Tag Archives: U.S. Environmental Protection Agency

Clean-up costs, Diluted bitumen (Dilbit), Emergency Readiness & Response, Enbridge, Evacuation, Oil spill, Pipeline transport, Tar sands crude, Volatile gases

Kalamazoo River 5 years later – still cleaning it up

Repost from OnEarth Magazine, Natural Resources Defense Council
[Editor:  Significant quote: “The Kalamazoo River still isn’t clean.  Let’s not forget how much it cost to (not completely) clean the Kalamazoo. The current price tag is $1.21 billion (and rising), making it the most expensive onshore oil spill in U.S. history.”  – RS]

Remember the Kalamazoo

Five years ago, a pipeline spilled a million gallons of tar sands crude into a Michigan river—and we’re still cleaning it up.
By Brian Palmer, July 22, 2015
Skimmers, like these used to clean up the Deepwater Horizon spill, were useless in Kalamazoo, where the tar sands crude sank to the bottom. Photo: NOAA

Five years ago, in the middle of the night, an oil pipeline operated by Enbridge ruptured outside of Marshall, Michigan. It took more than 17 hours before the Canadian company finally cut off the flow, but by then, more than a million gallons of tar sands crude had oozed into Talmadge Creek. The oil quickly flowed into the Kalamazoo River, forcing dozens of families to evacuate their homes. Oil spills of that magnitude are always disastrous, but the Kalamazoo event was historically damaging.

The first challenge was the composition of the oil. Fresh tar sands crude looks more like dirt than conventional crude—it’s far too thick to travel through a pipeline.

Try pumping this through a pipeline. Photo: Suncor

To get this crumbly mess to flow, producers thin it out with the liquid constituents of natural gas. Diluted bitumen, or dilbit, as it’s called in the tar sands industry, is approximately three parts tar sands crude, one part natural gas liquids.

When dilbit gushed into Talmadge Creek in 2010, the mixture broke apart. The volatile natural gas liquids vaporized and wafted into the surrounding neighborhoods. The airborne chemicals were so difficult to find and eliminate that Enbridge decided it would be better to simply buy some of the homes that were evacuated, preventing the residents from ever returning.

The tar sands oil, which stayed in the water, presented an even bigger chemistry problem. Most forms of oil, including conventional crude, are less dense than water. That’s why oil makes such pretty colors when dropped into a rain puddle—it floats and plays tricks with the sunlight. Traditional oil spill cleanup technology relies heavily on this density relationship. Skimmers and vacuums remove it from the surface. Floating booms prevent surface-level oil from moving into environmentally sensitive areas.

Tar sands crude behaves differently. “Tar sands bitumen is a low-grade, heavy substance,” says Anthony Swift, director of NRDC’s Canada Project (disclosure). “Unlike conventional crude, when bitumen is released into a water body, it sinks.” (See “Sink or Skim,” onEarth’s infographic on why tar sands oil is more difficult to clean up than conventional crude.)

Skimmers, like these used to clean up the Deepwater Horizon spill, were useless in Kalamazoo, where the tar sands crude sank to the bottom. Photo: NOAA

Put simply, the spilled dilbit traveled in every direction—into the air, with the current, to the bottom of the river—at the same time. The U.S. Environmental Protection Agency’s indisputably naïve response reveals how little anyone knew about tar sands crude. The EPA demanded that Enbridge remove the oil from wetlands surrounding the pipe by August 27, a little more than one month after the spill began. The agency wanted the stuff out of the creek, river, and shorelines by the September 27. Those deadlines would have been practical for a typical spill—but not for a tar sands oil spill. A half-decade later, some of the oil still remains—though, much of that has to do with Enbridge botching the cleanup effort (see onEarth’s three-part series, “The Whistleblower”).

Enbridge’s bungling began even before the spill. First, the company knew the pipeline was vulnerable by 2005, if not earlier. When the rupture finally came in July 2010, operators dismissed the alarms as a malfunction of the system for 17 hours before finally accepting that the pipeline had failed. Making things worse, six hours after Calhoun County residents were complaining to 911 about the smell of oil, Enbridge employees were still trying to fix the problem by pumping additional oil into the pipeline. In its review of the accident, the National Transportation Safety Board faulted Enbridge’s “culture of deviance” for what happened, pointing out that the response team in the first hours consisted of four local pipeline maintenance employees who were inadequately trained and made a series of bad decisions.

Not only did Enbridge fail to make the EPA’s initial cleanup deadline, it also blew through a series of fallback deadlines across more than four years. Not until late 2014 did the agency finally sign off on the remediation effort, handing the remaining responsibilities to the Michigan Department of Environmental Quality.

As the cleanup winds down, though, there is little cause for celebration. “The Kalamazoo River still isn’t clean,” says Swift. “The EPA reached a point where additional cleanup might do more harm than good. Much of the river is still contaminated.”

Some local residents accuse the company of overstating its progress. “In the process of beautifying everything and giving money to everybody and making everybody feel good about it, they’re not really telling people about the dangers still there in that water,” says Linda L. Cypret-Kilbourne of Michigan’s Potawatomi tribe.

It’s not clear when the river will go back to pre-spill quality. After conventional oil spills, crews eventually back off and allow microbes to break down the last bits of crude. That approach isn’t a good option in Kalamazoo. First, the area doesn’t have a large natural population of oil-eating microbes like the Gulf of Mexico has. In addition, tar sands crude contains very high levels of heavy metals, which don’t break down easily.

Let’s not forget how much it cost to (not completely) clean the Kalamazoo. The current price tag is $1.21 billion (and rising), making it the most expensive onshore oil spill in U.S. history.

The Kalamazoo River still isn’t clean. The EPA reached a point where additional cleanup might do more harm than good. Much of the river is still contaminated.

It’s tempting to dismiss the slow, botched, expensive, and still-unfinished cleanup as growing pains. Tar sands imports have risen significantly since 2010, as has public awareness of the difference between the Canadian crude and the conventional product. In the five years since the incident, we should have improved tar sands oil spill response. But we didn’t.

If another Enbridge spill were to happen tomorrow, the company might respond more quickly, but huge volumes of heavy tar sands crude would still pour out of the pipeline. David Holtz of the Michigan chapter of the Sierra Club told reporters that a rupture in Enbridge Line 5, another pipeline that runs through Michigan, would be disastrous.

“If they hit the shutoff valve immediately after a rupture, there would still be more than 650,000 gallons of oil spilled into the Great Lakes,” he said.

Cleaning it up would be as challenging today as it was five years ago. There have been no technological breakthroughs since 2010. The tar sands industry should accept a large portion of the blame for this stasis.

“The efforts to improve spill response have been caught up in a public relations war,” says Swift. “The tar sands industry wants you to believe that oil is oil, and that its product involves no heightened concerns. As a result, spill responders are working with largely the same tools today as in 2010.”

Tar sands pipelines—like the one operated by Enbridge, or TransCanada’s proposed Keystone XL pipeline—run for thousands of miles, crisscrossing the United States and Canada in elaborate networks. They entail certain risks, and those risks are not going away. We have to decide how to respond. If we accept them, we must work to minimize the consequences by developing the appropriate safety measures and technology. Or we can reject them by eliminating tar sands from our energy infrastructure. The one thing we must not do is to pretend they don’t exist. The Kalamazoo spill is a reminder. It won’t be the last.

 

Agricultural waste, Biofuels, Federal Regulation (U.S.), Household trash, Jet fuel, Oil prices, Renewable diesel, Research and development

Why Airlines Keep Pushing Biofuels: They Have No Choice

Repost from The New York Times

Why Airlines Keep Pushing Biofuels: They Have No Choice

By  Jonathan Fahey & Scott Mayerowitz, AP Business, July 21, 2015, 12:52 P.M. E.D.T.
FILE - In this Jan. 30, 2009 file photo, a Japan Air Lines staffer checks the biofuel-loaded No. 3 engine of Japan Airlines Boeing 747-300 before a demo flight at Tokyo International Airport in Tokyo. Using blend of 50 percent biofuel and 50 percent traditional Jet-A jet (kerosene) fuel, JAL conducted an hour-long demonstration flight. Many in the industry believe that without a replacement for jet fuel, growth in air travel could be threatened by forthcoming rules that limit global aircraft emissions. Photo: Itsuo Inouye, AP / AP
FILE – In this Jan. 30, 2009 file photo, a Japan Air Lines staffer checks the biofuel-loaded No. 3 engine of Japan Airlines Boeing 747-300 before a demo flight at Tokyo International Airport in Tokyo. Using blend of 50 percent biofuel and 50 percent traditional Jet-A jet (kerosene) fuel, JAL conducted an hour-long demonstration flight. Many in the industry believe that without a replacement for jet fuel, growth in air travel could be threatened by forthcoming rules that limit global aircraft emissions. Photo: Itsuo Inouye, AP / AP

NEW YORK — The number of global fliers is expected to more than double in the next two decades. In order to carry all those extra passengers, airlines are turning to a technology very few can make work on a large scale: converting trash into fuel.

They have no other choice.

As people in countries such as China, India and Indonesia get wealthier they are increasingly turning to air travel for vacation or business, creating an enormous financial opportunity for the airlines. The number of passengers worldwide could more than double, to 7.3 billion a year, in the next two decades, according to the International Air Transport Association.

But many in the industry believe that without a replacement for jet fuel, that growth could be threatened by forthcoming rules that limit global aircraft emissions.

“It’s about retaining, as an industry, our license to grow,” says Julie Felgar, managing director for environmental strategy at plane maker Boeing, which is coordinating sustainable biofuel research programs in the U.S., Australia, China, Brazil, Japan and the United Arab Emirates.

Cars, trucks and trains can run on electricity, natural gas, or perhaps even hydrogen someday to meet emissions rules. But lifting a few hundred people, suitcases and cargo 35,000 feet into the sky and carrying them across a continent requires so much energy that only liquid fuels can do the trick. Fuel from corn, which is easy to make and supplies nearly 10 percent of U.S. auto fuel, doesn’t provide enough environmental benefit to help airlines meet emissions rules.

“Unlike the ground transport sector, they don’t have a lot of alternatives,” says Debbie Hammel, a bioenergy policy expert at the Natural Resources Defense Council.

That leaves so-called advanced biofuels made from agricultural waste, trash, or specialty crops that humans don’t eat. United Airlines last month announced a $30 million stake in Fulcrum Bioenergy, the biggest investment yet by a U.S. airline in alternative fuels. Fulcrum hopes to build facilities that turn household trash into diesel and jet fuel.

FedEx, which burns 1.1 billion gallons of jet fuel a year, promised Tuesday to buy 3 million gallons per year of fuel that a company called Red Rock Biofuels hopes to make out of wood waste in Oregon. Southwest Airlines had already agreed to also buy some of Red Rock’s planned output.

These efforts are tiny next to airlines’ enormous fuel consumption. U.S. airlines burn through 45 million gallons every day. But airlines have little choice but to push biofuels because the industry is already in danger of missing its own emissions goals, and that’s before any regulations now being considered by the U.S. Environmental Protection Agency and international agencies.

The industry’s international trade group has pledged to stop increasing emissions by 2020 even as the number of flights balloons. By 2050, it wants carbon dioxide emissions to be half of what they were in 2005.

Like airlines, the U.S. military is also supporting development of these fuels for strategic and financial reasons. For biofuels makers, it is a potentially enormous customer: The military is the biggest single energy consumer in the country.

Making biofuels at large, commercial scale is difficult and dozens of companies have gone belly up trying. The logistics of securing a steady, cheap supply of whatever the fuel is to be made from can take years. Financing a plant is expensive because lenders know the risks and demand generous terms. A sharp drop in the price of crude oil has made competing with traditional fuels on price more difficult.

The airlines are now seeing some of these difficulties up close. A United program to power regular flights between Los Angeles and San Francisco with fuels made from agricultural waste was delayed when the fuel producer, AltAir, had trouble retrofitting the existing refinery. The companies now say the flights should begin in August. Red Rock’s planned deliveries to Southwest have also been pushed back, to 2017 from 2016, and construction of the plant has not yet started.

But many in the industry say they are not surprised, or daunted, by the time and effort it will take to bring large amounts of biofuels, at competitive prices, to market.

“We really are trying to create a brand new fuel industry,” says Boeing’s Felgar. “We’ve always known this is a long term play, and our industry is long term.”

And if any industry is going to crack fuel from waste on a big scale, the airline industry might be the best bet.

Instead of having to build the infrastructure to distribute and sell these fuels at hundreds of thousands of gas stations, jet fuel only has to be delivered to a small number of major airports. For example, nearly half of United’s passengers fly through its five hubs in Houston, Chicago, Newark, San Francisco and Denver.

Still, after the many disappointments that have plagued biofuel development, few want to promise an imminent biofuel revolution. “I’m not Pollyannaish about this,” says Felgar. “I’m not optimistic, I’m not pessimistic, but I’m determined.”

Bakken Crude, Clean-up, Crude By Rail, Derailment, Explosion, Fire, Oil spill, Rivers, Soil contamination, Spill prevention and response, Water contamination

CSX Provides Update on W.Va. Oil Train Derailment Cleanup

Repost from ABC News

CSX Provides Update on W.Va. Oil Train Derailment Cleanup

By JOHN RABY Associated Press, Jul 21, 2015, 7:51 PM ET

GLEN FERRIS, W.Va. – CSX is continuing to closely monitor the environmental impact of a fiery oil-train derailment in southern West Virginia, a spokeswoman said Tuesday.The company held a public informational meeting that drew a sparse turnout Tuesday evening at the Glen Ferris Inn.

On Feb. 16, 27 cars of a CSX train’s 109 cars derailed during a snowstorm in Mount Carbon. Twenty of the cars leaked oil, some of which burned or was released into the ground.

Under a March consent order with the U.S. Environmental Protection Agency, the railroad agreed to a long-term plan for cleaning up and restoring the area around the derailment.

“It’s important for the community to know that we said we would be here,” CSX spokeswoman Melanie Cost said. “This is part of that process. We want to keep the open dialogue for them.”

Donna Shabdue lives near the derailment site and was forced to evacuate her home for more than a day. She showed up to the meeting to voice her concerns about local emergency response and pleaded for quickly informing the public about future incidents.

“They need to have a plan,” she said. “We didn’t know what to do. There needs to be a siren somewhere go off to evacuate. We didn’t know what to do. I just want out of there safely.”

The train was carrying 3 million gallons of Bakken crude and headed to Yorktown, Virginia. In recent years, trains hauling crude from the Bakken region of North Dakota and Montana have been involved in fiery derailments in six states.

The Federal Railroad Administration is investigating the West Virginia accident, which shot fireballs into the sky, burned down a nearby house and caused fires on the ground that smoldered for days.

The cause of the derailment hasn’t been released. Speed had previously been ruled out as a factor. The FRA has said the train was going 33 mph at the time of the crash. The speed limit was 50 mph.

CSX said more than 181,000 gallons of crude oil was recovered after the accident. About 10,000 tons of soil has been removed and shipped for disposal. Additional soil removal is planned next to the Kanawha River and a tributary at the derailment site.

Air, water and soil sampling continues. The water monitoring is at five locations along the river, including a drinking water intake, because of the occasional presence of oil sheens. CSX said the local drinking water supply has been unaffected by the spill.

Oil-absorbing booms were attached to a metal wall more than 410 feet long in the river as an additional containment measure. The wall will eventually be taken down once the sheens are no longer detected, Cost said.

Cost declined to disclose how much the company has spent on the cleanup.

Aquifers, Crude By Rail, Fracking, Injection wells

Some California oil firms may lose sites for dumping … by 12/31/16

Repost from The San Francisco Chronicle

U.S. likely to bar oil-waste dumping into 10 California aquifers

By David R. Baker, July 16, 2015 7:26pm

"The

Oil companies will probably have to stop injecting their wastewater into 10 Central Valley aquifers that the state has let them use for years, in the latest fallout from a simmering dispute over whether California has adequately protected its groundwater from contamination.

The aquifers lie at the heart of a decades-old bureaucratic snafu whose discovery has upended the state office that regulates oil-field operations and prompted lawmakers to demand reform.

Starting in 1983, California’s Division of Oil, Gas and Geothermal Resources let companies dump water left over from their drilling operations into 11 aquifers that the state believed had received federal exemptions from the U.S. Safe Drinking Water Act, which shields groundwater supplies from pollution. But the U.S. Environmental Protection Agency insisted it had never granted the exemptions. The aquifers, according to the EPA, should have been protected.

After the disagreement came to light, the division agreed to stop oil-company injections into the disputed aquifers or ask the EPA for formal exemptions, which would allow oil companies to continue using the aquifers for disposal. But in an update to the EPA on Wednesday, the division said 10 of the 11 aquifers probably would not meet the legal standards for exemption. They lie too close to the surface — in one case, as shallow as 200 feet — and their water isn’t salty enough.

One of the 10 aquifers may still be eligible for an exemption, because it may be part of an oil reservoir, said division spokesman Donald Drysdale. The division is still seeking more information.

“We’re trying to run that to ground right now,” he said.

Five of the aquifers are no longer being used for wastewater disposal, according to the division. If the others don’t receive exemptions, wastewater injections there must stop by Dec. 31, 2016.

California’s oil fields contain large amounts of salty water mixed with the oil, the remains of an ancient sea. That water must be stripped from the petroleum and disposed of, usually by pumping it back underground. Often, it goes back into the same oil reservoir it came from.

But over time, the division has allowed oil companies to inject billions of barrels of this wastewater into aquifers that had relatively clean water — water that with treatment could have been used for drinking or irrigation. So far, the state has not found any instances in which the injections contaminated drinking-water supplies. But the division has shut down 23 injection wells that it considered high-risk, due to their close proximity to drinking-water wells.

The division has now established a timetable for phasing out all of the injections into aquifers that should have been protected by the Safe Drinking Water Act, with the last injection wells scheduled to close in February 2017. That long time frame will give the oil companies a chance to find other ways to deal with their “produced water.” But it has infuriated environmentalists, who have sued the state to force an immediate shutdown of the injection wells.

The federal EPA can exempt aquifers from the law, but only under stringent conditions. The aquifer must be salty enough or deep enough that tapping it for drinking water isn’t practical. If it contains significant amounts of oil or minerals, it’s considered a strong candidate for exemption.

If, however, someone already uses it for drinking, it cannot receive an exemption.

David R. Baker is a San Francisco Chronicle staff writer.