Availability Designs and Analyses of Solid-state Amplifiers for CiADS
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摘要: ADS加速器面临的一大技术挑战是高可用性要求,进行固态功率源可用性设计是为ADS加速器的可用性设计与分析做准备。首先对CiADS的可用性要求进行了分配,固态功率源的分配结果为0.999;然后对固态功率源进行了初步可用性设计,分析的结果无法满足要求;最后对固态功率源进行了冗余设计,使用Reliasoft软件建立了固态功率源的可靠性框图,分析结果显示:满足一定的维修条件下,当其他元件的平均故障间隔时间(MTBF)达到171 702 h,25/28冗余设计可以满足0.999的可用性要求。
One of the challenging technologies of ADS is the high availability requirement. The availability design of the solid-state amplifier is the preparation for ADS. Firstly the availability requirement of CiADS is proposed as 0.8. The distribution result of the solid-state amplifier is 0.999 according to this requirement. Then the availability result shows the preliminary design of solid-state amplifiers can not reach the availability requirement. At last the power loss is considered to build the k/N redundancy model of the main amplifier and the mean time between failure (MTBF) is calculated for various redundancy models. The reliability block diagram of the solid-state amplifier is set up by Reliasoft and the simulation results show that the 25/28 redundancy model can meet the requirement 0.999 when MTBF of other components reaches 171 702 hours with the certain maintenance.Abstract: One of the challenging technologies of ADS is the high availability requirement. The availability design of the solid-state amplifier is the preparation for ADS. Firstly the availability requirement of CiADS is proposed as 0.8. The distribution result of the solid-state amplifier is 0.999 according to this requirement. Then the availability result shows the preliminary design of solid-state amplifiers can not reach the availability requirement. At last the power loss is considered to build the k/N redundancy model of the main amplifier and the mean time between failure (MTBF) is calculated for various redundancy models. The reliability block diagram of the solid-state amplifier is set up by Reliasoft and the simulation results show that the 25/28 redundancy model can meet the requirement 0.999 when MTBF of other components reaches 171 702 hours with the certain maintenance.-
Key words:
- ADS /
- accelerator /
- solid state amplifiers /
- availability /
- reliability /
- maintainability
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[1] AIT ABDERRAHIMH H, GALAMBOSD J, GOHAR Y, et al. Accelerator and Target Technology for Accelerator Driven Transmutation and Energy Production[R]. United States Department of Energy, 2010. [2] CARMINATI F, KLAPISCH R, REVOL I P, et al. An Energy Amplifier for Cleaner and Inexhaustible Nuclear Energy Production Driven by a Particle Beam Accelerator[R]. Switzerland:CERN, 1993. [3] BOWMAN C D. Annu Rev Nucl Part Sci, 1998, 48:505. [4] ZHAN Wenlong, XU Hushan, Bull Chin Acad Sci, 2012, 27(3):375. (in Chinese) (詹文龙, 徐瑚珊. 中国科学院院刊, 2012, 27(3):375.) [5] WANG Zhijun, HE Yuan, LIU Yong, et al. Chin Phys C, 2012, 36:256. [6] BARGALLO E. IFMIF Accelerator Facility RAMI Analyses Engineering Design Phase[D]. Spain:Polytechnic University of Catalonia, 2014. [7] FILIPPINI R, DELMING B, GUAGLIO G, et al. Reliability Assessment of the LHC Machine Protection System[R]. Switzerland:CERN, Proceedings of PAC05, 2005. [8] JAKUB JANCZYK, ISABELLE LAUGIER, SERGIO PASINELLI, et al. Fault Tracking at the LHC[R]. Switzerland:CERN, EuCARD, 2015. [9] SCHMIDT R. Machine Protection and Interlock Systems for LHC[R]. Switzerland:CERN, EuCARD, 2015. [10] SCHMIDT R. Reliability and Availability of Machine Protection Systems[R]. Switzerland:CERN, U.S. Particle Accelerator School, 2017. [11] GUTLEBER J. FCC Reliability, Availability, Maintainability, Supportability Study[R]. Switzerland:CERN, EuroCirCol, 2017. [12] BARGALLO E. Reliability and Availability at ESS[R]. ESS, 4th International Workshop on ADSR systems and Thorium, 2017. [13] JEAN-LUC BIARROTTE. Reliability challenges for SC linacs as ADS drivers[R]. Switzerland:CERN, 2015. [14] PITIGOI A E,FERNANDEZ R P. Reliability Modeling of an ADS Accelerator[R]. Switzerland::CERN, 2015. [15] MARCHAND P, RUAN T, RIBEIRO F,et al. Phys Rev Accel Beams, 2007, 10:112001. [16] XU Hushan, HE Yuan, PAN Weimin, et al. Design Report of China Initiative Accelerator Driven System[R]. Beijing:Chinese Academy of Sciences. (in Chinese) (徐瑚珊, 何源, 潘卫民, 等.加速器驱动嬗变研究装置可行性研究报告[R]. 北京:中国科学院, 2017.) [17] BARGALLO E, GIRALT A, MARTINEZ G, et al. Fusion Engineering and Design 2013, 88:2732. -
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