Archive for the ‘Biomimicry’ Category

MendoCoastCurrent, March 14, 2011

Dear President Obama,

Continuing to hear comments that you, your administration and your cabinet members consider nuclear power as a clean, renewable solution is most alarming.

Mr. President, let’s consider the nuclear event occurring in Japan right now and learn the simple truth that any safe renewable energy portfolio DOES NOT include nuclear energy.

The ramifications of the current Japanese nuclear trauma will be felt worldwide as will the fall-out, for months and possibly years to come.

Mr. President, I strongly encourage your team to change course, hit the ground running in alternative, renewable and sustainable energy r&d right now.

Here’s a solution that may be started TODAY ~ http://bit.ly/t7ov1

I call it Mendocino Energy and am not attached to the name, yet very passionate about this important safe, renewable energy development concept. Time has come for us to get rolling!

Mendocino Energy ~ At this core energy technology incubator, energy policy is created as renewable energy technologies and science move swiftly from white boards and white papers to testing, refinement and implementation.

The Vision

Mendocino Energy is located on the Mendocino coast, three plus hours north of San Francisco, Silicon Valley. On the waterfront of Fort Bragg, utilizing a portion of the now-defunct Georgia-Pacific Mill Site to innovate in best practices, cost-efficient, safe renewable and sustainable energy development – wind, wave, solar, bioremediation, green-ag/algae, smart grid and grid technologies, et al.

The process is collaborative in creating, identifying and engineering optimum, commercial-scale, sustainable, renewable energy solutions with acumen.

Start-ups, utility companies, universities (e.g. Precourt Institute for Energy at Stanford), EPRI, the federal government (FERC, DOE, DOI) and the world’s greatest minds gathering at this fast-tracked, unique coming-together of a green work force and the U.S. government, creating responsible, safe renewable energy technologies to quickly identify best commercialization candidates and build-outs.

The campus is quickly constructed on healthy areas of the Mill Site as in the past, this waterfront, 400+ acre industry created contaminated areas where mushroom bioremediation is underway.

Determining best sitings for projects in solar thermal, wind turbines and mills, algae farming, bioremediation; taking the important first steps towards establishing U.S. leadership in renewable energy and the global green economy.

With deep concern & hope,

Laurel Krause

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DAVID TOW, Future Planet, January 16, 2010

By 2015 India and China will both have outstripped the US in energy consumption by a large margin. Cap and Trade carbon markets will have been established by major developed economies, including India and China, as the most effective way to limit carbon emissions and encourage investment in renewable energy, reforestation projects etc.

There will have been a significant shift by consumers and industry to renewable energy technologies- around 25%, powered primarily by the new generation adaptive wind and solar energy mega-plants, combined with the rapid depletion of the most easily accessible oil fields. Coal and gas will continue to play a major role at around 60% useage, with clean coal and gas technologies still very expensive. Nuclear technology will remain static at 10% and hydro at 5%.

Most new vehicles and local transport systems will utilise advanced battery or hydrogen electric power technology, which will continue to improve energy density outputs.

Efficiency and recycling savings of the order of 30% on today’s levels will be available from the application of smart adaptive technologies in power grids, communication, distribution and transport networks, manufacturing plants and consumer households. This will be particularly critical for the sustainability of cities across the planet. Cities will also play a critical role in not only supporting the energy needs of at least 60% of the planet’s population through solar, wind, water and waste energy capture but will feed excess capacity to the major power grids, providing a constant re-balancing of energy supply across the world.

By 2025 a global Cap and Trade regime will be mandatory and operational worldwide. Current oil sources will be largely exhausted but the remaining new fields will be exploited in the Arctic, Antarctic and deep ocean locations.  Renewable energy will account for 40% of useage, including baseload power generation. Solar and wind power will dominate in the form of huge desert solar and coastal and inland wind farms; but all alternate forms- wave, geothermal, secondary biomass, algael etc will begin to play a significant role.

Safer helium-cooled and fast breeder fourth generation modular nuclear power reactors will replace many of the older water-cooled and risk-prone plants, eventually  accounting for around 15% of energy production; with significant advances in the storage of existing waste in stable ceramic materials.

By 2035 global warming will reach a critical threshold with energy useage tripling from levels in 2015, despite conservation and efficiency advances. Renewables will account for 60% of the world’s power supply, nuclear 15% and fossils 25%. Technologies to convert CO2 to hydocarbon fuel together with more efficient recycling and sequestration, will allow coal and gas to continue to play a significant role.

By 2045-50 renewables will be at 75-80% levels, nuclear 12% and clean fossil fuels 10-15%. The first Hydrogen and Helium3 pilot fusion energy plants will be commissioned, with large-scale generators expected to come on stream in the latter part of the century, eventually reducing carbon emissions to close to zero.

However the above advances will still be insufficient to prevent the runaway effects of global warming. These long-term impacts will raise temperatures well beyond the additional two-three degrees centigrade critical limit.

Despite reduction in emissions by up to 85%, irreversible and chaotic feedback impacts on the global biosphere will be apparent. These will be triggered by massive releases of methane from permafrost and ocean deposits, fresh water flows from melting ice causing disruptions to ocean currents and weather patterns.

These will affect populations beyond the levels of ferocity of the recent Arctic freeze, causing chaos in the northern hemisphere and reaching into India and China and the droughts and heat waves of Africa, the Middle East and Australia.

The cycle of extreme weather events and rising oceans that threaten to destroy many major coastal cities will continue to increase, compounded by major loss of ecosystems, biodiversity and food capacity. This will force a major rethink of the management of energy and climate change as global catastrophe threatens.

Increasingly desperate measures will be canvassed and tested, including the design of major geo-engineering projects aimed at reducing the amount of sunlight reaching earth and reversal of the acidity of the oceans. These massive infrastructure projects would have potentially enormous ripple-on effects on all social, industrial and economic systems. They are eventually assessed to be largely ineffective, unpredictable and unsustainable.

As forecasts confirm that carbon levels in the atmosphere will remain high for the next 1,000 years, regardless of mitigating measures, priorities shift urgently to the need to minimise risk to life on a global scale, while protecting civilisation’s core infrastructure, social, knowledge and cultural assets.

Preserving the surviving natural ecosystem environment and the critical infrastructure of the built environment, particularly the Internet and Web, will now be vital. The sustainability of human life on planet Earth, in the face of overwhelming catastrophe, will be dependent to a critical degree on the power of the intelligent Web 4.0, combining human and artificial intelligence to manage food, water, energy and human resources.

Only the enormous problem-solving capacity of this human-engineered entity, will be capable of ensuring the continuing survival of civilisation as we know it.

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Scientific Computing, Advantage Business Media, November 2009

The ocean is a potentially vast source of electric power, yet as engineers test new technologies for capturing it, the devices are plagued by battering storms, limited efficiency and the need to be tethered to the seafloor. Now, a team of aerospace engineers is applying the principles that keep airplanes aloft to create a new wave energy system that is durable, extremely efficient and can be placed anywhere in the ocean, regardless of depth.

While still in early design stages, computer and scale model tests of the system suggest higher efficiencies than wind turbines. The system is designed to effectively cancel incoming waves, capturing their energy while flattening them out, providing an added application as a storm wave breaker.

The researchers, from the U.S. Air Force Academy, presented their design at the 62nd annual meeting of the American Physical Society’s Division of Fluid Dynamics on November 24, 2009.

“Our group was working on very basic research on feedback flow control for years,” says lead researcher Stefan Siegel, referring to efforts to use sensors and adjustable parts to control how fluids flow around airfoils like wings. “For an airplane, when you control that flow, you better control flight — for example, enabling you to land a plane on a shorter runway.”

A colleague had read an article on wave energy in a magazine and mentioned it to Siegel and the other team members, and they realized they could operate a wave energy device using the same feedback control concepts they had been developing.

Supported by a grant from the National Science Foundation, the researchers developed a system that uses lift instead of drag to cause the propeller blades to move.

“Every airplane flies with lift, not with drag,” says Siegel. “Compare an old style windmill with a modern one. The new style uses lift and is what made wind energy viable — and it doesn’t get shredded in a storm like an old windmill. Fluid dynamics fixed the issue for windmills, and can do the same for wave energy.”

Windmills have active controls that turn the blades to compensate for storm winds, eliminating lift when it is a risk, and preventing damage. The Air Force Academy researchers used the same approach with a hydrofoil (equivalent to an airfoil, but for water) and built it into a cycloidal propeller, a design that emerged in the 1930s and currently propels tugboats, ferries and other highly maneuverable ships.

The researchers changed the propeller orientation from horizontal to vertical, allowing direct interaction with the cyclic, up and down motion of wave energy. The researchers also developed individual control systems for each propeller blade, allowing sophisticated manipulations that maximize (or minimize, in the case of storms) interaction with wave energy.

Ultimately, the goal is to keep the flow direction and blade direction constant, cancelling the incoming wave and using standard gear-driven or direct-drive generators to convert the wave energy into electric energy. A propeller that is exactly out of phase with a wave will cancel that wave and maximize energy output. The cancellation also will allow the float-mounted devices to function without the need of mooring, important for deep sea locations that hold tremendous wave energy potential and are currently out of reach for many existing wave energy designs.

While the final device may be as large as 40 meters across, laboratory models are currently less than a meter in diameter. A larger version of the system will be tested next year at NSF’s Network for Earthquake Engineering Simulation (NEES) tsunami wave basin at Oregon State University, an important experiment for proving the efficacy of the design.

Compelling images of the cycloidal turbine:

The view from the far downstream end into the test section of the U.S. Air Force Academy water tunnel. Three blades of the cycloidal turbine are visible at the far end. Engineer Stefan Siegel and his colleagues test the turbine using the tunnel, with both steady and oscillating flow conditions simulating a shallow-water wave-flow field. Courtesy of SSgt Danny Washburn, U.S. Air Force Academy, Department of Aeronautics


A cycloidal turbine is installed on top of the test section of the U.S. Air Force Academy water tunnel. In the background, Manfred Meid (left) and Stefan Siegel (right) operate the turbine. Courtesy of SSgt Danny Washburn, US Air Force Academy, Department of Aeronautics




A cycloidal turbine prototype with three blades (translucent, at bottom of image), is shown lifted out of the tunnel. One of the blade pitch control servo amplifiers is visible in the foreground, and the servo motors can be seen in the top portion of the image. Courtesy of SSgt Danny Washburn, US Air Force Academy, Department of Aeronautics

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JESSICA MARSHALL, Discovery.com News, November 30, 2009

The patterns that schooling fish form to save energy while swimming have inspired a new wind farm design that researchers say will increase the amount of power produced per acre by at least tenfold.

“For the fish, they are trying to minimize the energy that they consume to swim from Point A to Point B,” said John Dabiri of the California Institute of Technology in Pasadena, who led the study. “In our case, we’re looking at the opposite problem: How to we maximize the amount of energy that we collect?”

“Because both of these problems involve optimizing energy, it turns out that the model that’s useful for one is also useful for the other problem.”

Both designs rely on individuals capturing energy from their neighbors to operate more efficiently.”If there was just one fish swimming, it kicks off energy into the water, and it just gets wasted,” Dabiri said, “but if there’s another fish behind, it can actually use that kinetic energy and help it propel itself forward.”

The wind turbines can do the same thing. Dabiri’s wind farm design uses wind turbines that are oriented to rotate around the support pole like a carousel, instead of twirling like a pinwheel the way typical wind turbines do.

Like the fish, these spinning turbines generate a swirling wake. The energy in this flow can be gathered by neighboring turbines if they are placed close enough together and in the right position. By capturing this wake, two turbines close together can generate more power than each acting alone.

This contrasts with common, pinwheel-style wind turbines where the wake from one interferes with its neighbors, reducing the neighbors’ efficiency. The vortexes occur in the wrong orientation for the neighboring turbines to capture them.

For this reason, such turbines must be spaced at least three diameters to either side and 10 diameters up — or downwind of another, which requires a lot of land.

Although individual carousel-style turbines are less efficient than their pinwheel-style counterparts, the close spacing that enhances their performance means that the amount of power output per acre is much greater for the carousel-style turbines.

Dabiri and graduate student Robert Whittlesey calculated that their best design would generate 100 times more power per acre than a conventional wind farm.

The model required some simplifications, however, so it remains to be seen whether tests of an actual wind farm produce such large gains. That will be the team’s next step. “Even if we’re off by a factor of 10, that’s still a game changer for the technology,” Dabiri noted.

In the end, schooling fish may not have the perfect arrangement. The pair found that the best arrangement of wind turbines did not match the spacing used by schooling fish.

“If we just mimic the fish wake, we can do pretty well,” Dabiri said. “But, as engineers, maybe we’re smarter than fish. It turns out that for this application there is even better performance to be had.”

This may be because fish have other needs to balance in their schooling behavior besides maximizing swimming efficiency. They seek food, avoid predators and reproduce, for example.

“I think that this is a very interesting possibility,” said Alexander Smits of Princeton University, who attended a presentation of the findings at a meeting of the American Physical Society Division of Fluid Dynamics in Minneapolis last week.

But a field test will show the idea’s real potential, he noted: “You have to go try these things. You can do a calculation like that and it might not work out. But it seemed like there was a very large reduction in the land usage, and even if you got one half of that, that would be pretty good.”

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WENDEE HOLTCAMP, National Wildlife, December/January 2010

Frank Fish was browsing in a Boston sculpture shop a few years ago when he noticed a whale figurine. His first thought was, “This isn’t right. It’s got bumps on the leading edge of its flipper. It’s always a straight edge.”

Fish, a West Chester University professor specializing in the dynamics of locomotion, was surprised because all flippers he knew of had straight edges—including those of dolphins, penguins and even most whales. The straight-edge blade is also shared by ceiling fans and most industrial blades and rotors. But the store manager showed him a photo of a humpback whale, and sure enough, it had tubercles on its flippers. Humpbacks have a unique habit of catching fish in a bubble net that they create by diving deep and swimming in a spiraling circle, and Fish speculated that the tubercles may somehow give them a hydrodynamic advantage.

Turns out he was right. After testing a scaled-down flipper replica in a wind tunnel, Fish and colleagues Loren Howle and Mark Murray found the tubercles reduced drag by 32% and increased lift by 6% compared with a smooth-edge flipper. The bumps have the same effect on rotors and blades in air—a revolutionary discovery in aerodynamics. Fish co-patented so-called “Tubercle Technology” and in 2005 he helped found Whale Power, a company that is building energy-efficient windmills using scalloped-edge blades. The technology could eventually improve energy-efficiency for any machine that uses turbines, fans or pumps.

Fish is among an increasing number of scientists, inventors and companies turning to the natural world to help them create better, more sustainable products and to find solutions to some of humanity’s most vexing problems. The concept is called biomimicry and the idea behind it is simple: Over the millennia, living organisms in the natural world already have tested and solved many of the challenges humans are grappling with today.

“People are looking for ways to reduce material use, get away from toxic substances and reduce energy use. When they hear about biomimicry, they realize it’s an R&D program that’s been going on for 3.8 billion years,” says biologist Janine Benyus of the Biomimicry Guild, a Montana-based consulting firm that provides research and guidance on natural solutions for some of the country’s largest companies and government agencies.

In her landmark 1997 book Biomimicry: Innovation Inspired by Nature, Benyus issued a call to action, urging people to engage not just in shallow biomimicry—copying nature’s forms—but to push for deep biomimicry where manufacturing processes follow nature’s lead of sustainability. The ideal industrial loop, she says, would work as seamlessly as a redwood forest, where one’s processed wastes become food or input for another and nothing is wasted. In the book, Benyus also compiled dozens of examples of how people are emulating natural processes.

Velcro, for example, one of the most famous products to come from mimicking nature, was created by a Swiss engineer in the 1940s after observing how cockleburs got stuck in his dog’s fur. Three decades later, a German botanist discovered that lotus leaves contain tiny waxy bumps that cause water to bead up and run off the surface, washing and cleaning the leaves in the process. The discovery has since inspired a number of waterproof products including Lotusan, a self-cleaning paint that keeps the outsides of buildings free of algae and fungi.

More recently, scientists from the University of New South Wales discovered a revolutionary antibacterial compound in a type of red algal seaweed that lives off the coast of Australia. Bacteria form slimy biofilms but require a “quorum” to congregate, and so they constantly communicate with one another. The seaweed stays bacteria-free by emitting the compound furanone, which jams the bacteria’s communication sensors. Mimicking that natural action, the Australian company Biosignal created cleaning fluids that keep surfaces bacteria-free without killing them, which is a breakthrough because its use does not lead to the evolution of antibiotic resistance, as has happened with the proliferation of so many antibacterial cleaning compounds. So far, furanone works on various bacteria, including staphylococcus and vibrio, which causes cholera. It also works on the bacteria that corrode pipes, leading to oil spills.

In another flip on tradition, Mercedes-Benz recently modeled an ecologically friendly, fuel-efficient concept vehicle called the Bionic Car after the yellow boxfish, a squarish tropical creature found in reefs in the Pacific and Indian Oceans. Traditionally, aerodynamic cars have been built long and lean, but it turns out the boxfish has a drag coefficient nearly equal to that of a drop of water, which has one of the lowest drags possible. The automobile company not only borrowed from the boxfish’s boxy but aerodynamic shape but also from its unique skeletal structure that protects the animal from injury, making the car safer by putting extra material in certain parts of its frame and economizing by lightening up the load elsewhere.

Another product, the UltraCane, was developed not long ago as a result of research at the University of Leeds in Great Britain to help the blind “see” by utilizing the echolocation systems of bats. The cane emits an ultrasonic sound that bounces off objects, allowing vision-impaired people to develop a mental picture of where and how far away objects are—and hence better navigate around them.

In Zimbabwe, the architectural design firm Arup Associates modeled the country’s largest office complex, Eastgate Centre, after the passive cooling system used by African termites in their mounds. Termites farm fungus that they must keep at a precise 87 degrees F, while outside air varies from 35 degrees at night to 104 by day. To accomplish this amazing feat, termites constantly plug and unplug cooling vents that create convection currents, drawing air through the mound as needed. The Eastgate Centre builders copied this model, using fans and chimneys to shunt hot air out, and ground-level cavities to allow cooler air in—a concept known as passive cooling. Without any modern heating or air conditioning, the facility uses only 10% of the electricity of a conventional building its size. The energy-cost savings trickle down to tenants, who pay 20% lower rent than in neighboring buildings.

Elsewhere, scientists are turning to Mother Nature for inspiration for other energy-related materials. To increase the amount of sunlight that is absorbed by solar panels, for instance, a University of Florida researcher is developing a coating for the panels based on the structure of moth eyes, which reflect little light. In China and Japan, scientists are modeling more efficient solar cells after the scales on butterfly wings, which serve as highly effective, microscopic solar collectors.

The benefits humans gain as a result of such research provide a strong argument for conserving wildlife. “Protecting plant and animal habitats means also preserving the wellspring of ideas for the next industrial revolution,” says Benyus, who in 2007 was named by Time magazine as one of its “International Heroes of the Environment.”

That same year, she also founded the nonprofit Biomimicry Institute, which urges companies to donate a percentage of their profits to the habitat from which their biomimicry-inspired products come from. “We must become nature’s apprentice at this point,” she says, “and part of that path has to be preserving the wild places we now realize are the homes of geniuses.”

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MendoCoastCurrent, November 16, 2009

For centuries humanity has gazed at the sea, rivers and rambling brooks in awe of water currents and the energy potential they hold. With increasingly critical demand for safe renewable energy solutions, our ability to capture water power has been an abstruse, distant choice for mitigating our dependence on fossil fuels.

Now with Peak Oil and Climate Change concerns igniting our interest in renewable energies, our brightest, most creative thinkers the world-over turn their attention and intention toward creating efficient, sustainable and safe renewable energy capture devices. It’s understood best bets for generating constant electricity straddle natural energy sources: the sun, the wind and the tides, with the energy captured from water and the tides currently garnering longest odds.

Water power, known more formally as hydrokinetic energy, is based on hydro, meaning water, and kinetic with roots in Greek, κίνηση, or kinesis, meaning motion. The motion of water and study of it includes capturing its power. At the heart of this energy is spinning and flowing, ironically a strikingly dissimilar concept from capture.

Whether extracted, converted, captured or transformed, hydrokinetic energy may well be the ‘holy grail’ of renewable energy, especially when considering the math:

  • ‘One foot of tidal change, when funneled through the natural orifices of the coastal inlets, has the potential to generate pure, clean, green energy and all with absolutely no carbon footprint.’
  • Thus, as an example, one Florida inlet having an average tidal change between 2” up to 1’ carries 75 trillion Cu-Ft of fast moving water every tide.

Furthermore, hydrokinetic energy offers consistent yields and potentials unknown and possibly undiscoverable from other naturally-sourced energy. Wind power faces insufficient, constant wind to return the capital investment, even with government subsidies, and robust solar energy opportunities are mostly located in far, off grid locales.

Traditional hydrokinetic solutions include tidal turbines, wave buoys, wave hubs, tethered ocean, buoyant/flexible wave snakes and tidal stream machines that generate electricity yet also create gross negative impacts on marine wildlife and the environment.

These solutions must overcome fundamental issues like potential fish or turtle kill, corrosion and tethering issues, repair distance and processes, long-term durability in water/weather, noise pollution and super expensive grid connections that are also environmentally damaging.

Seems that when we embrace and mimic nature in creating organically-derived energy capture tools, the harmonious capacity of the design inherently overcomes the problems of other inelegant hydrokinetic systems.

Over the last two years, W. S. “Scotty” Anderson, Jr. may have either consciously or unconsciously designed along these lines as he victoriously led his team to invent and build the ECO-Auger™. You’ll find information on this and other cool inventions at Anderson’s laboratory, www.smartproductinnovations.com.

As a lifelong fisherman, Anderson designed his hydrokinetic system to convert energy from moving water, delivering renewable, sustainable energy, while completely safe for fish and marine wildlife.

The tapered helix permits fish and other marine life to pass through with absolutely no sharp edges to injure them. Even turtles can swim through or are gently pushed aside as the ECO-Auger generally rotates under 100 rpm. The tapered design also permits debris to pass.

First thoughts of the ECO-Auger came to Anderson in 2008 as he was fishing the waters of the fast-moving Kenai River in Alaska. His mind focused on capturing the river’s energy; here are his notes: “I got the vision of a screw turning in the river current and generating electricity on the river bank. The screw would turn a flexible shaft and drive an electric generator outside the water.”

The ECO-Auger is a double-helix, auger-shaped spinner regulated by the size of the radius and the strength of the water current. “It’s easy to array, bi-directional and housed in an individual, streamlined single form,” Anderson points out.

Anderson originally envisioned the ECO-Auger “simply installed under bridges between the arches of bridges, housed on the ECO-Sled, a sort of a pontoon boat like a floating dry-dock.” This permits easy launch and retrieval for maintenance or if/when the ice gets too thick.

Over the next year Anderson built and tested prototypes, refining his hydrokinetic system completely from U.S. materials, requiring that each generation of the ECO-Auger be “very reasonable to build, deploy, easy to service and inexpensive to array.”

In describing his invention, Anderson said, “the ECO-Auger does not have blades, straight or twisted like other devices, and is environmentally-friendly to all marine wildlife. The fish are not harmed and swim through the organic design. With no electrical generation under or in water, there also is no danger to transmitting vibrations or naval sonar to whales and dolphins.”

This novel approach is so very different to existing technology. So very different and innovative that in late September 2009 Anderson’s team won First Place in the ConocoPhillips Energy Prize, a joint initiative of ConocoPhillips and Penn State University recognizing new ideas and original, actionable solutions that help improve the way the US develops and uses energy.

The prize-winning ECO-Auger was described as “a hydrokinetic energy capturing device that converts moving water from river and ocean currents to renewable electric energy using the constant hydraulic pressure and storage to maintain continuous energy output regardless of tidal current strength.”

How the ECO-Auger Works:

The ECO-Auger rotates in either direction from the moving water and current and is directly transferred through planetary gears to a high-pressure hydraulic pump located in the machine’s nose cone. The nose cone, which is physically tethered to bridges by cables, or anchored in moving water, stabilizes the torque generated from the rotation and transfers it to a hydraulic pump. The pump supplies variable volumes of high-pressure fluid at controlled, set pressure, regardless of the direction or speed of rotations. This pressure turns an oil-driven electric generator that delivers stable electrical current. Thus, constant power is generated through the ECO-Auger’s unique hydraulic circuit.

As the ECO-Auger rotates, the high-pressure oil flows through check valves to an array of standard air oil accumulators that are connected directly in line to the oil motor driving the electric generator. The oil to the electric generator is sized below the maximum gallons per minute of the ECO-Auger’s hydraulic pump, allowing the pumped oil to be supplied to the motor, while the excess volume is stored in the accumulator. A computer-monitored storage system assures maximum energy stability, storing energy and supplying the generators during the slow down of tidal flow.

Guide for Installation Opportunities:

Since the ECO-Auger is bi-directional, it is well-suited for high velocity, coastal ocean and bay locations. Near the ocean, the generation hydraulic system uses nitrogen-over-oil accumulators to maintain power generation during ebb tides or slack tidal movement under 1 knot (0.5m/s).

Each potential installation of the ECO-Auger is unique, requiring the water velocity and profile or depth of the installed area to be fully studied and documented. Anderson recommends a month-long study to support 30-year energy capture forecasts and projections.

River installations of the ECO-Auger are successful when current is in excess of 3 kts (1.5 meters/sec). The accumulators mentioned above are not required in mono-flow installations and installation reflects this cost savings. With the mono-directional ECO-Auger, electricity can be generated already existing power dams, downstream in any dam outlet, discharge from municipal water treatment facility, cooling water discharge and many river bridge options.

The ECO-Auger in its recent First Place win in the 2009 ConocoPhillips Energy Prize, a joint initiative of ConocoPhillips and Penn State University — won specifically for its new, original idea improving the way the U.S. creates and uses energy.

Anderson and his team are up to this important challenge and set their sights on installing this remarkable fish-friendly, economical, high-yielding hydrokinetic solution in a river, alongside a bridge or coastal inlet near you.

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MIKE CHINO, Inhabitat, July 27, 2009

48_group-2-1Although electric vehicle use is on the rise, we’re certainly not out of the woods yet in terms of providing them with a steady supply of clean energy – that’s why designer Neville Mars has conceived of an incredible EV charging station that takes the form of an evergreen glade of solar trees. His photovoltaic grove serves a dual function, acting as a go-to source for clean renewable energy while providing a shady spot for cars to park as they charge.

Each of the trees in Neville Mars’s solar forest is composed of a set of photovoltaic leaves mounted on an elegantly branching poll. The base of each trunk features an power outlet that can be used to juice up your eco ride as you run errands.

Neville told Inhabitat that the tree and leaf design wasn’t a goal but came naturally as they tried to maximize the shaded surface that the structures provide. Although the efficiency of overlapping photovoltaic panels initially raised some concerns, Neville went on to explain that the leaves rotate with the sun to ensure maximum efficiency. The solar forest is certainly an aesthetic step up from your standard sun-baked concrete parking lot, and serves as great inspiration for integrating solar technology with natural forms.

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