两相流振动测试系统中换热管圆周压力的测试方法

doi:10.16085/j.issn.1000-6613.2024-0541

摘要/Abstract

摘要：

热交换器作为化工中重要的换能设备，管束的流致振动（FIV）成为诱发管束振动破裂的重要因素，其安全可靠性变得尤为重要。工程上计算FIV导致的振动响应时，需先确定流体力的功率谱密度（PSD），而这需要大量的流体力的测试数据。本文设计特殊结构换热管，利用电子压力扫描阀在两相流振动测试系统中进行了实验，并利用可靠的加速度传感器测试进行验证。结果表明，本文测试方法能够对两相流条件下管束受到的流体压力进行准确测量，并且不会对管周流场产生影响。含气率较低时存在旋涡脱落现象，含气率的升高会破坏旋涡的形成，加剧管束湍流抖振时的振动损伤。利用两种转化方法得到的量纲为1参考等效功率谱密度高度一致，并将实验获得的功率谱密度与其他学者确定的量纲为1参考等效功率谱密度进行了对比，多组实验数据与本文转化的功率谱密度重叠，数据整体趋势相同，验证了本文测试方法的合理性。本文测试方法能够为蒸汽发生器的设计、运行、维护、结构改进以及安全性评估提供基础数据支撑。

关键词: 两相流, 流体力学, 电子压力扫描阀, 功率谱密度, 换热管

Abstract:

Heat exchangers, as vital energy conversion devices in chemical engineering, face significant challenges due to flow-induced vibrations (FIV) of tube bundles, which are a crucial factor in inducing vibration fractures. The safety and reliability of these systems become particularly critical. In engineering calculations of the vibrational response caused by FIV, it is necessary first to determine the power spectral density (PSD) of the fluid excitation forces, which requires extensive testing data of the fluid excitation forces. This paper designed a special structure heat exchanger tube and conducted experiments in a two-phase flow water tunnel using an electronic pressure scanning valve, validated by reliable accelerometer testing methods. The results demonstrated that the testing method proposed in this paper could accurately measure the fluid pressure exerted on the tube bundles under two-phase flow conditions without affecting the surrounding flow field. At lower gas content, vortex shedding occurred, and both lift and drag increased with rising gas content. An increase in gas content disrupted vortex formation, exacerbating vibration damage during turbulent flutter of the tube bundles. The dimensionless reference equivalent power spectral densities obtained using two conversion methods were highly consistent. The experimentally obtained PSDs were compared with the dimensionless reference equivalent PSDs determined by other researchers, showing overlapping data sets and similar overall trends, thus validating the rationality of the testing method described in this paper. This testing method could provide foundational data support for the design, operation, maintenance, structural improvement, and safety assessment of steam generators.

Key words: two-phase flow, fluid mechanics, electronic pressure scanning valve, power spectral density, heat exchange tube

中图分类号:

TQ053

齐思久, 谭蔚, 蔺文静, 韩佩泽, 朱国瑞. 两相流振动测试系统中换热管圆周压力的测试方法[J]. 化工进展, 2024, 43(S1): 85-93.

QI Sijiu, TAN Wei, LIN Wenjing, HAN Peize, ZHU Guorui. Test method for fluid excitation force around a heat exchange tube in a two-phase flow tunnel[J]. Chemical Industry and Engineering Progress, 2024, 43(S1): 85-93.

图/表 10

参考文献 12

1	SADEK Omar, MOHANY Atef, HASSAN Marwan. The prediction of fluidelastic forces in triangular tube bundles subjected to a two-phase flow: The effect of the flow approach angle[J]. Journal of Fluids and Structures, 2021, 106: 103386.
2	PETTIGREW M J, TAYLOR C E, FISHER N J, et al. Flow-induced vibration: Recent findings and open questions[J]. Nuclear Engineering and Design, 1998, 185(2/3): 249-276.
3	PETTIGREW M J, TAYLOR C E. Fluidelastic instability of heat exchanger tube bundles: Review and design recommendations[J]. Journal of Pressure Vessel Technology, 1991, 113(2): 242-256.
4	TAYLOR C E, PETTIGREW M J, CURRIE I G. Random excitation forces in tube bundles subjected to two-phase cross-flow[J]. Journal of Pressure Vessel Technology, 1996, 118(3): 265-277.
5	PETTIGREW M J, GORMAN D J. Vibration of heat exchanger tube bundles in liquid and two-phase cross-flow[J]. American Society of Mechanical Engineers, 1981, 52: 89-110.
6	CHEN S S, JENDRZEJCZYK J A. Fluid excitation forces acting on a square tube array[J]. Journal of Fluids Engineering, 1987, 109(4): 415-423.
7	TAYLOR C E, PETTIGREW M J, AXISA F, et al. Experimental determination of single and two-phase cross flow-induced forces on tube rows[J]. Journal of Pressure Vessel Technology, 1988, 110(1): 22-28.
8	侯峰, 张奭, 刘瑞, 等. 低温多效海水淡化蒸发器换热管振动监测与分析[J]. 噪声与振动控制, 2022, 42(1): 150-155, 161.
	HOU Feng, ZHANG Shi, LIU Rui, et al. Vibration monitoring and analysis of heat exchange tube of low temperature multi-effect seawater desalination evaporators[J]. Noise and Vibration Control, 2022, 42(1): 150-155, 161.
9	姜乃斌, 臧峰刚, 张毅雄, 等. 横掠管束的两相流湍流激振力的包络谱研究[J]. 原子能科学技术, 2016, 50(9): 1634-1640.
	JIANG Naibin, ZANG Fenggang, ZHANG Yixiong, et al. Envelope spectral study of two-phase flow turbulent excitation force in a cross-swept tube bundle[J]. Atomic Energy Science and Technology, 2016, 50(9): 1634-1640.
10	AXISA F, VILLARD B, ANTUNES J. Random excitation of heat exchanger tubes by two-phase cross-flows[J]. Journal of Fluids and Structures, 1990, 4(3): 321-341.
11	AXISA F, VILLARD B, GIBERT R J, et al. Vibration of tube bundles subjected to air-water and steam-water cross flow: Preliminary results on fluidelastic instability[C]//Proceedings of the Symposium on Flow-Induced Vibrations, Volume 6: Computational Aspects of Flow-Induced Vibration Presented at the 1984 ASme Winter Annual Meeting, New Orleans, LA, USA, 1984.
12	刘丽艳, 冯家祥, 吴皓, 等. 换热器管束排列角对流体力的影响研究[J]. 压力容器, 2016, 33(12): 13-19, 27.
	LIU Liyan, FENG Jiaxiang, WU Hao, et al. Study on influence of arrangement angle of tube bundle on fluid forces in heat exchangers[J]. Pressure Vessel Technology, 2016, 33(12): 13-19, 27.

名称	规格	参考范围
空气压缩机	GA 37 VSD	最大压力0.95MPa，流量0~360m³∙h^-1
离心泵	ZS100-80-200/37	流量0~240m³∙h^-1，扬程51m
电磁流量计	LDG-SUO-DN150	流量范围0~318m³∙h^-1
电动调节对夹蝶阀	BD941X	电动执行器：BRTEE-16
金属转子流量计	F56/F/S4/P10A/G	量程0~450m³∙h^-1①

名称	规格	参考范围
空气压缩机	GA 37 VSD	最大压力0.95MPa，流量0~360m³∙h^-1
离心泵	ZS100-80-200/37	流量0~240m³∙h^-1，扬程51m
电磁流量计	LDG-SUO-DN150	流量范围0~318m³∙h^-1
电动调节对夹蝶阀	BD941X	电动执行器：BRTEE-16
金属转子流量计	F56/F/S4/P10A/G	量程0~450m³∙h^-1①

名称	型号	数量	主要配置和参数
动态数据采集仪	DH5922	1套	通道数：4通道·卡^-1，共16通道
			采样速率：最高采样速率128kHz
			模数转换器：每通道独立24位模拟数字（A/D）转换器
			供电方式：220V交流电
			系统内置24V·4mA^-1偏置电路
压力扫描阀	KT1608	1套	通道数：16通道
			采样频率：0~500Hz
			压力量程：0~100kPa
			测量介质：无腐蚀性气体、液体、气液混合物
			温度范围：-20~65℃
微小型压电式加速度传感器	3305A	2个	灵敏度：50mV·ms^-2
			量程范围：0~10g
			采样频率范围：0.15~10000Hz
			外形尺寸：10mm×8.1mm×17.8mm
			质量：3.7g

名称	型号	数量	主要配置和参数
动态数据采集仪	DH5922	1套	通道数：4通道·卡^-1，共16通道
			采样速率：最高采样速率128kHz
			模数转换器：每通道独立24位模拟数字（A/D）转换器
			供电方式：220V交流电
			系统内置24V·4mA^-1偏置电路
压力扫描阀	KT1608	1套	通道数：16通道
			采样频率：0~500Hz
			压力量程：0~100kPa
			测量介质：无腐蚀性气体、液体、气液混合物
			温度范围：-20~65℃
微小型压电式加速度传感器	3305A	2个	灵敏度：50mV·ms^-2
			量程范围：0~10g
			采样频率范围：0.15~10000Hz
			外形尺寸：10mm×8.1mm×17.8mm
			质量：3.7g

含气率	折合频率	量纲为1参考等效功率谱密度
80%	0.00775	48.1
	0.00751	40.8
	0.00708	43.8
	0.00796	67.7
	0.00728	71.6
	0.00704	72.8