SlideShare a Scribd company logo

Overview Of Reactors

Download as DOC, PDF
Prashant Jain
Prashant Jain
TechnologyBusiness
1 of 5
Overview of Reactors In a commercial power plant, the conversion of energy is usually from thermal energy to mechanical energy to electrical energy. More specifically, the steam from heating water (thermal energy) is used to turn the blades of a steam-turbine engine (mechanical energy) which in turn, generates electricity. The source of heat energy has traditionally been the combustion of fossil fuels. In a nuclear power plant, the source of heat energy is the fission reactions of heavy nuclei in a nuclear reactor. Uranium-235 is the most common form of heavy nuclei used. The energy produced by the fission of 1 kilogram of uranium is comparable to that produced by the combustion of 10 tons of oil(1). Uranium-235 is the less abundant of the two naturally occurring uranium isotopes (uranium-238 is the other isotope). Since only uranium- 235 is fissionable, natural uranium is sometimes enriched ( that is the percentage of uranium-235 is increased) before it used as fuel in a nuclear reactor. HOW NUCLEAR REACTORS WORK Source: Environmental Sci nce, Lancaster University webpage, e http://www.es.lancs.ac.uk/casestud/jp/image4.gif  Fuel (that is, fissionable nuclei such as uranium-235 or plutonium-239), is contained in fuel rods in the reactor core. It is usually in the form of pellets. The fissionable nuclei are bombarded with neutrons. If fission results, the nuclei split into lighter nuclei (the fission products). Energy and neutrons are also released in the process. These neutrons can then be directed to bombard even more fissionable nuclei in the fuel. A chain reaction develops and energy production continues.  A gas or liquid functions as the coolant. The coolant prevents the overheating of the system. It flows around the reactor core and absorbs the heat energy produced by the fission reactions. This heat energy is then transferred to the heat exchanger for steam generation. The steam is used to drive turbines in electricity generation. It is then condensed, pumped back to the heat exchanger and the entire cycle begins again. The higher the temperature the coolant can be heated to, the more heat energy that will be transferred to the heat exchanger, the more steam that will be generated and thus the more power that will be produced. Ideally, a coolant will not undergo a phase change in the reactor due to an increase in temperature. Phase changes require energy and will reduce the thermal efficiency of the reactor. Good coolants are also inert.  The neutrons that are produced as fission products are very energetic and so move very quickly. To increase the likelihood that a fission chain reaction is set up, these neutrons can be slowed down by a substance called the moderator. The moderator ensures that the neutrons are moving slow enough to be able to collide with the nuclei. Common moderators are light water (H2O), heavy water (D2O) and graphite. A good moderator is one whose atoms are similar in mass to neutrons so that when collisions occur between the two, energy will be efficiently transferred from the neutrons to the moderator material. Gases are not good moderators because they are too low in density and would not allow for regular collisions with the neutrons. A good moderator is also a poor neutron absorber - we want a moderator that slows down neutrons not absorbs them. Light water is not the best moderator because it tends to absorb neutrons. The less enriched the fuel, the less fissionable material it contains, the more efficient the moderator must be to ensure that the neutrons are slowed down and directed to bombard the limited fissionable nuclei.  Reactors with moderators are c alled Thermal Reactors. There are reactors without moderators. These are termed Fast Neutron Reactors because the neutrons’ speed is not controlled. Unlike Thermal Reactors, highly enriched fuel must be used to increase the probability that the neutrons are captured by the fissionable nuclei.  To ensure that the fission reaction does not explode out of control, control rods can be periodically inserted into the reactor core. These rods contain materials (such as cadmium, hafnium and boron) that absorb neutrons and thus limit the fission reaction rate.
 The reactor core is shielded to prevent the release of harmful radioactive material to the environment. REACTOR TYPES Nuclear reactors are characterized by their type of coolant and moderator and by their design in general. Table 1 gives an account of some of the more common nuclear reactor types. All of the listed reactors are thermal reactors. Table 1: Types of Nuclear Reactors Source: What is a Nuclear Reactor? European Nuclear Society webpage, http://www.euronuclear.org/info/energy- ses.htm u LIGHT WATER REACTOR (LWR) Currently, the LWR is the main reactor type employed in the U.S. In LWRs, light water (H2O) is used as both the coolant and the moderator. There are two main types of LWRs; pressurized water reactors (PWRs) and boiling water reactors (BWRs) PWR Energy from the fission reactions can cause the temperatures in the reactor core to reach 300 degrees Celcius (2). This is way above the temperature that would cause the light water coolant to boil if the pressure were that of the atmosphere (101kPa). To prevent the water from boiling and thus vaporizing, the coolant is forced to flow around the reactor core at an exceedingly high pressure of approximately 15 to 16 MPa (See Primary water in Figure 3) (3). A disadvantage of the PWR is that it must shut down regularly for routine check ups - under such high pressure, it is wise to regularly check that there is no wear and tear on the system’s components.
The coolant also functions as the moderator. If the moderator were to vaporize, the fission reactions would be less efficient. The gas would be too low in density to have effective collisions with the neutron fission products to cause them to slow down. The coolant then transfers the heat to the Secondary water. The Secondary water can boil and generate steam because this part of the system is held under less pressure (6MPa). The steam is used to turn the blades of the turbine and generate electricity. It is then condensed and the resulting water is pumped back to steam generator to begin the process all over again. Figure 3: Nuclear power plant with pressurized water reactor Source: What is a Nuclear Reactor? European Nuclear Society webpage, http://www.euronuclear.org/info/energy- ses.htm u BWR In these reactors, the reactor cores are held under a pressure of approximately 7MPa (4) - a much lower pressure than that of the PWR. This pressure is close enough to atmospheric pressure to allow the light water coolant/moderator to begin to boil. Unlike the PWR, because the steam is generated directly in the reactor core of the BWR, the core is bigger and more expensive.The steam produced (at the top part of the reactor core) is delivered directly to the turbine to aid in electricity generation (See Figure 4). The BWR system is much simpler than that of the PWR because no heat exchangers/steam generators are needed. In the reactor core, the steam is separated from the water below by steam separator plates. The neutron efficiency of BWR is less than that of the PWR because 12-15% of the moderator is vaporized (5). The coolant/moderator is in contact with the turbine. Since the coolant/moderator is radioactive (due to its contact with the fuel rods), the turbine is contaminated and must also be shielded. In a PWR however, the turbine is only in contact with the Secondary water which does not contain s ignificant amounts of radioactive material. The turbine in the PWR plant does not need to be shi lded. e PRESSURIZED HEAVY WATER REACTOR (PHWR) The PHWR design is also called the CANDU design because it originated in Canada in the 1950s. It is very similar to the PWR with respect to the pressure system. However, the main difference is that unlike the LWRs, these reactors use natural uranium as the fuel. There is thus, not a lot of fissionable uranium-
235 in the fuel. A moderator that will control the speed of the neutron fission products but will not absorb the neutrons is needed. As many neutrons as possible are needed to bombard the limited uranium-235 in order to continue the fission chain reaction. Light water, though it slows down neutrons efficiently, has a tendency to also absorb the neutrons. These reactors therefore use heavy water (deuterium oxide, D2O) as the moderator. Deuterium oxide is less likely to absorb neutrons because deuterium already has twice the amount of neutrons as the hydrogen in light water. However, a large quantity of heavy water is needed to have an influence on the neutron speed. Another disadvantage of heavy water is that if it absorbs neutrons it produces the radioactive isotope of hydrogen called tritium. Though heavy water is expensive, costs are cut down since natural uranium rather than processed enriched uranium can be used as the fuel. Furthermore, the PHWR can be refueled while in operation. GAS-COOLED REACTORS (GCR) GCRs are of European origin. The coolant is carbon dioxide and the moderator isgraphite. Carbon dioxide is an effective coolant because it can be heated to high temperatures and can thus maxim heat ize transfer to the steam generation process. Also, because it is gaseous, carbon dioxide will not absorb the neutrons that are involved in the fission chain reaction. However, as explained in the PWR section, gases are poor moderators. Graphite is used as the moderator because it is inexpensive, readily available and not damaged by high temperatures (6). The thermal efficiency of these reactors is very high but the fuel efficiency is low. Figure 6: Nuclear Power Plant with Gas Cooled Reactor Source: Joseph’s Gonyeau’s The Virtual Nuclear Tourist! webpage, http://www.nucleartourist.com/ LIGHT WATER GRAPHITE REACTORS(LWGR) The LWGR is a Soviet invention. It was uniquely designed to generate power and produce plutonium. The coolant is light water and the moderator is graphite. This coolant/moderator combination is unique to the LWGR. THe light water vaporizes as it passes through the reactor core. This steam is used to drive the turbines. One major advantage of the LWGR is that it can be refueled while in operation. NUCLEAR FUSION
In Nuclear Fusion the nuclei of atoms fuse together, causing much more energy being released than in Nuclear Fission. This is the process which powers the Sun.Here the Deuterium and Tritium atoms (these are the isotopes of Hydrogen:- these haveextra neutrons in the nucleus than normal) fuse together to form He. Energy is released due to a difference in mass between He atoms compared with the sum of the Hydrogen atoms therefore it is conclusive evidence that some mass is converted into energy via Einstein’s relationship of E=mc2; where E=Energy, m=mass of nuclei, and c=speed of light (3x108). This is why the energy (E) released is greater in fusion than in fission because of a very large mass deficit (m). PROS AND CONS OF NUCLEAR FUSION PROS CONS There is a lot more energy released during Fusion will only occur at temperatures of 10- fusion than fission so would be more 15 million Kelvin (K), hence there is no point profitable once set up. of producing energy since it is not profitable. Even if fusion did take place, it would be far Hardly any waste produced comparedto ahead of it’s time since no material exists Nuclear Fusion, so no money wasted in which can cope with temperatures of 10-15 disposing Nuclear waste. million K. Fusion could power the entire world at a very At the moment the only profitable way for low cost compared with power sources today. fusion to occur is using cold fusion*, but this Fusion would not be depleted like non- has not yet been discovered. (*cold fusion is renewable sources today si ce it would be n fusion at low enough temperatures to make possible to make hydrogen nuclei manually profits because this would mean that the as it is a very simple element (requires only 1 output energy would be greater than input proton and 1 neutron). energy ). CONCLUSION: For the moment the only way to produce energy using nuclear power is via nuclear fission. This is because Physicists are still trying to discover ways in which to produce energy using cold fusion. If discovered all our energy crisis would be solved.

Recommended

Nuclear fission & fusion ppt animation
Nuclear fission & fusion ppt animationNuclear fission & fusion ppt animation
Nuclear fission & fusion ppt animation
BalkrushnaBhuva
 
Ppt fusion and_fission_wk4
Ppt fusion and_fission_wk4Ppt fusion and_fission_wk4
Ppt fusion and_fission_wk4
ronniesidhu
 
nuclear fission and fusion
nuclear fission and fusionnuclear fission and fusion
nuclear fission and fusion
Yash Lad
 
Nuclear Fission Reactor
Nuclear Fission ReactorNuclear Fission Reactor
Nuclear Fission Reactor
muhammad shoaib
 
Nuclear fission and fusion By Pratimesh pathak
Nuclear fission and fusion By Pratimesh pathakNuclear fission and fusion By Pratimesh pathak
Nuclear fission and fusion By Pratimesh pathak
Pratimesh Pathak
 
Fusion
FusionFusion
Fusion
Anush Shenoy
 
Nuclear fission
Nuclear fissionNuclear fission
Nuclear fission
vicky vicky
 
Fission
FissionFission
Fission
sanjokk
 

Recommended

Nuclear fission & fusion ppt animation
Nuclear fission & fusion ppt animationNuclear fission & fusion ppt animation
Nuclear fission & fusion ppt animation
BalkrushnaBhuva
 
Ppt fusion and_fission_wk4
Ppt fusion and_fission_wk4Ppt fusion and_fission_wk4
Ppt fusion and_fission_wk4
ronniesidhu
 
nuclear fission and fusion
nuclear fission and fusionnuclear fission and fusion
nuclear fission and fusion
Yash Lad
 
Nuclear Fission Reactor
Nuclear Fission ReactorNuclear Fission Reactor
Nuclear Fission Reactor
muhammad shoaib
 
Nuclear fission and fusion By Pratimesh pathak
Nuclear fission and fusion By Pratimesh pathakNuclear fission and fusion By Pratimesh pathak
Nuclear fission and fusion By Pratimesh pathak
Pratimesh Pathak
 
Fusion
FusionFusion
Fusion
Anush Shenoy
 
Nuclear fission
Nuclear fissionNuclear fission
Nuclear fission
vicky vicky
 
Fission
FissionFission
Fission
sanjokk
 
Nuclear fusion seminar
Nuclear fusion seminarNuclear fusion seminar
Nuclear fusion seminar
KSHITIJ NISHAN
 
Nuclear fission
Nuclear fissionNuclear fission
Nuclear fission
plsriram8
 
Nuclear fission and fusion
Nuclear fission and fusionNuclear fission and fusion
Nuclear fission and fusion
Yashu Chhabra
 
Nuclear fission and fushion (ALIV - Bangladesh)
Nuclear fission and fushion (ALIV - Bangladesh)Nuclear fission and fushion (ALIV - Bangladesh)
Nuclear fission and fushion (ALIV - Bangladesh)
Md Abu Jauad Khan Aliv
 
Nuclear fission and fusion
Nuclear fission and fusionNuclear fission and fusion
Nuclear fission and fusion
Neelabh Shukla
 
Ch40 nuclear fissionandfusion
Ch40 nuclear fissionandfusionCh40 nuclear fissionandfusion
Ch40 nuclear fissionandfusion
Denisiu
 
Physics and Technology of Nuclear Reactors
Physics and Technology of Nuclear ReactorsPhysics and Technology of Nuclear Reactors
Physics and Technology of Nuclear Reactors
Paul Callaghan
 
Fission reaction
Fission reactionFission reaction
Fission reaction
Leilani Marcelo
 
Arn 01-0-nuclear fission
Arn 01-0-nuclear fissionArn 01-0-nuclear fission
Arn 01-0-nuclear fission
Dion Boediono
 
Nuclear fission
Nuclear fission Nuclear fission
Nuclear fission
Irtsam Ali
 
Fission and fusion
Fission and fusionFission and fusion
Fission and fusion
Inga Teper
 
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear FusionChapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
Chris Foltz
 
Nuclear Fusion
Nuclear FusionNuclear Fusion
Nuclear Fusion
Kajameson2014
 
Nuclear Fission
Nuclear FissionNuclear Fission
Nuclear Fission
stooty s
 
Fission energy
Fission energyFission energy
Fission energy
Suryapratim Paul
 
Module No. 49
Module No. 49Module No. 49
Module No. 49
Rajput Abdul Waheed Bhatti
 
Nuclear energy
Nuclear energyNuclear energy
Nuclear energy
Krishan267
 
Unit 3 Nuclear Power Plants
Unit 3 Nuclear Power PlantsUnit 3 Nuclear Power Plants
Unit 3 Nuclear Power Plants
PALANIVEL SUBBIAH
 
Nuclear power plant pwi u3
Nuclear power plant pwi u3Nuclear power plant pwi u3
Nuclear power plant pwi u3
Purushottam Ingle
 
Sheraz assignment ppt
Sheraz assignment pptSheraz assignment ppt
Sheraz assignment ppt
umairkhan119
 
Nuclear reactors
Nuclear reactorsNuclear reactors
Nuclear reactors
mehlilhafeez
 
Nuclear Reactor Presentation
Nuclear Reactor PresentationNuclear Reactor Presentation
Nuclear Reactor Presentation
aminuljust
 

More Related Content

What's hot

Nuclear fission and fusion
Nuclear fission and fusionNuclear fission and fusion
Nuclear fission and fusion
Yashu Chhabra
 
Ch40 nuclear fissionandfusion
Ch40 nuclear fissionandfusionCh40 nuclear fissionandfusion
Ch40 nuclear fissionandfusion
Denisiu
 
Fission and fusion
Fission and fusionFission and fusion
Fission and fusion
Inga Teper
 
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear FusionChapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
Chris Foltz
 
Nuclear Fission
Nuclear FissionNuclear Fission
Nuclear Fission
stooty s
 

What's hot (18)

Nuclear fusion seminar
Nuclear fusion seminarNuclear fusion seminar
Nuclear fusion seminar
 
Nuclear fission
Nuclear fissionNuclear fission
Nuclear fission
 
Nuclear fission and fusion
Nuclear fission and fusionNuclear fission and fusion
Nuclear fission and fusion
 
Nuclear fission and fushion (ALIV - Bangladesh)
Nuclear fission and fushion (ALIV - Bangladesh)Nuclear fission and fushion (ALIV - Bangladesh)
Nuclear fission and fushion (ALIV - Bangladesh)
 
Nuclear fission and fusion
Nuclear fission and fusionNuclear fission and fusion
Nuclear fission and fusion
 
Ch40 nuclear fissionandfusion
Ch40 nuclear fissionandfusionCh40 nuclear fissionandfusion
Ch40 nuclear fissionandfusion
 
Physics and Technology of Nuclear Reactors
Physics and Technology of Nuclear ReactorsPhysics and Technology of Nuclear Reactors
Physics and Technology of Nuclear Reactors
 
Fission reaction
Fission reactionFission reaction
Fission reaction
 
Arn 01-0-nuclear fission
Arn 01-0-nuclear fissionArn 01-0-nuclear fission
Arn 01-0-nuclear fission
 
Nuclear fission
Nuclear fission Nuclear fission
Nuclear fission
 
Fission and fusion
Fission and fusionFission and fusion
Fission and fusion
 
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear FusionChapter 22.4 : Nuclear Fission and Nuclear Fusion
Chapter 22.4 : Nuclear Fission and Nuclear Fusion
 
Nuclear Fusion
Nuclear FusionNuclear Fusion
Nuclear Fusion
 
Nuclear Fission
Nuclear FissionNuclear Fission
Nuclear Fission
 
Fission energy
Fission energyFission energy
Fission energy
 
Module No. 49
Module No. 49Module No. 49
Module No. 49
 
Nuclear energy
Nuclear energyNuclear energy
Nuclear energy
 
Unit 3 Nuclear Power Plants
Unit 3 Nuclear Power PlantsUnit 3 Nuclear Power Plants
Unit 3 Nuclear Power Plants
 

Similar to Overview Of Reactors

Reaction
ReactionReaction
Reaction
meresa
 
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdf
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdfDiscus this topic..A nuclear reactor generates heat in the fuel ro.pdf
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdf
sales96
 

Similar to Overview Of Reactors (20)

Nuclear power plant pwi u3
Nuclear power plant pwi u3Nuclear power plant pwi u3
Nuclear power plant pwi u3
 
Sheraz assignment ppt
Sheraz assignment pptSheraz assignment ppt
Sheraz assignment ppt
 
Nuclear reactors
Nuclear reactorsNuclear reactors
Nuclear reactors
 
Nuclear Reactor Presentation
Nuclear Reactor PresentationNuclear Reactor Presentation
Nuclear Reactor Presentation
 
Reaction
ReactionReaction
Reaction
 
nuclear reactors
nuclear reactors nuclear reactors
nuclear reactors
 
Admens Effect 2655.pdf
Admens Effect 2655.pdfAdmens Effect 2655.pdf
Admens Effect 2655.pdf
 
Nuclear reactor
Nuclear reactorNuclear reactor
Nuclear reactor
 
Lec-Nuclear-2.pptx
Lec-Nuclear-2.pptxLec-Nuclear-2.pptx
Lec-Nuclear-2.pptx
 
Nuclear Energy
Nuclear Energy Nuclear Energy
Nuclear Energy
 
Nuclear_power_plant.pdf
Nuclear_power_plant.pdfNuclear_power_plant.pdf
Nuclear_power_plant.pdf
 
TYPES OF NUCLEAR POWER PLANT.pptx
TYPES OF NUCLEAR POWER PLANT.pptxTYPES OF NUCLEAR POWER PLANT.pptx
TYPES OF NUCLEAR POWER PLANT.pptx
 
Unit-III-Nuclear Power Plants.pptx
Unit-III-Nuclear Power Plants.pptxUnit-III-Nuclear Power Plants.pptx
Unit-III-Nuclear Power Plants.pptx
 
Nuclear reactors
Nuclear reactorsNuclear reactors
Nuclear reactors
 
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdf
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdfDiscus this topic..A nuclear reactor generates heat in the fuel ro.pdf
Discus this topic..A nuclear reactor generates heat in the fuel ro.pdf
 
Nuclear power plant fundamentals
Nuclear power plant fundamentalsNuclear power plant fundamentals
Nuclear power plant fundamentals
 
15ee17 (Group)
15ee17 (Group)15ee17 (Group)
15ee17 (Group)
 
Nuclear powerplant
Nuclear powerplantNuclear powerplant
Nuclear powerplant
 
Nuclear lecture
Nuclear lectureNuclear lecture
Nuclear lecture
 
Presentation Topic:- Nuclear Reactor
Presentation Topic:- Nuclear ReactorPresentation Topic:- Nuclear Reactor
Presentation Topic:- Nuclear Reactor
 

Recently uploaded

08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men
Delhi Call girls
 
CNv6 Instructor Chapter 6 Quality of Service
CNv6 Instructor Chapter 6 Quality of ServiceCNv6 Instructor Chapter 6 Quality of Service
CNv6 Instructor Chapter 6 Quality of Service
giselly40
 
08448380779 Call Girls In Greater Kailash - I Women Seeking Men
08448380779 Call Girls In Greater Kailash - I Women Seeking Men08448380779 Call Girls In Greater Kailash - I Women Seeking Men
08448380779 Call Girls In Greater Kailash - I Women Seeking Men
Delhi Call girls
 
08448380779 Call Girls In Civil Lines Women Seeking Men
08448380779 Call Girls In Civil Lines Women Seeking Men08448380779 Call Girls In Civil Lines Women Seeking Men
08448380779 Call Girls In Civil Lines Women Seeking Men
Delhi Call girls
 
Boost PC performance: How more available memory can improve productivity
Boost PC performance: How more available memory can improve productivityBoost PC performance: How more available memory can improve productivity
Boost PC performance: How more available memory can improve productivity
Principled Technologies
 
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
Igalia
 
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
Earley Information Science
 
TrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
TrustArc Webinar - Stay Ahead of US State Data Privacy Law DevelopmentsTrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
TrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
TrustArc
 

Recently uploaded (20)

08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men
 
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
Bajaj Allianz Life Insurance Company - Insurer Innovation Award 2024
 
How to Troubleshoot Apps for the Modern Connected Worker
How to Troubleshoot Apps for the Modern Connected WorkerHow to Troubleshoot Apps for the Modern Connected Worker
How to Troubleshoot Apps for the Modern Connected Worker
 
How to Troubleshoot Apps for the Modern Connected Worker
How to Troubleshoot Apps for the Modern Connected WorkerHow to Troubleshoot Apps for the Modern Connected Worker
How to Troubleshoot Apps for the Modern Connected Worker
 
CNv6 Instructor Chapter 6 Quality of Service
CNv6 Instructor Chapter 6 Quality of ServiceCNv6 Instructor Chapter 6 Quality of Service
CNv6 Instructor Chapter 6 Quality of Service
 
Partners Life - Insurer Innovation Award 2024
Partners Life - Insurer Innovation Award 2024Partners Life - Insurer Innovation Award 2024
Partners Life - Insurer Innovation Award 2024
 
08448380779 Call Girls In Greater Kailash - I Women Seeking Men
08448380779 Call Girls In Greater Kailash - I Women Seeking Men08448380779 Call Girls In Greater Kailash - I Women Seeking Men
08448380779 Call Girls In Greater Kailash - I Women Seeking Men
 
08448380779 Call Girls In Civil Lines Women Seeking Men
08448380779 Call Girls In Civil Lines Women Seeking Men08448380779 Call Girls In Civil Lines Women Seeking Men
08448380779 Call Girls In Civil Lines Women Seeking Men
 
2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...2024: Domino Containers - The Next Step. News from the Domino Container commu...
2024: Domino Containers - The Next Step. News from the Domino Container commu...
 
Finology Group – Insurtech Innovation Award 2024
Finology Group – Insurtech Innovation Award 2024Finology Group – Insurtech Innovation Award 2024
Finology Group – Insurtech Innovation Award 2024
 
Boost PC performance: How more available memory can improve productivity
Boost PC performance: How more available memory can improve productivityBoost PC performance: How more available memory can improve productivity
Boost PC performance: How more available memory can improve productivity
 
Evaluating the top large language models.pdf
Evaluating the top large language models.pdfEvaluating the top large language models.pdf
Evaluating the top large language models.pdf
 
Strategies for Landing an Oracle DBA Job as a Fresher
Strategies for Landing an Oracle DBA Job as a FresherStrategies for Landing an Oracle DBA Job as a Fresher
Strategies for Landing an Oracle DBA Job as a Fresher
 
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
Raspberry Pi 5: Challenges and Solutions in Bringing up an OpenGL/Vulkan Driv...
 
ProductAnonymous-April2024-WinProductDiscovery-MelissaKlemke
ProductAnonymous-April2024-WinProductDiscovery-MelissaKlemkeProductAnonymous-April2024-WinProductDiscovery-MelissaKlemke
ProductAnonymous-April2024-WinProductDiscovery-MelissaKlemke
 
What Are The Drone Anti-jamming Systems Technology?
What Are The Drone Anti-jamming Systems Technology?What Are The Drone Anti-jamming Systems Technology?
What Are The Drone Anti-jamming Systems Technology?
 
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
 
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
 
TrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
TrustArc Webinar - Stay Ahead of US State Data Privacy Law DevelopmentsTrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
TrustArc Webinar - Stay Ahead of US State Data Privacy Law Developments
 
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
 

Overview Of Reactors

  • 1. Overview of Reactors In a commercial power plant, the conversion of energy is usually from thermal energy to mechanical energy to electrical energy. More specifically, the steam from heating water (thermal energy) is used to turn the blades of a steam-turbine engine (mechanical energy) which in turn, generates electricity. The source of heat energy has traditionally been the combustion of fossil fuels. In a nuclear power plant, the source of heat energy is the fission reactions of heavy nuclei in a nuclear reactor. Uranium-235 is the most common form of heavy nuclei used. The energy produced by the fission of 1 kilogram of uranium is comparable to that produced by the combustion of 10 tons of oil(1). Uranium-235 is the less abundant of the two naturally occurring uranium isotopes (uranium-238 is the other isotope). Since only uranium- 235 is fissionable, natural uranium is sometimes enriched ( that is the percentage of uranium-235 is increased) before it used as fuel in a nuclear reactor. HOW NUCLEAR REACTORS WORK Source: Environmental Sci nce, Lancaster University webpage, e http://www.es.lancs.ac.uk/casestud/jp/image4.gif  Fuel (that is, fissionable nuclei such as uranium-235 or plutonium-239), is contained in fuel rods in the reactor core. It is usually in the form of pellets. The fissionable nuclei are bombarded with neutrons. If fission results, the nuclei split into lighter nuclei (the fission products). Energy and neutrons are also released in the process. These neutrons can then be directed to bombard even more fissionable nuclei in the fuel. A chain reaction develops and energy production continues.  A gas or liquid functions as the coolant. The coolant prevents the overheating of the system. It flows around the reactor core and absorbs the heat energy produced by the fission reactions. This heat energy is then transferred to the heat exchanger for steam generation. The steam is used to drive turbines in electricity generation. It is then condensed, pumped back to the heat exchanger and the entire cycle begins again. The higher the temperature the coolant can be heated to, the more heat energy that will be transferred to the heat exchanger, the more steam that will be generated and thus the more power that will be produced. Ideally, a coolant will not undergo a phase change in the reactor due to an increase in temperature. Phase changes require energy and will reduce the thermal efficiency of the reactor. Good coolants are also inert.  The neutrons that are produced as fission products are very energetic and so move very quickly. To increase the likelihood that a fission chain reaction is set up, these neutrons can be slowed down by a substance called the moderator. The moderator ensures that the neutrons are moving slow enough to be able to collide with the nuclei. Common moderators are light water (H2O), heavy water (D2O) and graphite. A good moderator is one whose atoms are similar in mass to neutrons so that when collisions occur between the two, energy will be efficiently transferred from the neutrons to the moderator material. Gases are not good moderators because they are too low in density and would not allow for regular collisions with the neutrons. A good moderator is also a poor neutron absorber - we want a moderator that slows down neutrons not absorbs them. Light water is not the best moderator because it tends to absorb neutrons. The less enriched the fuel, the less fissionable material it contains, the more efficient the moderator must be to ensure that the neutrons are slowed down and directed to bombard the limited fissionable nuclei.  Reactors with moderators are c alled Thermal Reactors. There are reactors without moderators. These are termed Fast Neutron Reactors because the neutrons’ speed is not controlled. Unlike Thermal Reactors, highly enriched fuel must be used to increase the probability that the neutrons are captured by the fissionable nuclei.  To ensure that the fission reaction does not explode out of control, control rods can be periodically inserted into the reactor core. These rods contain materials (such as cadmium, hafnium and boron) that absorb neutrons and thus limit the fission reaction rate.
  • 2. The reactor core is shielded to prevent the release of harmful radioactive material to the environment. REACTOR TYPES Nuclear reactors are characterized by their type of coolant and moderator and by their design in general. Table 1 gives an account of some of the more common nuclear reactor types. All of the listed reactors are thermal reactors. Table 1: Types of Nuclear Reactors Source: What is a Nuclear Reactor? European Nuclear Society webpage, http://www.euronuclear.org/info/energy- ses.htm u LIGHT WATER REACTOR (LWR) Currently, the LWR is the main reactor type employed in the U.S. In LWRs, light water (H2O) is used as both the coolant and the moderator. There are two main types of LWRs; pressurized water reactors (PWRs) and boiling water reactors (BWRs) PWR Energy from the fission reactions can cause the temperatures in the reactor core to reach 300 degrees Celcius (2). This is way above the temperature that would cause the light water coolant to boil if the pressure were that of the atmosphere (101kPa). To prevent the water from boiling and thus vaporizing, the coolant is forced to flow around the reactor core at an exceedingly high pressure of approximately 15 to 16 MPa (See Primary water in Figure 3) (3). A disadvantage of the PWR is that it must shut down regularly for routine check ups - under such high pressure, it is wise to regularly check that there is no wear and tear on the system’s components.
  • 3. The coolant also functions as the moderator. If the moderator were to vaporize, the fission reactions would be less efficient. The gas would be too low in density to have effective collisions with the neutron fission products to cause them to slow down. The coolant then transfers the heat to the Secondary water. The Secondary water can boil and generate steam because this part of the system is held under less pressure (6MPa). The steam is used to turn the blades of the turbine and generate electricity. It is then condensed and the resulting water is pumped back to steam generator to begin the process all over again. Figure 3: Nuclear power plant with pressurized water reactor Source: What is a Nuclear Reactor? European Nuclear Society webpage, http://www.euronuclear.org/info/energy- ses.htm u BWR In these reactors, the reactor cores are held under a pressure of approximately 7MPa (4) - a much lower pressure than that of the PWR. This pressure is close enough to atmospheric pressure to allow the light water coolant/moderator to begin to boil. Unlike the PWR, because the steam is generated directly in the reactor core of the BWR, the core is bigger and more expensive.The steam produced (at the top part of the reactor core) is delivered directly to the turbine to aid in electricity generation (See Figure 4). The BWR system is much simpler than that of the PWR because no heat exchangers/steam generators are needed. In the reactor core, the steam is separated from the water below by steam separator plates. The neutron efficiency of BWR is less than that of the PWR because 12-15% of the moderator is vaporized (5). The coolant/moderator is in contact with the turbine. Since the coolant/moderator is radioactive (due to its contact with the fuel rods), the turbine is contaminated and must also be shielded. In a PWR however, the turbine is only in contact with the Secondary water which does not contain s ignificant amounts of radioactive material. The turbine in the PWR plant does not need to be shi lded. e PRESSURIZED HEAVY WATER REACTOR (PHWR) The PHWR design is also called the CANDU design because it originated in Canada in the 1950s. It is very similar to the PWR with respect to the pressure system. However, the main difference is that unlike the LWRs, these reactors use natural uranium as the fuel. There is thus, not a lot of fissionable uranium-
  • 4. 235 in the fuel. A moderator that will control the speed of the neutron fission products but will not absorb the neutrons is needed. As many neutrons as possible are needed to bombard the limited uranium-235 in order to continue the fission chain reaction. Light water, though it slows down neutrons efficiently, has a tendency to also absorb the neutrons. These reactors therefore use heavy water (deuterium oxide, D2O) as the moderator. Deuterium oxide is less likely to absorb neutrons because deuterium already has twice the amount of neutrons as the hydrogen in light water. However, a large quantity of heavy water is needed to have an influence on the neutron speed. Another disadvantage of heavy water is that if it absorbs neutrons it produces the radioactive isotope of hydrogen called tritium. Though heavy water is expensive, costs are cut down since natural uranium rather than processed enriched uranium can be used as the fuel. Furthermore, the PHWR can be refueled while in operation. GAS-COOLED REACTORS (GCR) GCRs are of European origin. The coolant is carbon dioxide and the moderator isgraphite. Carbon dioxide is an effective coolant because it can be heated to high temperatures and can thus maxim heat ize transfer to the steam generation process. Also, because it is gaseous, carbon dioxide will not absorb the neutrons that are involved in the fission chain reaction. However, as explained in the PWR section, gases are poor moderators. Graphite is used as the moderator because it is inexpensive, readily available and not damaged by high temperatures (6). The thermal efficiency of these reactors is very high but the fuel efficiency is low. Figure 6: Nuclear Power Plant with Gas Cooled Reactor Source: Joseph’s Gonyeau’s The Virtual Nuclear Tourist! webpage, http://www.nucleartourist.com/ LIGHT WATER GRAPHITE REACTORS(LWGR) The LWGR is a Soviet invention. It was uniquely designed to generate power and produce plutonium. The coolant is light water and the moderator is graphite. This coolant/moderator combination is unique to the LWGR. THe light water vaporizes as it passes through the reactor core. This steam is used to drive the turbines. One major advantage of the LWGR is that it can be refueled while in operation. NUCLEAR FUSION
  • 5. In Nuclear Fusion the nuclei of atoms fuse together, causing much more energy being released than in Nuclear Fission. This is the process which powers the Sun.Here the Deuterium and Tritium atoms (these are the isotopes of Hydrogen:- these haveextra neutrons in the nucleus than normal) fuse together to form He. Energy is released due to a difference in mass between He atoms compared with the sum of the Hydrogen atoms therefore it is conclusive evidence that some mass is converted into energy via Einstein’s relationship of E=mc2; where E=Energy, m=mass of nuclei, and c=speed of light (3x108). This is why the energy (E) released is greater in fusion than in fission because of a very large mass deficit (m). PROS AND CONS OF NUCLEAR FUSION PROS CONS There is a lot more energy released during Fusion will only occur at temperatures of 10- fusion than fission so would be more 15 million Kelvin (K), hence there is no point profitable once set up. of producing energy since it is not profitable. Even if fusion did take place, it would be far Hardly any waste produced comparedto ahead of it’s time since no material exists Nuclear Fusion, so no money wasted in which can cope with temperatures of 10-15 disposing Nuclear waste. million K. Fusion could power the entire world at a very At the moment the only profitable way for low cost compared with power sources today. fusion to occur is using cold fusion*, but this Fusion would not be depleted like non- has not yet been discovered. (*cold fusion is renewable sources today si ce it would be n fusion at low enough temperatures to make possible to make hydrogen nuclei manually profits because this would mean that the as it is a very simple element (requires only 1 output energy would be greater than input proton and 1 neutron). energy ). CONCLUSION: For the moment the only way to produce energy using nuclear power is via nuclear fission. This is because Physicists are still trying to discover ways in which to produce energy using cold fusion. If discovered all our energy crisis would be solved.