Thermal Stress Analysis of Transversally Corrugated Tube in Solar Receiver Under Semi-Circumference Heating

doi:10.12096/j.2096-4528.pgt.23126

Abstract

Abstract:

Objective In daily operation, the outer wall of solar receiver tube is subjected to uneven heat flux between the inner and outer sides at cylindrical receiver, which leads to the uneven distribution of wall temperature and large temperature gradient. It is easy to generate high thermal stress, which causes the deformation and structural damage of receiver tube. Therefore, the thermal stress of the transversally corrugated tube in the cylindrical receiver is studied. Methods The three-dimensional model of the transversally corrugated tube is established by Design Modeler in Ansys, and the mesh is divided by Mesh. The thermal stress of the transversally corrugated tube under semi-circumference heating is numerically simulated by Fluent. Results The outer wall thermal stress at high heat flux side of the tube is the largest, and the wall thermal stress at the junction of the high and low heat flux surfaces is the lowest. The thermal stress value at the groove section of transversally corrugated tube is larger than that of the smooth section. For the same groove width, the groove depth is deeper, and the maximum equivalent thermal stress on the groove section is bigger. For the same groove depth, the groove width is wider, and the maximum equivalent thermal stress is smaller. The maximum equivalent thermal stress of the transversally corrugated tube increases with the rise of molten salt inlet temperature, and the maximum equivalent thermal stress reduces with the increase of molten salt inlet flow rate. Conclusion Through the thermal stress analysis, it can be seen that the influence law of the thermal stress on transversally corrugated tube changes with heat flux, groove depth and width, inlet temperature and inlet flow rate, which is of great significance to prolong the service life of the cylindrical receiver.

Key words: solar thermal power, solar receiver, cylindrical receiver, transversally corrugated tube, thermal stress, molten salt, numerical simulation

CLC Number:

TK 513.3

Xianmin ZENG, Boyun LI, Xiangyang SHEN, Jiashu CHEN, Lixing DING. Thermal Stress Analysis of Transversally Corrugated Tube in Solar Receiver Under Semi-Circumference Heating[J]. Power Generation Technology, 2025, 46(1): 190-199.

Figures/Tables 13

Fig. 1 Physical model of a transversally corrugated tube under semi-circumference heating

Tab. 1 Physical properties of stainless steel 316L

热膨胀系数/

℃^-1

Fig. 2 Grid of the transversally corrugated tube

Fig. 3 Relationship between the Nu of molten salt heat transfer and the number of grids

Fig. 4 Comparison of Nu simulated value with experimental value

Fig. 5 Seven typical positions for a pitch of transversally corrugated tube

Fig. 6 Temperature and thermal stress distribution in the cross-section of transversally corrugated tube

Tab. 2 Parameters of groove width and groove depth for transversally corrugated tubes

横纹管	槽宽P₁/mm	槽深e/mm
1号管(T1-a)	4.3	0.45
2号管(T1-b)	4.3	0.70
3号管(T1-c)	4.3	0.95
4号管(T2-a)	7.3	0.45
5号管(T2-b)	7.3	0.70
6号管(T2-c)	7.3	0.95

Fig. 7 Maximum values of the three major stresses in cross-section at a pitch of transversally corrugated tube

Fig. 8 Maximum values of equivalent thermal stress in cross-section at a pitch for differently structured transversally corrugated tubes

Fig. 9 Comparison of the maximum equivalent thermal stress with transversally corrugated tube and smooth circular tube

Fig. 10 Effect of molten salt temperature on the maximum equivalent thermal stress of transversally corrugated tube

Fig. 11 Effect of molten salt flow rate on the maximum equivalent thermal stress of transversally corrugated tube

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