Steven Biegalski, Ph.D., P.E. Director, Nuclear Engineering Teaching Laboratory Associate Professor, Mechanical Engineering Dusting off the Atom: Nuclear.

Slides:

Advertisements

Similar presentations

Sofía Ramírez Hannah Ashworth Federico Madrigal NUCLEAR POWER.

Advertisements

1 Future Changes in Fuel Mix of Electricity Generation in Hong Kong and Implications By Larry Chuen-ho Chow Professor, Department of Geography Director,

Presentation to 40 th Meeting of the APEC Energy Working Group Brunei Darussalam November 2010.

Nuclear Power – Need and Future. Outline Economics of Nuclear Energy Basics of a Power Plant Heat From Fission History of Nuclear Power Current Commercial.

A Timely and Difficult Problem Anne Fitzpatrick, Ph.D. Federation of American Scientists (202) Nuclear Energy Technology.

Nuclear Renaissance and Nonproliferation in North-East Asia Hua HAN Associate Professor School of International Affairs Beijing University.

Miss Nelson SCIENCE ~ CHAPTER 12 ENERGY AND MATERIAL RESOURCES.

Resource and Energy.

Energy Energy- the capacity to do work –Work- force through a distance Joule- amount of work done –4 Joules = 1 calorie –Calorie- energy to heat 1 g of.

NUCLEAR ENERGY What is it? David J. Diamond Energy Sciences & Technology Department February 2009.

NUCLEAR POWER FUTURE, PROS, & CONS. WHAT IS NUCLEAR POWER?

NUCLEAR POWER PLANT. NUCLEAR FUEL  Nuclear fuel is any material that can be consumed to derive nuclear energy. The most common type of nuclear fuel is.

Nuclear Power Technology Steven Biegalski, Ph.D., P.E. Director, Nuclear Engineering Teaching Laboratory Associate Professor, Mechanical Engineering The.

OVERVIEW: Definition Types of nuclear reactions First commercial application Mechanism & Brief History Advantages and Disadvantages Facts of Nuclear energy.

A threat or an opportunity?

Nuclear Power Isar Plant - Germany Diablo Canyon - California.

Spent Nuclear Fuel Timothy Pairitz. Nuclear Power 101 Uranium-235 is enriched from 0.7% to 3-5%. Enriched fuel is converted to a uranium oxide powder.

 Benefits of Nuclear Energy  How Fission Works  Nuclear Power Plant Basics  Overview of Uranium Fuel Cycle  Energy Lifecycle of Nuclear Power  Generation.

Nuclear Power What is nuclear energy? Power plants use heat to produce electricity. Nuclear energy produces electricity from heat through a process called.

Should Japan Continue to Use Nuclear Power? GROUP 8 Nancy, Jefrey, Alice

Nuclear Energy General Concept. In 2001, total US generation of electricity was 3,777 billion kilowatt-hours.

Nuclear Fact Sheet Matthew Pigott EGRS 352 Professor Nicodemus Process: Nuclear energy results from the splitting of uranium atoms in a process called.

Making Electricity.  A generator takes mechanical energy (movement) and turns it into electrical energy.  A generator makes electricity by turning a.

Japan’s Nuclear Energy Program

The Nuclear Renaissance Dr. Charles K. Ebinger Director, Energy Security Initiative Brookings.

The Role of International Organizations in Nuclear Regulation Daniel Yerkes

Nuclear Reactors and Nuclear Energy Conversion of mass-energy to electrical energy mass-energy  thermal  kinetic  electric Produces large amounts of.

Chapter 4 Nuclear Energy. Objectives Describe how nuclear fuel is produced. List the environmental concerns associated with nuclear power. Analyze the.

Solar Energy and Nuclear Power

The Future of Energy Fred Loxsom Eastern Connecticut State University.

Nuclear Energy. How does it work? Some atoms, (like Uranium), are so big that we can break them apart by shooting tiny particles at them. This process.

Nuclear Power Plants. History of nuclear power 1938– Scientists study Uranium nucleus 1941 – Manhattan Project begins 1942 – Controlled nuclear chain.

Nuclear Energy. The Nearest Nuclear Power Plant DTE Fermi II is just about 40 miles from us.

Nuclear Power: Pros & Cons By: Shokoofeh Akhavan Professor: Emily Brett August 2012.

IB SL NUCLEAR POWER. WHAT IS IT? The process of generating nuclear power starts with the mining and processing of uranium and other radioactive elements.

THE FUTURE OF NUCLEAR POWER GREG RAABERG NOVEMBER 24, 2008 The University of Texas at Austin Department of Chemical Engineering ChE 359.

Natural Resources. Two Types of Natural Resources Nonrenewable- limited Renewable-”unlimited”

1 Nuclear Energy Division MIT Report on the Future of Nuclear Power in the United-States : review and discussion Eric Proust Director, Industrial Affairs.

FUEL SOURCES: NUCLEAR BY NINA GREEN

Nuclear Power Physics /7/03. Outline  The Nucleus  Radioactivity  Fission  Fusion  Nuclear Weapons  Nuclear Power.

ENERGY FOR THE 21 ST CENTURY the Potential for Nuclear Power Luis Echávarri Director-General, OECD Nuclear Energy Agency IAEA Scientific Forum at the General.

Nuclear Power Nuclear energy comes from a naturally occurring material that is refined and used to produce nuclear power. Uranium is the material used.

Nuclear Energy ESCI 420 Spring 07 Nuclear Energy ESCI 420 Galen University Spring 2007.

Brevard Community College EST1830 Bruce Hesher

Introduction to Nuclear Power Kenneth M. Klemow, Ph.D. For BIO / EES 105 at Wilkes University Susquehanna Nuclear Plant - Berwick.

Aasia Ross 8 th hour. In a nuclear reactor the energy released from continuous fission of the atoms in the fuel as heat is used to make steam. The steam.

Nuclear Power Plants Gina Gallione NUCLEAR POWER PLANTS GINA GALLIONE.

NUCLEAR POWER. What is Nuclear Power? Process of harvesting energy stored in atoms Used to produce electricity Nuclear fission is the form of nuclear.

Nuclear Power. What Is Nuclear Power? Nuclear power is the use of nuclear reactions that release nuclear energy, which generates heat. The energy produced.

Nuclear Energy Quinci James Dawson Miller. What is nuclear Energy? Nuclear energy is the energy in the nucleus, or core, of an atom. Atoms are tiny units.

Chapter 8 Energy and Civilization: Patterns of Consumption Energy and Civilization: Patterns of Consumption.

Nuclear_Power_Plant Prepared by: Nimesh Gajjar. Introduction A generating station which converts heat energy produced by nuclear materials to electrical.

Current Energy Use in America. How much energy we use The United States only makes up 5% of the worlds population however consumes 25% of the worlds total.

Introduction to Nuclear Energy Candace Davison Senior Reactor Operator Penn State University.

Nuclear Energy: Good, Bad, or Ugly? By: Russell Dehaut, Courtney Sperger, and Craig Hughes.

Nuclear Power – Energy for the Future

Nuclear Power Economics and Project Structuring 2017 Edition

NuScale Generator A Practical Energy Alternative for the Future

IAEA PERSPECTIVE ON THE FUTURE OF NUCLEAR POWER

IAEA International Conference on Fifty Years of Nuclear Power – The next Fifty Years Moscow - Obninsk, Russian Federation - June 28, 2004 Nuclear.

NUCLEAR POWER PLANT SUBMITED BY…. ANJALI PRAKASH EN 3rd YEAR

Japan’s Nuclear Energy Program

NUCLEAR POWER PLANT.

Nuclear Power – Energy for the Future

Summary Resources are naturally occurring substances of use to humans.

Nuclear Energy By: Michael Deedrick, Jared Rafferty, Niko Mireles, and Simon Hulser.

Ella Simon, Alex Horb, Grant Steiner

NUCLEAR ENERGY What is it?

Presentation transcript:

Steven Biegalski, Ph.D., P.E. Director, Nuclear Engineering Teaching Laboratory Associate Professor, Mechanical Engineering Dusting off the Atom: Nuclear Energy Futures

Outline Energy Policy Act of 2005 What has changed in the last 25 years? Common questions about nuclear power Future plans for nuclear Nuclear Power Plant Basics Conclusions

Energy Policy Act of 2005 The Energy Policy Act of 2005 had specific provisions to encourage the development of nuclear power in the United States Some specific examples: Liability limits Cost-overrun support Tax credits Research and development Steps up DoE work to address high-level waste problem.

What has changed in the last 25 years? Growth – Energy Demands In US Total electricity sales increase by 29 percent in the AEO2008 reference case, from 3,659 billion kilowatthours in 2006 to 4,705 billion in 2030, at an average rate of 1.1 percent per year. (Energy Information Association) Worldwide increase by 50 percent from 2005 to Nuclear industry capacity factor up to 90% Increased Environmental Awareness (e.g., Global warming) World politics Reduction in dependence on foreign countries for energy Cost – “Days of cheap energy sources are behind us.” No new accidents Increased operational efficiency of nuclear power plants.

Growth

U.S. Nuclear Plant Capacity Factor Source: Energy Information Administration Updated: 5/10

Increased Environmental Awareness Per capita CO 2 emissions.

Carbon Footprints

Reduction in dependence on foreign countries for energy

Cost Data from U.S. DoE

OECD electricity generating cost projections for year 2010 NuclearCoalGas Finland France Germany Switzerland Netherlands Czech Rep Slovakia Romania Japan Korea USA Canada Source: OECD/IEA NEA 2005.

Common questions about nuclear power What is the nuclear waste problem? What is the nuclear proliferation risk? How much uranium is left? How much radiation comes from a nuclear power plant? How much water does a commercial nuclear reactor consume?

Nuclear Waste Nuclear reactors produce nuclear waste. Waste is produced throughout the entire fuel cycle. The high-level waste (spent nuclear fuel) is the primary concern. Disposal is being paid for by a combination of a tax on each kilowatt hour of nuclear power.

Yucca Mountain On June 3, 2008 DOE submitted a license application to the NRC for Yucca mountain. The NRC now has a statute time limit of 3 to 4 years to complete its safety analysis and public hearings. In 2010 DOE withdrew its application for Yucca Mountain licensing.

Reprocessing

Nuclear Non-Proliferation Nuclear proliferation is a term now used to describe the spread of nuclear weapons, fissile material, and weapons-applicable nuclear technology and information, to nations which are not recognized as "nuclear weapon States" by the Treaty on the Nonproliferation of Nuclear Weapons, also known as the Nuclear Nonproliferation Treaty or NPT.

Nuclear Non-Proliferation ? Things to be done: Control of world-wide nuclear fuel cycle. Monitoring of nuclear activities. Proliferation resistant fuels and fuel cycles.

Uranium Resources The Organization for Economic Cooperation and Development (OECD) and the International Atomic Energy Agency (IAEA) in 2005 jointly produced a report on uranium resources. The report states that uranium resources are adequate to meet the needs of both existing and projected reactors.

Uranium Resources

Radiation

Water Resources Nuclear power plants consume water through water vapor emissions. This water is from a condenser loop that does not run through the reactor core. Electricity generation accounts for3.3 % of water consumption in U.S % for residential use 81.3% for irrigation

Future Plans for Nuclear Nuclear power capacity worldwide is increasing steadily but not dramatically, with about 35 reactors under construction in 12 countries. Most reactors on order or planned are in the Asian region, though plans are firming for new units in Europe, the USA and Russia. Significant further capacity is being created by plant upgrading.

Location of Projected New US Nuclear Power Reactors

World Growth for Nuclear Power Data from U.S. DoE

Nuclear Power Plant Basics The basic premises for the majority of power plants is to: 1) Create heat 2) Boil Water 3) Use steam to turn a turbine 4) Use turbine to turn generator 5) Produce Electricity Some other power producing technologies work differently (e.g., solar, wind, hydroelectric, …)

Nuclear Power Plants use the Rankine Cycle

Heat From Fission

Fission Chain Reaction

PWR

BWR

World-wide demand for electricity continues to grow. Environmental concerns play a part in selecting electricity sources to meet the demand. Nuclear energy will play a vital role in the production of electricity for the foreseeable future. Conclusions