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LIVE INTERACTIVE YOUR DESKTOP January 25, 2012 What's Cool About Nuclear Science – and Why Our Country Needs Nuclear Energy Presented by: Mark.

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Presentation on theme: "LIVE INTERACTIVE YOUR DESKTOP January 25, 2012 What's Cool About Nuclear Science – and Why Our Country Needs Nuclear Energy Presented by: Mark."— Presentation transcript:

1 LIVE INTERACTIVE LEARNING @ YOUR DESKTOP January 25, 2012 What's Cool About Nuclear Science – and Why Our Country Needs Nuclear Energy Presented by: Mark T. Peters and Justin Thomas

2 What's Cool About Nuclear Science – and Why Our Country Needs Nuclear Energy Mark T. PetersJustin Thomas Deputy Laboratory Director for ProgramsPrincipal Nuclear Engineer Argonne National Laboratory National Nuclear Science Week January 25, 2012

3 1/10/2012 3 What’s cool about nuclear science?

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5 1/10/2012 5

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9 9 Why does our country need nuclear energy?

10 How will our future energy demands be met? Today: 15 terawatts(TW) Future: 30 TW (2030) to 50 TW (2100)

11 Nuclear energy: Best U.S. source of sustainable, reliable, affordable, plentiful electricity

12 Nuclear energy is the most widely used source of carbon-free electricity in the United States Energy Information Administration, 2006 Annual Energy Review Wind: 2.3% Geothermal: 1.3% Solar: <0.05%

13 Nuclear energy provides lowest-cost baseload energy

14 Despite benefits of nuclear energy, concerns remain

15 Challenge of nuclear waste management remains 15

16 1/10/2012 16

17 1/10/2012 17

18 18 There is still adventure in nuclear energy

19 1/10/2012 19 What’s under the hood?

20 Nuclear Fission Chain Reaction National Nuclear Science Week

21 Nuclear Fuel National Nuclear Science Week

22 Nuclear Electric Generation Source: http://www.nrc.gov/reading-rm/basic-ref/students/animated-pwr.html Heat sink U.S. nuclear plants produce electricity for 1.72 cents per kilowatt-hour, compared to 2.37 cents for coal and 6.75 cents for natural gas.

23 23 Nuclear Power Plant Coal Power Plant

24 How much fuel?  One metric ton (1000 kg) of nuclear fuel:  50 Giga-Watt-days of thermal energy  400 million kW-hours of electrical energy  According to the Energy Information Agency, average U.S. household electricity usage in 2008 was 920 kW-hours per month  How much fuel is required to power one family’s home for a month?  About 2 grams Mass of nuclear fuel required to generate enough electricity for an American family’s home for a month National Nuclear Science Week

25 Most of Used Fuel (a.k.a. “Nuclear Waste”) Is Still Useful About 965 kg of fissionable material remains National Nuclear Science Week

26 Current Reactors Are “ Once-Through ”  Uranium ore is mined from the ground  Natural uranium is only 0.7% U-235. Enrichment increases the U-235 content to 4- 5%.  Enriched uranium goes to fuel fabrication to make UO2 ceramic pellets.  After generating power in a reactor (4–6 years) used fuel may be disposed of in a geologic repository. Conventional Power Plant National Nuclear Science Week

27 Fast Reactors Can Recycle Fuel  Reduces need for mining  Conserves valuable resources  Enables reliable fuel services  Reduces repository burden  Reduces long-term toxicity Conventional Power Plant Fast Reactor National Nuclear Science Week

28 Recycling Nuclear Fuel Reduces Its Toxicity (What was taken from the Earth) With recycling, used fuel becomes less toxic than what was removed from the ground in ~200 years. National Nuclear Science Week

29 Nuclear Power Plants Have Many Protections against Accidents  Containment building –Steel, reinforced concrete, or a combination –Missile protection, confines any radioactive release  Automated shutdown systems  Emergency core cooling systems  Redundancy and diversity in design  Defense in depth  Passive Safety –Relies on natural forces (e.g. gravity), rather than electrical pumps –Relies less on intervention by plant operators National Nuclear Science Week

30 Passive Safety? National Nuclear Science Week

31 Small Modular Reactors (SMRs)  Financing: Lower absolute overnight capital cost for low power plant  Fitness for small electricity grids, reduced design complexity, reduced impact of human factors and, perhaps, reduced infrastructure and staff requirements –May be a good choice for developing countries  An option of incremental capacity increase  Move generation closer to where electricity is needed  Option of operation without on-site refueling –Attractive for nonproliferation regime  Potential for enhanced safety mPower System Babcock & Wilcox 125 MWe capacity (example) National Nuclear Science Week

32 Modeling and Simulations  Nuclear reactor design relies heavily upon computer simulation to predict how a reactor will respond to adverse conditions –What will the reactor do when the power goes out? –What would happen if we increased the power a little?  How do we know that a computer model is realistic? –Compare models to experiment –Compare results from competing computer models  Example: Physics of fluid flow and heat transfer –Heat generated by nuclear fission must be removed by a cooling fluid (water), which then performs work on a turbine to convert the energy to electricity –Just above the core, this cooling fluid mixes in a large tank (or plenum) Need to reduce any “hot spots” where a small area could have a higher than average temperature Hot spots could damage the materials over a long time  The MAX experimental facility takes high-resolution measurements that can be compared to our simulation codes’ results for this problem National Nuclear Science Week

33 MAX Experimental Facility National Nuclear Science Week

34 Code Simulations of the MAX facility Comparison of results from two simulation codes (Nek5000 and STAR-CCM+) Velocity Predictions by the Nek5000 code National Nuclear Science Week

35 Major Difference in Jet Behavior for Minor Design Change MAX1 MAX2 Simulation Results: –Small perturbation yields big change in jet behavior –Unstable jet, with low- frequency (20 – 30 s) oscillations –Visualization shows change due to jet / cross-flow interaction –MAX2 results NOT predicted by steady RANS (URANS ok) National Nuclear Science Week

36 For more info…  Nuclear energy learning resources: –http://students.ne.anl.gov/schools/http://students.ne.anl.gov/schools/ –For students at or below high school level and their teachers. Resources that will help you find information on how nuclear reactors work, what makes certain materials radioactive, the importance of nuclear energy in the 21st century, and many other nuclear energy topics.  Argonne’s Nuclear Engineering Division –http://students.ne.anl.gov/outreach/http://students.ne.anl.gov/outreach/ –http://www.facebook.com/NuclearEngineeringAtArgonnehttp://www.facebook.com/NuclearEngineeringAtArgonne –neoutreach@anl.govneoutreach@anl.gov  Student programs in nuclear energy at Argonne –http://students.ne.anl.gov/students/http://students.ne.anl.gov/students/ –Find out about the programs Argonne has for students just graduating from high school or in college. National Nuclear Science Week

37 Questions from the audience.

38 Thank you to the sponsor of today's Web Seminar: This web seminar contains information about programs, products, and services offered by third parties, as well as links to third-party websites. The presence of a listing or such information does not constitute an endorsement by NSTA of a particular company or organization, or its programs, products, or services.

39 National Science Teachers Association Dr. Francis Q. Eberle, Executive Director Zipporah Miller, Associate Executive Director Conferences and Programs Al Byers, Assistant Executive Director e-Learning LIVE INTERACTIVE LEARNING @ YOUR DESKTOP NSTA Web Seminars Paul Tingler, Director Jeff Layman, Technical Coordinator Brynn Slate, Program Coordinator


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