PPT-Reactor Design for Complex Configurations

1 Ref Seider et al Product and process design principles 3 rd ed Wiley 2010 Temperature Control Temperature control is an important consideration in reactor design Adiabatic operation is always considered first because it provides the simplest and leastexpensive reactor. e a circuit Pumps packet bits nonstop to destination No intermediate buffer Requires setup and teardown time Multicomputer Network Interface Interface boards usually contain buffer for packets Needs to control flow onto interconnection network when s We will discuss two design paradigms that are quite common and partially overlapping Decomposition in Data Path and Control Unit Register Level Transfer RTL design Data Path and Control unit A common design practice decomposes the system in two Bioreactor configurations. Bioreactor operation modes. Practical considerations for bioreactor design. Outline of Lecture. Bioreactor:. device, usually a vessel, used to direct the activity of a biological catalyst to achieve a desired chemical transformation.. . V. Chareyre / EN-EL. LHC Beam Operation Committee. 11 February 2014. EDMS . No.. . 1354977. 1. 11/02/2014. Outline. UPS systems and replacement project during LS1. New configuration in the alcoves and LHC odd points. الجمهور: هو احنا هناخد إيه النهاردة؟. أنا: هناخد . Reactor. الجمهور: بس؟. أنا: آه بس. الجمهور: هو السكشن طويل . أنا: آه. 2:. Reactor Design and Simulation. Dr. . Jia. Li. Project Scope. Learn the importance of the . reactor design of . chemical processes. Perform a reactor conceptual . design for a given reaction system. Real CSTRs. R. elatively high reactant . conc. at entrance. Relatively low . conc. in stagnant regions, called dead zones (corners & behind baffles) . Dead . Zone. Dead . Zone. Short . Circuiting. Michael A. Norato, PhD. Chief, Component Integrity, Performance & Testing Branch 2 (BWRs). Division of Engineering. Office of New Reactors. June 15, 2011. 1. NRC’s Primary Functions. License and regulate the Nation’s civilian use of byproduct, source, and special nuclear materials to ensure adequate protection of public health and safety, promote the common defense and security, and protect the environment. . Nuclear Energy Fundamentals . Module 4: Nuclear Reactor Design . Module Objectives . After the completion of this module, the student will be able to: . • . Explain the fuel assembly geometry, specifications and material. . Michael A. Norato, PhD. Chief, Component Integrity, Performance & Testing Branch 2 (BWRs). Division of Engineering. Office of New Reactors. June 15, 2011. 1. NRC’s Primary Functions. License and regulate the Nation’s civilian use of byproduct, source, and special nuclear materials to ensure adequate protection of public health and safety, promote the common defense and security, and protect the environment. Dr. Andrew Ketsdever. Design Process. The design process is driven by mission requirements (all propulsion systems). Payload mass. Mission . ∆V. Operational environment. Key differences for nuclear propulsion system from the design of a liquid rocket. Nuclear Technology of the GT Fusion DEMO Reactor Andrew Rosenstrom, Nathan Morgenstern, Wes Crane, Stephen Johnston, Christian Maniscalco, Xianwei Wang Advisors : Dr . Stacey, Dr. Petrovic 1 Objectives The Integral Fast Reactor (IFR) is a fast reactor system developed at Argonne National Laboratory in the decade 1984 to 1994. The IFR project developed the technology for a complete system the reactor, the entire fuel cycle and the waste management technologies were all included in the development program. The reactor concept had important features and characteristics that were completely new and fuel cycle and waste management technologies that were entirely new developments. The reactor is a fast reactor - that is, the chain reaction is maintained by fast neutrons with high energy - which produces its own fuel. The IFR reactor and associated fuel cycle is a closed system. Electrical power is generated, new fissile fuel is produced to replace the fuel burned, its used fuel is processed for recycling by pyroprocessing - a new development - and waste is put in final form for disposal. All this is done on one self-sufficient site. The scale and duration of the project and its funding made it the largest nuclear energy R and D program of its day. Its purpose was the development of a long term massive new energy source, capable of meeting the nation\'s electrical energy needs in any amount, and for as long as it is needed, forever, if necessary. Safety, non-proliferation and waste toxicity properties were improved as well, these three the characteristics most commonly cited in opposition to nuclear power. Development proceeded from success to success. Most of the development had been done when the program was abruptly cancelled by the newly elected Clinton Administration. In his 1994 State of the Union address the president stated that unnecessary programs in advanced reactor development will be terminated. The IFR was that program. This book gives the real story of the IFR, written by the two nuclear scientists who were most deeply involved in its conception, the development of its R and D program, and its management. Between the scientific and engineering papers and reports, and books on the IFR, and the non-technical and often impassioned dialogue that continues to this day on fast reactor technology, we felt there is room for a volume that, while accurate technically, is written in a manner accessible to the non-specialist and even to the non-technical reader who simply wants to know what this technology is. The Integral Fast Reactor (IFR) is a fast reactor system developed at Argonne National Laboratory in the decade 1984 to 1994. The IFR project developed the technology for a complete system the reactor, the entire fuel cycle and the waste management technologies were all included in the development program. The reactor concept had important features and characteristics that were completely new and fuel cycle and waste management technologies that were entirely new developments. The reactor is a fast reactor - that is, the chain reaction is maintained by fast neutrons with high energy - which produces its own fuel. The IFR reactor and associated fuel cycle is a closed system. Electrical power is generated, new fissile fuel is produced to replace the fuel burned, its used fuel is processed for recycling by pyroprocessing - a new development - and waste is put in final form for disposal. All this is done on one self-sufficient site. The scale and duration of the project and its funding made it the largest nuclear energy R and D program of its day. Its purpose was the development of a long term massive new energy source, capable of meeting the nation\'s electrical energy needs in any amount, and for as long as it is needed, forever, if necessary. Safety, non-proliferation and waste toxicity properties were improved as well, these three the characteristics most commonly cited in opposition to nuclear power. Development proceeded from success to success. Most of the development had been done when the program was abruptly cancelled by the newly elected Clinton Administration. In his 1994 State of the Union address the president stated that unnecessary programs in advanced reactor development will be terminated. The IFR was that program. This book gives the real story of the IFR, written by the two nuclear scientists who were most deeply involved in its conception, the development of its R and D program, and its management. Between the scientific and engineering papers and reports, and books on the IFR, and the non-technical and often impassioned dialogue that continues to this day on fast reactor technology, we felt there is room for a volume that, while accurate technically, is written in a manner accessible to the non-specialist and even to the non-technical reader who simply wants to know what this technology is.