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Advanced Design Activities

Advanced Design Activities. Farrokh Najmabadi Virtual Laboratory for Technology Meeting Dec. 10, 1998 VLT PAC Meeting, UCSD. Program Elements. Next-step device (burning plasma experiment) design studies (covered in the next presentation).

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Advanced Design Activities

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  1. Advanced Design Activities Farrokh Najmabadi Virtual Laboratory for Technology Meeting Dec. 10, 1998 VLT PAC Meeting, UCSD

  2. Program Elements • Next-step device (burning plasma experiment) design studies (covered in the next presentation). • Fusion application and Test Facilities design studies. • Strategic planning and forecasting -- role of fusion energy in a sustainable global energy strategy. • Development pathway analysis. • Safety and environmental Design Studies (in support of above elements).

  3. FY99 Funding Levels* • Total (including taxes, SBIR) 2,500k • Fusion application and Test Facilities design 1,800k • Strategic planning and forecasting 600 k • Development pathway analysis. 0 * Approximate numbers, excluding NSO activity

  4. Development Pathway Analysis Mission: Develop and apply methodologies for assessing the cost, risk, and schedule impact of different approaches to fusion development. Strategic Pathway: • For each concept, identify the critical issues and a sequence of R&D steps needed to reach a competitive end-product. • Develop methodology to incorporate factors such as technical uncertainties and the size and the cost of the need facilities.

  5. Development Pathway Analysis Deliverables by 2005: • A formalism for objective discussion, evaluation, and selection among various proposed development paths based on cost versus risk/benefits. FY99 Priorities: • Identify a lead contractor/individual to begin to assemble a team to prepare the methodology.

  6. Role of Fusion in a Sustainable Global Energy Strategy Mission: Assess the role of fusion energy in a long-term vision of a sustainable global energy strategy, taking into account the portfolio of energy options available. Strategic Pathway: • Include a range of scenarios to deal with future social, economic, and environmental conditions such as limit on greenhouse gases. • Determine how fusion fits given fusion’s environmental and economic characteristics. • Determine the goals and requirements for fusion energy through examination of portfolio of fusion concepts and options.

  7. Role of Fusion in a Sustainable Global Energy Strategy Deliverables by 2005: • Assessment of role of fusion in a sustainable global energy strategy. • Communication of the results to national policy makers, scientific and engineering societies, Congress, the Administration, and the general public. FY99 Priorities: • Initiation of the study.

  8. FY99 Activities Role of large power fusion stations in future energy markets. Role of fusion in a global energy strategy. Macro-economics modeling of global energy market and role of fusion. Comparison of various sources of energy based on equivalent CO2 emission. Outreach to other communities.

  9. Fusion Application & Test-Facilities Design Mission: • Design of of commercial facilities for all confinement concepts are carried out to guide the science and technology R&D and to assist major program evaluations. • Fusion application studies continue assessment of supply, demand, and cost of electricity from fusion as well as exploration of other non-electric application. • Design of fusion test facilities, such as neutron sources, define cost and risk associated with different fusion development pathways. Examples of Recent Accomplishment: • ARIES designs

  10. Fusion Application & Test-Facilities Design Strategic Pathway: • Through self-consistent design and trade-off among physics and technology constraints, optimum goals are set and high-leverage areas identified which in turn guide the physics and technology R&D. • Studies are performed at varying level of detail and emphasis: • Scoping studies for “Concept Exploration” concepts • Conceptual design to guide R&D for “proof-of-principle” concepts • Conceptual design for concept optimization for “proof-of-performance” concepts. • Non-electric application help gain new clients (specially near-term).

  11. Fusion Application & Test-Facilities Design Deliverables by 2005: • Advanced power-plant studies of tokamaks and alternatives (including IFE) as new information become available or a concept enters proof-of-principle phase. • Conceptual design of advanced neutron sources for non-electric applications as well as fusion development. • Design studies of large-output fusion devices for hydrogen production (or co-generation). FY99 Priorities: • Conceptual design of advanced neutron sources • Evaluate potential of fusion for hydrogen production.

  12. FY99 Activities • ARIES Team activities (~$1.5M): • Advanced neutron source; • Advanced ARIES-RS; • Support for proof-of-principle concepts; • Support for hydrogen production by fusion, impact of ferromagnetic material on plasma performance, etc. • Pre-conceptual designs (analysis of critical issues) of advanced fusion concepts, such as FRC (U.W. and U.W.), Dipole (MIT), etc. (~$150k) • Non-electric applications studies (~$100k).

  13. Some Recent Highlights (ARIES-ST study) • A high-performance blanket using ferritic steels: • Innovative design allows the coolant outlet temperature (~700oC) to be much higher than the upper temperature limit of ferritic steels (~550oC) boosting thermal conversion efficiency. • ARIES project “virtual” meeting: • Use of Web to view presentation slides during conference call. • Novel manufacturing techniques to reduce component costs: • Unit cost of ARIES-ST TF coils were reduced from 66 to 8 $/kg leading to ~12% reduction in COE (89 to 79 mills/kWh)

  14. A high-performance ferritic steels blanket

  15. Laser or Plasma Arc Forming • A laser or plasma-arc deposits a layer of metal (from powder) on a blank to begin the material buildup • The laser head is directed to lay down the material in accordance with a CAD part specification AeroMet has produced a variety of titanium parts as seen in attached photo. Some are in as-built condition and others machined to final shape. Also see Penn State for additional information.

  16. Schematic of Spray Casting Process Molten Metal Furnace, Courtesy of SECO/WARWICK, Inc

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