I have been posting lately about nuclear fusion reactors. I have not covered them before in my blog because I did not feel that there were any fusion projects that could possibly be turned into commercial energy sources for decades. There is an old joke that nuclear fusion is forty years away, always. Nuclear fusion just seemed to absorb billions of dollars but like the end of the rainbow it just kept receding as you approached it.

        I am happy to say that there now appears to be three different approaches to nuclear fusion power that might result in a commercial model in less than ten years. All three of these new fusion reactor projects are being done by private groups. For reference, I have also blogged about the huge ITER project that is being build in France  by a consortium of governments. This experimental fusion reactor will cost billions of dollars and will not even be completed until 2027 at the soonest. Then there will have to be years of testing before any possible commercial reactor could be built. The three private fusion reactors under development will be about ten times as small, ten times as simple, ten times as cheap and generate more power than the ITER design. And, more importantly, one or more may hit the market before ITER is ever finished.

       The fuel for these fusions reactors will be very light elements like hydrogen, deuterium, tritium and boron. Hydrogen is easily made by decomposing water into oxygen and hydrogen. Deuterium can be separated from normal water or from hydrogen produced by electrolysis. Tritium can be produced when deuterium captures a neutron from nuclear fission. Tritium can also be produced in nuclear fission reactors by neutron bombardment of lithium-6, a stable isotope.

        Lithium is a very useful common element in the crust of the Earth and there are many sources. World production is about one one hundredth of the economically extractable reserves. So there is easily a hundred years supply at current levels of production. Lithium-6 is about eight percent of naturally occurring lithium.

        Boron is a fairly rare element but is concentrated in water soluble minerals. About eighty percent of boron is in the form of the stable isotope borton-11. Proven boron reserves are about two hundred and fifty times current production levels so we have several centuries of boron available at current levels of use. However, it is time consuming and expensive to separate out the boron-11.

         Deuterium and tritium reactions produce fast neutrons which causes concrete and metal to become brittle and can make other materials radioactive. While boron-11 may be expensive to produce, the amount consumed in a nuclear fusion reactor is very small compared to the consumption of boron for other industrial application. The main benefit of a hydrogen-boron reactor is that it does not produce fast neutrons. If a commercial nuclear fusion reactor is created, I would prefer that it not produce neutrons.

        The basic waste product of these nuclear fusion reactors is alpha particles or helium nuclei. As a matter of fact, the U.S. has been selling off critical helium reserves lately and we need to produce more helium. I do not have the numbers to show that substantial quantities of helium would be produced by fusion reactors but it is nice to have a harmless waste product that could have commercial value instead of the horrible waste generated by a nuclear fission reactor that has to be buried for centuries.

         The development of a commercially competitive nuclear fusion power reactor would be a game changer for the global energy industry. It could solve the base-load problem of renewables such as wind and solar much better than nuclear fission reactors and fossil fuels.

 

Fukushima workers are urgently trying to prevent groundwater from leaking into ocean. enenews.com

Swedish utility Vattenfall is suing Germany at the Washington-based International Centre for Settlement of Investment Disputes over the closure of the Brunsbüttel and Krümmel nuclear power plants. world-nuclear-news.org

Russia’s national operator for radioactive waste management (NO RAO) has highlighted the main problems it faces in siting disposal facilities. world-nuclear-news.org

US-based Lightbridge Corp has extended its nuclear cooperation with Vietnam by agreeing to offer consultancy services for setting up a nuclear research centre, including a research reactor, in the country. world-nuclear-news.org

        I have been blogging about alternate approaches to nuclear fusion power reactors. If the scientists are able to create a working fusion reactor that can generate more energy that it consumes, it could be revolutionary for the power industry. Fusion reactors are generally designed to consume ions like hydrogen, deuterium, tritium and/or boron for fuel. Some produce fast neutrons but some don’t. And none of them produce the kind of waste that is generated by a nuclear fission power reactor. Today I am going to talk about a fusion reactor project at the Skunk Works which is the experimental technology division of Lockheed Martin.

       The Lockheed Martin Compact Fusion Reactor (CFR) utilizes a different design than the donut-shaped tokomak design which has been the basis for many fusion reactor experiments. Tokomak designs are limited in the amount of plasma that they can contain. This limitation has resulted in very big tokomak designs to hold as much plasma as possible. The CFR has borrowed magnetic confinement design elements from a number of different fusion research projects, taking the best of each. It is estimated that a CFR should be able to be one tenth the size of a tokomak that generates the same amount of power. The design can scale so a CFR the size of the ITER project would generate ten times as much power.

       The basic shape of a CFR is a short tube with a bulge in the middle unlike the tokomak donut design and the Dynomak spherical design. Two neutral beam injectors send deuterium gas into the confinement chamber which is ringed by two donut-shaped superconducting magnets. Deuterium gas in the confinement chamber is heated by microwaves and fuses, releasing helium, neutrons and a lot of energy. The CFR has a feedback system which increases the confining magnetic field as the plasma move away from the center of the tube. The magnetic confinement is designed to have fewer open field lines than tokomak designs. A “blanket” surrounds the confinement chamber to absorb neutrons produced in the reaction and transfer heat to turbines to generate electricity.

       The head of the Skunk Works lab says that they should be able to build a working prototype reactor after five generations of test devices. They hope to have a prototype in about five years. Within five years after the prototype they should be able to produce a commercial one hundred megawatt model for the energy market. The entire unit would be about twenty three by forty two feet. It could be transported on a semi truck trailer, installed and be working in a few weeks. CFRs are small enough to be used for propulsion on ships, submarines and big commercial planes. A plane with one of these reactors would be able to stay aloft indefinitely. It would never need refueling and would generate no pollution.

Artist’s rendering of a Compact Fusion Reactor:

Fukushima workers urgently trying to prevent groundwater from leaking into ocean. enenews.com

Technology for the rapid diagnosis of Ebola will soon be delivered to Sierra Leone by the International Atomic Energy Agency. world-nuclear-news.org

Westinghouse has been criticized by the Swedish nuclear regulator for failing to carry out required medical examinations of some workers at its fuel fabrication plant in Västerås. world-nuclear-news.org

Consumers stand to receive refunds and credits totaling $1.3 billion due to the premature closure of the San Onofre nuclear power plant under a settlement proposed by the California Public Utilities Commission.  world-nuclear-news.org

        My last couple of posts have been about projects for developing nuclear fusion. Today I am going to discuss the work of Robert Bussard on nuclear fusion. Bussard developed his own innovative fusion reactor design that he called the Polywell. He formed a company called Energy/Matter Conversion Corporation in 1985 to work on the Polywell. He was able to build and test fifteen experimental devices between 1994 and 2006 with funding from the U.S. Navy. He sought more funding from the Navy to build a full scale nuclear fusion power reactor for about half a billion dollars. The Navy was not willing to fund this stage of the project so Bussard started looking for funding from other sources. He died in 2007.

        The Polywell fusion reactor is based on a cube of stainless steel donut-shaped magnets that is called a magrid. The magrid is fed a positive charge of fifty thousand volts. The coils inside the steel donuts produce a magnetic field of two Tesla. For comparison, the magnetic field of the Earth is less than one thousandth of a Tesla. Beams of hydrogen and boron atoms are shot through four of the holes in the stainless steel donuts. Beams of high energy electrons are shot  through the holes in the remaining two donuts. All the beam meet in the center of the cube. The cloud of electrons from the two electron beams creates a strong negative potential at the center of the cube. This spherical electric field forces the positively charged hydrogen and boron nuclei into the center of the cube. The hydrogen and boron ions collide and this results in a nuclear reaction that produces high energy alpha particles  (helium nuclei) which carry energy away from the center of the cube. There is a spherical metal shell around the Polywell which uses electrical repulsion to slow down the alpha particles. This results in electrons being pushed down power cables forming an electrical current that can be fed to the power grid. One of the benefits of the Polywell reactor is that it does not produce any dangerous radiation such as high energy neutrons that some other nuclear reactions generate.

       The optimum size for the Polywell reactor is about ten feet in diameter. If the Polywell is much smaller, it will not be able to put out enough power to even heat the plasma and generate more power than it consumes. If the Polywell reactor is much bigger than ten feet in diameter, it will explode because there is no known material that could withstand the stress of operation. One Polywell power reactor should be able to produce about one hundred megawatts. This would be enough power for a community of about twenty thousand people. The production cost for a commercial Polywell should be about three hundred and fifty million dollars.

       The U.S. Navy allocated one million eight hundred thousand dollars to the research in 2007 and eight million dollars in 2009 to continue research on the Polywell. The research has continued up to the present day and the company is working on obtaining sufficient funding from other sources to build a full scale Polywell power reactor.

Artist’s rendering of the Polywell:

Heavy rain hit the tsunami-crippled Fukushima Daiichi nuclear power plant on the northeastern Pacific coast, “but we have not received any reports of damage or abnormality”, said a spokesman with TEPCO. enenews.com

Canadian nuclear safety regulators have updated regulations for the country’s nuclear power plant operators to prepare for and manage emergency situations. world-nuclear-news.org

South Africa has signed a civil nuclear cooperation agreement with France, opening the door to the possible deployment of French nuclear technology as South Africa looks to expand its nuclear power program. world-nuclear-news.org

The American Nuclear Society has written to a Senate committee expressing its concerns that a new bill will politicize the way the national nuclear regulator oversees security of radiological materials. world-nuclear-news.org