Coal in Your Car’s Tank

Coal in Your Car’s Tank by Ed Hiserodt

In 1943, when Germany had virtually no sources of petroleum to fuel its Luftwaffe, U-boats, and Tiger tanks, its scientists (arguably among the best in the world at that time) didn’t turn to solar and wind power. Evil does not equate to naïveté. Hitler’s technical advisers turned to another energy source to keep their Wehrmacht running steadily for several years without petroleum. They used the Fischer-Tropsch process to convert coal into diesel fuel and employed the Bergius hydrogenation (or liquefaction) process to convert coal into aviation gasoline and high-quality truck and automobile gasoline. Coal-to-liquid Technologies

Gasoline and diesel fuel are hydrocarbons. The name gives us a clue as to how to convert coal to liquid fuel: combine hydrogen and carbon. Hydrocarbon fuels are designated by the number of carbon atoms in their molecules. For example, methane, the main constituent in natural gas, has one carbon and four hydrogen atoms. Ethane, butane, and propane are gaseous at room temperature and have two, three, and four carbon atoms respectively.

There are many hydrocarbons, and each has its own unique properties. Pentane, hexane, and heptane are liquid hydrocarbons but not desirable as fuels for internal-combustion engines as they have low ignition temperatures and cause “knocking” or premature combustion that can seriously damage an engine. Octane, with 8 carbon and 18 hydrogen atoms, is the optimum for standard engines, while cetane with 16 carbon and 34 hydrogen atoms is most desirable as a diesel engine fuel.

Nothing about the chemistry of coal has changed since WWII, and it is still possible to synthesize fuel from coal, which ranges from about 65 percent to 95 percent pure carbon. All that’s required is hydrogen, heat, and pressure. Worldwide, such production is done only in limited amounts although one country is a significant producer: South Africa. Just as the Nazis were isolated from petroleum sources during WWII, South Africa’s policy of apartheid brought about an oil boycott from most sources. To survive, they adopted the Fischer-Tropsch process to convert their substantial coal reserves into gasoline and diesel fuel. This is no pie-in-the-sky “someday” technology. The Sasol Ltd. plant in Secunda, South Africa, alone converts coal to 150,000 barrels (6.3 million gallons) of liquid fuel each day.

The question arises: “Why, if the process is relatively simple, isn’t more coal converted into oil?” For years, the answer to that question was cost. It was simply too expensive compared to pumping oil out of the ground, reported to cost the Saudis less than $1 per barrel. Robert Wright of the Department of Energy said in 2007 that coal-to-liquid technology would only be economical once oil prices were at $40 to $50 a barrel. Now that prices are well above that mark and will likely remain there, the problem has become the environmentalists who fear pollution above economic hardships brought on by high-priced motor fuels. But what if we can all have our cake and eat it too? Taking Pollution Out of Coal

The Fischer-Tropsch coal-to-liquid (CTL) process has three reactions to yield hydrocarbon fuels. These reactions require a great deal of heat, heat derived from coal combustion. This process is referred to as Indirect Liquefaction. A major disadvantage of the technique is that the amount of coal used for heat in the coal-to-liquid process is greater than the amount converted to fuel. As a result, this process produces large amounts of ash, fly ash, sulfur dioxide, and nitrogen oxides, not to mention a waste of coal.

The Direct Liquefaction process developed by Nobel Laureate Friedrich Bergius in 1921 requires only one step where hydrogen is combined directly with pulverized coal under high pressure and temperature to produce various hydrocarbons depending on process variables. Since there are no naturally occurring sources of hydrogen like “hydrogen wells,” the H2 in existing coal-to-liquid plants (and in WWII Germany) is produced by the same chemical reactions used in the initial step of the Fischer-Tropsch process, i.e., it is obtained from heating coal with high-pressure steam producing hydrogen and carbon monoxide (C + H2O —> H2 + CO).

The bulk of pollutants created from direct liquefaction, the Bergius process, are created in the making of hydrogen for the process, but the creation of these pollutants can be largely avoided by separating the hydrogen with heat from a new generation of super-safe nuclear reactors.

While anti-nuclear activists have stymied the construction of any new power reactors in the United States for over 30 years, they have not been able to stop the development of new reactor technology, much of which has been done outside the United States. Third-generation modular reactors are designed to make meltdowns physically impossible. Among these developments is the “Pebble Bed Modular Reactor” that uses several hundred thousand baseball-sized fuel spheres, each of which contains 15,000 coated, grain-of-sand-sized fuel kernels. The pyrolytic graphite and silicon carbide layers coating the fuel kernels have melting temperatures far above that of the maximum equilibrium temperature of the reactor, making a meltdown impossible.

In traditional nuclear power plants (which are already extremely safe), water is used as a “moderator” to slow down neutrons so the nuclear reaction can occur, and also as a coolant and heat-transfer medium. In a Pebble Bed Modular Reactor, cooling is accomplished by piping helium through the pebble bed, with the spaces between fuel spheres serving as “pipes.” The pyrolytic graphite coating of the fuel kernels serves as the moderator. Since the helium is not made radioactive by the neutron flux in the reactor, it can be sent directly though a turbine generator to produce electricity or, in this case, used to provide ample heat for the Bergius process. Posma Puts the Pieces Together

Bonne Posma, a successful Canadian businessman who owned a mining technology company and a company specializing in electronics for mining and who previously worked for the South African Council for Scientific and Industrial Research, expanded his company to the United States in 1983. He eventually moved to Ft. Myers, Florida, and became a U.S. citizen. He recently sold the electronics side of his business but maintains a controlling interest in Saminco Electric Traction Drives, devices to power equipment for underground mining applications and public-transit vehicles. A dedicated believer in the free market, Posma’s passion is to see an America free of OPEC extortions and all the dangers that financing its terrorist members represents.

Posma and his Liquid Coal Inc. (www.liquidcoal.com) appear to have a common-sense plan to unleash American engineering and capital and to cause a sea change in our current dependence on unfriendly foreign energy suppliers: that plan consists of using third-generation nuclear power to provide the heat to create oil from coal. Remarkably, this is a technology that even most of those fearful of human-caused global warming could support, having a smaller “carbon footprint” than even electric cars. This holds true because the overall efficiency of a coal-fired power plant (where most electric energy is derived for electric cars) is limited by thermodynamic laws to about 35 percent, while use of a reactor for heat to run the Bergius coal-to-liquid process is nearly 100-percent efficient. Hence, in the CTL process, the carbon from coal is used only for producing fuel that is converted to propulsive energy. Conversely, only one-third of the “carbon footprint” of an electric car powered by the output of a coal-fired plant is for propulsion, with the remainder lost as waste heat.

The process works like this. One hundred and fifty 100-ton rail cars bring the coal feedstock for the conversion process each day. This is about 50 percent more coal per day than used in a typical 1,000 MW power generating plant. The feedstock is fed into the coal-to-liquid processor where the crushed coal is liquefied by heat derived from a Pebble Bed Modular Reactor.* Additional reactor heat is used to generate hydrogen from water. The hydrogen and coal react to produce a variety of hydrocarbon fuels based on the process temperatures and pressures, with diesel fuel being the most desirable according to Posma.

Diesel fuel, which has the highest specific energy of the hydrocarbon fuels, provides “gas mileage” twice that of ethanol and 40 percent higher than gasoline. And this isn’t the “dirty diesel” of years gone by. For those of you accustomed to the smell of exhaust from diesel fuel containing 500 parts per million (ppm) of sulfur, times are a’changing. Low-sulfur fuel now on the market has only 15 ppm. Diesel derived from the CTL process has 5 ppm and is virtually odorless.

Liquid Coal’s projections indicate that it would require 200 CTL plants to produce 10 million barrels of oil per day, reducing our dependence on current imports of 12 million barrels per day by 83 percent. While this may seem like a huge number of CTL plants, energy industry sources report between 132 and 137 major coal-fired power plants currently under construction. Why Not?

Of course there are obstacles standing in the way of the building of such plants to wrest transportation fuels from coal using methods that are both economical and have little impact on the environment — even satisfying most of the global-warming crowd. Tax disincentives and costly regulatory penalties for projects are high on the list of hurdles to overcome.

An example of the above is the current cost of licensing each reactor, regardless of whether it is an exact clone of an earlier design: $60 million to $100 million, even though, according to Posma, the Nuclear Regulatory Committee’s attitude toward new applications has become more reasonable. Besides the regulatory cost disincentives, which in reality would end up getting passed on to consumers through higher energy costs, the big collar and chain holding back nuclear power’s freedom are litigation and the bureaucratic licensing process. Posma elaborates:

To streamline the approval process, the Nuclear Regulatory Commission (NRC) has recently introduced the COL concept (Combined Operating License), which grants a combined construction and operating license to applicants meeting the NRC’s COL requirements. Trouble is, not all of these regulations have been finalized, so the utilities still take somewhat of a financial gamble because past practice mandated issuing a nuclear operating license only after a reactor is constructed — and this is a beautiful opportunity for enemies of energy to start tedious litigation to bankrupt the plant. This is what happened with the Shoreham nuclear power plant. But there is progress: on April 8 this year, the NRC granted our country’s first COL for Georgia Power’s Vogtle 2 and 3 nuclear power sites by considering the existing draft regulations as sufficiently complete to be used as a basis. If all goes well, this COL alone will allow 2,300 MW of electric power to come on line in 2015. Eight more COL approvals should follow shortly.

While ever ready to put up roadblocks to proven sources of reliable energy, environmentalist influences in our government are quick to use tax dollars to subsidize expensive, unreliable wind and solar projects. The subsidy for wind generation is 1.9 cents per kWh alone — more than the cost of nuclear power production, including operations, fuel, depreciation, decommissioning, and spent-fuel storage. Solar-generation subsidies appear purposely unfathomable, but likely off the chart. Both these technologies, being intermittent power sources because of changes in wind speeds and things like cloudiness, night, and precipitation, need to be backed up by conventional power plants that must be kept constantly running (spinning reserves) so as to be able to produce power when needed.†

There are other significant hurdles to overcome before beginning the building of these plants, obstacles that fall under the category of general “environmental concerns,” such as the dangers from nuclear power-plant wastes. Besides the fact that the dangers from plant wastes are greatly exaggerated (see “Nuclear Waste: Not a Problem” in our February 18 issue), such concerns should be weighed against other, larger environmental concerns. For instance, what could be a bigger “environmental concern” than for the United States to go through an oil drought that would destroy industries, jobs, families — indeed the entire economy of our nation? Do we want to be faced with having to use force to acquire producing oil fields around the world or see a depression and misery as we have never known as a country? My vote is “no” to that scenario and “yes” to the coal-to-liquid process. How say you?

* Alternate technologies such as the General Atomics GT-MHR reactors are also able to supply process heat in the 700- to 1,000°-C range, far above the 300° C temperatures current pressurized- or boiling-water power reactors can provide. High process heat temperatures are critical to the production of hydrogen for CTL technology. Heat from the process can be “scavenged” to produce steam for electrical generation.

† On February 29, 2008, the West Texas grid that has the largest percentage of wind turbine power in the United States suddenly dropped from 1,700 MW to 300 MW. Grid operators brought on available “spinning reserves” only to find they were insufficient to compensate for the sudden loss. Similarly, electrical feeds from other sources could not provide sufficient energy. To avoid “brownouts” or rolling blackouts, major electrical users were forced to discontinue operation.

With 27 percent of global reserves, the United States is far and away the leader in coal resources. Using current mining techniques, some 275 billion tons are considered to be recoverable out of a demonstrated reserve base of 491 billion tons. With an annual production rate of 1.2 billion tons, nearly 250 years of use is currently available. This, however, could be greatly extended by generating electric power with plentiful nuclear fuel instead of using 86 percent of coal production for that purpose.

Commercial coal mines operate in 26 states, with 1,331 mines east of the Mississippi and 93 west of the river. Most eastern mines are underground while western mines are almost entirely high-production surface mines allowing the West to “outstrip” the East by 672 million tons to 490 million tons per year.

I’ve heard of a WWII “wood-burning Mercedes” and I believe the German term for it is “Holzgas-Generator”. Saw a photo of a Volkswagen equipped with this device.

That's a completely different (and completely impractical, and completely uneconomic) technology. I remember (years ago) Mother Earth News publishing an article about a truck making a cross-country trip, fueled (IIRC) by carbon monoxide derived from burning wood. So what? You could probably get a truck from coast to coast, pushed by 'Sports Illustrated' readers, if you had enough pull. Would that provide any benefit whatsoever to an average (like me) American? No. Period. End of story (in the real world, that is, not the D@mocrat world). And that is exactly what most D@mocrat proposals amount to - all fluff, and absolutely no real substance...

thought Rommel was in Africa in order to seal off the British Empah via the Suez Canal.

Yes, but oil also played a major part in why the British were in North Africa in the first place.

Battlefield North Africa: Rommel's Rise And Fall

"The battle for North Africa was a struggle for control of the Suez Canal and access to oil from the Middle East and raw materials from Asia. Oil in particular had become a critical strategic commodity due to the increased mechanization of modern armies. Britain, which was the first major nation to field a completely mechanized army, was particularly dependent on the Middle Eastern oil. The Suez Canal also provided Britain with a valuable link to her overseas dominions -- part of a lifeline that ran through the Mediterranean Sea. Thus, the North African campaign and the naval campaign for the Mediterranean were extensions of each other in a very real sense."

If the environmentalists and liberals want us out of the Middle East and off oil dependency, then they shouldn't stand in the way when an alternative technology like this is developed, but which doesn't fit their 'pictures' exactly. I think coal-to-oil is fascinating and would work, at least in the short-term (50 years). We are not going to have solar or electric cars and the system to support them overnight. We have to live in reality and work with what we have now.

The American people need to grow a spine and just tell these troublemakers to shut up or come up with a workable, viable solution. So far, I haven't seen them doing anything but complain. They even have issues with solar power because of global warming. Give me a break.

One last tidbit: based on what I've read, CTL would fly at only ~$45.00 per barrel.

FACT: oil has been selling for more than $45 per can for quite some time.

FACT: we have more coal than we know what to do with.

FACT: the D@mocrats have been forcing you to pay extra for your gasoline, every single day of the week, ever since oil hit ~$50 per can (do you even remember when it was that cheap?).

Congratulations!

I literally LAUGH every time the price of gasoline goes up, because I know for a fact that cheap energy is still out there, it is still available today, and the folks who 'qualify' as American voters doen't want to hear it. (I don't make a penny off it, but I still laugh... ;>)

LMAO!!!

My Energy Manifesto:

* Cease all ethanol production. It takes away from food production and the unintended consequence is higher food costs. As diesel prices go up, the cost of farming tips the balance of cost to make ethanol a bad idea. Just say "no" to ethanol! Even Jimmy Carter says that diverting farm production from food to fuel is dumb – even HE gets it.

* Immediately create only ONE "blend" of gasoline and cease regional "boutique" blends which are stupid, costly, and meaningless. Even if this is the "cleanest" blend, just make it ONE and be done with it. Trucking custom blends around the country is wasteful.

* Lift the restrictions in order to drill for oil in Alaska, Gulf of Mexico, and other sites in the CONUS as a matter of national security.

* Encourage the petro industry to construct state-of-the-art refineries and/or retrofit current and dormant ones and crank up production for our newly-accessed oil in the CONUS.

* Make all “carbon credit” scams unlawful. Discrediting Algore should have been a slam-dunk a long time ago. Stop electing Reps who buy into the Global Warming / Global Cooling / Climate Change Hoax. CO2 is not our enemy!

* Construct SEVERAL, regional Pebble-Bed Modular Reactors (or other similar modern designs) that are not considered "breeders", are rechargeable, and cleaner than any current nuclear generator design. Breeders are OK, but PBMR's are better. DO SOMETHING NUCLEAR to resolve energy problems.

* Use the residual heat from the reactors above to process motor fuel from coal and/or shale. Even though Clinton "stole" some of the best coal reserves, we still have a lot to use.

* Become independent enough to make the cartels (i.e. OPEC) inconsequential.

* Convince local taxing bodies to lift or cap the sales tax on gasoline so that as gas prices go up, the local tax collectors don’t see a windfall revenue jump at the expense of the consumer. The Federal government could compel the states (and locals) to cap the fuel taxes.

If you squint real hard, and read between the lines, the ‘manifesto’ will require the dismissal of all RINOs and LibDems and the election of some clear-minded conservatives to even consider any of the above.

The efficiency figures in the article are a bit misleading. The energy from the nuclear reactor will not go into a Carnot Cycle engine, hence has a theoretical limit of full 100% conversion into chemical energy stored in the fuel (in practice there will be losses). However, the auto or truck engine using the resulting liquid fuel will have the same efficiency as current auto and truck engines, of the order of 30%. This isn't an argument against this process, just a caution that the numbers aren't as good as the article makes them look.

It has always struck me as inefficient to burn coal to power the conversion of coal to liquid fuel. You end up with far less than half the original coal energy in the liquid fuel itself. Even with energy from a nuclear reactor to drive the reaction, less than half the energy gets stored in the final product. However, using energy from a nuclear reactor, you don't produce any CO2 to get the energy to drive the reaction. That alone makes it worth trying.

We need to start building Pebble Bed Modular Reactors to produce heat and steam for making electricity, powering the coal for the Fischer-Tropsch process to produce fuel and the Bergius process for hydrogen as an future alternative and heat for desalination to take saltwater from the coasts of America and pump it inland as freshwater. That would make us truly independent from foreign oil and help solve the coming world wide water crisis.

However, I don't see this coming about in the few years I have left because the Liberal Democrats will never let it happen and I surely do not see it under the nObama regime.

The German process was real and worked, although it was expensive.

South Africa use a similar process called SASSOL to make liquid fuels during the UN embargo over apartheid.

While the chemistry is apolitical, the opponents of even maintaining our lifestyle point to the non-PC nature of the previous users of the process to discredit it.

While I usually dislike government intervention, one of the ideas I really like is a US Government price support of liquid fuels at an equivalent of $100/barrel of oil. Essentially a variable tax on lower production cost fuels. One of the big drawbacks to investment in alternative energy sources is that if the price of oil goes down, you lose all of your money. A government price support prevents that. Of course with the current oil price the tax would be zero.

Once we develop a liquid fuel technology other than oil, the economies of scale will eventually reduce the price significantly.

Wouldn’t it be wonderful for the US to lead the world in alternative fuel production? We could be selling to other nations and collecting obscene profits instead of a bunch of camel-jamming muslims.

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