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Chapter 4. Nuclear Energy. Objectives. Describe how nuclear fuel is produced. List the environmental concerns associated with nuclear power. Analyze the tradeoffs associated with the use of nuclear power, in comparison to generating power via other means. Introduction.
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Chapter 4 Nuclear Energy
Objectives • Describe how nuclear fuel is produced. • List the environmental concerns associated with nuclear power. • Analyze the tradeoffs associated with the use of nuclear power, in comparison to generating power via other means.
Introduction • Nuclear fission: involves splitting a large atom to produce two smaller atoms and a tremendous amount of energy. • Nuclear fission is used to produce heat for steam to make electricity. • Nuclear fusion: involves fusing two smaller atoms to produce one large atom and a tremendous amount of energy. • Nuclear fusion is not presently used to produce commercial power.
Uranium: The fuel for Nuclear Fission • Uranium is the most common type of nuclear fuel. It is mined much the same way as coal. • Uranium atoms are bombarded by neutrons. This causes the nuclei to split apart. This splitting is known as nuclear fission. • All of the reaction takes place inside a strong closed container called a reactor. A nuclear reactor is to a nuclear power plant what a furnace is to a home. It produces the heat used to generate power at the plant. • Nuclear power produces about 20% of the electricity in the United States. • Uranium is a very hazardous substance. When the atoms of uranium decay, they give off atomic particles . This reaction produces radioactivity, which is harmful to humans and other living things.
The Fission Process • Fission is the term associated with the splitting of atoms. • Uranium 235 fission yields a large amount of energy, small amounts of barium and krypton and two additional neutrons. • The two free electrons can be used to split other atoms. • This is how a chain reaction occurs.
The Terminology and Measurement of Radiation • Half life is the time it takes for half of the atoms present in an unstable element to transform into a new element. • After a period of one half life, the radioactivity of an element is decreased by 50%.
How a nuclear reactor works • The two types of reactors are boiling water reactors (BWRs) and pressurized water reactors (PWRs). • 1. Boiling Water Reactors (BWR): • It is the simplest of the reactor types. • The control rods sit between the fuel rods. • Control rods can be inserted and retracted out to control the fission process. They are made of neutron absorbing elements such as graphite, cadmium, and carbon. • The heat converts the surrounding water to steam. • The steam spins a turbine to produce electricity. • Cooling towers are used to reduce the temperature of the water that is returning to the river or lake so that it does not damage the ecosystem of the water source.
How a nuclear reactor works • 2. Pressurized Water Reactors (PWR): • It works the same way as the BWR except that it makes used of a heat exchanger known as a steam generator. • The water heated in the primary loop does not come in direct contact with the turbine. • Inside the steam generator, the heat from the primary loop is transferred to water in the secondary loop, thereby creating steam in the secondary loop. • The steam in the secondary loop is used to drive the turbine that spins the generator. • The steam generator in the PWR allows the turbine to be free of radioactive contamination. • This can be beneficial from a maintenance standpoint.
Supply and demand for nuclear power • Approximately 100 nuclear power plants supply about 20% of electricity in the United States. • As of 2004 there were 439 nuclear power reactors in operation around the world. • France produces about 78% of its power from nuclear power. • In certain countries the lack of natural resources and access to inexpensive labor makes nuclear power more appealing. • Nuclear power may also be desirable to countries that wish to reduce carbon dioxide emissions to reach targets set in the Kyoto Protocol. • More than 100 countries met in Kyoto, Japan and set targets to reduce carbon dioxide emissions. • The United States did not sign the Kyoto Protocol.
Nuclear Power and the Environment • Almost all high level waste is stored in on site pools at various power plants. • Utilities have charged their customers a 1 cent surcharge for each kilowatt hour (kWh) generated using nuclear power for development of a permanent waste disposal site. • Reprocessing concentrates plutonium in to a form that is capable of being used to produce nuclear weapons.
Storage of Nuclear Waste • Scientists have recommended that the nuclear waste be stored in stable rock formations deep within the earth’s surface. • The Yucca Mountain site in Nevada has been postponed indefinitely due to opposition. • Shipping casks have been designed to transport spent fuel from one facility to another.
Nuclear Reactor Safety • All commercial reactors constructed within the United States must contain an environmental shield that has been engineered to withstand plane crashes, extreme weather conditions, and the possibility of an explosion from within the reactor vessel. • In the case of the Three Mile Island (Harrisburg, PA)accident a small portion of the reactor core melted when the reactor coolant was accidently shut off.
Breeder Reactor • A breeder reactor is designed to create nuclear fuel from a substance that is not fissionable. • When uranium is mined nearly 99% is uranium 238. Only 1% is uranium 235. • A breeder reactor can create plutonium 239 (Pu-239) from U238. • The Pu-239 can then be used as fuel in other nuclear plants the way U235 is presently used. • The disadvantage is that Pu-239 is the material of which nuclear bombs are made.
Nuclear Fusion • A fusion reactor would be inherently safer than a fission reactor. • If a problem were to occur, simply closing the fuel feed would stop the fusion. • A practical fusion test reactor has not had much success as of yet.
Summary • Nuclear fission: involves splitting a large atom to produce two smaller atoms and a tremendous amount of energy. Nuclear fission is used to produce heat for steam to make electricity. • Nuclear power produces about 20% of the electricity in the United States. • After a period of one half life, the radioactivity of an element is decreased by 50%. • The steam generator in the pressurized water reactor (PWR) allows the turbine to be free of radioactive contamination. This can be beneficial from a maintenance standpoint. • France produces about 78% of its power from nuclear power. • Almost all high level waste is stored in on site pools at various power plants. Utilities have charged their customers a 1 cent surcharge for each kilowatt hour (kWh) generated using nuclear power for development of a permanent waste disposal site.
Home Work • 1. How much electricity comes from nuclear power in the United States? • 2. What is the significance of half life of a radioactive element? • 3. What is the advantage of the pressurized water reactor (PWR) over the boiling water reactor (BWR)?