architect, Futurist, Sci-fi Shaper, Extreme Explorer, Provocateur, Technology Storyteller, who uses his design background combined with experience in crafting environments to prototype new worlds — worlds that reveal unexpected aspects of how we live today and how we will live in the future. Liam teaches speculative architecture and world building at Sci Arc, a leading architecture school. He founded Unknown Fields, a nomadic studio documenting expeditions to the ends of the earth, exploring unusual forgotten landscapes, and obsolete ecologies. And Liam has co-founded Tomorrows Thoughts Today, a futures think tank envisioning fantastic speculative urban settings of tomorrow.
Podcast version at: https://is.gd/MM_on_iTunes

More about and from Liam at:

http://www.propela.co.uk/liamyoung
MIND & MACHINE features interviews by August Bradley with leaders in transformational technologies.
Twitter: https://twitter.com/augustbradley
Instagram: http://www.instagram.com/mindandmachine
Website: https://www.MindAndMachine.io

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook

 


Top 20: Technology & Innovation Ideas For Architects

Thank you for all the support and encouragement over the years.  Here are some of our favorite blog posts about technology and innovation related to the field of Architecture:

  1. High Performance Building Design
  2. 3-D Printing
  3. Connected Spaces
  4. Benefits of Using Digital Twins for Construction
  5. Digital Twins
  6. Drone Technology
  7. Artificial Intelligence
  8. Immersive Experience in Architecture
  9. Smart Cities
  10. Big Data in Architecture
  11. Creating High Performance Buildings through Integrative Design Process
  12. Forget Blueprints, Now You Can Print the Building
  13. The 7 Dimensions of Building Information Modeling
  14. Parametric Architecture and Generative Design System
  15. Architecture Robots
  16. Internet of Spaces
  17. Sustainable Design Elements to Consider While Designing a Project
  18. What is a High Performance School?
  19. What is BIM? Should Your Firm Upgrade? by @FrankCunhaIII
  20. Renewable Wave Power Energy

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


Drone Technology

Drone-Technology-02Drones—also called unmanned aerial vehicles (UAVs) or unmanned aerial systems (UAS)—are most simply described as flying devices that do not carry a human pilot. They can be remotely piloted or they can pilot themselves based on pre-programmed instructions. They can be equipped with GPS, on board computers, hardware, electronics, sensors, stabilizers, auto-pilots, servo controllers, and any other equipment the user desires to install. Drones can resemble fixed-wing airplanes but more commonly take the form of quad-copters, that is, rotor-wing aircraft that can take off and land vertically. Most people know that drones can be equipped with infra-red cameras (still and video), license-plate readers, “ladar” (laser radar that generate three-dimensional images and can be seen through trees and foliage), thermal-imaging devices, or even sensors that gather data about weather, temperature, radiation or other environmental conditions. All of this can be used to generate images, recordings or data that design professionals eventually will want to use in their business.

Drones could be a valuable tool in construction, widening the spectrum of what’s possible in architecture, according to architect Ammar Mirjan.

“We can fly [drones] through and around existing objects, which a person couldn’t do or a crane couldn’t do,” explains Mirjan. They can be programmed to weave simple tensile structures in the air, for example.

Sources & References:

https://www.dezeen.com/2017/05/04/mark-dytham-interview-drones-uavs-bring-profound-change-architecture-cities/

http://www.theaiatrust.com/architects-guide-using-drones/

https://www.dezeen.com/2018/05/25/10-ways-drones-will-change-the-world/

How are aerial mapping drones helping architects?

Architects are exploring the many benefits of mapping drones for improving and expanding their businesses. Here are just a few examples:

The most popular application for small drones is aerial photography and video capture to track and share “before and after” progress over time.

Ability to securely collaborate on specific areas of interest with your team, contractors, and customers.

Tell the story of your project.  Show current and potential customers before and after fly-throughs of your job site so they can experience and appreciate the scale and impact of your work.

3-D point clouds with centimeter grade accuracy on progress, so you can get the precision updates you need to keep project approvals on time, without physically traveling to the site.

Get context for your project, plan your architecture with a full view of the surrounding area.

See 3D volumetrics so you know what you’re building on and can track progress.

Uses for Drones

  • Project documentation
  • Presentation + marketing
  • Architectural cinematography
  • Site analysis
  • Topographic mapping
  • Construction observation
  • Educational tool
  • Lead generation (working with Realtors)

Conclusion

According to an interview in Dezeen.com with Mark Dytham, architect and co-founder of Tokyo-based Klein Dytham Architecture, “Drones will transform the way buildings are designed, the way they look and the way they are used.

One way in which drones are proving to be a useful tool in architecture is through surveying. Due to their small size and relative ease of maneuverability, drones make an easy task of accessing difficult to reach places.

According to ArchDaily.com, “While using satellite imagery for site planning is common among architects, these visuals are often available in low resolution and produce less accurate data. Data collected by drones can completely eliminate the need for hiring land surveyors for creating topographic surveys. Instead, architects can use this information to build accurate 3D models of the terrain and site and import them directly into drafting and modeling software like Rhino.” In the past, architects would have relied on planes, helicopters, or satellite imaging for aerial footage.

Sources & References:

https://www.identifiedtech.com/blog/construction-drones/how-aerial-mapping-drones-can-help-architects/

http://residencestyle.com/the-use-of-drones-in-architecture-soars-to-new-heights/

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


Using 3-D Technology to Evaluate Existing Conditions & Brainstorm Conceptual Design Options

Quick Conceptual Hand Sketch by Frank Cunha III

IMG-3546

Google Photograph of Existing Conditions

7-3-18 original

3-D Model of Existing Conditions by Michael Chiappa

7-3-18

Exploded 3-D Model of Existing Conditions by Michael Chiappa

7-4-18.jpgFollow Michael Chiappa on Instagram and LinkedIn.

Software: Rhino 6; Photoshop

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook


Babbio Center, Stevens Institute of Technology

My Role: Project Manager – Involved in the project from concept design through construction.

Owner: Stevens Institute of Technology

Architect: Cubellis Ecoplan

Contractor: Terminal Construction

About the Project:

The Lawrence T. Babbio, Jr. Center for Technology Management is one of the world’s preeminent institutions in the education of professionals who lead and manage technological innovation in businesses in America and around the world.  Educating managers who use technology to create extraordinary value for the societies in which they live, it offers education programs designed and delivered by leading industry practitioners who are important contributors to the creation of new knowledge in the field.   The Howe School also conducts worldclass research in several focused areas of Technology Management, especially in the domain of Technology Innovation, Commercialization and Entrepreneurship.  Research is applied in orientation and grounded in Technogenesis®.   Technogenesis is Stevens’ educational environment where students, faculty and industry collaborate to turn innovation, invention and discovery into marketplace success.Opened in the Spring of 2006, the Lawrence T. Babbio, Jr. Center for Technology Management, a six-story, 95,000 square foot structure serves as the new signature headquarters for the Wesley J. Howe School of Technology Management at Stevens Institute of Technology.  On the lower four levels, a vibrant mix of classrooms, laboratories and research library are united by an atrium lobby.  Externally, the lecture hall volume is used expressively to evoke the energy of the activity within.  Above, students, faculty and visiting business representatives work together in an office environment that is the antithesis of the “traditional” faculty office suite.  A glass-enclosed conference and open teaming area seems to hover within the top of the atrium lobby enclosure and offers a suitable environment to foster the kind of corporate partnerships that form the basis of the program.

The Center is blessed with amazing contextual opportunities. On one side is a rich and vibrant urban landscape of 6-8 story buildings of a variety of materials and historical styles. On another it faces campus buildings, gates and pathways leading to more campus-like areas of the Institute. Finally, sitting atop the cliffs to the Hudson, the site offers panoramic views of the river and the Manhattan skyline. The entrepreneurial drive and spirit of the Howe School of Technology Management was a catalyst for developing a vocabulary that highlights the contrast between a contextually-responsive primary form and vigorously sculptural and modern forms. The primary form of the building takes cues from its neighbors for materials, setbacks and various alignments of both mass and detail.  A round, tapering, metal-clad form housing lecture rooms, intersects the primary volume aggressively and helping to form a high arcade that very loosely recalls the crenellations of the adjacent gothic gateway to the original campus area. Finally, a very simple glass-clad atrium form, engages the primary form at it’s center to unite a variety of interior areas and to afford to many within the building the incredible view of the Hudson River and Manhattan skyline.  The atrium’s angled alignment acknowledges the configuration of adjacent pedestrian walkways, using this prominent site to unite the urban and more traditional landscapes of the Steven’s campus.A four-story parking garage built into the side of the promontory edge of the campus forms the base of the building.  When completed, the garage will extend toward the river, its roof top forming an expansive plaza entrance for the Babbio Center and an important new campus landscape asset.

For more information about the management program click here.

Also Check Out:

 

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments.

If you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
Frank Cunha III, AIA
Registered Architect
Licensed in CT, DC, DE, FL, MD, NJ, NY, PA, VA
I Love My Architect – Facebook
FC3 ARCHITECTURE+DESIGN, LLC
e-mail: fcunha@fc3arch.com
mobile: 201.681.3551
web: http://fc3arch.com


SchoolDesigns.Com – Babbio Center, Stevens Institute of Technology


SchoolDesigns.Com – Stevens Institute of Technology, Lawrence T. Babbio Center for Technology Management
Originally uploaded by fc3arch

Project: The Babbio Center for Technology Management
Owner: Stevens Institute of Technology
Architect: Cubellis (Formerly Ecoplan)
Contractor: Terminal Construction
Status: Construction Completed in Spring of 2006

My responsibilities:
Project Manager

Sincerely, 
Frank

Frank Cunha III – Architect & Visual Artist
Registered Architect, NJ, NY, PA, CT, DE
PO Box 335, Hamburg, NJ 07419
E-mail: fc3arch @me.com
Phone: 973.970.3551
Fax: 973.718.4641

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What is the Role of the Architect in the Future of AR Design?

Never before in the modern history of technology has the architect, the designer, been a more important part of technology’s future. Architects have been curating and ideating on the development of ‘place’ for centuries. Gensler covers how they are leveraging AR in the coverage of AI, the Internet of Things, and Cloud computing, and how to design places using game engine technology.

Speaker: Alan Robles of Gensler

Over 24 years exploring the relationship between users and their surroundings, Alan’s been creating experience environments for clients and projects of every scale around the world. In his role at Gensler he explores the opportunities found at the fringes of the design practice, searching for the edges of the play space of each design opportunity.

(Source: bit.ly/visionsummit17)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


Drywall Installation & Masonry Installation…. by Robots

A while back ILMABlog did a series on Technology in Architecture & Construction.

More recently we just discovered the latest technology coming from Japan.  Researchers at Japan’s Advanced Industrial Science and Technology Institute have built HRP-5P, a humanoid bot prototype, reported Engadget.

The bot combines environmental detection, object recognition and careful movement planning to install drywall independently, including hoisting boards and fastening them with screwdrivers. To make up for its lack of movement compared to a human, HRP-5P has numerous joints that flex to degrees people are unable to. It also can correct for slips and is capable of fields of view beyond that of a human worker’s.

The team hopes to collaborate with private companies that will treat the bot as a development platform and lead to further breakthroughs. The robot is meant to tackle the “manual shortages” Japan is facing, AIST also posits, and will allow the limited pool of human workers to focus on lighter, less dangerous work.​


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(Sources: https://www.constructiondive.com/news/japanese-researchers-create-humanoid-bot-that-installs-drywall-independentl/538678 & https://www.engadget.com/2018/10/01/aist-humanoid-robot-installs-drywall)


SAM100 is a bricklaying robot for onsite masonry construction. Designed to work with the mason, assisting with the repetitive and strenuous task of lifting and placing each brick. The mason will continue to own the site setup and final wall quality but will improve efficiency through the operation of SAM.

(Source: https://www.construction-robotics.com/sam100/)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


The ‘Allegory of the Cave’

The Allegory of the Cave is a story from Book VII in the Greek philosopher Plato‘s masterpiece The Republic, written in 517 BCE. It is probably Plato’s best-known story, and its placement in The Republic is significant, because The Republic is the centerpiece of Plato’s philosophy, and centrally concerned with how people acquire knowledge about beauty, justice, and good. The Allegory of the Cave uses a metaphor of prisoners kept chained in the dark to explain the difficulties of reaching and sustaining a just and intellectual spirit.

The ‘Allegory Of The Cave‘ is a theory put forward by Plato, concerning human perception. Plato claimed that knowledge gained through the senses is no more than opinion and that, in order to have real knowledge, we must gain it through philosophical reasoning.

Plato’s “The Republic Book 7” ‘On Shadows and Realities in Education

As our interaction with technology accounts for more of each day, I cannot help but wonder if our perceptions of reality will shift as a civilization. What is real and what is an illusion?

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


Glossary of Green Terminologies

The following is a quick reference guide to get you started understanding the jargon associated with green design and construction. We hope you find it useful.

1,000 ppm

One thousandth parts per million is the minimum disclosure threshold. Manufacturer measures and discloses all intentionally added ingredients and residuals that exist in the product at 1000 ppm (0.1%) or greater. These may  trigger a GreenScreen Benchmark (BM-1 or LT-1) or Possible Benchmark 1 (BM-P1 or LT-P1).

10,000 ppm (As per MSDS)

Manufacturer discloses all intentionally added ingredients and residuals that exist in a product. This is the threshold that is required by current MSDS standards

100 ppm

One hundred parts per million is the ideal disclosure threshold. Manufacturer measures and discloses all intentionally added ingredients and residuals that exist in the product at 100 ppm (0.01%) or greater. These may trigger a GreenScreen Benchmark (BM-1 or LT-1) or Possible Benchmark 1 (BM-P1 or LT-P1).

Accessory Materials

Used for the installation, maintenance , cleaning and operations materials; including materials recommended by warranty. For example, if a carpet requires a specific type of adhesive. The adhesive would be the accessory materials.

Assessment

the evaluation of the toxicological properties (hazards) of chemicals; evaluates exposure and risk assessment in relation to both environmental and human health scenarios.

Associated Hazard

disclosure of the health hazards associated with each ingredient; Portico uses a minimum set of authoritative chemical hazard lists against which ingredients are screened for human health and environmental hazards.

Asthmagen

Asthmagens are substances that are known to cause or exacerbate asthma. Asthma is a complex disease, and there is not enough evidence to point to any single cause. Public health agencies often report dust, pet dander, environmental air pollution, tobacco smoke, respiratory infections, mold, exercise, and stress as common triggers of asthma attacks.

Health organizations have also identified a number chemical asthmagens, including many that are commonly used in building materials, such as floorings, insulations and cabinet substrates. These chemicals include: formaldehyde, toluene, styrene, BPA and certain phthalate plasticizers.

Despite better management of asthma through medication, improved outdoor air quality and a dramatic decline in tobacco smoking, the incidence of asthma has continued to rise, especially in children — and in particular among children who are living in poverty.

Authoritative chemical hazard lists

a list of chemicals and their association to human health or environmental hazards. These lists are created by an expert assessment of scientific evidence by a recognized authoritative body.

Biobased

“Biobased” is a term used in the marketing materials of many types of products. While biobased technically describes a product made from a living material (soybean oil, wool, etc.) marketing materials may stretch this definition to include minerals or other naturally occurring materials that aren’t renewable, or suggest that an entire product is made of biobased materials, when in fact only a small percentage of the product is.

Blowing Agent

A class of chemicals that can generate foam in materials, such as those used in insulation, which later harden or solidify into long-lasting structures. Many are known to possess extremely high global warming potential; chlorofluorocarbons (CFCs) have been mostly eliminated from new production since the 2000s, but hydrofluorocarbons (HFCs) are still prevalent. Blowing agents, as a class of products used in building product manufacture, are in an active transition toward healthier and more environmentally friendly options.

CAS Number

chemical abstract service number is a unique numerical identifier for every chemical described in open scientific literature of elements, chemical compounds, polymers and other substances.

Carcinogen/Cancer

Can cause or contribute to the development of cancer.

Characterization

identification and disclosure of ingredients and all hazards associated with ingredient components in the product/material formulation.

Common Product Profile

A profile of a generic, non-manufacturer-specific product type that contains: a brief description of the product type, the expected composition of the product based on publicly available sources, and corresponding health hazards inherent to this composition. Common Product Profiles (CPs) developed as part of the Quartz Project include additional information about the life cycle of the product, such as its contribution to global warming. See http://www.quartzproject.org/ for more information on CPs.

Developmental Toxicant

Can cause harm to a developing child, including birth defects, low birth weight, and biological or behavioral problems that appear as the child grows.

Disclosure Threshold

the level at which all intentionally added ingredients and residuals in the product/material formulation are disclosed (1,000 ppm, 100 ppm, or other). Different standards require specific disclosure threshold. MSDS (Materials Safety Data Sheets require minimum of 10,000ppm.

Endocrine/Hormone Disruptor

Can interfere with hormone communication between cells which controls metabolism, development, growth, reproduction, and behavior (the endocrine system). Linked to health effects such as obesity, diabetes, male reproductive disorders, and altered brain development.

Environmental Attributes

this information can be found in an EPD, LCA, or other studies of global warming impact, carbon content, and embodied energy. We recommend providing this information (when available) because it will be helpful for LEED and LBC regional credit documentation and carbon accounting.

Flame Retardants

Flame retardants are chemical additives to building products that reduce their flammability. They are commonly found in textiles, plastics, coatings, finishes and foams. Halogenated flame retardants – those made with chlorine or bromine – are particularly toxic to human health, and the planet.

Flue-Gas Desulfurization (FGD)

Flue-gas desulfurization is an environmental control technology installed in the smokestacks of coal-fired power plants designed to remove pollutants from the air. These controls are also called “scrubbers”. Once the scrubbers are full of sulfur dioxide, they are often used to create synthetic gypsum. FGD gypsum can be used in drywall, but also in concrete and other applications where mined gypsum can be used. FGD can contain heavy metals such as mercury that can be released into the air when it is incorporated into these products.

Formaldehyde

Formaldehyde is a colorless gas used as a preservative and disinfectant in the building industry, and in the manufacture of polymers. Formaldehyde is carcinogenic, irritates the eyes, nose, and lungs, and is known to react with other atmospheric chemicals to produce the deadly gas carbon monoxide. Formaldehyde is used in some paints and adhesives, in some fabric treatments, and, significantly, in the manufacture of polymeric binding resins used in a wide variety of building products. Phenol formaldehyde, urea formaldehyde, and melamine formaldehyde are all known to release formaldehyde over time long after product installation in residential and commercial spaces.

Global Warming

Can absorb thermal radiation, increasing the temperature of the atmosphere and contributing to climate change.

Global Warming Potential (GWP)

Known as “greenhouse gasses,” certain gasses have the ability to warm the earth by absorbing heat from the sun and trapping it the atmosphere. Global Warming Potential is a tool that allows scientists to compare the severity of greenhouse gasses based on how much heat they can trap, and how long they remain in the atmosphere. By using carbon dioxide for each comparison, a larger GWP number, the more a gas warms the earth, and contributes to climate change.

Look for GWP data on Environmental Product Declarations, and learn more about interpreting these numbers at http://www.epa.gov/ghgemissions/understanding-global-warming-potentials.

GreenScreen

short for “GreenScreen for Safer Chemicals”, a chemical disclosure and assessment standard  developed by Clean Production Action to rank chemicals along a four point scale between the most toxic chemicals and the most benign to guide substitution efforts.

HPD

also known as Health Product Declaration. It is a standardized format that allows manufacturers to share contents of their products, including any hazardous chemicals.

HPD-1

status marked for products that have a Health Product Declaration with full ingredient and hazard listings and a hazard translator with a disclosure threshold of 1000 or 100 ppm; can contain LT-1 scored components

HPD-2

status marked for products that have a Health Product Declaration with full ingredient and hazard listings and a hazard translator with a disclosure threshold of 1000 or 100 ppm; can NOT contain LT-1 scored components

HPD-Partial

status marked for products that have a Partial Health Product Declaration and have characterization of hazards and hazard translator for ingredients; exceptions are acceptable with a disclosure threshold of 1000 ppm

Hazard

Hazard is an intrinsic property of a substance – its potential to harm humans or some part of the environment based on its physical structure and properties. We can assess the hazard of a chemical or material by reviewing the scientific evidence for the specific kinds of harm that a substance can cause (often called the endpoints), such as damage to the human reproductive system, or the onset of asthma. On HomeFree, hazards are displayed with a color indicating the level of concern for each one. Purple is the highest level of concern, followed by red, and then orange.

Because very few products on the market are made with ingredients that have no hazards, you should expect to see hazards called out, even for products that are considered healthier options. The trick is to compare hazards between products, and whenever possible, prefer the product with fewer hazards.

Health Endpoint

A disease symptom or related marker of a health impact on a human or other organism. Examples of human health endpoints include carcinogenicity (causes cancer), reproductive and developmental toxicity, respiratory sensitization, etc. Health endpoints are due to the inherent hazards of a substance, and are determined by authoritative bodies, such as the US EPA or the National Institutes of Health.

Information Request Sent

this means that an email letter has been sent to the manufacturer requesting information about a specific product. This IR may ask the manufacturer to share HPD type data, a GreenScreen Assessment, or a C2C certification in order to meet Google’s Healthy Materials criteria

Intentional Content

each discrete chemical, polymer, metal, bio-based material, or other substance added to the product by the manufacturer or supplier that exists in the product as delivered for final use requires its own line entry and must account for over 99% of the total product. To add content you may enter it by using a CAS registry number, chemical name, abbreviations, common/ trade names, genus/species (for biobased materials), product or manufacturer name (for components)

Inventory

list of product contents, ingredients

Lifecycle

In biology, the term “lifecycle” describes the arc an organism undergoes from birth, through stages of growth and development, to its death. When applied to building products, “lifecycle”describes the arc that chemicals or materials take from the extraction of the raw materials needed for their creation, through their synthesis and inclusion in a building product, the period of time that the product is installed in a building, its eventual removal from the building, and its disposal/reuse/recycling at the end of its useful life. Products (and the chemicals and materials used to make them) often present human and environmental health hazards at any step in this lifecycle.

Material Health

listing the ingredients and present chemical hazards of a product and optimizing towards safer materials

Mutagen

Can cause or increase the rate of mutations, which are changes in the genetic material in cells. This can result in cancer and birth defects.

Optimization

the absence of any “chemicals of concern” in the product/material formulation.

Ozone Depletion

Can contribute to chemical reactions that destroy ozone in the earth’s upper atmosphere.

PBTs

Persistent, Bio-accumulative Toxicants; these are chemicals that are toxic, persist in the environment, bioaccumulate in the food chains, and consequently pose risks to the human health and environment

Persistent Bioaccumulative Toxicant (PBT)

Does not break down readily from natural processes, accumulates in organisms, concentrating as it moves up the food chain, and is harmful in small quantities.

Portico

formerly known as the Healthy Materials Tool; is a new portal for entering and accessing building  product data. Portico is a database that allows project teams unparalleled access to a vast selection of building products. Portico automatically screens manufacturer product information so that products are available in front of Google’s design teams right away.

Predicted from Process Chemistry

Fully disclosed projected residuals based on process chemistry. This option is suggested for manufacturers without the capability of measuring actual residuals. Indicate the tool or other basis for prediction in the Disclosure Notes. The HBN Pharos tool is an example of a tool that predicts potential residuals.

Publish

share HPD information solely to Google, not to general public. If public, please share public URL in the transparency section

Reproductive Toxicant

Can disrupt the male or female reproductive systems, changing sexual development, behavior or functions, decreasing fertility, or resulting in loss of a fetus during pregnancy.

Residual Content

the by-product of a reaction of two or more chemicals that are used in the manufacturing process; known as trace substances remaining in the product from manufacturing steps (such as monomers and catalysts) or contaminants that come with raw materials. Residuals can be known from testing as well as estimated from process chemistry assessment. Predicted from Process Chemistry definition noted above.

Respiratory Sensitization/Asthmagen

Can result in high sensitivity such that small quantities trigger asthma, rhinitis, or other allergic reactions in the respiratory system. This can can exacerbate current asthma as well as cause the disease of asthma.

Screening

review contents against authoritative chemical hazard lists. Health Product Declaration standard uses screening as a pathway to understand and assess products for any human health hazard endpoints.

Self-declared

a product disclosure and screening/assessment which is created “in-house” by the manufacturer of the product, and does not utilize a third party assessor.

Third Party Assessor

an independent assessment body which is not affiliated with the manufacturer or the product.

Tint

Tints are a mix of pigments and other ingredients that give paints their distinct color. These tints can be a substantial source of VOC content in addition to whatever VOCs are in the paint itself. Darker and richer colors will tend to be higher in VOC content. Some manufacturers have developed low or zero VOC tint lines that can be used to insure that a low VOC paint product remains so even in dark or rich colors.

Transparency

the level of product/material formulation information (including ingredients names and associated hazards) being shared by the manufacturer with the end users (i.e. public, third party, Google).  Portico’s transparency category gives points to manufacturers who share product information (HPD) publicly rather than just to Google.

VOC

Volatile Organic Compound

VOC Content

provide the regulatory VOC content  for liquid/wet applied product in g/L; if the VOC content has not been third party certified and there is no standard for the product, indicate “none” on the VOC content line. If the product is not wet applied, indicate N/A

VOC Emission

emissions testing and certification for any product for which the current version of the CDPH (CA Department of Public Health) Standard Method provides emission scenarios

VOCs

Volatile organic compounds (VOC) means any compound of carbon (excluding carbon monoxide, carbon dioxide, carbonic acid, metallic carbides or carbonates, and ammonium carbonate), which react in the atmosphere in the presence of sunlight.

Verification

assessments verified by an independent, third party assessor, in compliance with specific requirements pertaining to the standard at hand.

Zero VOC

5 g/L cutoff threshold recognized by SCAQMD for products that are Zero VOC

ppm

parts per million (1,000 ppm = 0.1%; 100 ppm = 0.01%).

(Source: https://homefree.healthybuilding.net/glossary)

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


Architect of the Week: Eugene Tsui

Eugene Tssui (also spelled Tsui, born September 14, 1954) is an American Architect. His built projects are known for their use of ecological principles and highly experimental “biologic” design, a term coined by Tssui himself in the 2010 issue of World Architecture Review. He has also proposed a number of massive, radical projects, such as a bridge over the Strait of Gibraltar and a 2-mile-high tower capable of housing 1 million residents.

The following article was first published by Nov. 30, 2015, 7 a.m. at Berkeleyside; Tom Dalzell’s blog: http://quirkyberkeley.com.

2727 Mathews Street. Photo: John StoreyThe “Fish House” at 2747 Mathews St. in Berkeley. Photo: John Storey

The “Fish House” at 2747 Mathews St. in Berkeley, designed by Emeryville’s Eugene Tssui, is the least-expected and probably the most-photographed architectural design in Berkeley.

2727 Mathews Street. Photo: John Storey2747 Mathews St. Photo: John Storey

2727 Mathews Street. Photo: John Storey
2747 Mathews St. Photo: John Storey

2727 Mathews Street. Photo: Joe Reifer
2747 Mathews St. Photo: Joe Reifer

The image above was photographed during the June 2008 full moon around midnight, with an exposure time of approximately 6 minutes. It takes the house’s other-wordly element into a whole new other world.

2727 Mathews Street. Photo: John Storey
2747 Mathews St. Photo: John Storey

Crumbled abalone shell is mixed in with the stucco-ish exterior, providing the sparkle.

2727 Mathews Street. Photo: John Storey
2747 Mathews St. Photo: John Storey

What look like flying buttresses — sort of — project from the rear of the house. They serve as slide escapes from the second story in the event of an evacuation.

Tssui designed the home for his parents, who lived in it from 1995 until last year. It is on Mathews Street, just west of San Pablo Park. But for it, Mathews Street is largely a street without quirk.

A color-enhanced scanning electron micrograph of a tardigrade found in moss samples. Photo: New York Times
A color-enhanced scanning electron micrograph of a tardigrade found in moss samples. Photo: New York Times

The house is designed based on the tardigrade, a segmented marine micro-animal. The tardigrade can  survive extreme cold and extreme hot, extreme pressure or a vacuum, radiation doses, and can go without food or water for more than ten years.

When Tssui’s parents moved to Berkeley, they were concerned about earthquakes and wanted him to design a house in which they would be safe no matter what the Richter Scale said. Tssui consulted zoology and learned that the tardigrade is the most indestructible creature on the planet. True to his belief in biomimicry, he created a house based on the architecture of the lowly tardigrade. He believes that the Mathews Street house is safe from fire, earthquake, flood and pest.

Several neighbors from the block of 1920s California bungalows strenuously objected to the house design; the design review process dragged out more than a year. Tssui credits then-mayor Loni Hancock with stepping in and putting an end to the debate in the name of freedom of thought and design.

The house’s proper name is Ojo del Sol or Tai Yang Yen – the Sun’s Eye. The name alludes to the south-facing 15-foot oculus window, a common feature of Byzantine and Neoclassical architecture. The oculus here serves to light and warm the house. Tssui now uses the name given the house by the public, the Fish House, tardigrade or not.

Eugene Tssui. Photo: John Storey
Eugene Tssui. Photo: John Storey

Tssui is a visionary architect. His degrees are from the University of Oregon and Cal, but he owes much of his architectural vision to three architects with whom he apprenticed: Victor Prus in Montreal, Bruce Goff in Tyler, Texas, and Frei Otto (tensile and membrane structures of glass and steel) in Germany. After Tssui’s first semester at Columbia’s School of Architecture, Dean of Architecture James Stewart Polshek suggested to Tssui that an apprenticeship might suit him better than Columbia. That was a good call.

Bavinger House, Norman, Oklahoma. Photo: Wikipedia
Bavinger House, Norman, Oklahoma. Photo: Wikipedia

Tssui apprenticed with Goff (previous ILMA of the Week: Bruce A. Goff), an extraordinarily creative and innovative architect from 1977 until 1982. Most of Goff’s built projects were in Oklahoma.

Like Goff, Tssui scorns rectilinear design. Tssui calls his design ethic-biologic, based on the architecture of living things. Biomimicry is another term that might describe Tssui’s approach, finding sustainable solutions to human challenges by emulating nature’s patterns and strategies.

Watsu Center at Harbin Hot Springs, Middletown, California. Photo courtesy of Eugene Tssui.
Watsu Center at Harbin Hot Springs, Middletown, California. Photo: courtesy Eugene Tssui

Tssui’s built projects include several in the East Bay, as well as the Watsu Center in Middletown, recently damaged by the Valley Fire.

Ultima Tower design. Photo courtesy of Eugene Tssui.
Ultima Tower design. Photo: courtesy Eugene Tssui

Gibralter Bridge design. Photo courtesy of Eugene Tssui.
Gibraltar Bridge design. Photo: courtesy Eugene Tssui

Tssui thinks big, an unspoken advocate of the “go big or go home” school of thought. He has designed a submerged bridge with an island half way across to span the Straits of Gibraltar, as well as a two-mile-high tower to house 1,000,000 people. He has visited Tarifa, Spain and North Africa, talking up his bridge project, which draws on wave power and wind power.

There is nothing about Tssui’s upbringing in Minneapolis that would have predicted his trajectory. His parents were no-nonsense immigrants who left Mainland China as Mao’s revolution swept Communists into power. The outward and physical manifestation of his inner self in high school was to play the prankster — Dennis the Menace constantly in trouble. That he would become a polymath nonpareil would not have been obvious at the time.

Business Card

I have never before today used the term “polymath,” a person whose expertise spans a significant number of different subject areas. The polymath draws upon complex bodies of knowledge to solve specific problems. Eugene Tssui is a polymath.

I actually came across the word before I saw his business card. I believed that I had thought of something he hadn’t. Obviously I had not. The polymath beat me to it. I think Tssui makes most of the world’s polymaths look lazy and shallow, but there is no way to prove or disprove this.

Courtesy of Eugene Tssui.
Photo: courtesy Eugene Tssui

Courtesy of Eugene Tssui.
Photo: courtesy Eugene Tssui

Tssui believes in vigorous, challenging exercise. He studied Northern Praying Mantis, a style of Chinese martial arts. He is a boxer and gymnast of some renown. He eats every other day, and sparingly. What discipline! He sees it as a logical, if not obvious, way to maintain a healthy weight.

Courtesy of Eugene Tssui.
Photo: courtesy Eugene Tssui

He is a concert pianist and flamenco guitarist. Piano was the instrument of his childhood. He keeps it up, with Chopin at the top of his favorite composer list. He is intrigued by the mathematics of music, but more drawn by the emotion, which he sees as central to human meaning, be it in music, architecture, or any facet of life.

He composes, at times blending his life philosophy with his music, as in “Make What is Wrong, Right”, played “with insistent, battle march feeling” in the five-flats challenging key of D♭major: “We will not be lured by comfort or ease / To make right the acts we know are wrong / And when challenge sends it clarion call / We will act, we will stand, we will fight.”

Tssui began Flamenco dancing in Montreal in 1970, and by 1972 was the principal dancer of the Minneapolis Flamenco Dance Troupe. University of Oregon professor David Tamarin introduced Tssui to flamenco guitar in 1978. Tssui is drawn to flamenco because it exudes pain and suffering and sadness.

Eugene Tssui, wearing a ring given him by a Mongolian shaman. Photo: John Storey
Eugene Tssui, wearing a ring given him by a Mongolian shaman. Photo: John Storey

Photo courtesy: Eugene Tssui.
Photo: courtesy Eugene Tssui

Tssui has lived for long stretches in China. In recent years he has become fascinated with Mongolia. Mongolian culture and history inform Tssui in many ways, as do the life and writings of Genghis Kahn. His experiences with a Mongolian shaman have made him a more spiritual man, an aspect of life that he had not formerly explored.

He has lectured at Cal, served as a research scholar at Harvard, taught at Ohio University and North Carolina State University and Harbin University and Peking University and South China University of Technology. He speaks fluent Mandarin.

He [also] designs furniture.

Rolling buffet table designed by Eugene Tssui. Photo courtesy of Eugene Tssui.
Rolling buffet table designed by Eugene Tssui. Photo: courtesy Eugene Tssui

He [also] designs clothes.

Eugene Tssui. Photo: John Storey
Eugene Tssui. Photo: John Storey

Eugene Tssui. Photo: John Storey
Eugene Tssui. Photo: John Storey

Eugene Tssui. Photo: John Storey
Eugene Tssui. Photo: John Storey

Eugene Tssui. Photo: John StoreyEugene Tssui. Photo: John Storey

The style draws on indigenous Mongolian designs and is highly functional. The sequins on the purple suit shown above, and in the photo of Tssui in front of the Fish House, are small solar panels which can be used to charge a mobile phone.

What’s next for our hometown polymath?

Courtesy of Eugene TssuiCourtesy of Eugene Tssui

Courtesy of Eugene TssuiCourtesy of Eugene Tssui

Courtesy of Eugene TssuiCourtesy of Eugene Tssui

Courtesy of Eugene TssuiCourtesy of Eugene Tssui

He is designing a live/work space to be built in San Pablo. The biologic design is obvious, although the organism that is mimicked is less obvious. He is designing it such that the electricity used in the building will be generated by the user — bicycling or by arms; he will not install solar panels because he finds them toxic when constructed. He is designing it to be cooled and warmed by the earth, and it is aerodynamic for passive ventilation. And so on. Tssui describes himself as someone who asks questions that most people try to avoid. He takes the tough questions and looks for fascinating and universally applicable answers. It is, to say the very least, the product of a creative, answer-seeking polymath mind.

Check out a film on Netflix about Eugene Tsui by clicking here.

And don’t forget to check out Tom Dalzell’s blog: http://quirkyberkeley.com.

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook


Higher Education

Blog Posts Related to Higher Education

  1. Library of the Future – For Colleges & Universities
  2. Mansueto Library by JAHN
  3. Creative Arts Center at Brown University by Diller Scofidio + Renfro
  4. What is a High Performance School?
  5. Architect’s Sketchbook – Montclair State University (Sketches by @FrankCunhaIII, 2017)
  6. 13 Examples of Green Architecture
  7. WELL Communities: Health & Wellness Lifestyle
  8. You Know LEED, But Do You Know WELL?
  9. The 2030 Challenge for Planning @Arch2030
  10. What is The 2030 Challenge? @Arch2030
  11. Smart Cities
  12. Top 20: Technology & Innovation Ideas For Architects

My Higher Education Projects

  1. New Computer Science Facility for College of Science & Mathematics
  2. School of Nursing & Graduate School
  3. New Research Facility, Montclair State University
  4. Conrad J. Schmitt Hall Renovation, Montclair State University
  5. Frank Sinatra Hall, Montclair State University
  6. Music School, Montclair State University
  7. Student Recreation Center, Montclair State University
  8. College Hall (In Progress)
  9. Conceptual Design – Adaptive Re-Use of Existing Cogeneration Plant
  10. Conceptual Design – Study Atrium
  11. Small Project – Successful Conversion (Tech Classrooms) Before & After
  12. New Center for Environmental Life Sciences
  13. Babbio Center, Stevens Institute of Technology

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,

FRANK CUNHA III
I Love My Architect – Facebook

 


13 Examples of Green Architecture

The Morris & Gwendolyn Cafritz Foundation Environmental Center

The nickname for the Morris and Gwendolyn Cafritz Foundation Environmental Center is the Grass Building, and it perfectly captures its spirit. It’s a structure so thoughtfully designed it’s almost as energy-efficient and low impact as the greenery that surrounds it.

The Maryland building is part of an educational farm on the Potomac River Watershed that the Alice Ferguson Foundation used to teach people about the natural world. This new building—which became the 13th in the world to receive full Living Building Challenge certification in June 2017—is an educational facility designed to blur the lines between indoors and out, while still providing shelter as needed. “Part of the intent of the building is to be in the landscape and still have a bathroom to use,” says Scott Kelly, principal-in-charge at Re:Vision, a Philadelphia-based architecture and design studio.

Further Reading:
https://gbdmagazine.com/2017/grass-building
https://www.aia.org/showcases/92581-the-morris–gwendolyn-cafritz-foundation-env
https://living-future.org/lbc/case-studies/morris-gwendolyn-cafritz-foundation-environmental-center
http://hughloftingtimberframe.com/gallery/commercial/cafritz-foundation-environmental-center
http://www.cafritzfoundation.org/

Brock Environmental Center

Drawing thousands of students, the Brock Environmental Center is a regional hub for the Chesapeake Bay Foundation, in Virginia Beach, Virginia, supporting its education and wetlands restoration initiatives. A connection to nature defines the building’s siting, which provides sweeping views of the marsh and also anticipates sea-level rise and storm surges with its raised design. Parts were sourced from salvage: Its maple floors once belonged to a local gymnasium while school bleachers, complete with graffiti, were used for interior wood trim. The center was recognized for its positive footprint: It has composting toilets, captures and treats rainfall for use as drinking water, and produces 80 percent more energy than it uses, selling the excess to the grid.

Further Reading:
http://www.cbf.org/about-cbf/locations/virginia/facilities/brock-environmental-center
https://living-future.org/lbc/case-studies/the-chesapeake-bay-brock-environmental-center
https://www.visitvirginiabeach.com/listing/chesapeake-bay-foundations-brock-environmental-center/979
https://www.aia.org/showcases/76311-brock-environmental-center

Discovery Elementary School

Students have three distinct, age-appropriate playgrounds—with natural elements such as rocks and fallen trees—at Arlington, Virginia’s Discovery Elementary School. The name honors astronaut John Glenn, who returned to space on the Discovery shuttle and once lived in the neighborhood. Exploration is a theme at the school, whose interior focuses on forests, oceans, atmosphere, and the solar system. The largest zero-energy school in the country, it offers “hands-on learning around energy efficiency and generation,” jurors noted. The school maximizes natural light and provides views to the outside in all classrooms.

Further Reading:
https://www.aia.org/showcases/71481-discovery-elementary-school-
https://www.aiadc.com/sites/default/files/031%20-%20DiscoveryElementarySchool.pdf
https://www.google.com/search?q=Discovery+Elementary+School+AIA&tbm=isch&tbo=u&source=univ&sa=X&ved=0ahUKEwjS-pnHo6LcAhUMON8KHSlUDlYQsAQIdA&biw=1583&bih=1187

Bristol Community College

A laboratory is an energy-intensive enterprise, with specialized lighting and ventilation needs. That’s why jurors praised the airy health and science building at Bristol Community College, in Fall River, Massachusetts, for its net-zero energy achievement, “a difficult feat,” they noted, “in a cold climate like New England’s.” The move saves $103,000 in annual operating costs and allows the college, which offers a suite of courses in sustainability and energy, to practice what it teaches. Part of a holistic campus redesign, the new building’s location increases the density—and thus walkability—of campus for students.

Further Reading:
https://www.aia.org/showcases/71576-bristol-community-college-john-j-sbrega-heal
https://www.mass.gov/service-details/bristol-community-college-john-j-sbrega-health-and-science-building
http://www.architectmagazine.com/project-gallery/bristol-community-college-john-j-sbrega-health-and-science-building_o

Central Energy Facility

Orange and red pipes flaunt their role in “heat recovery” at Stanford University’s Central Energy Facility. The center for powering the California campus—more than a thousand buildings—the facility was transformed from an aging gas-fired plant to one fueled mostly by an off-site solar farm, fulfilling a goal of carbon neutrality and reducing energy use by a third. With large health care and research buildings, the campus needs as much heating as cooling; now a unique recovery system taps heat created in cooling processes to supply 93 percent of the heating and hot water required for campus buildings. The plant reduces Stanford emissions by 68 percent and potable water usage by 18 percent, potentially saving millions of dollars and one of the state’s scarce resources.

Further Reading:
https://www.aia.org/showcases/25976-stanford-university-central-energy-facility
https://sustainable.stanford.edu/new-system
https://www.archdaily.com/786168/stanford-university-central-energy-facility-zgf-architects
https://www.zgf.com/project/stanford-university-central-energy-facility

Ng Teng Fong General Hospital

Like other buildings in Singapore, Ng Teng Fong General Hospital incorporates parks, green roofs, and vertical plantings throughout its campus. But the city-state’s hospitals haven’t traditionally offered direct access to fresh air, light, and outdoor views. This hospital marks a dramatic change, optimizing each for patients. About 70 percent of the facility is naturally ventilated and cooled by fans, cross-ventilation, and exterior shading, saving on precious water resources. The building uses 38 percent less energy than a typical hospital in the area.

Further Reading:
https://www.aia.org/showcases/76821-ng-teng-fong-general-hospital–jurong-commun
http://www.hok.com/about/news/2017/07/25/ng_teng_fong_general_international_academy_for_design_and_health_awards
https://www.archdaily.com/869556/aia-selects-top-10-most-sustainable-projects-of-2017/58f7c23ce58eceac31000615-aia-selects-top-10-most-sustainable-projects-of-2017-photo
http://www.topicarchitecture.com/articles/154396-how-modern-hospitals-recognize-the-impact-o

Eden Hall Farm, Chatham University

After receiving the donation of 388-acre Eden Hall Farm, 20 miles north, Pittsburgh’s Chatham University created a satellite campus centered around a sustainable living experiment. The university views the landscape—an agricultural area adjacent to an urban center—as critical to supporting cities of the future. The original buildings are complemented by new facilities for 250 residential students (and eventually 1,200), including a dormitory, greenhouse, dining commons, and classrooms. Students get hands-on experience in renewable energy systems—the campus generates more than it uses—sustainable agriculture and aquaculture, waste treatment, and water management. Now home to the Falk School of Sustainability, the farm is producing the next generation of environmental stewards, who follow in the footsteps of alum Rachel Carson.

Further Reading:
https://www.aia.org/showcases/76481-chatham-university-eden-hall-campus
http://www.chatham.edu/news/index.php/2018/01/chatham-views/from-eden-hall-pioneer-to-farm-manager
https://www.archdaily.com/869556/aia-selects-top-10-most-sustainable-projects-of-2017
https://falk.chatham.edu/masterplan.cfm

Milken Institute School of Public Health, George Washington University

At George Washington University’s Milken Institute School of Public Health, located in the nation’s capital, design embodies well-being. Built around an atrium that admits light and air, the structure encourages physical activity with a staircase that spans its eight levels. A green roof reduces storm runoff; rainwater is collected and stored for plumbing, resulting in a 41 percent reduction in toilet fixtures’ water use. Limestone panels (left) were salvaged from the previous building on the site. Materials used throughout the building contain recycled content.

Further Reading:
https://www.aia.org/showcases/71306-milken-institute-school-of-public-health
https://publichealth.gwu.edu/content/milken-institute-school-public-health-wins-excellence-architecture-new-building-merit-award
http://designawards.architects.org/projects/honor-awards-for-design-excellence/milken-institute-school-of-public-health-george-washington-university/

National Oceanic and Atmospheric Administration’s Inouye Regional Center

Located at the heart of Pearl Harbor, on Oahu’s Ford Island, the National Oceanic and Atmospheric Administration’s Inouye Regional Center repurposed two airplane hangars—which narrowly escaped destruction in the 1941 attack—linking them with a new steel and glass building (right). The research and office facility for 800 employees was raised to guard it from rising sea levels. Given the size of the hangars, daylight illuminated only a small fraction of the space, so specially crafted lanterns reflect sunlight further into their interiors. Necessity required invention: Due to anti-terrorism regulations, no operable windows were allowed in the space. Through a passive downdraft system that taps prevailing sea breezes, the building is completely naturally ventilated. The adjacent waterfront was returned to a more natural state with native vegetation.

Further Reading:
https://www.aia.org/showcases/76911-noaa-daniel-k-inouye-regional-center
http://www.hpbmagazine.org/NOAA-Daniel-K-Inouye-Regional-Center-Honolulu-Hawaii/
http://www.architectmagazine.com/project-gallery/noaa-daniel-k-inouye-regional-center_o
http://www.hok.com/design/type/government/national-oceanic-and-atmospheric-administration-noaa/

R.W. Kern Center

Serving as the gateway to Hampshire College, in Amherst, Massachusetts, the multipurpose R.W. Kern Center holds classrooms, offices, a café, and gallery space—and is the place where prospective students are introduced to campus. The school converted what was once an oval driveway into a wildflower meadow, now encouraging a pedestrian approach (seen above). The center is self-sustaining, generating its own energy through a rooftop solar array, harvesting its water from rainfall, and processing its own waste. Its gray water treatment system is in a pilot program for the state, and may pave the way for others.

Further Reading:
https://www.aia.org/showcases/76921-rw-kern-center
https://architizer.com/projects/rw-kern-center
https://www.hampshire.edu/discover-hampshire/rw-kern-center

Manhattan 1/2/5 Garage & Salt Shed

Two buildings belonging to New York City’s sanitation department redefine municipal architecture. Resembling a grain of salt, the cubist form of the Spring Street Salt Shed holds 5,000 tons for clearing icy streets. The Manhattan 1/2/5 Garage (background), whose floors are color-coded for each of the three districts, is home to 150 vehicles, wash and repair facilities, and space for 250 workers. The garage is wrapped in 2,600 aluminum “fins,” shading devices that pivot with the sun’s rays, reducing heat gain and glare through the glazed walls while still allowing views to the outside. Municipal steam heats and cools the building, so no fuels are burned. A 1.5-acre green roof reduces heat-island effect and filters rainwater. A condensate by-product of the steam is also captured, and, along with the rainwater, used for toilets and the truck wash. Combined with low-flow fixtures, the process reduced water consumption by 77 percent.

Further Reading:
https://www.dattner.com/portfolio/manhattan-districts-125-garage/
https://www.ohny.org/site-programs/weekend/sites/dsny-manhattan-125-sanitation-garage-salt-shed
https://www.aia.org/showcases/76671-manhattan-districts-125-garage–spring-stree
http://www.architectmagazine.com/project-gallery/manhattan-districts-1-2-5-garage-spring-street-salt-shed_o
https://www.burns-group.com/project/manhattan-125-garage-and-spring-street-salt-shed/

Starbucks Hillsboro, Oregon

Starbucks has been a leader in the development and implementation of a scalable green building program for over a decade .Starbucks joined the U.S. Green Building Council® (USGBC) in 2001 and collaborated with them to develop the LEED® for Retail program, an effort to adapt LEED (Leadership in Energy and Environmental Design) to new construction and commercial interior strategies for retail businesses. In 2008,Starbucks challenged themselves to use LEED certification not just for flagship stores and larger buildings, but for all new, company-operated stores. Many people, even internally, were skeptical, especially with Starbucks growth across the globe. But by collaborating with USGBC and other like-minded organizations, we have been able to integrate green building design not only into new stores but also into our existing store portfolio. Starbucks has also succeeded in providing a practical certification option for retailers of all sizes.

Further Reading:
https://www.starbucks.com/responsibility/environment/leed-certified-stores

The Edge, Deloitte

The Edge, located in Amsterdam, is a model of sustainability.is billed as the world’s most sustainable office building and has the certification to prove it. But, it’s more than that. The place is, well, fun. And interesting. And inviting. So much so that professionals are actually applying for employment with Deloitte Netherlands because they want to work in the building. That it has become a recruiting tool is a satisfying side effect of a project designed to both redefine efficiency and change the way people work. “We wanted to ensure that our building not only had the right sustainability credentials, but was also a real innovative and inspiring place for our employees,” says Deloitte Netherlands CEO Peter Bommel.

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3-D Printing

We can attribute 3D printing technology to an American engineer and the co-founder of 3D systems, Chuck (Charles) Hull. He invented the first printing process that was capable of creating an actual, physical 3D object from a digital data file.  He called this process Stereolithography. In an interview, Hull admits how surprised he was of the capabilities and potential of his discovery. And however amazed people were of 3D printing in its infancy, few could have imagined where it was heading.

Chuck Hull Inventor

Early stage models: Concept models are quick and easy to produce. The moment you have your model you can begin discussions with clients and prospects. This saves time and money, reduces the risk of costly errors, and speeds up the entire design-to-agreement process.

Urban planning: Architects now have the ability to 3D print a model of an entire town or city. This is something that’s achievable within hours with the right equipment and print materials.

Model variations: Sometimes it’s useful to print a few variations of the same or similar models. This is an affordable way to help architects get to their final designs faster and with much less fuss.

3D-SectionModelTo summarize, here are the three key benefits of 3D printing for architects:

  1. Detailed 3D printed models help clients to better visualize final projects
  2. Reduced time (hours and days) spent creating models
  3. Over time, Architects can build a library of reusable 3D designs

(Source: http://3dinsider.com/3d-printing-architecture)

Further Reading:

http://www.lgm3d.com/professionals/students

We would love to hear from you on what you think about this post. We sincerely appreciate all your comments – and – if you like this post please share it with friends. And feel free to contact us if you would like to discuss ideas for your next project!

Sincerely,
FRANK CUNHA III
I Love My Architect – Facebook