Some facts about nuclear reactor for power generation:

Some facts about nuclear reactor for power generation:

A. Understanding running of nuclear reactor (fission) for power generation –

i. Nuclear power can come from the fission of uranium, plutonium or thorium or the fusion of hydrogen into helium. Today it is almost all uranium. The fission of an atom of uranium produces few million times the energy produced by the combustion of an atom of carbon from coal.

ii. Natural uranium is almost entirely a mixture of two isotopes, U-235 and U-238. Today’s commercial nuclear reactor uses U-235 for fission reaction. Natural uranium has 99.3 percent of U-238 and only 0.7 percent of U-235.

iii. Most nuclear power plants today use enriched uranium in which the concentration of U-235 is increased from 0.7 percent to (nowadays) about 4 to 5 percent.

iv. The U-238 "tails" are left over for eventual use in "breeder reactors". The Canadian CANDU reactors don't require enriched fuel, but since they use expensive heavy water instead of ordinary water, their energy cost is about the same.

v. Present reactors that use only the U-235 in natural uranium are very likely good for some hundreds of years.

vi. A power reactor contains a core with a large number of fuel rods. Each rod is full of pellets of uranium oxide. An atom of U-235 fissions when it absorbs a neutron. The fission produces two fission fragments and other particles that fly off at high velocity. When they stop the kinetic energy is converted to heat.

vii. The steam withdrawn and run through the turbines controls the power level of the reactor. The heat from the fuel rods is absorbed by water which is used to generate steam to drive the turbines that generate the electricity.

viii. After about two years, when enough U-235 is converted to fission products and the fission products have built up enough so that the fuel rods must be removed and replaced by new ones.

ix. Besides fission products, spent fuel rods contain some plutonium produced by the U-238 in the reactor absorbing a neutron. This plutonium and leftover uranium can be separated in a reprocessing plant and used as reactor fuel.

x. Thus running a reactor for four years produces enough plutonium (about 1/4 as much as the U-235 that was in the fuel rods) to run it for one more year provided the plutonium is extracted and put into new fuel rods. Newer designs with higher "burnup ratios" get more of their energy from plutonium.

B. Understanding nuclear waste –

i. After the fuel has been in the reactor for about 18 months, much of the uranium has already fissioned.

ii. A considerable quantity of fission products also have built up in the fuel.

iii. The reactor is then refueled by replacing about 1/3 of the fuel rods. This generally takes one or two months. Canadian CANDU reactors replace fuel continuously.

iv. When fuel rods are removed from the reactor they contain large quantities of highly radioactive fission products and are generating heat at a high rate.

v. They are then put in a large tank of water about the size of a swimming pool. There they become less radioactive as the more highly radioactive isotopes decay and also generate less and less heat.

vi. The fuel rods should then be chemically reprocessed. Reprocessing removes any leftover uranium and the plutonium that has been formed.

vii. The fission products are then put in a form for long term storage.

viii. A large reactor produces about 1.5 tonnes of fission products per year.

ix. Economic advantages of reprocessing are great. If we do not reprocess, we lose the economic benefit of the plutonium.

x. At the same time, the spent fuel remains radioactive for longer duration and has to be better guarded, because it contains plutonium.

C. Understanding of future nuclear reactor - ‘breeder reactor’ -

i. If the design of reactor is such that, enough U-238 can also be converted to plutonium so that after a fuel cycle there is more fissionable material than there was in the original fuel rods in the reactor. This system is more economical.

ii. Such a design is called a ‘breeder reactor’.

iii. Breeder reactors essentially use U-238 as fuel. Therefore, it is more advantageous and it is estimated that, there is 140 times more beneficial than the conventional reactor.

iv. They are more expensive than present reactors.

v. Breeder reactor will be reprocessing on site, so no plutonium will ever become externally available.

vi. It is much safer system than the present one. It is hoped that it wiould address the proliferation concerns of the anti-nukes.

Energy from Nuclear Fuel:

Energy from Nuclear Fuel:

Nuclear energy is the energy that directly releases after controlled Atomic reactions. Nuclear power is obtained from release of nuclear energy, a type of nuclear technology involving the controlled use of nuclear reactions. Out of two (fission and fusion) known technology, fission technology is used by nuclear power plant and fusion technology is under development stage.

A. In nuclear fission technology is splitting of the nucleus of an atom to produce two more or less equal fragments. In this process, a large amount of energy is produced; which is used for generation of electricity. This phenomenon of fission reaction is mostly done with nuclei of the element uranium; when bombarded by neutrons, to produce a great variety of products including large amount of heat energy.

B. Nuclear power plants generate electricity by using heat obtained from such fission reaction; usually use uranium-235 (U-235) as fuel. The nucleus of U-235 has 92 protons and 143 neutrons. When bombarded by extra neutrons on U-235, it loses atomic balance and becomes unstable to split into smaller pieces of fission products and releases more neutrons. This post splitting mass difference causes to release huge energy in the form of heat. The extra neutrons produced responsible for further chain reaction within the leftover mass of uranium. In nuclear power plant this generated heat is utilized to drive a turbine generator to produce electricity. As no physical burning of fuel is taken place, the nuclear power plants emit very low carbon dioxide (CO2) as compared to their counterpart of coal, oil or gas fired power plants. World has quite a large reserve of Uranium (more than gold); mostly located in Australia (35 per cent), Russia and CIS countries (29 per cent), Canada (13 per cent), Africa (8 per cent), and South America (8 per cent).

C. Nuclear power poses great environmental advantages:

• Emission of carbon dioxide and other greenhouse gases into atmosphere is very negligible; thereby not responsible for global warming;
• Quantum of energy obtained is very large from very less quantity of nuclear fuel (the complete fission of 1 kg of U-235 could produce 8 x 1013 joules of energy, almost one million times more than the amount of energy produced by burning 1 kg of coal);
• Neutron produced from fission reaction used for initiating self-sustaining series of reactions; i.e., chain reaction, results in a continuous release of nuclear energy.

D. Nuclear Fusion technology is to combine two light atomic nuclei to form one heavier nucleus. This process generates tremendous amount of energy - heat. As this technology generates enormous amount of energy, we are now struggling to control this quantum of energy obtained out of fusion reaction– thereby, not yet developed fully. Developed world is making every effort to make nuclear fusion technology workable. The energy released from atomic fusion can be unimaginably great - our celestial Sun and other stars shine through this fusion since their inception. If fusion energy does become practicable it would offer the advantages such as:

(1) an effectively limitless source of fuel;

(2) it would be of inherent safety , as the amount of radioactive material present would be much low;

(3) as waste products that are less radioactive and simpler it would be easer to handle them than those from fission .

COAL AND OTHER FORM OF FUEL

COAL AND OTHER FORM OF FUEL:

We all know, energy is important in almost every aspect of modern life - societies need increasing amounts of energy as they grow and develop. Mostly energy we know are in the form of Electricity, Heat, Light, Sound, nuclear etc. Fuel is a material that is burnt or chemically altered to obtain energy. Fuel releases energy either through chemical means in the way of combustion or of nuclear means in the way of nuclear fission or fusion. The essence of any fuel is that energy is stored; and when needed it is released either by combustion or by nuclear reactions.

Coal is one of the most important fuels available as energy source – not only does coal provides electricity, but it is an essential ingredient for steel, cement and other industrial activities. Coal is one of fossil fuel (hydrocarbons) available on the earth crust. Another important fossil fuel (hydrocarbons) is Petroleum (liquid or natural gas form).

Nuclear fuel is kind of material from which we obtain Nuclear energy, by way of nuclear fission chain reaction or by nuclear fusion (a kind of energy produced by any celestial stars).

Therefore, fuel is most important element in our every day life, for growth, for sustaining civilization; as it help us generate energy.