Dynamic study on the thermal and stress performances of the molten salt packed-bed thermal storage tank

doi:10.19799/j.cnki.2095-4239.2021.0678

Abstract

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

CLC Number:

TK 513.5

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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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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