填充床熔盐蓄热器的动态温度与应力特性

doi:10.19799/j.cnki.2095-4239.2021.0678

摘要/Abstract

摘要：

建立了填充床熔盐蓄热器的热-力耦合数值模型，基于此模型，研究了多次蓄-放热循环下罐体壁面温度与应力的动态变化特性，并探讨了蓄热罐体产生高温蠕变与塑性屈服的失效区域。结果表明：单次蓄-放热循环中，①壁面温度呈4个阶段的变化趋势，即蓄热时的急剧温升与稳定阶段，放热时的缓慢温降与急剧下降阶段，且大部分罐壁均会产生蠕变现象；②筒节1～5的壁面处于低应力水平的弹性状态，壁板底端存在应力集中导致的塑性屈服现象，且峰值应力在蓄热时呈逐渐上升、放热时逐渐下降的变化趋势；多次蓄-放热循环中，①罐壁最高温度在631～836 K之间呈周期性变化，随着循环次数的增加，处于弹性状态的壁面在低应力与蠕变的作用下损伤累积，增加了蓄热器失效的风险；②内壁面峰值应力在275～423 MPa之间呈周期性变化，使得蓄热罐体可能会产生高应力(大于屈服强度)引起的低周疲劳断裂失效现象。本研究可为开展填充床蓄热器的动态应力疲劳寿命评估提供有效参考方法。

关键词: 太阳能热发电, 熔盐, 填充床蓄热器, 蠕变, 应力

Abstract:

A coupled thermal stress integration model of the molten salt-packed-bed thermal storage tank is developed. The dynamic thermal and stress performances under various charging and discharging cycles are calculated using this model. High-temperature creep and plastic yield failure areas are also explored. For the single cycle, the results demonstrate that ①there exist four variation tendencies of the tank wall temperature: sharply rise and stabilization stages in the charging process, gently decline and sharply decrease stages in the discharging process. Meanwhile, the creep phenomena would occur at the tank's outermost portion. ②The 1-5 shell section walls are in an elastic condition with lower stress levels, resulting in stress concentration at the bottom. Besides, the peak stress presents the first rise and then fall tendencies in the charging and discharging processes, respectively. ①The highest temperature of the tank wall displays a cyclic fluctuation condition between 631 and 836 K over the multiple cycles. Under the impact of decreased stress and creep, damage to the tank wall in the elastic condition would likely accrue, increasing the danger of tank failure. ②Particularly, because the peak stress of the inner wall also varies in the period between 275 and 423 MPa, the low-cycle fatigue fracture failure is induced by the high stress (greater than yield strength) that could occur during the charging and discharging cycles. This research might give a useful reference approach for determining the fatigue life of a packed bed tank under dynamic load.

Key words: concentrating solar power, molten salt, packed-bed thermal storage tank, creep, stress

中图分类号:

TK 513.5

杜保存, 黄丽娟, 雷勇刚, 宋翀芳, 王飞. 填充床熔盐蓄热器的动态温度与应力特性[J]. 储能科学与技术, 2022, 11(7): 2141-2150.

Baocun DU, Lijuan HUANG, Yonggang LEI, Chongfang SONG, Fei WANG. Dynamic study on the thermal and stress performances of the molten salt packed-bed thermal storage tank[J]. Energy Storage Science and Technology, 2022, 11(7): 2141-2150.

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参考文献 18

1	何雅玲, 杜保存, 王坤, 等. 太阳能腔式熔盐吸热器随时空变化的光-热-力耦合一体化方法、机理分析及其失效准则研究[J]. 科学通报, 2017, 62(36): 4308-4321.
	HE Y L, DU B C, WANG K, et al. Study on the coupled photon-thermal-stress integration method, characteristics with time and failure criterion in the solar molten salt cavity receiver[J]. Chinese Science Bulletin, 2017, 62(36): 4308-4321.
2	汪翔, 陈海生, 徐玉杰, 等. 储热技术研究进展与趋势[J]. 科学通报, 2017, 62(15): 1602-1610.
	WANG X, CHEN H S, XU Y J, et al. Advances and prospects in thermal energy storage: A critical review[J]. Chinese Science Bulletin, 2017, 62(15): 1602-1610.
3	GAUTAM A, SAINI R P. A review on sensible heat based packed bed solar thermal energy storage system for low temperature applications[J]. Solar Energy, 2020, 207: 937-956.
4	Libby C. Solar thermocline storage systems: Preliminary design study[R]. Palo Alto, CA: Electric Power Research Institute, 2010.
5	PACHECO J E, SHOWALTER S K, KOLB W J. Development of a molten-salt thermocline thermal storage system for parabolic trough plants[J]. Journal of Solar Energy Engineering, 2002, 124(2): 153-159.
6	尹辉斌, 丁静, 杨晓西. 高温熔融盐斜温层单罐蓄热的热过程特性[J]. 中国电机工程学报, 2013, 33(26): 68-74, 1.
	YIN H B, DING J, YANG X X. Thermal characteristics of the high-temperature molten-salt heat storage process with a thermocline in single tank[J]. Proceedings of the CSEE, 2013, 33(26): 68-74, 1.
7	XU C, WANG Z F, HE Y L, et al. Sensitivity analysis of the numerical study on the thermal performance of a packed-bed molten salt thermocline thermal storage system[J]. Applied Energy, 2012, 92: 65-75.
8	LI M J, QIU Y, LI M J. Cyclic thermal performance analysis of a traditional single-layered and of a novel multi-layered packed-bed molten salt thermocline tank[J]. Renewable Energy, 2018, 118: 565-578.
9	ZHAO B C, CHENG M S, LIU C, et al. Thermal performance and cost analysis of a multi-layered solid-PCM thermocline thermal energy storage for CSP tower plants[J]. Applied Energy, 2016, 178: 784-799.
10	FLUECKIGER S, YANG Z, GARIMELLA S V. An integrated thermal and mechanical investigation of molten-salt thermocline energy storage[J]. Applied Energy, 2011, 88(6): 2098-2105.
11	WANG G, YU S Y, NIU S Q, et al. A comprehensive parametric study on integrated thermal and mechanical performances of molten-salt-based thermocline tank[J]. Applied Thermal Engineering, 2020, 170: 115010.
12	张晓明, 吴玉庭, 张灿灿. 大型熔盐罐结构设计、温度分布与强度分析[J]. 北京工业大学学报, 2021, 47(9): 1064-1073.
	ZHANG X M, WU Y T, ZHANG C C. Temperature distribution and strength analysis of large-scale molten salt thermal storage tank[J]. Journal of Beijing University of Technology, 2021, 47(9): 1064-1073.
13	WAN Z J, WEI J J, QAISRANI M A, et al. Evaluation on thermal and mechanical performance of the hot tank in the two-tank molten salt heat storage system[J]. Applied Thermal Engineering, 2020, 167: 114775.
14	Petroleum Standardization Research Institute. Welded tanks for oil storage: API Std 650 [S]. Washington: American Petroleum Institute, 2013.
15	国家市场监督管理总局, 国家标准化管理委员会. 压力管道规范工业管道第2部分:材料: GB/T 20801.2—2020[S]. 北京: 中国标准出版社, 2020.
	Standardization Administration of the People's Republic of China. Pressure piping code—Industrial piping—Part 2: Materials: GB/T 20801.2—2020[S]. Beijing: Standards Press of China, 2020.
16	ASME Boiler and Pressure Vessel Committee on Nuclear Power. ASME Boiler and pressure vessel code Ⅱ. Materials Part D Properties (Metric)[S]. New York: The American Society of Mechanical Engineers, 2013.
17	吴家龙. 弹性力学[M]. 北京: 高等教育出版社, 2001.
	WU J L. Elasticity[M]. Beijing: Higher Education Press, 2001.
18	姚仰平. 土力学[M]. 2版. 北京: 高等教育出版社, 2011.

筒节名称	高度/m	罐壁厚度/mm	保温层厚度/mm
1	2.0	6	226
2	2.1	12	220
3	2.1	16	216
4	2.1	20	212
5	2.1	26	206
6	2.1	32	200

名称	材料	ρ/(kg/m³)	c_p /[J/(kg·K)]	k/[W/(m·K)]
填料	石英岩	2500	830	5.69
罐体	304不锈钢	7800	470	35
保温层	硅酸铝纤维毡	2000	960	0.1

边界	内容
BC-1	u_in=0.7×10^-3m/s，蓄热时T_in=838 K，放热时T_in=563 K
BC-2	自由出流边界
BC-3	轴对称边界
BC-4	无滑移边界
BC-5	与外界对流换热，T_air=300 K，u_air=5 m/s
BC-6	绝热边界

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