Green building (also known as green construction or sustainable building) refers to a structure and using process that is environmentally responsible and resource-efficient throughout a building's life-cycle: from siting to design, construction, operation, maintenance, renovation, and demolition. Although new technologies are constantly being developed to complement current practices in creating greener structures, the common objective is that green buildings are designed to reduce the overall impact of the built environment on human health and the natural environment.
^Yan Ji and Stellios Plainiotis (2006): Design for Sustainability. Beijing: China Architecture and Building Press. ISBN 7-112-08390-7 Commercial Green Building System: In the various post we will discuss inspiring and innovative buildings around the United States of America and worldwide, while taking a briefly look at the new technologies and products rapidly immersing worldwide In my post below, I discuss some Latest Innovations in Commercial Green Building Products.
In my other two posts, April 26th and April 29th, I discussed some case studies in the US and around the world and some more recent innovations in Green Building Systems (mostly Residential).
Case Studies in the US (Google California Headquarters, San Francisco Public Utilities Headquarters, The Vitruvian Building System, Pittsburgh Skyscraper, The Wayne L. Morse Courthouse)
Case Studies around the world (South Africa's first green building, "Algae-powered" building in Germany, The Dice House in UK, Rotating Tower in Dubai)
More Recent Innovations in Residential Buildings (Solar Power, EcoSeal, BIPV windows from Tropiglas, Climate Wizard Evaporative Air Conditioner, Foamglas, A high R-value coating with Silica Aerogel, Drainline Heat Exchangers)
Latest Innovations As sustainable buildings become a necessity, we must constantly venture to find the most cost effective and innovative products and solutions. Below are a few new green building products that have exceeded their expectations, with newer technologies, recyclable materials and energy efficient product and trends. 1. The following video shows newer technologies that introduces you to innovation that improve the building HVAC, heating and cooling systems ensuring a highly energy efficient building. Filmed at the Toronto Green Build Expo: The Hottest Technology in Green Building 2011-2012
LifeLine CS (blue flooring at left) with a non-porous surface was used in this installation at Mercy Hospital in Muskegon, Michigan because of its low emissions, durability, and ease of maintenance.
The Finnish company Upofloor’s PVC-free LifeLine CS commercial resilient sheet flooring uses a tough wear layer and low-emitting materials to create a durable surface. It is appropriate for healthcare, education, and other public spaces prone to consistent, heavy foot traffic. Like Stratica, LifeLine CS has an “ionomer” wear layer comprised of an ethylene/methacrylic acid copolymer thermoplastic resin strengthened by ionically charged salts. The remainder of the material is approximately 60% calcium carbonate (limestone), small amounts of titanium dioxide, and 25% pre-consumer recycled LifeLine flooring from the trimming process that is melted back into the base. And though LifeLine CS is petroleum based, it provides several potential environmental advantages over other commercial flooring options.
Cypress Envirosystems offers analog-to-digital wireless controls for commercial thermostats, lighting, and other equipment. Engineered for retrofit applications, the company’s Wireless Pneumatic Thermostat (WPT) provides the ability to wirelessly control setpoints for daytime zone and night setback temperatures without having to change out pneumatic pipes, run wires, or open up walls or ceilings. These thermostats can be selected with options integrating them into building automation systems and can be used for utility demand response programs. http://www2.buildinggreen.com/buildinggreen-top-10-products-2012#6
4. AllSun Trackers Series 24 from All Earth renewable
These combine photovoltaic collectors, inverters, and controls with a ground-mounted tracker that uses GPS to follow the sun precisely as it moves across the sky in order to maximize the amount of light hitting the panels.
Knight Wall Systems makes commercial rainscreen framing systems that contain all the component parts, including cladding, and accommodate exterior insulation
helps keep moisture out of commercial building envelopes while permitting continuous insulation over the steel frame — typically an expensive and labor-intensive hand-cutting process when using other rainscreen systems. Because there are no clips, installation time is reduced and there is far less thermal bridging through the insulation.
CREE’s innovation is a slab and post wood design method that requires up to 50 percent shorter construction time compared to reinforced concrete and steel construction. The LCT system also requires 39 percent fewer resources, over the life of a building and takes advantage of engineered timber products.The company’s innovative timber and concrete hybrid technology enables architects to design stunning tall wood buildings up to 30 stories, that can be erected as quickly as a story a day.
Below I have highlighted a few sustainable building that stand out as inspirational examples both in the U.S.A and worldwide. Each building striving to use new and creative ways, architects and designers have successfully built structures that represent a growing sense of stewardship for the environment.
Commercial Green Buildings in the US:
Google's California Headquarters
San Francisco Public Utilities Headquarters
The Vitruvian Building System
Pittsburgh's skyscraper
Wayne L. Morse U.S Courthouse
Google to build green-roof California HQ
An image has been released of what looks set to become Google's new California HQ. Named Bay View, the nine-building campus is designed to maximize the likelihood of innovation-friendly chance encounters between the workforce.
"You can't schedule innovation," Google's David Radcliffe tells Vanity Fair. "We want to create opportunities for people to have ideas and be able to turn to others right there and say, 'What do you think of this?'"
This philosophy has fostered the design's angular office blocks, arranged back to back like nodding clergy. Despite the 1.1 million sq ft (102,000 sq m), employees will be a maximum of a 2.5-minute walk away from one another, Vanity Fair reports.
Perhaps most remarkable is that this is Google's first build. In its 15-year history, Google has only ever occupied buildings previously used by others. "We've been the world's best hermit crabs: we've found other people's shells, and we've improved them," Radcliffe told the magazine.
The Vitruvian Building System: green, cost-efficient and fast
Green Building with EPS
The essence of the green building is creating structures that are more efficient in their consumption of energy and water and less wasteful in their use of materials than conventional buildings. Vitruvian have achieved this in a number of ways. The modular roof and wall panels are made from Expanded Polystyrene (EPS) and light gauge steel. EPS is light weight (98% air and 2% polystyrene by volume) and highly energy efficient, requiring much less energy to produce than traditional building materials. The savings in heating and cooling alone, more than compensates for its production. Typically for every kilogram of oil used in its manufacture, about 200kg will be saved in reduced heating over the life of the building. The inter-lockable panels can easily be assembled and disassembled and due to their inert nature and longevity can be reused over and over again, without the need to find their way into landfill. The light weight panels and other building materials also reduce transport cost over traditional construction materials, adding to the minimization of greenhouse gases.
Smart software
Vitruvian’s proprietary software will build the shell in 3D once the design has been completed. Every component is labeled and cutting lists are produced for all elements of the structure and finish. Vitruvian claim that this will result in an overall waste of less than 1%, or 1/10 of that of traditional construction methods. The interlocking panel systems ensure installation is quick and easy, reducing construction costs. The result is an overall efficiency that will cut up to 20% off the costs of traditional construction whilst providing a clean, green, healthy and safe environment. Clever use of the software in the design stage will also enable identification of any problems upfront, eliminating them from the costly building phase. The software ensures that 3D structure and any associated data can be readily updated in seconds if design alterations are required
Pittsburgh's "breathing" building aims to be the world's greenest skyscraper
The PNC Financial Services Group hopes to exceed LEED Platinum requirements along with promoting a healthy indoor workplace with its latest development – the Tower at PNC Plaza. Located in downtown Pittsburgh on the corner of Fifth and Wood Streets, the building will be approximately 800,00 gross sq.ft (74,322 sq.mt) in size with a construction budget of approximately US$240 million. The "breathing" design created by architecture firm Gensler moves away from the traditional closed air-conditioned environment and has the lofty aim of becoming the greenest skyscraper in the world.
Employees in the 33 floor glass tower will be able to access daylight and fresh air, an experience which Gensler design director Hao Ko recognizes is much more of a European design feature then has been incorporated into current U.S. skyscrapers
The PNC Tower design recognizes that the Pittsburgh climate can also provide increased levels of natural light onto the floorspace along with improved regulation of temperatures for much of the year without using traditional, energy-intensive HVAC systems. The Tower hopes to achieve this by using a double-skin facade consisting of two panes of glass separated by an enclosed cavity which will allow external air inside. The facade will feature operable doors and windows that admit fresh air into the building during optimal conditions, which is effectively when the building is "breathing." A solar chimney is another component of the structures passive system: it pulls air in through the open windows, rather than sucking air out as usually occurs in a high rise building, the air then travels across the floors, is heated and exhaled through the roof shaft.
Like the CDC, this courthouse in Eugene, Oregon is a sustainable federal government building. This massive structure is on a site previously occupied by a cannery plant that contributed to water runoff in a climate with 51 inches (about 1 meter) of rainfall each year. Efforts to reduce runoff led to the construction of underground parking, allowing for more landscape, instead of concrete, to surround the building. Moisture sensors that regulate irrigation and plants that can sustain little irrigation also reduce water consumption for the site. Waterless urinals and low flow plumbing fixtures help as well. All in all, this structure reduces water consumption by 40 percent [source: AIA].
To conserve energy, the building's architects designed the roof with clerestory windows which let significant light into the courtrooms, restricting the need for other lights (which have sensors that detect occupancy and other light). Glazing on the structure also insulates heat. Although buildings with such high ceilings are costly to keep warm, a heating systems in the floor offers a solution for efficiency. Because heat rises, warming these rooms through the floor helps keep some heat near the floor. To keep the building cool in the winter, architects designed the structure to provide shade for certain areas of the building.
Builders also placed a high priority in using recycled content in such structures that used steel and aluminum.
According to the World Green Building Trends study, firms are shifting their business toward green building, with 51 percent of respondents planning more than 60 percent of their work to be green by 2015. This is a significant increase from the 28 percent that said the same for their work in 2013 and double the 13 percent in 2008.
This growth is not a trend localized to one country or region. From 2012 to 2015, the number of firms anticipating that more than 60 percent of their work will be green:
· More than triples in South Africa;
· More than doubles in Germany, Norway and Brazil;
· Grows between 33 and 68 percent in the United States, Singapore, the United Kingdom, the United Arab Emirates and Australia.
http://www.ca.uky.edu/gogreen/
The key driver to going green, according to the survey, is that now green building is a business imperative around the world. In the 2008 report, McGraw-Hill Construction found that the top driver for green building was "doing the right thing." However in 2012, business drivers such as client and market demand are the key factors influencing the market.
"The acceleration of the green building marketplace around the world is creating markets for green building products and technologies, which in turn will lead to faster growth of green building," said Harvey Bernstein, vice president of Industry Insights and Alliances at McGraw-Hill Construction. "And the fact that green is growing in all parts of the world indicates that there are market opportunities in both established markets as well as developing countries."
These opportunities are mapping against expected benefits:
· 76 percent report that green building lowers operating costs
· More than one third point to higher building values (38 percent), quality assurance (38 percent), and future-proofing assets (i.e., protecting against future demands) (36 percent)
On March 20, 2013: South Africa unveiled its first green building
Splitterwerk Architects and engineering firm Arup have unveiled what is thought to be the world's first building to be powered partly by algae. Officially "unveiled" at the International Building Exhibition hosted in Hamburg, the design, dubbed the BIQ, has a "bio-adaptive" facade that is claimed to be a first for using algae within its glass-paneled facades in order to generate energy, and provide shade, to a working building.
The Dice House looks like part of a Monopoly set, but the design has real-world ambitions. The 30-by-30-by-30-foot concept home, designed by the British architecture firm Sybarite, improves on standard building tech to erase its carbon footprint.
The centerpiece is a photovoltaic umbrella dome that collects roughly 90 percent of the house’s energy needs. Made of a common plastic, the pillowy dome traps heat like a greenhouse. That hot air warms water in a tank tucked under the roof, turning out a daily average of 80 bath-ready gallons, even on the darkest days of December. At the umbrella’s apex, a generator-equipped turbine produces electricity and, in chilly months, drives heat into the house. Photovoltaic cells studding the 484-square-foot dome floor create additional electricity.
Generating an estimated average of 33 kilowatt-hours per day, the house can power itself and charge a Tesla Roadster. And the building, submitted for a carbon-neutral housing competition, manages to stay comfortable year-round without air conditioning. The roof is covered in plants under the dome. Walls made of structural board stabilize temperatures. Windows circumscribed by a big dot—the “one” side of the die—absorb light from the sun-drenched south. And the compact footprint means less space to heat and cool.
Visionary architect Dr. David Fisher is the creator of the world’s first building in motion - the revolutionary Dynamic Tower. It will adjust itself to the sun, wind, weather and views by rotating each floor separately.
This building will never appear exactly the same twice.
It is amazing but you will have the choice of waking up to sunrise in your bedroom and enjoying sunsets over the ocean at dinner. In addition to being such an incredible engineering miracle it will produce energy for itself and even for other buildings because it will have wind turbines fitted between each rotating floor (picture 2). So an 80-story building will have up to 79 wind turbines, making it a true green power plant.
The Dynamic Tower in Dubai will be 1,380 feet (420 meters) tall, 80 floors, apartments will range in size from 1,330 square feet (124 square meters), to Villas of 12,900 square feet (1,200 square meters) complete with a parking space inside the apartment. It will consist of offices, a luxury hotel, residential apartments, and the top 10 floors will be for luxury villas located in a prime location in Dubai.
The Dynamic Tower in Dubai will be the first skyscraper to be entirely constructed in a factory from prefabricated parts. So instead of some 2000 workers, only 680 will be sufficient. Construction is scheduled to be completed by 2010.
New materials/process’s/laws to keep buildings green
Green buildings continue to gain attention as many recent innovations have surfaced in the Residential space of which I will discuss the following:
Solar Power
EcoSeal
BIPV windows from Tropiglas
Climate Wizard Evaporative Air Conditioner
Foamglas
A high R-value coating with Silica Aerogel
Drainline Heat Exchangers
Solar Power incorporated into commercial buildings
Solar power has historically been very expensive, holding back its wide use. It is about three times more expensive than electricity produced by natural gas, according to estimates by theEnergy Information Administration.
But the financial barriers are falling fast. “Solar panel prices have plunged by two-thirds since 2008, making it easier for installers to market solar's financial benefits, and not simply its environmental ones” according to USA today.
“Exelon and NextEra Energy, each acquired a large California solar power farm in the early stages of development. Another utility,NRG Energy, has announced a plan withBank of Americaand the real estate firm Prologis to spend $1.4 billion to install solar systems on 750 commercial rooftops” according to GTM Research.
Cost analysis of electricity use is pertinent when commercial buildings are deciding whether or not to use solar power as a form of electricity. Many commercial buildings benefit from different types of energy upgrades including solar
The Database of State Incentives for Renewable Energy (DSIRE)www.dsireusa.orghas current incentives for Texas
“For year 2013, the Federal Government is allowing companies bonus depreciation of 50% of the adjusted basis of the system. 5 Year rapid MACRS depreciation as well as the 30% Tax Credit” according to gleanpower.com
According to gleanpower “Typical rooftop installations can be done with minimal impact to business operations. Length of time from start to finish is about 4-9 weeks. This is everything from evaluation to flipping the switch.”
EcoSeal: A New System for Air Sealing Homes
Knauf EcoSeal, a sprayable caulk installed prior to cavity-fill insulation, can provide a significant reduction in air leakage.EcoSeal is an acrylic product that is applied using high-pressure paint-spraying equipment. It is installed with two 5-gallons buckets of the acrylic material which is the consistency of very thick paint. The system comes with a long, 200-foot hose, so the pump and bucket can stay in one place in the house while the work proceeds.
EcoSeal doesn’t expand as it is installed (as do foam sealants), and it takes up to day to fully cure. The cure time depends significantly on the environmental conditions — temperature, humidity, etc. The material can span up to about a 3/8-inch gap, according to Knauf, and it remains flexible.
EcoSeal was used in a building in Vermont to seal up cracks and gaps in walls and floors, here are the findings:
When the project manager started using EcoSeal installation, the blower door was showing 950 cfm of air leakage at 50 pascals (cfm50). During the course of about four hours of work on the air sealing, that air leakage rate dropped to 640 cfm50. That’s an improvement of a third. That would significantly lower the amount of energy a building would need to heat and cool itself down !!
The downsides of foam insulation include the blowing agents used in extruded polystyrene (XPS) and most closed-cell spray polyurethane foam and the flame retardants that are added to all foam-plastic insulation to impart some level of fire resistance.
Now there’s an effort afoot to change building codes in a way that would allow manufacturers to remove the hazardous flame retardants. This is the subject of a just-published feature article in Environmental Building News
This is a significant energy issue, because layers of foam insulation provide the easiest way to achieve the level of energy performance needed to approach net-zero-energy performance.
Nobody wants insulation materials to catch fire, so it is logical to add flame retardant (FR) chemicals to these materials if it will prevent them from catching fire. That’s the reason HBCD (hexabromocyclododecane) is added by all polystyrene insulation and TCPP (Tris (1-chloro-2-propyl) phosphate) is added to most polyisocyanurate and spray polyurethane foam insulation. These are both halogenated flame retardants—the first using bromine, the second chlorine.
The problem with these halogenated FRs is that they have significant health and environmental risks. The HBCD that is used in all polystyrene (both extruded and expanded) is being targeted for international phase-out by the Stockholm Convention on Persistent Organic Pollutants. It is highly persistent in the environment and bioaccumulative in the food chain; it is believed to cause reproductive, developmental, and neurological impacts. Less is known about the TCPP used in spray polyurethane foam and polyisocyanurate, but there is significant concern in the health and environmental community.
Building codes require that foam-plastic insulation meet a very specific flammability standards. But building codes also require—for most applications—that foam insulation has to be separated from living space by thermal barriers, such as gypsum drywall.
The efficacy of flame retardants compared with thermal barriers
Combustion studies that were done in the 1970s showed that if the insulation is not protected with a thermal barrier, there is no correlation between the presence of FR and the extent of the resultant fire. Thus, the inclusion of a FR does not seem to appreciably increase the fire resistance of foam insulation, according to a peer-reviewed technical paper recently published in the journalBuilding Research and Information.
However, thermal barriers like half-inch drywall work extremely well at containing fires. The 15-minute protection provided by half-inch drywall gives occupants time to escape a fire. In other words, of the two measures used to impart fire safety to a building assembly (FRs in foam insulation and thermal barriers) almost all of the fire safety benefit is provided by the thermal barrier.
Tropiglas was displaying its building-integrated photovoltaic (BIPV) window technology, which uses a polymer layer sandwiched between two panes of glass. When sunlight passes through the first pane, it is captured by the inner layer and directed to the edge of the glass (similar to how optical fibers work), where standard monocrystalline PV cells convert the light to electricity.
The glass is free of visible cells, unlike most current BIPV glazing options, whose cells block part of the view. But the efficiency is only around 4% (35 watts/m2, 80% transparency, 90% IR blocking,SHGC< 0.41). The company claims the manufacturing process is similar to that of low-e coatings, so it shouldn’t cost much more to manufacture, but of course, you still have to contend with the other PV components and wiring.
Tropiglas is still looking for glazing partners but expects to have product on the market in 2013.
Climate Wizard Evaporative Air Conditioner
Climate Wizard (see it in GreenSpec here), from the Australian company Seeley International and distributed in the U.S. by L&H Airco, is a refrigerant-free indirect evaporative air conditioner similar to theCoolerado we list in GreenSpecand reviewed forEBNback in2008.
The Climate Wizard uses fans with energy-efficient electronically commutated motors (ECM) to move air through a heat exchanger that contains both wet and dry channels.
Climate Wizard is a refrigerant-free evaporative air conditioner that provides cool, dry, fresh air along with energy savings.Heat is transferred across the membrane from the dry to the moist channel, where it is vented into the atmosphere.
The cool, dry, fresh air then passes into the building to provide cooling. Climate Wizard uses 6.6 gallons of water an hour for the 10 kW model (about 2.8 tons cooling); a 15 kW (4.3 tons) version is also available.
Climate Wizard is used primarily in commercial applications.
Foamglas
Foamglas is a cellular glass insulation material. Foamglas is water-resistant so can be used below-grade; it has high compressive strength so can be used beneath a concrete slab floor; it insulates very well (R-5 per inch); and it’s inexpensive. These properties make XPS the nearly universal choice for sub-slab and exterior foundation insulation today.
Extruded polystyrene is what is in the mainstream as of today. Relative to performance, extruded polystyrene (XPS) is a great product. It is water-resistant so can be used below-grade; it has high compressive strength so can be used beneath a concrete slab floor; it insulates very well (R-5 per inch); and it’s inexpensive.
These properties make XPS the nearly universal choice for sub-slab and exterior foundation insulation today. But along with these benefits are some significant downsides. All XPS today (as well as expanded polystyrene, EPS) is made with the brominated flame retardant HBCD that has recently been added to the Stockholm list of Persistent Organic Pollutants (POPs) and is being banned in much of the world. HBCD provides some level of fire protection, though some studies suggest that its benefits are greatly exaggerated—and that that protection, if real, is irrelevant below grade. In addition, XPS is currently made with the blowing agent HFC-134a, which is a potent greenhouse gas that contributes to global warming. And some of the petrochemical-derived raw materials, including benzene and styrene monomer, are carcinogenic—though once converted into polystyrene, that carcinogenicity is not present.
Foamglas is a cellular glass, rigid boardstock insulation material. It has high compressive strength, excellent moisture resistance, and tremendous fire resistance without the use of flame retardants. It is moderately well-insulating at R-3.4 per inch (32% lower than XPS), and it’s made without environmentally damaging blowing agents. It is also about the only insulation material that is totally impervious to wood-boring insects—a useful property for below-grade applications—particularly in a warming planet with termites extending their ranges north.
Foamglas has actually been around a long time—since Pittsburgh Corning introduced it in the 1930s—but it is used primarily for high-temperature industrial applications, such as insulating steam pipes and furnaces. It’s use as an insulation material for buildings remains very uncommon, though this use is increasing in Europe.
Even though Foamglas is significantly more expensive than XPS and its per-inch insulating value is lower, the environmental and health benefits made me want to try it out on our own home.
A high-R-value coating with Silica Aerogel
Silica aerogel is a bizarre material. Aerogel is the lowest-density solid known. It transmits light and insulates extremely well, owing to its molecular structure. For the past decade, the Cabot Corporation has produced silica aerogel granules under the brand name Lumira (previously Nanogel) that are used in daylighting panels that provide diffused light even while offering remarkably high insulating value (about R-20 in a 2-1/2" panel), and the material is also incorporated into a felt-like mat that can be used in roofing fabrics. Find Lumira in GreenSpechere.
At Greenbuild the company introduced a new formulation of silica aerogel. Enova, which can be added to paint to provide a thin, insulating coating. A very effective demonstration in the booth used a piece of aluminum that was half painted with this 2 mm-thick coating and half uncoated with a refrigerated space behind. You could feel dramatic difference in temperature since the aerogel coating significantly reduced heat flow through the material. A key benefit will be preventing condensation.
This simple system for recovering heat from wastewater makes a lot of sense—especially for families and commercial buildings that produce a lot of hot water.
A special section of copper drainpipe is installed beneath a shower (typically the largest hot water use in a home) or other hot wastewater source. This section of drainpipe has smaller-diameter copper piping wrapped tightly around it. The cold-water supply pipe leading into the water heater is diverted so that it flows through the small-diameter copper pipe.
When hot water is being pulled from the water heater to supply the shower, the water going into the water heater is preheated by the wastewater going down the shower drain. If it’s a tankless—rather than storage—water heater, the incoming water temperature will be higher, so less energy will be required to get it up to the needed delivery temperature—thus saving energy (though the tankless water heater has to be thermostatically controlled and, thus, able to deal with inlet water of varying temperature.
The man who invented the drainwater heater exchanger, Carmine Vasile, called the product a GFX, for “gravity-film exchange,” recognizing that water going down a vertical pipe forms a film that clings to the inner walls of the pipe where the heat can effectively be transferred through the copper to the supply water.
No moving parts, nothing to wear out
The beauty of drainline heat exchangers is that there are no moving parts, nothing the wear out, and nothing to get clogged. Only fresh water goes through the small-diameter supply pipes; any hair or other materials pass through a standard, smooth drain pipe.
Maximizing recovery efficiency
According to an article in Environmental Building News, heat recovery efficiency can be as high as 60%—which can effectively double the water heating efficiency. Just how much benefit a drainline heat exchanger will provide will depend on usage patterns and how the plumbing in a house is configured.
http://www2.buildinggreen.com/buildinggreen-top-10-products-2012#6