A Seminar Report ON
“NUCLEAR POWER PLANT” Submitted in the partial fulfillment of the requirement for the award of the Degree Of Bachelor of Technology By Aakash Yadav (13E1AEMEM3XP001) (VIIIth Sem)
DEPARTMENT OF MECHANICAL ENGINEERING ALWAR INSTITUTE OF ENGINEERING AND TECHNOLOGY
MIA, ALWAR - 301030 (RAJ), INDIA Session: 2016-17
I
CANDIDATE’S DECLARATION
I, Aakash Yadav, hereby declare that the seminar report on “NUCLEAR POWER PLANT” is being present in partial fulfillment of the requirement for the award of the degree of Bachelor of Technology in the Department of Mechanical Engineering in the Alwar Institute of Engineering & Technology Alwar, is an authentic record of my work carried out during 8th semester. The matter that embodied in this report has not been submitted by us for the award or any other degree or diploma. Date: Sing. (Aakash Yadav) (13E1AEMEM3XP001)
II
CONTENTS
Serial no
Topic
Page no
1.
Candidate declaration
II
2.
List of Figures
IV
3.
Abstract
1
4.
Introduction
2
5.
Literature Review
3
6.
Technical Advancement
4-16
7.
Conclusion
17
8.
References
18
III LIST OF FIGURES Fig no
Figures
Page no
1.
An image of the Kudankulam nuclear power plant at Tirunelveli, Tamil Nadu
02
2.
The image is a view of the Tarapur Nuclear Power Plant
04
3.
A schematic representation of the equation of a nuclear fusion reaction. A schematic representation of the Equation of a nuclear fission reaction.
05
5.
The above figure shows the various components and the schematic layout of a nuclear power plant
08
6.
An image of Pressurized Water reactor
09
7.
An image of Boiling Water Reactor
10
8.
An image of Nuclear Reactor Core
12
4.
06
IV
ABSTRACT A nuclear power plant is a thermal power station in which the heat source is a nuclear reactor. As is typical in all conventional thermal power stations the heat is used to generate steam which drives a steam turbine connected to a electric generator which produces electricity. Nuclear power plants are usually considered to be base load stations, since fuel is a small part of the cost of production. Nuclear power plants are not located according to specific attributes of geography, and are therefore found all over the world. Although as a coin has two sides, nuclear power plants also have many merits and demerits. The present status of nuclear energy and future is also discussed further.
INTRODUCTION Conventional thermal power stations use oil or coal as the source as the source of energy. The reserves of these fuels are becoming depleted in many countries and thus there is a tendency to seek alternative sources of energy. In a nuclear power station instead of a furnace there is a nuclear reactor, in which heat is generated by splitting atoms of radioactive material under suitable conditions. The conversion to electrical energy takes place indirectly, as in conventional thermal power plants. The heat is produced by fission in a nuclear reactor. Directly or indirectly, water vapor (steam) is produced. The pressurized steam is then usually fed to a multi-stage steam turbine. For economical use in a power system a nuclear power station generally has to be large and where large units are justifiable.
Fig 1. An image of the Kudankulam nuclear power plant at Tirunelveli, Tamil Nadu
As of 23 April 2014, the International Atomic Energy Agency reports that there are 435 nuclear power reactors in operation operating in 31 countries.
LITERATURE REVIEW
1. An introduction to Nuclear Power Generation by Christopher E. Bremen, California institute of technology Pasadena, California.
The book is an introduction to a graduate level (or advanced undergraduate level) course in a nuclear power generation. It assumes a basic knowledge of physics, fluid mechanics and heat transfer. Of course, the design of a nuclear power plant involves a broad range of engineering expertise. The monograph focuses on the thermo hydraulics and neutronics of nuclear power generation and, in particular, on the interplay between these that determines the design of the reactor core. The book also has some brief description of other critical issues such as nuclear reactor safety. This necessarily includes brief descriptions of the three major accidents (Three Mile Island, Chernobyl and Fukushima) that have influenced the development of nuclear power.
History of Nuclear Energy and Power Generation The neutron was discovered in 1932. The concept of a nuclear chain reaction brought about by nuclear reactions mediated by neutrons was first realized shortly thereafter, by Hungarian scientist Leo Szilard, in 1933. Inspiration for a new type of reactor using uranium came from the discovery by Lise Meitner, Fritz Strassmann and Otto Hahn in 1938 that bombardment of uranium with neutrons (provided by an alpha-onberyllium fusion reaction, a “neutron howitzer”) produced a barium residue, which they reasoned was created by the fissioning of the uranium nuclei. On June27, 1954, the USSR’s Obninsk Nuclear Power Plant became the world’s first nuclear power plant to generate electricity for a power grid, and produced around 5
megawatts of electric power. The first commercial nuclear power stations, Calder Hall in Sellafield, England was opened in 1956 with an initial capacity of 50 MW (later 200 MW). India’s first research nuclear reactor and its first nuclear power plant were built with assistance from Canada. The 40 MW research reactor agreement was signed in 1956, and CIRUS achieved first criticality in 1960. This reactor was supplied to India on the assurance that it would not be used for military purposes, but without effective safeguards against such use. The technical and design information were given free of charge by Atomic Energy of Canada Limited to India. The United States and Canada terminated their assistance after the detonation of India’s first nuclear explosion in 1974. Tarapur Atomic Power Station located in Tarapur, Maharashtra is the first nuclear power reactor of India. It was established in October 28, 1969. It has a total capacity of 1,400MW.
Fig 2. The image is a view of the Tarapur Nuclear Power Plant
Nuclear Reactions In nuclear physics and nuclear chemistry, a nuclear reaction is semantically considered to be the process in which two nuclei, or else a nucleus of an atom and a subatomic particle (such as a proton, neutron, or high energy electron) from outside the atom, collide to produce one or more nuclides that are different from the nuclide(s) that began the process. Thus, a nuclear reaction must cause a transformation of at least one nuclide to another. If a nucleus interacts with another nucleus or particle and they then separate without changing the nature of any nuclide, the process is simply referred to as a type of nuclear scattering, rather than a nuclear reaction. There are two types of nuclear reaction
Nuclear Fusion
Fig 3. A schematic representation of the equation of a nuclear
Nuclear Fission
fusion reaction.
Nuclear Fusion In nuclear physics, nuclear fusion is a nuclear reaction in which two or more atomic nuclei collide at a very high speed and join to form a new type of atomic nucleus. During this process, matter is not conserved because some of the matter of the fusing nuclei is converted to photons (energy). Fusion is the process that powers active or “main sequence” stars. Fusion power is the energy generated by nuclear fusion processes. The origin of the energy released in fusion of light elements is due to interplay of two opposing forces, the nuclear force which combines together protons and neutrons, and the Coulomb force which causes protons to repel each other but they nonetheless stick together, demonstrating the existence of another force referred to as nuclear attraction. This force, called the nuclear force, overcomes electric repulsion in a very close range. Most nuclear fusion reactions involve the fusion of two hydrogen isotopes (Deuterium and Tritium) to form a helium atom releasing huge amounts of energy and a neutron. Nuclear fusion is currently in its experimental phases and is not being utilized for commercial purposes due to its requirements of high initial energy and pressure so as to overcome the Coulombic forces and bring the nuclei in close proximity.
NUCLEAR FISSION In nuclear physics and nuclear chemistry, nuclear fission is either a nuclear reaction or radioactive decay process in which the nucleus of an atom splits into smaller parts (lighter nuclei). The fission process often produces free neutrons and photons (in the form of gamma rays), and release a very large amount of energy even by the energetic standards of radioactive decay. Fission as encountered in the modern world is usually a deliberately produced man-made nuclear reaction induced by a neutron. In a induced fission reaction, a neutron is absorbed by uranium-235 nucleus turning it briefly into an excited uranium-236 nucleus, with the excitation energy provided by the kinetic energy of the neutron plus the forces that bind the neutron. Fig 4. A schematic representation of the
equation of a nuclear fission reaction.
The uranium-236 in turns splits into fast moving lighter elements (fission products) and releases three free neutrons at the same time, one or more “prompt gamma rays” are produced as well.
Comparison between Nuclear Fusion and Nuclear Fission
Nuclear Fission
Nuclear Fusion
Definition
Fission is the splitting of a large atom into two or more smaller ones.
Fusion is the fusing of two or more lighter atoms into a larger one.
Natural occurrence of the process
Fission reaction does not normally occur in nature.
Fusion occurs in stars, such as the sun.
Byproducts of the reaction
Fission produces many highly radioactive particles.
Few radioactive particles are produced by fusion reaction, but if a fission "trigger" is used, radioactive particles will result from that.
Conditions
Critical mass of the substance and highspeed neutrons are required.
High density, high temperature environment is required.
Energy Requirement
Takes little energy to split two atoms in a fission reaction.
Extremely high energy is required to bring two or more protons close enough that nuclear forces overcome their electrostatic repulsion.
Energy Released
The energy released by fission is a million times greater than that released in chemical reactions, but lower than the energy released by nuclear fusion.
The energy released by fusion is three to four times greater than the energy released by fission.
Nuclear weapon
One class of nuclear weapon is a fission One class of nuclear weapon is the bomb, also known as an atomic bomb hydrogen bomb, which uses a fission reaction to "trigger" a fusion or atom bomb. reaction.
Energy production
Fission is used in nuclear power plants.
Fusion is an experimental technology for producing power.
Fuel
Uranium is the primary fuel used in power plants.
Hydrogen isotopes (Deuterium and Tritium) are the primary fuel used in experimental fusion power plants.
Components of a Nuclear Power Plant
Fig 5. The above figure shows the various components and the schematic layout of a nuclear power plant
The Various Components of a Nuclear Power Plant are:
NUCLEAR REACTOR: A nuclear reactor is a device to initiate and control a sustained nuclear chain reaction. In its central part, the reactor core’s heat is generated by controlled nuclear fission. With this heat, a coolant is heated as it is pumped through the reactor and thereby removes the energy from the reactor. Heat from nuclear fission is used to raise steam, which runs through turbines, which in turn powers either ship’s propellers or electrical generators.
COOLING SYSTEM: A cooling system removes heat from the reactor core and transport it to another area of the plant, where the thermal energy can be harnessed to produce electricity or to do other useful work. Typically the hot coolant is used as a heat source for a boiler, and the pressurized steam from that one or more steam turbine driven electrical generators. Almost all currently operating nuclear power plants are light water reactors using ordinary water under high pressure as coolant and neutron moderator. A neutron moderator slows down the speed of the neutron as a medium, thereby turning them into thermal neutrons capable of sustaining a nuclear chain reaction involving uranium-235. Heavy water reactors
use deuterium oxide which has similar properties to ordinary water but much lower neutron capture, allowing more through moderation.
STEAM GENERATOR/BOILER: The heat from the reactor is used to convert water to steam, this steam is used to run a turbine to produce electricity. The position of the boiler depends on the type of reactor. The two most widely used reactors are
PRESSURIZED WATER REACTOR (PWR): These constitute the majority of the reactors, the above diagram shows a PWR. The primary characteristics of PWR is a pressurizer that is a specialized pressure vessel that stores the coolant in it and is sent into the reactor as per the requirement. In a PWR the boiler is situated in a different assembly, away from the reactor. Two fluid system are used in a PWR, one coolant cycle circulated in the reactor and pumped into the steam generator. This hot fluid from the reactor is used to heat the water to generate steam to be sent to the steam turbine. The water used in the turbine is not radioactive.
Fig 6. An image of Pressurized Water reactor
BOILING WATER REACTOR (BWR): BWRs are characterized by boiling water around the fuel rods in the lower portion of a primary reactor pressure vessel. A boiling water reactor uses 235U, enriched as uranium dioxide, as its fuel. The fuel is assembled into rods housed in a steel vessel that is submerged in water. The nuclear fission causes the water to boil, generating steam. This steam flows through pipes into turbines. The turbines are driven by the steam and this process generates electricity. The main characteristics is that the boiler here is the reactor itself and the coolant itself is used to drive the turbines. The fluid used in the turbine is radioactive.
Fig 7. An image of Boiling Water Reactor
SAFETY VALVES: in the event of an emergency, safety valves can be used to prevent pipes from bursting or the reactor from exploding. The valves are designed so that they can derive all of the supplied flow rates with little increase in pressure. In the case of the BWR, the steam is directed into the suppression chamber and condenses there. The chamber on a heat exchanger are connected to the intermediate cooling circuit.
FEEDWATER PUMP: The water level in the steam generator and nuclear reactor is controlled using the feedwater system. The feedwater pump has the task of taking the water from the condensate system, increasing the pressure and forcing it into either the steam generators (in the case of pressurized water reactor) or directly into the reactor( for boiling water reactor).
STEAM TURBINE: The steam generated from the boiler is used to drive the turbine. This turbine is connected to an electric generator so as to generate electricity. Care is taken in maintaining the condition of the turbine as it handles steam of very high heat capacity. The turbines used in BWRs have to be radioactive sealed so as to avoid leakage of the radioactive water.
ELECTRIC GENERATOR: The generator converts kinetic energy supplied by the turbine into electrical energy. Low-pole AC synchronous generators of high rated power are used.
COOLING TOWERS: A cooling tower is a heat rejection device which extracts waste heat to the atmosphere through the cooling of a water steam to a lower temperature. Cooling towers may either use the evaporation of water to remove process heat and cool the working fluid to near the wet-bulb air temperature or, in the case of closed circuit dry cooling towers, rely solely on air to cool the working fluid to near the dry-bulb air temperature.
EMERGENCY POWER SUPPLY: Most nuclear plants require two distinct sources of offsite power feeding station service transformers that are sufficiently separated in the plant’s switchyard and can receive power from multiple transmission lines. Nuclear power plants are equipped with emergency power systems to maintain safety in the event of unit shutdown and loss of offsite power. Batteries provide uninterruptible power to instrumentation, control systems, and valves. The emergency diesel generators do not power all plant systems, only those required to shut the reactor down safely, remove decay heat from the reactor, provide emergency core cooling, and, in some plants, spent fuel pool cooling.
PARTS OF NUCLEAR REACTOR
Fig 8. An image of Nuclear Reactor Core
Nuclear Fuel: Fuel of a reactor should be fissionable material which can be defined as a fissionable material which can be defined as an element or isotope whose nuclei can be caused to undergo nuclear fission nuclear bombardment and to produce a fission chain reaction. The fuels used are: U238, U235, U234, and U02. Fertile materials, those which can be transformed into fissile materials, cannot sustain chain reactions. When a fertile material is hit by neutrons and absorbs some of them, it is converted to fissile material. U238 and Th232 are examples of fertile materials used for reactor purpose.
Reactor Core: This contains a number of fuel rods made of fissile material.
Moderator: This material in the reactor core is used to moderate or to reduce the neutron speeds to a value that increases the probability of fission occurring.
Control Rods: The energy inside the reactor is controlled by the control rod. These are in cylindrical or sheet form made of boron or cadmium. These rods can be moved in and out of the holes in the reactor core assembly.
Reflector: This completely surrounds the reactor core within the thermal shielding arrangement and helps to bounce escaping neutrons back into the core. This conserves the nuclear fuel.
Reactor Vessel: It is a strong walled container housing the core of the power reactor. It contains moderate, reflector, thermal shielding and control rods.
Biological Shielding: Shielding helps in giving protection from the deadly α- and β- particles radiation and γ-rays as well as neutrons given off by the process of fission within the reactor.
Coolant: This removes heat from the core produced by nuclear reaction. The types of coolant used are carbon dioxide, air, hydrogen, helium, sodium or sodium potassium.
NUCLEAR POWER IN INDIA Nuclear power is the fourth largest source of electricity in India after thermal, hydroelectric and renewable source of electricity. As of 2013, India has 21 nuclear reactors in operation in 7 nuclear power plants, having an installed capacity of 5780MW and producing a total of 30,292.91 GWh of electricity while seven other reactors are under construction and are expected to generate an additional 6,100 MW.
Power Station
Operato r
State
Type
Units
Total Capacity (MW) 880
Kaiga
NPCIL
Karnataka
PHWR
220 ×4
Kakrapar
NPCIL
Gujarat
PHWR
220 ×2
440
Madras
NPCIL
Tamil Nadu
PHWR
220 ×2
440
Narora
NPCIL
Uttar Pradesh
PHWR
220 ×2
440
Rajasthan
NPCIL
Kota Rajasthan
PHWR
100 ×1
1180
200 ×1
220 ×4 Tarapur
Kudankula m
NPCIL
NPCIL
Maharashtra
Tamil Nadu
BWR PHWR
160 ×2
WER-1000
1000× 1
1140
540 ×2 1000
Advantages of Nuclear Power Plant
Space requirement of a nuclear power plant is less as compared to other conventional power plants of equal size.
A nuclear power plant consumes very small quantity of fuel. Thus fuel transportation cost is less and large fuel storage facility is not needed. There is increased reliability of operation.
Nuclear power plants are not affected by adverse weather conditions.
Nuclear power plants are well suited to meet large power demands. They give better performance at higher load factors (80-90%).
Materials expenditure on metal structures, piping, storage mechanisms are much lower for a nuclear power plant than a coal burning power plant.
It does not require large quantity of water.
The generation of electricity through nuclear energy reduces the amount of energy generated from fossil fuels (coal and oil). Less use of fossil fuels means lowering greenhouse gas emissions (CO 2 and others).
Currently, fossil fuels are consumed faster than they are produced, so in the next future these resources may be reduced or the price may increase becoming inaccessible for most of the population.
The production of electric energy is continuous. A nuclear power plant is generating electricity for almost 90% of annual time. It reduces the price volatility of other fuels such as petrol. Disadvantage of Nuclear Power Plant Initial cost of nuclear power plant is higher as compared to hydro or steam power plant.
Nuclear power plants are not well suited for varying and conditions. Radioactive waste if not disposed carefully may have bad effect on the health of workers and other population.
Maintenance cost of the plant is high. It requires highly trained personnel to handle nuclear power plants.
Nuclear power plants generate external dependence. Not many countries have uranium mines and not all the countries have nuclear technology, so they have to hire both things overseas. Nuclear power plants are objectives of terrorist organization.
Decommissioning of nuclear power stations is expensive and takes a long time. Nuclear accidents can spread ‘radiation producing particles’ over a wide area, this radiation harms the cells of the body which can make humans sick or even cause death. Illness can appear or strike people years after they were exposed to nuclear radiation and genetic problems can occur too. A possible type of reactor disaster is known as a meltdown. In meltdown, the fission reaction of an atom goes out of control, which leads to a nuclear explosion releasing great amounts of radioactive
particles into the environment. Chernobyl and Fukushima are the worst nuclear accidents to date causing many lives and leakage of radiation.
CONCLUSION
Widely used nuclear energy can be of great benefit for mankind. It can bridge the gap caused by inadequate coal and oil supply. It should be used to as much extent as possible to solve power problem. With further developments, it is likely that the cost of nuclear power stations will be lowered and that they will soon be competitive. With the depletion of fuel reserves and the question of transporting fuel over long distances, nuclear power stations are taking an important place in the development of the power potentials of the nations of the world today in the context of the changing pattern of power.
REFERENCES
An introduction to Nuclear Power Generation by Christopher E. Bremen, California institute of technology Pasadena, California. Safety of the Indian Pressurized Water Reactors, Department of Atomic Energy, government of India. http://nuclear-energy.net/advanytages-and-disadvantages-of-nuclear-energy.html http://en.wikipedia.org/wiki/nuclear_reaction http://en.wikipedia.org/wiki/nuclear_fission http://en.wikipedia.org/wiki/nuclear_power_in_india http://en.wikipedia.org/wiki/nuclear_reactor http://en.wikipedia.org/wiki/nuclear_fusion http://en.wikipedia.org/wiki/nuclear_power http://en.wikipedia.org/wiki/nuclear_power_plant
http://www.cyberphysics.co.uk/topics/nuclear/advantages_disadvantages_nuclear_power.html