Comverge Gets Another Smart Meter Management Deal

By Jeff St. John

Comverge (COMV) has landed another deal that calls for it to turn down homes' energy use during peak demand times with pagers at first, and with smart meters later on.The deal is with Dominion Virginia Power (D), and calls for Comverge to manage about 117 megawatts of commercial and industrial power loads.

Comverge will also provide its Apollo software platform to manage demand response devices for about 150,000 homes – representing roughly 150 megawatts of power use – which the utility wants to hook up with smart meters eventually.

The idea is to turn down home air conditioners, water heaters and pool pumps – the devices Comverge can now control – using its existing mainly pager-based communication system at first, said Mike Picchi, Comverge's interim president and CEO.

Then, as Dominion rolls out its smart meters, made by German manufacturer Elster, Comverge will switch over to using them as the gateway into the home instead, Picchi said. Comverge's Apollo software can manage both means of control, he said (see Green Light post).

• The East Hanover, N.J.-based demand response provider has a similar contract with Pepco Holdings Inc., which plans to give its 1.9 million customers General Electric smart meters enabled with Silver Spring Networks communications gear over the next four years.
  
• Comverge also is working with smart meter maker Itron to link its smart meters to Comverge's set of ZigBee-enabled thermostats and other systems. In Texas, it's working on integrating its systems with smart meters from Landis+Gyr, Picchi said.
  
• After all, while every utility installing smart meters says they'll eventually be able to turn down home energy use, none have done so in a full-scale commercial deployment, he said (see The Elusive Smart Meter-Demand Response Combo).
  
• That gives utilities like Pepco and Dominion a short-term choice, he said - wait for smart meters to be in place to start controlling home energy use, or turn to Comverge's existing set of programs, which range from turnkey systems that utilities can control to those managed by Comverge itself.
  
• Comverge mainly controls power in commercial and industrial facilities, a market it shares with demand response competitors such as EnerNoc Inc. (ENOC), CPower, EnergyConnect and Constellation NewEnergy (see Green Light post).

The idea is to turn down energy use when utilities are facing peak demand, saving the cost of building and buying power from "peaker" plants that may need to run only a few hundred hours every year.
But Comverge distinguishes itself from those competitors in that about a quarter of its more than 3,000 megawatts under management come from homes.

Other residential demand response programs exist out there, but most are managed directly by utilities, though Cooper Power Systems does residential demand response work as well.

Big facilities and offices are easier to manage when it comes to demand response – they're bigger targets, and they tend to have staff, and some form of building control system, already in place to carry out the task.

Whether or not millions of homes can be as efficiently networked and controlled for peak demand reduction is a big question in the demand response field (see Demand Response: The Home vs. C&I Debate).

The Electric Power Research Institute predicted in January that the residential, commercial and industrial sectors would roughly share the market for demand response over the coming decades. But expanding the residential share of the pie will require a whole new host of technologies – and business models and regulatory structures – to get there.

One uncertainty is how to get the homeowner involved. Most of Comverge's existing residential demand response programs involve homeowners that sign up for cheaper power in exchange for giving the utility the power to adjust their thermostats for them.

But such direct load control could well give way to using the millions of smart meters being deployed across the United States to offer homeowners a wider variety of options (see 8.3M Smart Meters and Counting in U.S.)

In particular, direct utility control is being downplayed by many of the companies looking to the next generation of smart meters to enable their home energy management offerings (see The Smart Home, Part I).

The idea is that giving customers some kind of control – even if it's only control over choosing settings that automatically turn down stuff via utility commands anyway – is likely to be more popular with utility customers, as well as the regulatory bodies that tell utilities how they can spend their money.

Simply giving customers a view into their energy use can yield big savings, according to many pilot trials of in-home energy devices (see Smart Grid: Test Customers Give Thumbs Up).

And the host of companies looking to make such in-home energy display systems is expanding rapidly, with dozens of startups such as Tendril Networks, EnergyHub, Energate, Control4, Greenbox Technology, Onzo, AlertMe, eMeter and OpenPeak all competing with each other, as well as new home energy systems from Google, Microsoft and Cisco, for utilities' favor (see stories here, here and here).

Some of those systems extend beyond providing information to actual control over home energy suckers, using digital thermostats or "smart plugs" that turn power on and off at the wall socket. Those can be controlled with or without utility involvement, though analysts predict it will take subsidies from utilities – or perhaps a move by telecommunications companies to add them on to existing home entertainment and security systems – to make them more widely popular (see The Telco Home Energy Invasion).

Using smart meters to send pricing signals that encourage people to cut down on using power when its most expensive could be one way to do that. Many utilities are testing such pricing schemes in pilot projects. Some, such as Arizona utilities Salt River Project and Arizona Public Service and a host of utilities in Canada's Ontario province, such as Milton Hydro, are trying them out in a more widespread fashion.

In the meantime, General Electric and Whirlpool are planning to make smart appliances that can power down in response to utility or homeowner controls, though how fast those could come to market will depend on how quickly utilities settle on a standard set of technologies (see GE's Smart Appliances: Smarter With GE Home Energy Manager).

The question of standards and technologies, in turn, is likely to be guided by emerging guidelines for the $3.9 billion in federal stimulus grants directed at smart grid projects, including smart meter deployments (see DOE Hands Out $47M for Smart Grid Demos).

The Rest @ Seeking Alpha

Prudent Uses Vanadium-based Redox Regenerative Fuel Cell

I got an interesting comment on one of my posts about distributed power generation and storage.

Charles Toca representing Prudent Energy VRB Energy Storage System (VRB-ESS) says they have an energy storage system base on the the vanadium-based redox regenerative fuel cell that converts chemical energy into electrical energy.

This is from their website:

-Editor

How It Works

The VRB Energy Storage System (VRB-ESS) is an electrical energy storage system based on the patented vanadium-based redox regenerative fuel cell that converts chemical energy into electrical energy.

Energy is stored chemically in different ionic forms of vanadium in a dilute sulphuric acid electrolyte. The electrolyte is pumped from separate plastic storage tanks into flow cells across a proton exchange membrane (PEM) where one form of electrolyte is electrochemically oxidized and the other is electrochemically reduced. This creates a current that is collected by electrodes and made available to an external circuit. The reaction is reversible allowing the battery to be charged, discharged and recharged.

The principle of the VRB is shown in more detail in Figure 1 - it consists of two electrolyte tanks, containing active vanadium species in different oxidation states

• (positive: V(IV)/V(V) redox couple,
• negative: V(II)/(III) redox couple).

These energy-bearing liquids are circulated through the cell stack by pumps. The stack consists of many cells, each of which contains two half-cells that are separated by a membrane. In the half-cells the electrochemical reactions take place on inert carbon felt polymer composite electrodes from which current may be used to charge or discharge the battery.

The VRB-ESS employs vanadium ions in both half-cell electrolytes. Therefore, cross-contamination of ions through the membrane separator has no permanent effect on the battery capacity, as is the case in redox flow batteries employing different metal species in the positive and negative half-cells. The vanadium half-cell solutions can even be remixed bringing the system back to its original state.

The open circuit cell voltage at a concentration of 2 mole per liter for each vanadium species is 1.6 V when fully charged. The relatively fast kinetics of the vanadium redox couples allows high Coulombic and voltage efficiencies to be achieved without costly catalysts. The same current is passed through all of the cells as they are arranged in series. Such systems have many admirable properties including high efficiency, long cycle life, ease of scalability and negligible environmental impact.

More....

The VRB-ESS can economically store and supply large amounts of electricity on demand and is focused on stationary applications. It is a long life, cost effective, low maintenance, efficient technology that allows for the scalability of power and storage capacity independently.

The VRB-ESS is particularly beneficial to renewable energy providers, utilities and end users through its ability to “inventory” electricity, allowing for the optimal match of supply and demand.

The VRB-ESS is well suited for a variety of applications. Enabling the provision of “firm” capacity from intermittent renewable generation such as wind and solar; more cost effective and efficient generation of electricity in remote areas; capital deferral for utilities; and load levelling (peak shaving) applications. The VRB-ESS is also capable of providing backup power solutions including applications for utility sub-stations and telecommunication sites.

......

T

Originoil Videos

Here is a video of their process in Action from their website

Originoil is only obne of several companies researching algea as biofuel.

SmartMeters to Grow by 400% in Two Years

The number of smart electricity meters with two-way communications is poised to mushroom in the next two years, according to a study.

Research company Park Associates this week released figures for smart-meter installations in the U.S., saying that there are 8 million units installed, or about 6 percent of all meters.
(Credit: Martin LaMonica/CNET)

As utilities upgrade equipment as part of smart-grid trials, the number of smart meters is forecast to grow to 13.6 million installed next year and to over 33 million in 2011.

Having a method to broker regular communications between a utility and a customer will set the foundation for a widening array of home-energy management tools, said Bill Ablondi, Park Associates' director of home systems.

Home energy management systems can be relatively simple displays or Web-based programs that show how much electricity a home is using. More high-end systems can be built around home-area networks where consumers can program smart appliances and lighting to cut power consumption.

The enabling technology for the more sophisticated home-energy management systems includes various wireless communications options for within the home and for smart meters. But even though many of the technology components are now available, there are a number of barriers to widespread adoption of the smart grid, even with billions of stimulus dollars targeted for smart-grid programs.

Upgrading the electricity distribution system is expensive and variable pricing structures that reflect the cost of peak-time electricity could take a long time to be implemented, Ablondi said in a recent presentation. Also, consumer interest in managing energy, which is high right now, could wane, he added.

Previous smart-grid coverage

FAQ: What the smart grid means to youThere are many definitions and technologies under the smart grid banner. What's the goal and why all the attention?

Images: The many faces of the smart grid - CNET NewsThere are many technologies that go into making the smart grid, a grid that is more efficient and reliable as a whole.

Are consumers ready for the smart grid?Smart meters and in-home energy displays are trickling out into people's homes. But there's still some question whether the technology is consumer-friendly enough.

GE: Smart grid yields net-zero energy home At its research labs, GE says it has the smart-grid technology, including solar panels and efficient appliances, to build a home that has a net-zero energy consumption.

Photos: GE's smart-grid kitchen of the futureAt its research labs, GE shows off demand-response appliances that can take advantage of cheaper electricity rates automatically.

Control4 adds energy monitoring to home networkBest known for its home entertainment controllers, Control4 gets funds to expand into smart-grid products to monitor and control home energy use.

GE appliances to connect to smart grid via TendrilSmart-grid start-up Tendril Networks and GE will test a system in which home appliances share data with utilities to cut electricity consumption.

Martin LaMonica is a senior writer for CNET's Green Tech blog. He started at CNET News in 2002, covering IT and Web development. Before that, he was executive editor at IT publication InfoWorld. E-mail Martin.

The Rest @ CNET

Hydrogen-HCNG Car from Norway

FYK is a Norwegian sports car designed to run on a blend of hydrogen and natural gas. It was developed by a Norwegian company named Aetek and received backing from Statoil, the largest petroleum company in the Nordic countries and Norway's largest company in all categories.

FYK was launched in 2006 as a technology demonstrator and there are currently no plans on putting it into series production.

FYK was launched in august 2006, at the same time as Statoil opened up the first filling station in Norway for hydrogen, Natural Hy and natural gas.

• This filling station can be found in Forus, Stavanger. F


• YK is powered on NaturalHy (HCNG), a blend consisting of 8-20% hydrogen and 92-80% compressed natural gas.


• The car is built almost entirely in aluminium in order to reduce weight and the car is fitted with cutting edge wireless communications solutions from Norway.


• Not only body and chassis, but suspension, motor, wheels and the entire has been made from recyclable aluminium and exterior as well as interior is formidable display of various aluminium-shaping techniques and surface treatments.


• Critics has put forward that just like gasoline, natural gas is a fossil fuel that contributes to increased levels of carbon dioxide in the atmosphere. Natural gas is found in oil fields, natural gas fields and coal beds. (There is another type of methane-rich gas that can be produced by non-fossil organic materials as they decay, but this type of gas is commonly referred to as biogas, not natural gas.)

According to Statoil and Aetec, FYK should however only be seen as the first step towards future hydrogen powered cars. Aetec, the company behind the ground-breaking FYK is a Norwegian design- and prototype development company focused on the development of environmentally friendly concepts for the transport sector.

According to Aetec, they wish to combine environmentally friendly designs with excitement, and it therefore comes as no surprise that they are behind innovative creations like a hydrogen/natural gas powered sports car.

The Rest @ XM3 CArs

Is The Loopwing Wind Turbine Coming to the US?

The Loopwing Wind Turbine

This loopy looking item is a striking wind turbine design with some interesting features. A Japanese company is offering this small-scale wind turbine that touts an amazingly low 1.6m/sec (3.5 mph) minimum generation speed (compared with 8-11 mph for many turbines.)
The company claims a number of benefits for the Loopwing turbine attributed to the unusual configuration of the blades. Because there are no blade tips, the Loopwing doesn't have tip vortex effects, and is therefore much quieter. This also reduces vibration, which helps with both noise and extending the life of the turbine and generator. The blade configuration is also responsible for its low start speed.
Check out this awesome broken-english press material:
People witnessing a test model in operation gave high evaluation saying that there is no noise at all. The unique-shaped blade has self-stalling capability and it can avoid over-speeding. Loopwing’s rotation has globular trajectory and it can deflect smoothly even in gust, for example in a place on the roof of a building where the strong wind blows.There you have it...it's all about the globular trajectory avoiding over-speeding.
The Loopwing turbine appears to making the rounds of Japanese trade shows, and they have secured a US patent. So it's possible that it will be coming, but as yet there doesn't seem to be a North American distributor.

The Rest @ Ecogeek

Via: Metaefficient

11kW machines were installed in the hospital. (http://www.yahagi-seikei.com/)
(diameter 6.67m, rated power 11kW) was installed in a hospital near the windmill.

Wind speed of 2m / s wind from the start only, the estimated annual energy production is 5234kWh (annual average wind speed of 4m / s time).

Google Translation from the website in Japanese

US Treasury Guidance for Grants over ITC and PTC

July 9, 2009
The American Recovery and Reinvestment Act of 2009 (ARRA), which was enacted in February, permits an applicant to receive a grant from Treasury in lieu of claiming investment tax credits (ITCs) or production tax credits (PTCs).

Today the U.S. Treasury Department issued much-anticipated guidance concerning applications to receive cash grants in lieu of claiming income tax credits for certain renewable energy projects.

Although the guidance includes a sample application form, the U.S. Treasury has stated that it will not accept applications until August 1.

Click here to read the full analysis on this guidance including grant details, eligibility and the application process at www.stoel.com.

The Rest @ Stoel Rives

Commercial Dye-sensitised solar cells - Graetzel cells- Are Two Years Away

JERUSALEM, July 9 (Reuters) - It may take a little bit of colour to create cheaper solar energy.
Israeli start-up 3GSolar says it has developed the world's first commercial-size solar energy system that uses coloured dyes to turn sunlight into electricity.

The technology emerged from a relatively new field in solar energy that uses simple organic dyes instead of rare or costly materials, like silicon, which scare many consumers away from solar power.

Energy companies have been struggling for years to make dye-sensitised solar cells (DSC) large enough to be used in commercial-size systems. Such next generation cells could be used in cutting-edge applications, like windows that turn passing sun rays into electricity.

Japanese electronics conglomerate Sony Corp (6758.T) said last year it had developed dye-sensitised cells with an energy conversion efficiency of 10 percent, a level seen necessary for commercial use, but that its technology was still in the research and development stage.

A 1.5 square metre (16 square foot) prototype, boasting red panels, stands on the rooftop of the 3GSolar's Jerusalem laboratories. The company's founder, Jonathan Goldstein, says it is by far the largest in the world.

It transforms just seven percent of the sunlight it absorbs into electricity, but he said that its efficiency would increase steadily in the coming years.

Scaling up the size of solar panels has been hampered by problems of metal corrosion in their grids. 3GSolar would not disclose the exact process it used to overcome the obstacle.

"These cells, each individual one of 225 square centimetres (34 square inches), we believe are the largest of this type in the world and give a record-breaking current," Goldstein said.
Dye-sensitised solar cells are also known as Graetzel cells, after Michael Graetzel, a professor at Ecole Polytechnique Federale de Lausanne in Switzerland, who discovered them about 20 years ago.

He found that sunlight excites the dye and creates and electronic charge without the need for pricey semiconductors, similar to the way a plant uses chlorophyll to turn sunlight into energy through photosynthesis.

Graetzel told Reuters the dye-based technology has been gaining momentum in the renewable energy market.

He said there were key advantages over other systems.
These included lower costs, its ability to create electricity in cloudy areas or in non-peak sunlight, and the smaller amount of energy needed to manufacture the panels, which leaves a smaller carbon footprint.

Other companies, including Australia's Dyesol (DYE.AX) and Japan's Sharp Corp (6753.T), have been racing to "scale up" dye solar cells to a commercial size, Graetzel said.

"3GSolar came up with a solution. They report to have a collector that doesn't corrode," Graetzel said. He added that the company has shown promising results from durability tests on their panels carried out over 1,500 hours at 85 degrees Celsius.

"They are not the only company working with DSC, but they have deliberately pushed their particular current collector technology first," he said.

CANDLE-LIT VILLAGES

Ken Zweibel, director of George Washington University's Solar Institute, said dye cells should be pursued but they remain among the "low efficiency" group of solar cells.

"They are inching their way up in efficiency, and they appear to have some headroom," Zweibel said.

He added that the different colour options and range of applications may make dye cells more attractive. But he emphasised the importance of durability: "Can they warrantee 25 years outdoors as their competitors do?"

3GSolar says its first system -- with two solar panels, a charge controller and a battery -- will hit the market in two years. It will target the off-grid market in developing countries, where many villages still depend on candlelight.

The Brussels-based Alliance for Rural Electrification estimated the off-grid market at $1.5 billion.

3GSolar said its system will have a lifespan of about seven years and have an output of 110 watts, enough to power many types of refrigerators.

It will cost $400, less than similar silicon-based systems, when produced locally. That translates into 30 cents per kWh, which is still much higher than fossil fuels.

The company expects the price will come down as the lifespan increases and production costs drop.

The Rest @ Reuters

By Ari Rabinovitch, Editing by Anthony Barker)

Pickens Looking for Partners

Plans for the world's largest wind farm in the Texas Panhandle have been scrapped, energy baron T. Boone Pickens said Tuesday, and he's looking for a home for 687 giant wind turbines.
Pickens has already ordered the turbines, which can stand 400 feet tall — taller than most 30-story buildings.

"When I start receiving those turbines, I've got to ... like I said, my garage won't hold them," the legendary Texas oilman said. "They've got to go someplace."
Pickens' company Mesa Power ordered the turbines from General Electric Co. — a $2 billion investment — a little more than a year ago.

Pickens said he has leases on about 200,000 acres in Texas that were planned for the project, and he might place some of the turbines there, but he's also looking for smaller wind projects to participate in. He said he's looking at potential sites in the Midwest and Canada.

In Texas, the problem lies in getting power from the proposed site in the Panhandle to a distribution system, Pickens said in an interview with The Associated Press in New York. He'd hoped to build his own transmission lines but he said there were technical problems.

Wind power is a big part of the "Pickens Plan," which was announced a year ago Wednesday. Pickens has spent $60 million crisscrossing the country and buying advertising in an effort to reduce the nation's reliance on foreign oil.

"It doesn't mean that wind is dead," said Pickens, who runs the Dallas-based energy investment fund BP Capital. "It just means we got a little bit too quick off the blocks."
Pickens announced in 2007 plans to install the turbines in parts of four Texas Panhandle counties.

He had hoped to complete the four-phase project in 2014 and eventually have 4,000 megawatts of capacity, enough to power more than one million homes. The total cost was expected to
approach $12 billion.

Renewable energy provides a small fraction of electricity used today, but the wind and solar sectors are the fastest growing in the U.S. In 2008, the U.S. became the world's leading provider of wind power.

Like most industries around the world, the recession has hurt wind turbine manufacturers and wind farm developers. Companies have shelved development plans and laid off workers.

See also: FOXNEWS.COM HOME > SciTech > Texas Billionaire Pickens Blows Off Plans for Wind Farm

Distributed Clean Energy In a Brownfield Redevelopment

BRISTOL TOWNSHIP – Pennsylvania Department of Environmental Protection Secretary John Hanger today toured The Bridge Business Center in Bristol Township, Bucks County, where $1 million in federal recovery funds are being used to install a modern energy system in a former Rohm & Haas laboratory.

Secretary Hanger witnessed a milestone in the project’s development, as seven micro-turbines were lifted by crane and placed on the roof of a building at 360 George Patterson Blvd., where renovations are underway in the 50,000-square-foot, multi-tenant facility.
“This is how recovery funds are making a real difference in people’s lives,” said Hanger. “In a community that has suffered from an economic downturn, we see this developer making not only a $4.5 million investment in adaptive reuse of a building on a designated brownfield site, but also in providing a clean, affordable and reliable source of energy for its tenants.”

In March, Governor Edward G. Rendell announced the $1 million Pennsylvania Energy Development Authority grant to the Keystone Redevelopment Group to install an energy system that uses gas-fired micro-turbines. This project is one of the first in the state to receive funding through the federal American Recovery and Reinvestment Act.

Through the installation of this system, total savings on energy costs over a 10-year period are expected to equal approximately $2 million. A significant portion of that savings – as much as $150,000 a year – will come from the sale of energy back to PECO. This system will reduce CO2 emissions by roughly 3 million pounds per year, the equivalent of removing 318 average sized passenger cars off the road.

The retrofitting of 360 George Patterson Blvd., the design and installation of its sustainable energy system, and employment by its tenants are expected to result in the creation of 100 high-wage jobs.

“Chemical research and development is an energy-intensive business,” Hanger said. The incorporation of this energy system is expected to make The Bridge Business Center highly competitive in the life sciences real estate market, and to attract tenants that will create hundreds of additional high-wage jobs in the future.”

The Bridge Business Center is located in a Keystone Innovation Zone. KIZs are established in communities with institutions of higher education, and are designed to foster innovation and create entrepreneurial opportunities. More than 600 jobs have been lost in Bristol Township since 2005 as employers Rohm & Haas and Jones New York downsized.

To learn more about how the federal economic stimulus will benefit communities across Pennsylvania, visit http://www.ahs2.dep.state.pa.us/redirector?varURL=http://www.recovery.pa.gov.
###

COMMONWEALTH OF PENNSYLVANIADept. of Environmental ProtectionCommonwealth News BureauRoom 308, Main Capitol BuildingHarrisburg, PA 17120FOR IMMEDIATE RELEASE6/25/2009CONTACT:John Repetz Phone: (717) 787-1323

The Rest @ Capstone

Wood Biomass Gasification Combined Heat and Power in the UK

I pulled this from a Alfagy's website: They are developing wood mass gassification in a high heat low oxegen invironment, the burining the clean gas. Very interesting...

-CTE Editor

The range of fully automated Wood Gasified Heat and Power Plants are as follows:


The ENERCARB wood gas technology offers customers a turn-key automated solution for heat and power generation from wood. We can provide a complete solution covering the full value chain from wood preparation to power generation in the 250 kW to 1,000 kW range. This is a gap in the market where the company believes there is a potential £725m market worldwide.A full scale 500 kW wood gasification plant was built for a client and has been operating since April 2009.

Over the next 3 years sales of wood gasification plants are expected growing rapidly with the introduction of new support structures.

Biomass accounts for around 5 per cent of total energy consumption in Europe. In countries such as Finland, Sweden and Austria its contribution reaches 15-20 per cent as biomass is supported with specific policies.

It is primarily used for both production of electricity and heat in cogeneration plants and as a fuel in municipal district heating facilities.

Biomass is likely to have an important role in Europe's ability to meet its targets for renewable use by 2020, according to Frost & Sullivan. There are five accepted technologies for converting biomass fuels into electrical energy; the Schmitt ENERCARB plant is focussed on addressing the second technology:

1. Conventional steam cycle – biomass is burned to produce steam which is then used to drive a turbine

2. Gasification – biomass is converted to a gas using a high temperature oxygen starved environment

3. Pyrolysis – biomass is converted to a liquid rather than a gas

4. Anaerobic digestion – typically sewage sludge is digested to produce methane

5. Landfill gas – collection of gas from landfill sitesGasification is possibly the most attractive of the technologies, but also one of the least developed.

There are a number of practical and engineering issues with gasification which, until now, have been a barrier to full commercial roll out of this technology.The particular issues are:

• Quality of feedstock – can a system be developed to work with a range of different biomass fuels.
• Supply chain – can the fuel be provided in an efficient consistent way.
• Consistency of gas produced – can a plant produce gas of a standard quality that can be burned cleanly.
• Tar free gas production – can the resulting gas have low tar levels which will allow it to be burned for extended periods without maintenance.

The gasification plant has been developed to address all these issues. The Alfagy gasified heat and power plant offers a highly efficient solution to producing electricity from biomass in the 250 kWe – 1,000 kWe range.

Through careful engineering of the gasifier and scrubbing of the gas output, Schmitt has developed a virtually tar free wood gasfier. Specific aspects of the Alfagy Woodgas CHP system that give us a competitive advantage include:
• Improved process for automated fuel feeding
• Effective automated gas scrubbing and filtering systems to produce tar free gas.
• Modular approach offering a simple scalable solution with operational security
• Well engineered, automated, turn-key product giving customers an easy to implement plant.The benefits of producing tar free wood gas include:
• Increased running time between maintenance, in some cases from 24 hours to 8,000 hours
• Higher Return on Investment (ROI)


The Rest @ Alfagy

Sola Ventura

Anyone know anything about Sola Ventura? Not much on their website, but they seem to have a unique distributed cleantech business model.


Sola Ventura LLC brings technology and investment opportunity together to solve clients energy needs. Onsite Green Energy Production can reduce your energy usage, lock in a lower rate for an extended period of years, and cost you nothing for installation and maintenance of any solar, wind, geothermal, and fuel cells required.

Please Comment if you know more...

Nano Wire Mapping - Essential for Photovoltaic Technology

Nano wires are essential for the increase in efficiency of Photo Voltaic Technology. Since the PV effect can occur on wires one 1000th of the diameter of a human hair. The ability to build a mesh of nano wires within a PV cell or PV material is important toward increasing PV Materials.

Now a Company has created a mapping machine that can find a sugar cube in 25 square kilometer of three dimensional space....

Read this article to fin out more.

-Editor

Nano Measurement In The 3rd Dimension

ScienceDaily (July 6, 2009) — From the motion sensor to the computer chip - in many products of daily life components are used whose functioning is based on smallest structures of the size of thousandths - or even millionths - of millimetres. These micro and nano structures must be manufactured and assembled with the highest precision so that in the end, the overall system will function smoothly.
See also:

Because of this, details are important. Scientists at the Physikalisch-Technische Bundesanstalt (PTB) have now developed a meteorological scanning probe microscope into a micro and nano coordinate measuring instrument.

This allows dimensional quantities with nanometer resolution also to be measured on three-dimensional objects in an extraordinarily large measurement range of 25 mm x 25 mm x 5 mm. The new device is already extensively being used at PTB - to a large part for calibration orders from industry and research.

Often, such small dimensions can be grasped only when they are transferred to everyday life. If we assume, for example, that someone lost a cube of sugar within an area of 25 square kilometres – the new micro and nano coordinate measuring instrument would not only be able to find it, but it would also be able to determine its exact position and shape. This does not only apply to plane surfaces, but also to three-dimensional landscapes, for example if the cube of sugar were stuck to a steep wall.

As increasingly, components with structures in the micro- and nanometer range are being used in industry, dimensional metrology on such structures is becoming increasingly important. To meet the increasing requirements for 3D measurements of micro and nano structures, 3D measuring probes newly developed at PTB were incorporated in a metrological scanning probe microscope based on a commercial nano-positioning system with integrated laser displacement sensors of the company SIOS Messtechnik GmbH. The new functionalities given by the measuring probe and the software extend the scanning probe microscope to a metrological micro/nano coordinate measuring machine (CMM) which also allows 3D measurements conforming to standards to be performed on micro and nano structures.

International intercomparisons on step-height standards and lattice structures have shown that the measuring system is worldwide one of the most precise of its kind. For step heights, measurement uncertainties in the subnanometer range - and for measurements of the mean structure spacing on extensive lattice standards even in the range of 10 picometers - have been achieved and confirmed in comparison with optical diffraction measurements.

The new measuring instrument is available for dimensional precision measurements with nm resolution on 3D micro and nano structures such as micro gears, micro balls, hardness indenters and nano lattice standards as well as for comparisons of measures; moreover, it serves as a platform for research and development tasks. It is an important link between nano, micro and macro coordinate metrology.

The Rest @ Science Daily

Matter & EnergyNanotechnology
Materials Science Detectors
Computers & MathMobile Computing
Statistics
Computer Graphics
Reference
Confocal laser scanning microscopy
Scanning tunneling microscope
Nanorobotics
Scanning electron microscope

Coca Cola Bottling with Fuel Cell in New York

HELMSFORD, N.Y. -- Coca Cola Enterprises signed a 10-year contract with UTC Power that will bring two fuel cells to its southern New York bottling plant.

The UTC Power fuel cells will produce heat and energy that can satisfy nearly a third of demand at Coca Cola’s bottling plant in Elmsford, N.Y. The project received $2 million in funds from the state’s Energy Research and Development Authority.

• South Windsor, Conn.-based UTC Power will retain ownership of the fuel cells, in addition to operating and maintaining them.
• The company began offering the 10-year energy services agreement a few years ago, according to company spokeswoman Peg Hashem.“It’s helpful for those who don’t want to spend the capital upfront,” she said.
• Fuel cells produce electricity, heat and water by combining hydrogen and oxygen in an electrochemical process.
• The PureCell 400 fuel cells to be deployed at Coca Cola’s bottling plant are more than twice as energy efficient as traditional power sources and can each generate up to 400 kW of electricity and up to 1.7 million Btu/hour of heat, according to company materials.
  UTC Power's PureCell 400 can generate up to 400 kW of electricity and 1.7 million Btu/hour of heat
• UTC Power, which is a unit of United Technologies Corp., has seen the most success with its energy services contract program in states that offer incentives, she said, such as California, New York, Connecticut and Massachusetts.
• There must also be access to natural gas.
• Hashem believes the Coca Cola deal will be the fuel cell’s first application in a bottling plant when they are delivered next year.

Coca Cola said in a prepared statement it plans to deploy fuel cells to other facilities in North America and Western Europe.

In addition to producing fuel cells for transportation applications, UTC Power has also installed more than 260 stationary fuel cells in 19 countries.

Ideal sites for stationary fuel cells, Hashem said, should operate continuously. “

It also makes the most sense when it is not only generating power, but can take waste heat and put it to work by heating the facility or running it through a chiller for cooling,” she said.

Previous sites include hospitals, data centers, hotels and supermarkets.

For example, a Whole Foods Market in Dedham, Mass., will become the first supermarket in the state to use the PureCell 400 fuel cell to generate 90 percent of its power. The system will also produce almost all of the hot water used at the store when it begins operating later this year. The state provided a $400,000 grant for the project, which is also governed by an energy services contract.

The Rest @ Greenbiz

Fremont, CA School System Goes Solar With $30M Bond

(June 5, 2009) Campbell, CA - Real Goods Solar (NASDAQ: RSOL) announced today it has signed a contract to design and install solar electric systems totaling 3.65 megawatts for the Fremont Union High School District in Sunnyvale, Cupertino and west San Jose, California.

• The new solar systems will be constructed as carports at all five high schools in the District and are expected to save District taxpayers over $12 million in the total cost of electricity over the next 25 years.
• The five systems will contribute enough electricity to cover about 45% of the power usage of each school.
• This solar program, exceeding $30 million, is believed to be the largest direct purchase by a secondary school system in North America, financed by a portion of a $198M school bond approved by the District’s voters in June 2008.
  

The District researched many alternative energy options before choosing Real Goods Solar for these installations across school campuses.

The system monitoring that Real Goods Solar provides will enable campuses to track their electricity offset in the years ahead.

Glenn Evans, COO/Associate Superintendent, stated, “Electricity is our single largest expense other than teachers and staff and we can only use school bond funds for facilites and equipment.

By investing bond dollars in solar, we will save many tens of millions of dollars on electric utility bills over the coming decades and that savings will go directly into supporting educational programs and students.

Real Goods Solar worked very closely with us to develop a solar power system customized to our energy needs. Solar electricity will be a huge win for everyone – for taxpayers, for students, for our community and for the environment.”

A Groundbreaking ceremony will take place at the Homestead High School site on June 9 at 12:45 p.m.

About the Fremont Union High School District:

Located in the heart of Silicon Valley and the San Francisco Bay Area in the State of California, the Fremont Union High School District currently serves over 10,000 students in a 42 square mile area covering all of the City of Cupertino, most of Sunnyvale and portions of San Jose, Los Altos, Saratoga, and Santa Clara in Santa Clara County. People move to the community because of the outstanding elementary and high school districts. The five high schools — Cupertino, Fremont, Homestead, Lynbrook, and Monta Vista — continue to hold top ranking throughout the region, state, and nation.

About Real Goods Solar:

Real Goods Solar is a leading solar energy integrator, having installed over 4,500 solar electric systems for both residential and commercial properties. Real Goods Solar offers turnkey solar energy solutions, and has 30 years of experience in solar energy, beginning with its sale of the first solar photovoltaic panels in the United States in 1978. With offices in San Rafael, Richmond, Campbell, Fresno, Santa Cruz, Murrieta, and Hopland, California, as well as in Boulder, Colorado, Real Goods Solar is one of the largest residential solar installers in the United States. Real Goods Solar is publicly traded under the symbol RSOL (NASDAQ). For more information, go to www.realgoodssolar.com or call 1-888-507-2561.
###

Capstone C200 Microturbines Going to China

Capstone Receives Order for C200 Microturbines for China Southern Power Grid Pilot Project
Capstone Turbine Corporation - 05.26.2009


Capstone Turbine Corporation (www.microturbine.com) (Nasdaq:CPST), the world's leading clean technology manufacturer of microturbine energy systems, today announced that it has received an order for three C200 microturbine systems for China Southern Power Grid Co., Ltd. ("CSG").

CSG was established on December 29th, 2002 as a result of the power sector deregulatory reform in China. CSG is one of two state-owned power grid companies in China. CSG invests in, constructs and operates the transmission and distribution networks in Guangdong, Guangxi, Yunnan, Guizhou and Hainan provinces and regions.

The low-emission, highly efficient, natural-gas powered turbines will be installed in a 330,000-square-foot CSG dispatch building and serve as a pilot project to show the benefits of microturbines in a combined cooling heat and power ("CCHP") application.

The project also is designed to illustrate how CCHP projects can easily and safely connect to the CSG grid.

The Chinese Science Academy proposed the CCHP pilot project, which will produce 570-kilowatts of clean electricity and about 1,000-kilowatts per hour of thermal energy for the dispatch building.

The electricity will supplement power from the local utility, while the exhaust-heat energy generated by the compact C200 microturbines will be captured and run through an absorption chiller to produce air conditioning.

The Rest @ Energy CEntral

Capstopne's Intepretation of the Stimuls BIl

This is from the Ca[pstone Website



-Editor


Stimulus Package Signed by President Obama On February 17, President Obama signed the American Recovery and Reinvestment Act (H.R.1) into law.



The package contains a number of measures designed to promote clean energy and energy efficiency, many of which could be beneficial to deployment of Capstone’s products and the continued development of our technology. For example, the Stimulus provides:


Grants in lieu of the 10 percent investment tax credit (ITC) on microturbines and combined heat and power (CHP);
$3.2 billion in block grants to states and local governments to spend on energy efficiency and $3,1 billion to fund state energy programs;
$16.8 billion in funding for DOE to fund Research and Development of clean energy and efficiency technologies, among other programs;
Bonus depreciation of capital equipment;
$11 billion to fund clean energy and energy efficiency upgrades at federal buildings.




The following summary contains more details on the individual energy provisions in the Stimulus package that could be beneficial to Capstone’s business.


Overview of Energy Provisions in the Stimulus Bill

• Clean Energy Grants: Purchasers of microturbines and CHP systems can now elect to receive grants in lieu of the ITC for projects placed in service during 2009 and 2010 (or after 2010 if commenced in 2009-2010).


• The Act also allows facilities included in Section 45 (biomass, biodiesel, landfill gas, et al) to take a 30 percent refundable ITC in lieu of the Production Tax Credit (PTC) for projects placed in service on or before 2013.


• Energy Efficiency and Conservation Block Grants: Appropriates $3.2 billion for Energy Efficiency and Conservation Block Grants as authorized in the Energy Independence and Security Act of 2007. This funding goes to state and local governments to make investments in energy efficiency, including the application and implementation of energy distribution technologies that significantly increase energy efficiency.
  Repeals Penalty for Financing Section 48 Technologies (Microturbines and CHP, et al): Allows businesses and individuals to qualify for the full amount of the tax credit, even if projects are financed with local development bonds or other subsidized energy financing.
  


• Green and Efficient Federal Buildings: The Act includes $5.5 billion to be deposited into the Federal Buildings Fund for expenditures to construct, repair and make alterations on federal buildings to increase energy efficiency, including installing solar energy equipment. In addition, $4.5 billion is available for measures necessary to convert Government Services Administration facilities to green buildings. The act also provides $1 billion for non-recurring maintenance on Veterans Affairs medical facilities, including energy projects.


• State Energy Program: $3.1 billion dollars will be made available to the Secretary of Energy to award grants to states. The award of this funding is conditioned upon a notification to the Secretary of Energy by the governor that the state has obtained the necessary assurances to adopt certain utility regulatory polices to encourage utility-sponsored energy efficiency improvements and updated energy efficient building codes. In order to take advantage of existing institutional structures, a state is also encouraged to use federal funds to existing energy efficiency and renewable energy programs.
  Loan Guarantee Program: Establishes a temporary, low-cost loan guarantee program by DOE for renewable energy systems and electric power transmission projects that begin construction by September 30, 2011. The Act makes available $6 billion for use by this program, which is estimated to support more than $60 billion in loans for these projects.
  Manufacturing Investment Credit: Provides a 30 percent investment tax credit for facilities engaged in the manufacture of advanced energy property, including microturbines. Projects must be certified by the Treasury, in consultation with the Secretary of Energy, through competitive bidding. .Extend Bonus Depreciation: Allows businesses to recover 50 percent of the cost of capital investment in the first year in order to spur upfront expenditures in 2009 and 2010.
  Energy Department Funding: Appropriates $16.8 billion to energy efficiency and renewable energy, including $2.5 billion for applied R&D, demonstration and deployment projects. There will be $800 million for projects related to biomass and $400 million for geothermal projects which, according to the U.S. Clean Heat and Power Association, could also include funding for sections 451, 452 and 471 (these provisions were stripped from the House version). These provisions could entail a DOE grant program for CHP projects.
  


• New Clean Renewable Energy Bonds (“New CREBs”): Provides an additional $1.6 billion for local governments and municipalities to finance facilities that generate electricity from renewable energy (biogas, biodiesel, landfill gas, et al) sources.


• Qualified Energy Conservation Bonds: Authorizes $2.4 billion in bonds to finance state, municipal and tribal government programs that reduce greenhouse gas emissions.


• Green Collar Jobs: Appropriates $500 million to fund job training programs in energy efficiency and renewable energy.


• Smart Grid: Provides up to 50 percent reimbursement to electric utilities or other parties that carry out smart‐grid demonstration projects.
  Renewable Energy for Water Treatment Plants: Appropriates $2.4 billion in grants that could be used to put renewable energy in wastewater treatment plants.


• Department of Defense Energy and Efficiency Programs: The act provides $300 million to the DOD for the purpose of research, testing and evaluation of projects to energy generation, transmission and efficiency. The bill provides an additional $100 million for Navy and Marine Corps facilities to fund energy efficiency and alternative energy projects.


• The Defense Health Program will also receive $400 million to invest in energy efficiency projects and to improve, repair and modernize military medical facilities in the United States and its territories. There is also an additional $120 million appropriated for the Energy Conservation Investment Program for military construction defense-wide

Environmental Power Corporation

Environmental Power Corporation is a developer, owner, and operator of renewable energy production facilities. The Company owns and operates the Huckabay Ridge facility in Stephenville, Texas, a multi-digester facility for the production of pipeline-grade natural gas, which began commercial operation and has several similar facilities in varying stages of development.
It also operates three digester facilities in Wisconsin utilizing the same technology that is employed at Huckabay Ridge.

The Company has operated in two major segments through Microgy, Inc., as a
developer of renewable energy facilities for the production and commercial application of methane-rich biogas from agricultural and food industry wastes, and through EPC Corporation and its subsidiary, Buzzard Power Corporation, the holder of a leasehold interest in a waste-coal fired generating facility in Pennsylvania known as the Scrubgrass facility. On February 29, 2008, the Company completed the disposition of the leasehold interest Scrubgrass facility.

After the disposition the Company operated only in Microgy’s segment.
The biogas produced by Microgy facilities can be used to produce pipeline-grade methane, which it refer to as RNG, marketable biogas, compressed natural gas (CNG), liquified natural gas (LNG), renewable electrical energy or thermal energy, as well as other useful by-products.

In addition, Microgy has developed, for itself, significant engineering, construction and process knowledge regarding these systems.

Source Reuters

Green Ocean Energy Ltd

Green Ocean Energy has a device to add to wave energy generation to ocean based wind turbins.

[This from their website]

Wave Treader has grown out of our work with Ocean Treader and uses it's Sponsons and Arms but this time they are mounted on the base of a static offshore structure, typically a Wind Turbine or Tidal Turbine. By sharing the high infrastructure costs with another device, such as the foundation costs, cabling costs, etc., the economics of both devices are enhanced and the energy yield for a given sea area greatly improved.


[Wave only device]

Ocean Treader is a floating device designed to be moored 1 – 2 miles offshore in ocean wave systems, and as such will be largely unobtrusive from the shoreline. The theory behind the machine has been proven in wave tank testing and we are now working towards developing a full size machine for offshore testing.

Wave Treader has grown out of our work with Ocean Treader and uses it's Sponsons and Arms but this time they are mounted on the base of a static offshore structure, typically a Wind Turbine or Tidal Turbine. By sharing the high infrastructure costs with another device, such as the foundation costs, cabling costs, etc., the economics of both devices are enhanced and the energy yield for a given sea area greatly improved.

Both devices are unique in their respective fields, are patent applied for, and are both highly cost effective.

Due to our background in the offshore oil and gas industry we are well aware of the challenges in deploying such machines and therefore from the outset they have been designed to satisfy the triplicate requirements of:

Efficiency : Reliability : Survivability

The full story at Green Ocean Energy.com

National Wind Solutions forms "Zero Emissions Fuel Cell" Company

Feb 9, 2009

National Wind Solutions, Inc. (NWND) announced today that it has purchased an option to acquire a breakthrough new fuel cell technology developed by one of America’s major research universities.

The acquisition of this technology is expected to be completed in about 30 days, and will be the cornerstone of NWND’s recently formed subsidiary, Zero Emissions Fuel Cell, Inc. (http://www.zeroemissionsenergy.com/).

• Fuel cells promise clean, efficient power for both home and transportation. While most fuel cell development has focused on automotive applications,
• NWND’s technology will be aimed at delivering power to homes and businesses. The technology will allow users to meet their complete electrical needs using natural gas to drive the fuel cell.
• Natural gas is a readily available, environmentally friendly domestic fuel source which will be an integral part of weaning the United States from our addiction to foreign oil.
• More than 65 million residences and businesses in the United States already have natural gas service.
• These factors will allow for rapid adoption of this breakthrough green energy technology.

The Rest From Renewable Energy World