Tag Archives: Energy

Problems Using Corn as Biofuel

The pluses and (mostly) minuses of biofuels by Robert Sanders

one ripple effect from the stampede to create more ethanol from corn in the United States. As corn prices skyrocketed several years ago, soybean fields were converted to corn, and the price of soy rose. As a result, farmers in Brazil, one of the main countries with the soil, climate and infrastructure to make up the difference, began to bulldoze rainforest to grow more soybeans.

“If reduced U.S. soybean production results in a parallel increase in Brazilian soybean production, a potential net release of 1,800 to 9,100 Tg (trillion grams) of CO2-equivalents of greenhouse gas emissions due to land-use change is possible,” Coe wrote in a summary of his talk. That is equivalent to more than 9 billion metric tons of carbon dioxide.

Canadian Oil Sands

Photograph by Peter Essick, National Geographic

Canadian Oil Boom

To extract each barrel of oil from a surface mine, the industry must first cut down the forest, then remove an average of two tons of peat and dirt that lie above the oil sands layer, then two tons of the sand itself. It must heat several barrels of water to strip the bitumen from the sand and upgrade it, and afterward it discharges contaminated water into tailings ponds like the one near Mildred Lake. They now cover around 50 square miles.
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The Alberta government estimates that the province’s three main oil sands deposits, of which the Athabasca one is the largest, contain 173 billion barrels of oil that are economically recoverable today. “The size of that, on the world stage—it’s massive,” says Rick George, CEO of Suncor, which opened the first mine on the Athabasca River in 1967. In 2003, when the Oil & Gas Journal added the Alberta oil sands to its list of proven reserves, it immediately propelled Canada to second place, behind Saudi Arabia, among oil-producing nations. The proven reserves in the oil sands are eight times those of the entire U.S. “And that number will do nothing but go up,” says George. The Alberta Energy Resources and Conservation Board estimates that more than 300 billion barrels may one day be recoverable from the oil sands; it puts the total size of the deposit at 1.7 trillion barrels.
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But the free market does not consider the effects of the mines on the river or the forest, or on the people who live there, unless it is forced to. Nor, left to itself, will it consider the effects of the oil sands on climate. Jim Boucher has collaborated with the oil sands industry in order to build a new economy for his people, to replace the one they lost, to provide a new future for kids who no longer hunt ptarmigan in the moonlight. But he is aware of the trade-offs. “It’s a struggle to balance the needs of today and tomorrow when you look at the environment we’re going to live in,” he says. In northern Alberta the question of how to strike that balance has been left to the free market, and its answer has been to forget about tomorrow. Tomorrow is not its job.

This is a good article by National Geographic. We need energy. We also need to protect the environment. The trade-offs societies decide to make are often not easy. But open discussion of the issues is important.

Google Aids Green Action

Google has a focus on energy as I have discussed previously. Google has been working to provide a way for people to get information on energy use in their homes that can be used to reduce your energy use.

Power to the people

studies show that access to home energy information results in savings between 5-15% on monthly electricity bills. It may not sound like much, but if half of America’s households cut their energy demand by 10 percent, it would be the equivalent of taking eight million cars off the road.
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We’ve been participating in the dialogue in Washington, DC and with public agencies in the U.S. and other parts of the world to advocate for investment in the building of a “smart grid,” to bring our 1950s-era electricity grid into the digital age. Specifically, to provide both consumers and utilities with real-time energy information, homes must be equipped with advanced energy meters called “smart meters.” There are currently about 40 million smart meters in use worldwide, with plans to add another 100 million in the next few years.
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Over the last several months, our engineers have developed a software tool called Google PowerMeter, which will show consumers their home energy information almost in real time, right on their computer. Google PowerMeter is not yet available to the public since we’re testing it out with Googlers first.

$100 Million to Tackle Energy Issues

Stanford launches $100 million initiative to tackle energy issues

The $100 million in new funds will enable the hiring of additional faculty and support new graduate students, in addition to the more than $30 million in yearly funding now spent on energy research.
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Precourt holds bachelor’s and master’s degrees in petroleum engineering from Stanford and an MBA from Harvard University. He has spent his career in the energy industry, holding president and/or CEO positions at Hamilton Oil Co.; Tejas Gas Corporation, subsequently a Shell Oil Co. subsidiary; and ScissorTail Energy and Hermes Consolidated, gatherers, transporters and processors of natural gas, crude oil and refined products.

He is convinced that Stanford research can influence national energy policy for the better. “The wonderful resources that are available at Stanford, and the multidisciplinary approach they have to developing working solutions, are really attractive in terms of making things happen,” he said.

On a personal level, Precourt said, “Stanford made a huge impact on my life, as I look back on it. It was a superb education and I made some wonderful friends that I’ve taken with me for my lifetime.” Precourt donated $50 million to the energy institute that bears his name.

A $40 million gift from Steyer and Taylor will create a new research center as part of the institute, the TomKat Center for Sustainable Energy.

Easier Way to Make Coal Cleaner

MIT has an Energy “Manhattan project”. The USA has a huge amount of coal, if we ever can figure out how to make it clean that will be a huge benefit (though I have my doubts we can really make it clean enough). easier way to make coal cleaner

“Our approach — ‘partial capture’ — can get CO2 emissions from coal-burning plants down to emissions levels of natural gas power plants,” said Ashleigh Hildebrand, a graduate student in chemical engineering and the Technology and Policy Program. “Policies such as California’s Emissions Performance Standards could be met by coal plants using partial capture rather than having to rely solely on natural gas, which is increasingly imported and subject to high and volatile prices.”
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The researchers conclude that as a near-term measure, partial capture looks promising. New coal plants with lower CO2 emissions would generate much-needed electricity while also demonstrating carbon capture and providing a setting for testing CO2 storage — steps that will accelerate the large-scale deployment of full capture in the future.

Wind Turbine Manufacturing in Colorado

Vestas picks Pueblo for plant

Danish wind turbine manufacture Vestas Wind Systems has chosen Pueblo for what it has said is a nearly $240 million manufacturing plant to build the steel towers needed to hold wind turbines aloft, state officials said Friday.
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Two weeks ago, on Aug. 15, Gov. Ritter announced that Vestas was building two new manufacturing plants in Brighton. The wind-blade production plant and nacelle assembly factory represent a $290 million capital investment and will bring 1,350 new jobs to Colorado.

Just months before that, in March, the company opened Vestas Blades America Inc., a $60 million manufacturing plant in Windsor, north of Denver, employing about 464 people to build blades for wind turbines. Before that plant was even finished, the company announced in November 2007 that it would increase the plant 50 percent in size, production and employee numbers.

This is a reminder that manufacturing output continues to grow in the USA. In June they received an order for 500 MW in the USA. In October Vestas has received orders for 102 MW of turbines from Italy and 99 MW of turbines from Spain.

59 MPG Toyota iQ Diesel Available in Europe

image of seating in the toyota iQ

59 MPG Toyota iQ On Sale In Europe, US Plans Unclear

With lower carbon dioxide emissions than the Prius — around 159 grams of CO2 emitted per mile by the 1.0 liter gas engine and 166 g/mile for the diesel version — not only does the iQ deliver on fuel economy, but its straight-up conventional engine is a pollution winner too.
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At just about 9.8 feet long, 5.5 feet wide and 4.9 feet tall, Toyota certainly has pulled of a near engineering miracle with the amount of stuff they’ve crammed into this tiny vehicle. Toyota claims the iQ can fit 3 adults and 1 child “comfortably.”
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Toyota expects to sell about 80,000 of them a year in Europe.

I own some Toyota stock (and bought a bit more recently) based on their excellent management and production system and the results they have achieved (so I pay attention to what they are doing – plus I own them because they do things I see as wise so it is a self reinforcing dynamic). Business week recently wrote about Ford’s 65 mpg Diesel Car the U.S. Can’t Have.

I owned Ford stock back when they were adopting Deming based management principles but when they dropped those to pursue short sighted goals and poor management practices I sold and bought Toyota (turned out to be a very wise decision – my mistake was holding Ford too long hoping they would realize their mistake).

$92 Million for Engineering Research Centers

photo of Alex Huabg

NSF Launches Third Generation of Engineering Research Centers with Awards Totaling $92.5 Million. Each of the 5 sites will receive will use $18.5 million over five-years. Each center has international university partners and partners in industry.

The NSF Engineering Research Center for Biorenewable Chemicals (CBiRC), based at Iowa State University, seeks to transform the existing petrochemical-based chemical industry to one based on renewable materials.

The NSF Engineering Research Center for Future Renewable Electric Energy Delivery and Management (FREEDM) Systems, based at North Carolina State University, will conduct research to transform the nation’s power grid into an efficient network that integrates alternative energy generation and new storage methods with existing power sources.

The NSF ERC for Integrated Access Networks (CIAN), based at the University of Arizona, will conduct research to create transformative technologies for optical access networks that offer dramatically improved performance and expanded capabilities.

The NSF ERC for Revolutionizing Metallic Biomaterials, based at North Carolina Agricultural and Technical State University, aims to transform current medial and surgical treatments by creating “smart” implants for craniofacial, dental, orthopedic and cardiovascular interventions.

The NSF Smart Lighting ERC, based at Rensselaer Polytechnic Institute, aims to create new solid-state lighting technologies to enable rapid biological imaging, novel modes of communication, efficient displays and safer transportation.

Photo: Alex Huang will lead direct the research of ways to integrate renewable energy sources into the nation’s power grid at North Carolina State University.

Wind Power Provided Over 1% of Global Electricity in 2007

graph of global installed wind power capacity

Data from World Wind Energy Association, for installed Mega Watts of global wind power capacity in 2007. 19,696 MW of capacity were added in 2007, bringing the total to 93,849 MW. Europe accounts for 61% of installed capacity, Germany accounts for 24% and the USA 18%.

The graph shows the top 10 producers (with the exceptions of Denmark and Portugal) and includes Japan (which is 13th).

Tidal Turbine Farms to Power 40,000 Homes

Scotland Plans World’s First Tidal Turbine Farms

Scottish Power Renewables will apply for planning permission next year to build the two farms in Northern Ireland’s seabed. The turbines will be manufactured in Scotland in an intentional boost to the country’s green-collar job market. The 98-foot structures have been tested to operate in water as deep as 328 feet, and they spin slow enough to allow marine life to avoid the 66-foot blades.
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New York City installed its first turbine for their tidal power farm earlier this month, but the Scottish plan differs in that the farms will be located in the open sea, not a river or straight.

Project aims to harness sea power

Projects on the firth could be operational by 2020… The Scottish and Irish sites would host up to 60 of the turbines – 20 at each site – generating 60 megawatts of power for up to 40,000 homes.