科技报告详细信息
Assessment of next generation nuclear plant intermediate heat exchanger design.
Majumdar, S. ; Moisseytsev, A. ; Natesan, K. ; Nuclear Engineering Division
关键词: COOLANTS;    DESIGN;    ELECTRICITY;    GAS TURBINES;    HEAT EXCHANGERS;    HEAT TRANSFER;    HELIUM;    HYDROGEN;    MOLTEN SALTS;    POWER GENERATION;    PRESSURE DROP;    PRINTED CIRCUITS;    TEMPERATURE DISTRIBUTION;    THERMAL CONDUCTION;    THERMAL HYDRAULICS;    TURBINES;    NITROGEN;   
DOI  :  10.2172/946420
RP-ID  :  ANL/EXT-08/32
PID  :  OSTI ID: 946420
Others  :  TRN: US200904%%254
学科分类:再生能源与代替技术
美国|英语
来源: SciTech Connect
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【 摘 要 】

The Next Generation Nuclear Plant (NGNP), which is an advanced high temperature gas reactor (HTGR) concept with emphasis on production of both electricity and hydrogen, involves helium as the coolant and a closed-cycle gas turbine for power generation with a core outlet/gas turbine inlet temperature of 900-1000 C. In the indirect cycle system, an intermediate heat exchanger is used to transfer the heat from primary helium from the core to the secondary fluid, which can be helium, nitrogen/helium mixture, or a molten salt. The system concept for the vary high temperature reactor (VHTR) can be a reactor based on the prismatic block of the GT-MHR developed by a consortium led by General Atomics in the U.S. or based on the PBMR design developed by ESKOM of South Africa and British Nuclear Fuels of U.K. This report has made an assessment on the issues pertaining to the intermediate heat exchanger (IHX) for the NGNP. A detailed thermal hydraulic analysis, using models developed at ANL, was performed to calculate heat transfer, temperature distribution, and pressure drop. Two IHX designs namely, shell and straight tube and compact heat exchangers were considered in an earlier assessment. Helical coil heat exchangers were analyzed in the current report and the results were compared with the performance features of designs from industry. In addition, a comparative analysis is presented between the shell and straight tube, helical, and printed circuit heat exchangers from the standpoint of heat exchanger volume, primary and secondary sides pressure drop, and number of tubes. The IHX being a high temperature component, probably needs to be designed using ASME Code Section III, Subsection NH, assuming that the IHX will be classified as a class 1 component. With input from thermal hydraulic calculations performed at ANL, thermal conduction and stress analyses were performed for the helical heat exchanger design and the results were compared with earlier-developed results on shell and straight tube and printed circuit heat exchangers.

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