Another example of what continues to attract research funding and investment dollars. As others have pointed out, after seeing how well top down planning has solved so many transportation issues, I will continue to choose walking and biking as a bottom up alternative type of intelligent vehicles.
The holistic perspective, however, tends to undermine the legitimacy of the techno-fix approach with the fact that the most intelligent and healthy vehicles are self powered! Steve
Steve
How Intelligent Vehicles Will Increase the Capacity of Our Roads
As the percentage of computer-controlled cars on the road increases, traffic should flow smoothly for longer, says a new study.
Adaptive cruise control systems work by monitoring the road ahead using a radar or laser-based device and then use both the accelerator and brake to maintain a certain distance from the vehicle ahead. (Other variations can bring the car to a halt in the event of a potential accident).
These devices have been available on upmarket cars for ten years or more and are now becoming increasingly common. If you drive regularly on freeways, the chances are you regularly come across other vehicles being driven by these devices, especially in Europe and Japan (here, the density of traffic means that ordinary cruise control has never caught on in the way it has in the U.S.).
So how does the presence of computer-controlled vehicles affect traffic dynamics? Today, Arne Kesting and pals at the Technical University of Dresden in Germany provide an answer of sorts using a model of traffic flow in which both human and computer-driven cars share the road.
They say that the presence of computer-driven cars increases the amount of traffic that can flow on a road before jamming occurs. And the more of these cars, the greater the capacity becomes. "1 percent more [computer-controlled] vehicles will lead to an increase of the capacities by about 0.3 percent," they say.
That's interesting but there have been other studies suggesting that computer-controlled cars can lead to greater congestion and it's not at all clear why Kesting and company's analysis is superior.
Either way, the argument is probably moot. Computer-controlled cars are just the first step in what many expect to be a revolution in car travel. The big increases in traffic capacity are likely to come when cars are able to communicate with each other. This should allow entire platoons of vehicles to travel as one unit, with just a few centimetres gap between cars and the vehicle in the front communicating its intentions to all the others. Platooning should improve fuel efficiency, too.
Of course, that won't be possible until there is a critical mass of computer-controlled cars on the roads. Even then there is a bigger hurdle to overcome of creating the legal framework in which all this can happen: imagine the insurance claims if one of these platoons were to crash.
The biggest challenge for the makers of cars that drive themselves is no longer technical but legal.
Ref: arxiv.org/abs/0912.3613: Enhanced Intelligent Driver Model to Access the Impact of Driving Strategies on Traffic Capacity
Thursday, December 24, 2009
A sign [article] of what's trending in California. Reusing landfill makes sense [you may even be able to capture the landfill's methane]; the conversion of ag land into power generation land is already creating battlelines as 'we' struggle to maintain our "way of life". In the words of Stewart Brand, "The climate change problem is principally an energy problem". Steve
Stanislaus County Board of Supervisors Watch (12/23/09)
last updated: December 22, 2009 10:53:17 PM
By unanimous vote, Stanislaus County supervisors Tuesday:
• Awarded a one-year exclusive negotiating period to Sol Orchard, which wants to build a solar energy farm at the former Greer Road Landfill. Sol's response beat those submitted by two other companies, including JKB Energy, which recently won a one-year negotiating period for a much larger solar farm next to the county's Fink Road landfill near Crows Landing. Sol has a pending partnership with Solar Power Partners, the nation's third-largest solar energy developer. Preliminary plans include a mounting system that doesn't penetrate soil. Sol will have a year to do environmental studies, make a power-selling deal and negotiate a lease with the county.
-- Garth Stapley
Stanislaus County Board of Supervisors Watch (12/23/09)
last updated: December 22, 2009 10:53:17 PM
By unanimous vote, Stanislaus County supervisors Tuesday:
• Awarded a one-year exclusive negotiating period to Sol Orchard, which wants to build a solar energy farm at the former Greer Road Landfill. Sol's response beat those submitted by two other companies, including JKB Energy, which recently won a one-year negotiating period for a much larger solar farm next to the county's Fink Road landfill near Crows Landing. Sol has a pending partnership with Solar Power Partners, the nation's third-largest solar energy developer. Preliminary plans include a mounting system that doesn't penetrate soil. Sol will have a year to do environmental studies, make a power-selling deal and negotiate a lease with the county.
-- Garth Stapley
Monday, November 16, 2009
Vulcan Logic and the Missing Sink
By: David Richardson
The daily carbon dioxide emissions report probably doesn't come up very often at America's dining room tables, but Kevin Gurney and researchers from the Vulcan Project hope to soon see that change.
Gurney leads Purdue University's Vulcan Project , which has produced the nation's first county-by-county, hour-by-hour snapshot of CO2 emissions. With Vulcan — named after the Roman god of fire and funded by the federal government through the North American Carbon Program
A little goes a long way
The gases nitrogen and oxygen account for 98 percent of the Earth's atmosphere. As one of the alphabet soup of trace gases naturally present in the air, CO2 accounts for a mere .038 percent of the atmosphere by mass; however, it has a disproportionate impact on warming.
As Gurney , the associate director of the Climate Change Research Center
Although the oceans remove one-third to one-half of the carbon dioxide produced each year, "the bad news is, their ability to do so appears to be diminishing," Gurney said. Meanwhile, the thousand-year atmospheric lifespan of CO2 means levels will continue to ratchet up even if emissions ended immediately.
Nevertheless, given what is known about carbon dioxide sources and sinks (locales or processes that remove CO2 from the atmosphere), scientists say CO2 has not accumulated as fast as one might expect, leading to the ironic question, "Why is the atmosphere not more polluted?"
Gurney and Daniel Mendoza, a graduate student with the Vulcan Project, suspect the answer may lie in an unrecognized carbon sink somewhere on the planet, and in light of the diminishing CO2 capacity of the seas, they believe this "missing sink" will play an important role in the carbon policy equation.
Though Gurney said CO2 concentration varies by no more than a few parts per million from pole to pole, he believes that mapping these barely perceptible peaks and valleys in CO2 levels could lead the way to the missing carbon sinks.
"In effect the weather map is a great analogy," he said. "Most people know that the air has temperature everywhere, but we know that in some places it's a bit higher and in some places it's a bit lower just like a weather map shows. CO2 is kind of like that. It's everywhere but it definitely has little bumps and valleys depending upon what's happening at the surface.
"The absence of the gas, where it would otherwise be expected, would indicate the possible location of the missing sinks."
To find the hidden sink, Gurney explained, research must first pin down where the observed carbon dioxide in the atmosphere originates. But that is not easy. CO2 mixes thoroughly with air as it travels over the planet. "You can find CO2 at the South Pole that was generated by industrial activity in the Northern Hemisphere."
Nonetheless, Gurney said, "We've known at the national level how much is coming from the U.S. as a whole," but prior to the Vulcan Project, the best estimates of emissions at the state level were based on fuel sales figures and shipping records.
Drilling down to the local level the math gets even fuzzier. Gurney says "the gold standard" of CO2 emissions estimates merely apportioned total discharges among jurisdictions on the basis of population density. Noting the obvious flaw in that approach, he points out that major CO2 emitters such as interstate highways and power plants, which alone account for 40 percent of U.S. emissions, are often a considerable distance from the population centers they serve.
To get a more accurate view of emissions sources Gurney turned to the U.S. Environmental Protection Agency and its network of local air pollution monitors
Reverse engineering
Although the EPA monitoring system was never intended to record CO2 levels, Gurney said their reports can be reverse-engineered to quantify the CO2 component of the exhaust that produced the pollution, "provided you know the type of device and fuel."
Mendoza is using data recycled from transportation studies picked up by "the thin wires that you can see that run across the road."
"They're the Federal Highway Administration
Although Vulcan collects no original field data, Mendoza says an incredible amount of detail can be coaxed from archival sources. Looking back to the year 2002, he says, Vulcan provides a sector-by-sector breakdown of CO2 emissions from the power plant sector, residential, commercial sectors, and the cement sector. "We can bring it down to a 10-kilometer-by-10-kilometer grid and provide a temporal pattern for most sectors," he said.
"We were a little bit floored by how much emissions actually come out of very unpopulated areas — a lot of that is due to electricity generation, which is such a great part of the economy here," Mendoza noted.
He said Vulcan delivered an additional surprise, revealing large cities to be "much more" CO2 efficient than smaller communities. Aside from the efficiency of urban mass transit, Mendoza believes lifestyle plays a role in the disparity. "Here in rural Indiana, we have large houses out in the middle of two acres, so the heating cost are much larger, but in the city you have the urban heat island effect keeping costs down."
The Vulcan Project Web page offers animated displays that show local CO2 emissions ramping up and down in response to heating and cooling needs, traffic patterns or other cycles of daily American life for the year 2002.
International Appeal
Gurney said U.S. government officials asked him if Vulcan can be used for "verification purposes" for an eventual climate treaty. It's an idea he finds appealing: "It would certainly be better to have an independent scientific body perform that function than a government."
He believes the average citizen can benefit from a dialogue with Vulcan as well. (You can take a look immediately using Google Earth .)
"I was pretty amazed at how interested people were when we released the maps and the movies," he said. "It's always been difficult to communicate the essence of this problem because it's very abstract in a certain way. One of the things that Vulcan has done is start to make this problem a bit more real and at least make it recognizable to people's lives.
"It brings the discussion down to the human scale, to the scale people live, in their state, their county, in some cases, their city. It brings it into their living rooms."
Mendoza said his next tasks will include adding data from Mexico and Canada so the Vulcan grid covers the entire continent.
Gurney, who predicts Vulcan eventually will produce emissions forecasts three months in advance, said he has received funding for a global version of the project and is currently exploring partnership opportunities with candidates in Europe, Asia and South America.
Despite the detour down the public awareness road, Gurney says he has not wavered from his initial quest to discover the missing sink. However, with a better grasp on where the CO2 originates, he says it will take direct observation, on a global scale, to determine where it might be going, and that job he said, is best performed from space.
Print
The daily carbon dioxide emissions report probably doesn't come up very often at America's dining room tables, but Kevin Gurney and researchers from the Vulcan Project hope to soon see that change.
Gurney leads Purdue University's Vulcan Project
A little goes a long way
The gases nitrogen and oxygen account for 98 percent of the Earth's atmosphere. As one of the alphabet soup of trace gases naturally present in the air, CO2 accounts for a mere .038 percent of the atmosphere by mass; however, it has a disproportionate impact on warming.
As Gurney
Although the oceans remove
Nevertheless, given what is known about carbon dioxide sources and sinks (locales or processes that remove CO2 from the atmosphere), scientists say CO2 has not accumulated as fast as one might expect, leading to the ironic question, "Why is the atmosphere not more polluted?"
Gurney and Daniel Mendoza, a graduate student with the Vulcan Project, suspect the answer may lie in an unrecognized carbon sink somewhere on the planet, and in light of the diminishing CO2 capacity of the seas, they believe this "missing sink" will play an important role in the carbon policy equation.
Though Gurney said CO2 concentration varies by no more than a few parts per million from pole to pole, he believes that mapping these barely perceptible peaks and valleys in CO2 levels could lead the way to the missing carbon sinks.
"In effect the weather map is a great analogy," he said. "Most people know that the air has temperature everywhere, but we know that in some places it's a bit higher and in some places it's a bit lower just like a weather map shows. CO2 is kind of like that. It's everywhere but it definitely has little bumps and valleys depending upon what's happening at the surface.
"The absence of the gas, where it would otherwise be expected, would indicate the possible location of the missing sinks."
To find the hidden sink, Gurney explained, research must first pin down where the observed carbon dioxide in the atmosphere originates. But that is not easy. CO2 mixes thoroughly with air as it travels over the planet. "You can find CO2 at the South Pole that was generated by industrial activity in the Northern Hemisphere."
Nonetheless, Gurney said, "We've known at the national level how much is coming from the U.S. as a whole," but prior to the Vulcan Project, the best estimates of emissions at the state level were based on fuel sales figures and shipping records.
Drilling down to the local level the math gets even fuzzier. Gurney says "the gold standard" of CO2 emissions estimates merely apportioned total discharges among jurisdictions on the basis of population density. Noting the obvious flaw in that approach, he points out that major CO2 emitters such as interstate highways and power plants, which alone account for 40 percent of U.S. emissions, are often a considerable distance from the population centers they serve.
To get a more accurate view of emissions sources Gurney turned to the U.S. Environmental Protection Agency and its network of local air pollution monitors
Reverse engineering
Although the EPA monitoring system was never intended to record CO2 levels, Gurney said their reports can be reverse-engineered to quantify the CO2 component of the exhaust that produced the pollution, "provided you know the type of device and fuel."
Mendoza is using data recycled from transportation studies picked up by "the thin wires that you can see that run across the road."
"They're the Federal Highway Administration
Although Vulcan collects no original field data, Mendoza says an incredible amount of detail can be coaxed from archival sources. Looking back to the year 2002, he says, Vulcan provides a sector-by-sector breakdown of CO2 emissions from the power plant sector, residential, commercial sectors, and the cement sector. "We can bring it down to a 10-kilometer-by-10-kilometer grid and provide a temporal pattern for most sectors," he said.
"We were a little bit floored by how much emissions actually come out of very unpopulated areas — a lot of that is due to electricity generation, which is such a great part of the economy here," Mendoza noted.
He said Vulcan delivered an additional surprise, revealing large cities to be "much more" CO2 efficient than smaller communities. Aside from the efficiency of urban mass transit, Mendoza believes lifestyle plays a role in the disparity. "Here in rural Indiana, we have large houses out in the middle of two acres, so the heating cost are much larger, but in the city you have the urban heat island effect keeping costs down."
The Vulcan Project Web page
International Appeal
Gurney said U.S. government officials asked him if Vulcan can be used for "verification purposes" for an eventual climate treaty. It's an idea he finds appealing: "It would certainly be better to have an independent scientific body perform that function than a government."
He believes the average citizen can benefit from a dialogue with Vulcan as well. (You can take a look immediately using Google Earth
"I was pretty amazed at how interested people were when we released the maps and the movies," he said. "It's always been difficult to communicate the essence of this problem because it's very abstract in a certain way. One of the things that Vulcan has done is start to make this problem a bit more real and at least make it recognizable to people's lives.
"It brings the discussion down to the human scale, to the scale people live, in their state, their county, in some cases, their city. It brings it into their living rooms."
Mendoza said his next tasks will include adding data from Mexico and Canada so the Vulcan grid covers the entire continent.
Gurney, who predicts Vulcan eventually will produce emissions forecasts three months in advance, said he has received funding for a global version of the project and is currently exploring partnership opportunities with candidates in Europe, Asia and South America.
Despite the detour down the public awareness road, Gurney says he has not wavered from his initial quest to discover the missing sink. However, with a better grasp on where the CO2 originates, he says it will take direct observation, on a global scale, to determine where it might be going, and that job he said, is best performed from space.
Monday, November 2, 2009
Intelligent Lighting Controls Deliver ROI in 3 Years
October 16, 2009
More building owners and managers are considering intelligent lighting systems to cut energy use because lighting, on average, accounts for approximately one-quarter of a building’s overall electricity use, rivaled only by HVAC and office equipment, according to Gary Meshberg, LEED, AP, and director of sales for Encelium Technologies
State-of-the-art lighting systems reduce costs, demonstrate an overall commitment to being environmentally friendly, as well as contribute toward higher building values, higher tenant retention rates and overall end-user satisfaction, said Meshberg.
As an example, Encelium Technologies’ Energy Control System (ECS) uses addressable networking technology in combination with advanced control hardware and software, which can be integrated with HVAC, security and irrigation systems.
ECS uses a universal I/O (input/output) module to connect to standard lighting components such as low-voltage non-dimming ballasts, and occupancy sensors or photo sensors for digital control capabilities. The system allows each person to control his or her own workspace light levels from their desktop computer, and provides facility managers with energy management capabilities.
Installation of an intelligent lighting system also provides a significant return on investment (ROI), said Meshberg. He cites the following example. ECS installations, which cost between $3.00 and $3.50 per square foot for existing space, are designed to reduce lighting-related energy costs by 50 to 75 percent, so the projected savings of 75 cents to $1.25 per square foot per year means that the installation cost is amortized in less than three years.
As an example, the Rogers Centre sports and entertainment complex in Toronto, with approximately 7,000 light fixtures, cut
Meshberg also said ECS installations ease the way for buildings to earn the U.S. Green Building Council’s Leadership in Energy and Environmental (LEED) certification, contributing up to 18 points needed for certification, as well as facilitate a building’s compliance with ASHRAE 90.1, EPAct, Title 24 of the California Code of Regulations and various utility rebate programs.
More building owners and managers are considering intelligent lighting systems to cut energy use because lighting, on average, accounts for approximately one-quarter of a building’s overall electricity use, rivaled only by HVAC and office equipment, according to Gary Meshberg, LEED, AP, and director of sales for Encelium Technologies
State-of-the-art lighting systems reduce costs, demonstrate an overall commitment to being environmentally friendly, as well as contribute toward higher building values, higher tenant retention rates and overall end-user satisfaction, said Meshberg.
As an example, Encelium Technologies’ Energy Control System (ECS) uses addressable networking technology in combination with advanced control hardware and software, which can be integrated with HVAC, security and irrigation systems.
ECS uses a universal I/O (input/output) module to connect to standard lighting components such as low-voltage non-dimming ballasts, and occupancy sensors or photo sensors for digital control capabilities. The system allows each person to control his or her own workspace light levels from their desktop computer, and provides facility managers with energy management capabilities.
Installation of an intelligent lighting system also provides a significant return on investment (ROI), said Meshberg. He cites the following example. ECS installations, which cost between $3.00 and $3.50 per square foot for existing space, are designed to reduce lighting-related energy costs by 50 to 75 percent, so the projected savings of 75 cents to $1.25 per square foot per year means that the installation cost is amortized in less than three years.
As an example, the Rogers Centre sports and entertainment complex in Toronto, with approximately 7,000 light fixtures, cut
Meshberg also said ECS installations ease the way for buildings to earn the U.S. Green Building Council’s Leadership in Energy and Environmental (LEED) certification, contributing up to 18 points needed for certification, as well as facilitate a building’s compliance with ASHRAE 90.1, EPAct, Title 24 of the California Code of Regulations and various utility rebate programs.
Tuesday, October 6, 2009
Spinning flywheels said to make greener energy
Sep 21, 2009
Associated Press Online
By JAY LINDSAY
TYNGSBOROUGH, Mass., Sep. 21, 2009 (AP Online delivered by Newstex) -- Spinning flywheels have been used for centuries for jobs from making pottery to running steam engines. Now the ancient tool has been given a new job by a Massachusetts company: smooth out the electricity flow, and do it fast and clean.
Beacon Power's flywheels -- each weighing one ton, levitating in a sealed chamber and spinning up to 16,000 times per minute -- will make the electric grid more efficient and green, the company says. It's being given a chance to prove it: the U.S. Department of Energy has granted Beacon a $43 million conditional loan guarantee to construct a 20-megawatt flywheel plant in upstate New York.
"We are very excited about this technology and this company," said Matt Rogers, a senior adviser to the Secretary of Energy. "It's a lower (carbon dioxide) impact, much faster response for a growing market need, and so we get pretty excited about that."
Beacon's flywheel plant will act as a short-term energy storage system for New York's electrical distribution system, sucking excess energy off the grid when supply is high, storing it in the flywheels' spinning cores, then returning it when demand surges. The buffer protects against swings in electrical power frequency, which, in the worst cases, cause blackouts.
Such frequency regulation makes up just 1 percent of the total U.S. electricity market, but that's equal to more than $1 billion annually in revenues. The job is done now mainly by fossil-fuel powered generators that Rogers said are one-tenth the speed of flywheels and create double the carbon emissions.
Beacon said the carbon emissions saved over the 20-year life of a single 20-megawatt flywheel plant are equal to the carbon reduction achieved by planting 660,000 trees.
Flywheels also figure into the emerging renewable energy market, where intermittent energy sources such as wind and solar provide power at wildly varying intensities, depending on how long the breeze blows and sun shines. That increases the need for the faster frequency buffering, Rogers said.
Dan Rastler of the Electric Power Research Institute, an industry research group, added that if a carbon tax is passed by Congress, flywheels start looking a lot better than fossil-fuel powered alternatives.
Beacon's flywheels, massive carbon and fiberglass cylinders, have already been tested on a small scale in New York, California and the company's Tyngsborough offices. Chief executive officer Bill Capp hopes the Stephentown, N.Y., plant will be up and running by the end of 2010.
Flywheels are rotating discs or cylinders that store energy as motion, like the bicycle wheel that keeps rotating long after a pedal's been turned. That energy can be drawn off smoothly depending on the needs of the user, such as when the speed of a potter's wheel is adjusted to shape the clay as desired.
The basics of Beacon's flywheels seem simple enough as they spin silently in their chambers in a small facility outside Beacon's Tyngsborough plant. But the technological challenges to create them were immense and have cost Beacon $180 million, so far.
For instance, the one-ton flywheel had to be durable enough to spin smoothly at exceptionally high speeds. To avoid losing stored energy to friction, the flywheel levitates between magnets in a vacuum chamber.
"We've pretty much demonstrated that it works, it's just a question of scaling," Capp said. "The more we run, the more people get comfortable with us."
Beacon's flywheels are powered by the excess energy they take off the grid. When demand for electricity surges, the flywheels even things out and return the energy to the grid by slowing down.
Flywheels have some clear benefits in energy storage, including the durability to store and release power hundreds of thousands of times over a long, 20-year life, said Yuri Makarov, chief scientist in power systems at Pacific Northwest National Laboratory, which tested Beacon's system for the DOE. Chemical batteries being developed for the same job wear out after a couple thousand charge-and-discharge cycles.
Flywheels use less energy than fossil-fuel powered generators because they adjust more quickly to the ever-shifting demands of the electric grid by simply slowing down or spinning faster, Makarov said. Fossil-fuel generators are slower and less efficient as they constantly fire up and down.
The disadvantage of flywheels, Makarov said, is that they can only store a limited amount of energy for a limited amount of time. That can shut them out of numerous other services the grid demands -- and that other storage technologies can perform -- such as long-term power storage.
Regulations in many markets are also lagging. Beacon will bid against other power generators to provide frequency regulation, but in some markets, the bidding system doesn't even exist yet for energy storage.
Beacon's reward for taking on the technology is that it's the first flywheel company in the nation ready to provide utility-scale frequency regulation in the electric grid. Rogers said the New York project will help show whether the flywheels can do the job:
"If they're successful in New York, we'd expect this kind of technology to be picked up in many other markets around the country," he said.
Associated Press Online
By JAY LINDSAY
TYNGSBOROUGH, Mass., Sep. 21, 2009 (AP Online delivered by Newstex) -- Spinning flywheels have been used for centuries for jobs from making pottery to running steam engines. Now the ancient tool has been given a new job by a Massachusetts company: smooth out the electricity flow, and do it fast and clean.
Beacon Power's flywheels -- each weighing one ton, levitating in a sealed chamber and spinning up to 16,000 times per minute -- will make the electric grid more efficient and green, the company says. It's being given a chance to prove it: the U.S. Department of Energy has granted Beacon a $43 million conditional loan guarantee to construct a 20-megawatt flywheel plant in upstate New York.
"We are very excited about this technology and this company," said Matt Rogers, a senior adviser to the Secretary of Energy. "It's a lower (carbon dioxide) impact, much faster response for a growing market need, and so we get pretty excited about that."
Beacon's flywheel plant will act as a short-term energy storage system for New York's electrical distribution system, sucking excess energy off the grid when supply is high, storing it in the flywheels' spinning cores, then returning it when demand surges. The buffer protects against swings in electrical power frequency, which, in the worst cases, cause blackouts.
Such frequency regulation makes up just 1 percent of the total U.S. electricity market, but that's equal to more than $1 billion annually in revenues. The job is done now mainly by fossil-fuel powered generators that Rogers said are one-tenth the speed of flywheels and create double the carbon emissions.
Beacon said the carbon emissions saved over the 20-year life of a single 20-megawatt flywheel plant are equal to the carbon reduction achieved by planting 660,000 trees.
Flywheels also figure into the emerging renewable energy market, where intermittent energy sources such as wind and solar provide power at wildly varying intensities, depending on how long the breeze blows and sun shines. That increases the need for the faster frequency buffering, Rogers said.
Dan Rastler of the Electric Power Research Institute, an industry research group, added that if a carbon tax is passed by Congress, flywheels start looking a lot better than fossil-fuel powered alternatives.
Beacon's flywheels, massive carbon and fiberglass cylinders, have already been tested on a small scale in New York, California and the company's Tyngsborough offices. Chief executive officer Bill Capp hopes the Stephentown, N.Y., plant will be up and running by the end of 2010.
Flywheels are rotating discs or cylinders that store energy as motion, like the bicycle wheel that keeps rotating long after a pedal's been turned. That energy can be drawn off smoothly depending on the needs of the user, such as when the speed of a potter's wheel is adjusted to shape the clay as desired.
The basics of Beacon's flywheels seem simple enough as they spin silently in their chambers in a small facility outside Beacon's Tyngsborough plant. But the technological challenges to create them were immense and have cost Beacon $180 million, so far.
For instance, the one-ton flywheel had to be durable enough to spin smoothly at exceptionally high speeds. To avoid losing stored energy to friction, the flywheel levitates between magnets in a vacuum chamber.
"We've pretty much demonstrated that it works, it's just a question of scaling," Capp said. "The more we run, the more people get comfortable with us."
Beacon's flywheels are powered by the excess energy they take off the grid. When demand for electricity surges, the flywheels even things out and return the energy to the grid by slowing down.
Flywheels have some clear benefits in energy storage, including the durability to store and release power hundreds of thousands of times over a long, 20-year life, said Yuri Makarov, chief scientist in power systems at Pacific Northwest National Laboratory, which tested Beacon's system for the DOE. Chemical batteries being developed for the same job wear out after a couple thousand charge-and-discharge cycles.
Flywheels use less energy than fossil-fuel powered generators because they adjust more quickly to the ever-shifting demands of the electric grid by simply slowing down or spinning faster, Makarov said. Fossil-fuel generators are slower and less efficient as they constantly fire up and down.
The disadvantage of flywheels, Makarov said, is that they can only store a limited amount of energy for a limited amount of time. That can shut them out of numerous other services the grid demands -- and that other storage technologies can perform -- such as long-term power storage.
Regulations in many markets are also lagging. Beacon will bid against other power generators to provide frequency regulation, but in some markets, the bidding system doesn't even exist yet for energy storage.
Beacon's reward for taking on the technology is that it's the first flywheel company in the nation ready to provide utility-scale frequency regulation in the electric grid. Rogers said the New York project will help show whether the flywheels can do the job:
"If they're successful in New York, we'd expect this kind of technology to be picked up in many other markets around the country," he said.
Wednesday, September 16, 2009
Superefficient Solar from Nanotubes
Tuesday, September 15, 2009
Carbon nanotube photovoltaics can wring twice the charge from light.
By Katherine Bourzac
Today's solar cells lose much of the energy in light to heat. Now researchers at Cornell University have made a photovoltaic cell out of a single carbon nanotube that can take advantage of more of the energy in light than conventional photovoltaics. The tiny carbon tubes might eventually be used to make more-efficient next-generation solar cells.
"The main limiting factor in a solar cell is that when you absorb a high-energy photon, you lose energy to heat, and there's no way to recover it," says Matthew Beard
Researchers led by Paul McEuen
There's evidence that another class of nanomaterials called quantum dots
McEuen cautions that his work on carbon nanotube photovoltaics is fundamental. "We've made the world's smallest solar cell, and that's not necessarily a good thing," he says. To take advantage of the nanotubes' superefficiency, researchers will first have to develop methods for making large arrays of the diodes. "We're not at a point where we can scale up carbon nanotubes, but that should be the ultimate goal," says Lee, who developed the first nanotube diodes while a researcher at General Electric.
It's not clear why the nanotube photovoltaic cell offers this two-for-one energy conversion. "It's mysterious to us," says McEuen. However, the most likely reason is that while conventional solar materials have only one energy level for electrons to move through, carbon nanotubes have several. And two of them just happen to be very well matched: one of the energy levels, or bandgaps, is twice as high as the other. "We may have gotten lucky, and it has very little to do with the fact that it's a carbon nanotube," says McEuen. This means, McEuen hopes, that even if it proves too challenging to make arrays of nanotube solar cells, materials scientists can look for pairs of materials that have these kinds of matched bandgaps, and layer them to make solar cells that do with two materials what the single nanotube cells can do. "Maybe the answer won't be in nanotubes, but in another pair of materials," McEuen says.
Copyright Technology Review 2009.
Carbon nanotube photovoltaics can wring twice the charge from light.
By Katherine Bourzac
Today's solar cells lose much of the energy in light to heat. Now researchers at Cornell University have made a photovoltaic cell out of a single carbon nanotube that can take advantage of more of the energy in light than conventional photovoltaics. The tiny carbon tubes might eventually be used to make more-efficient next-generation solar cells.
"The main limiting factor in a solar cell is that when you absorb a high-energy photon, you lose energy to heat, and there's no way to recover it," says Matthew Beard
Researchers led by Paul McEuen
There's evidence that another class of nanomaterials called quantum dots
McEuen cautions that his work on carbon nanotube photovoltaics is fundamental. "We've made the world's smallest solar cell, and that's not necessarily a good thing," he says. To take advantage of the nanotubes' superefficiency, researchers will first have to develop methods for making large arrays of the diodes. "We're not at a point where we can scale up carbon nanotubes, but that should be the ultimate goal," says Lee, who developed the first nanotube diodes while a researcher at General Electric.
It's not clear why the nanotube photovoltaic cell offers this two-for-one energy conversion. "It's mysterious to us," says McEuen. However, the most likely reason is that while conventional solar materials have only one energy level for electrons to move through, carbon nanotubes have several. And two of them just happen to be very well matched: one of the energy levels, or bandgaps, is twice as high as the other. "We may have gotten lucky, and it has very little to do with the fact that it's a carbon nanotube," says McEuen. This means, McEuen hopes, that even if it proves too challenging to make arrays of nanotube solar cells, materials scientists can look for pairs of materials that have these kinds of matched bandgaps, and layer them to make solar cells that do with two materials what the single nanotube cells can do. "Maybe the answer won't be in nanotubes, but in another pair of materials," McEuen says.
Copyright Technology Review 2009.
Tuesday, September 8, 2009
Panels of Light Fascinate Designers
September 7, 2009
By ERIC A. TAUB
LED light bulbs, with their minuscule energy consumption and 20-year life expectancy, have grabbed the consumer’s imagination.
But an even newer technology is intriguing the world’s lighting designers: OLEDs, or organic light-emitting diodes , create long-lasting, highly efficient illumination in a wide range of colors, just like their inorganic LED cousins. But unlike LEDs, which provide points of light like standard incandescent bulbs, OLEDs create uniform, diffuse light across ultrathin sheets of material that eventually can even be made to be flexible.
Ingo Maurer in the shape of a tree. The first of its kind, it sells for about $10,000.
He is thinking of other uses. “If you make a wall divider with OLED panels, it can be extremely decorative. I would combine it with point light sources,” he said.
Other designers have thought about putting them in ceiling tiles or in Venetian blinds, so that after dusk a room looks as if sunshine is still streaming in.
Today, OLEDs are used in a few cellphones, like the Impression from Samsung, and for small, expensive, ultrathin TVs from Sony and soon from LG. (Sony’s only OLED television, with an 11-inch screen, costs $2,500.) OLED displays produce a high-resolution picture with wider viewing angles than LCD screens.
In 2008, seven million of the one billion cellphones sold worldwide used OLED screens, according to Jennifer Colegrove, a DisplaySearch analyst. She predicts that next year, that number will jump more than sevenfold, to 50 million phones.
But OLED lighting may be the most promising market. Within a year, manufacturers expect to sell the first OLED sheets that one day will illuminate large residential and commercial spaces. Eventually they will be as energy efficient and long-lasting as LED bulbs, they say.
Because of the diffuse, even light that OLEDs emit, they will supplement, rather than replace, other energy-efficient technologies, like LED, compact fluorescent and advanced incandescent bulbs that create light from a single small point.
Its use may be limited at first, designers say, and not just because of its high price. “OLED lighting is even and monotonous,” said Mr. Maurer, a lighting designer
“OLED lighting is almost unreal,” said Hannes Koch, a founder of rAndom International in London, a product design firm. “It will change the quality of light in public and private spaces.”
Mr. Koch’s firm was recently commissioned by Philips to create a prototype wall of OLED light, whose sections light up in response to movement.
Because OLED panels could be flexible, lighting companies are imagining sheets of lighting material wrapped around columns. (General Electric created an OLED-wrapped Christmas tree as an experiment.) OLED can also be incorporated into glass windows; nearly transparent when the light is off, the glass would become opaque when illuminated.
Because OLED panels are just 0.07 of an inch thick and give off virtually no heat when lighted, one day architects will no longer need to leave space in ceilings for deep lighting fixtures, just as homeowners do not need a deep armoire for their television now that flat-panel TVs are common.
The new technology is being developed by major lighting companies like G.E., Konica Minolta, Osram Sylvania, Philips and Universal Display.
“We’re putting significant financial resources into OLED development,” said Dieter Bertram, general manager for Philips’s OLED lighting group. Philips recently stepped up its investment in this area with the world’s first production line for OLED lighting, in Aachen, Germany.
Universal Display, a company started 15 years ago that develops and licenses OLED technologies, has received about $10 million in government grants over the last five years for OLED development, said Joel Chaddock, a technical project manager for solid state lighting in the Energy Department.
Armstrong World Industries and the Energy Department collaborated with Universal Display to develop thin ceiling tiles that are cool to the touch while producing pleasing white light that can be dimmed like standard incandescent bulbs. With a recently awarded $1.65 million government contract, Universal is now creating sheetlike undercabinet lights.
“The government’s role is to keep the focus on energy efficiency,” Mr. Chaddock said. “Without government input, people would settle for the neater aspects of the technology.”
G.E. is developing a roll-to-roll manufacturing process, similar to the way photo film and food packaging are created; it expects to offer OLED lighting sheets as early as the end of next year.
“We think that a flexible product is the way to go,” said Anil Duggal, head of G.E.’s 30-person OLED development team. OLED is one of G.E.’s top research priorities; the company is spending more than half its research and development budget for lighting on OLED.
Exploiting the flexible nature of OLED technology, Universal Display has developed prototype displays for the United States military, including a pen with a built-in screen that can roll in and out of the barrel.
The company has also supplied the Air Force with a flexible, wearable tablet that includes GPS technology and video conferencing capabilities.
As production increases and the price inevitably drops, OLED will eventually find wider use, its proponents believe, in cars, homes and businesses.
“I want to get the price down to $6 for an OLED device that gives off the same amount of light as a standard 60-watt bulb,” said Mr. Duggal of G.E. “Then, we’ll be competitive.”
By ERIC A. TAUB
LED light bulbs, with their minuscule energy consumption and 20-year life expectancy, have grabbed the consumer’s imagination.
But an even newer technology is intriguing the world’s lighting designers: OLEDs, or organic light-emitting diodes
Ingo Maurer
He is thinking of other uses. “If you make a wall divider with OLED panels, it can be extremely decorative. I would combine it with point light sources,” he said.
Other designers have thought about putting them in ceiling tiles or in Venetian blinds, so that after dusk a room looks as if sunshine is still streaming in.
Today, OLEDs are used in a few cellphones, like the Impression from Samsung, and for small, expensive, ultrathin TVs from Sony
In 2008, seven million of the one billion cellphones sold worldwide used OLED screens, according to Jennifer Colegrove, a DisplaySearch analyst. She predicts that next year, that number will jump more than sevenfold, to 50 million phones.
But OLED lighting may be the most promising market. Within a year, manufacturers expect to sell the first OLED sheets that one day will illuminate large residential and commercial spaces. Eventually they will be as energy efficient and long-lasting as LED bulbs, they say.
Because of the diffuse, even light that OLEDs emit, they will supplement, rather than replace, other energy-efficient technologies, like LED, compact fluorescent and advanced incandescent bulbs that create light from a single small point.
Its use may be limited at first, designers say, and not just because of its high price. “OLED lighting is even and monotonous,” said Mr. Maurer, a lighting designer
“OLED lighting is almost unreal,” said Hannes Koch, a founder of rAndom International in London, a product design firm. “It will change the quality of light in public and private spaces.”
Mr. Koch’s firm was recently commissioned by Philips to create a prototype wall of OLED light, whose sections light up in response to movement.
Because OLED panels could be flexible, lighting companies are imagining sheets of lighting material wrapped around columns. (General Electric
Because OLED panels are just 0.07 of an inch thick and give off virtually no heat when lighted, one day architects will no longer need to leave space in ceilings for deep lighting fixtures, just as homeowners do not need a deep armoire for their television now that flat-panel TVs are common.
The new technology is being developed by major lighting companies like G.E., Konica Minolta, Osram Sylvania, Philips and Universal Display.
“We’re putting significant financial resources into OLED development,” said Dieter Bertram, general manager for Philips’s OLED lighting group. Philips recently stepped up its investment in this area with the world’s first production line for OLED lighting, in Aachen, Germany.
Universal Display, a company started 15 years ago that develops and licenses OLED technologies, has received about $10 million in government grants over the last five years for OLED development, said Joel Chaddock, a technical project manager for solid state lighting in the Energy Department.
Armstrong World Industries
“The government’s role is to keep the focus on energy efficiency,” Mr. Chaddock said. “Without government input, people would settle for the neater aspects of the technology.”
G.E. is developing a roll-to-roll manufacturing process, similar to the way photo film and food packaging are created; it expects to offer OLED lighting sheets as early as the end of next year.
“We think that a flexible product is the way to go,” said Anil Duggal, head of G.E.’s 30-person OLED development team. OLED is one of G.E.’s top research priorities; the company is spending more than half its research and development budget for lighting on OLED.
Exploiting the flexible nature of OLED technology, Universal Display has developed prototype displays for the United States military, including a pen with a built-in screen that can roll in and out of the barrel.
The company has also supplied the Air Force with a flexible, wearable tablet that includes GPS technology and video conferencing capabilities.
As production increases and the price inevitably drops, OLED will eventually find wider use, its proponents believe, in cars, homes and businesses.
“I want to get the price down to $6 for an OLED device that gives off the same amount of light as a standard 60-watt bulb,” said Mr. Duggal of G.E. “Then, we’ll be competitive.”
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