基于等效线性化的核电厂频域隔震分析方法研究

甘莹莹; 刘子乔; 王东洋; 孙晓颖

doi:10.11899/zzfy20240116

基于等效线性化的核电厂频域隔震分析方法研究

doi: 10.11899/zzfy20240116

甘莹莹^1,,
刘子乔¹,
王东洋¹,
孙晓颖^{1, 2, ,}

1.
中国核电工程有限公司, 核安全结构技术研究中心, 北京 100840
2.
中国地震局工程力学研究所, 中国地震局地震工程与工程振动部门重点实验室, 哈尔滨 150080

基金项目: 中国核电工程有限公司自主研发课题（2024KY23111）

详细信息

作者简介:
甘莹莹，女，生于1993年。硕士研究生，工程师。主要从事核电厂抗震/隔震研究。E-mail：1534090690@qq.com

通讯作者:
孙晓颖，女，生于1980年。正高级工程师。主要从事核电厂抗震/隔震研究。E-mail：sunxy@cnpe.cc

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出版历程
- 收稿日期: 2022-09-20
- 刊出日期: 2024-03-31

Research on Frequency Domain Analysis Method Based on Equivalent Linearization for a Base-isolated Nuclear Power Plant

1.
Research Center for Nuclear Safety Related Structural Engineering and Technology, China Nuclear Power Engineering Co., Ltd, Beijing 100840, China
2.
Key Laboratory of Earthquake Engineering and Engineering Vibration, Institute of Engineering Mechanics, China Earthquake Administration, Harbin 150080, China

摘要

摘要: 在核电构筑物土-结构相互作用（SSI）分析中常用的方法是子结构法，这是由于其采用半解析法地基模拟技术，具有求解速度快、分析系统频率稳定的优势。因此，可在隔震核电厂房楼层反应谱计算中采用子结构法。因隔震支座具有明显的非线性特征，而子结构法基于叠加原理，在求解非线性问题时具有局限性，为了能够采用子结构法求解隔震核电厂房地震响应问题，基于等效线性化理念，在子结构法中实现隔震支座非线性行为模拟，并用SAP 2000软件验证本方法的可行性。将该方法应用于不同地基参数下隔震厂房反应谱计算，将得到的反应谱与采用隔震支座等效刚度计算结果进行对比。研究结果表明，在子结构法中应用等效线性化方法得到的隔震支座滞回曲线与采用SAP2000软件得到的滞回曲线基本一致，证明该方法是可行的；与采用等效刚度计算结果相比，采用迭代收敛刚度计算出的零周期加速度变化较小，主频略降低，峰值略有提高；由于隔震系统卓越频率与场地卓越频率并不接近，因此隔震结构楼层反应谱对地基参数的变化并不敏感。
- 核电厂 /
- 子结构法 /
- 隔震支座 /
- 等效线性化
Abstract: Sub-structuring method is generally used in the soil-structure interaction (SSI) analysis for nuclear structures due to that such method is of the semi-analytic foundation simulation technique, the high calculation efficiency and constant damping of the whole analysis system. Therefore, the sub-structuring method can be adopted in SSI analysis for base-isolated buildings. However, the sub-structuring method has limitations to solve base-isolation problem because it bases on the superposition theory while the isolation bearing has significant non-linear characteristic. To solve this problem, we simulate the nonlinear behavior of the isolation bearing based on the concept of equivalent linearization in sub-structuring method and verify its feasibility by using SAP2000. In this paper, the method was applied to the in-structure response spectrum (ISRS) calculation of a base-isolated nuclear building under different site conditions, and the results were compared with those from the calculation using the equivalent stiffness of bi-linear constitutive model of the bearing. Our results show that the hysteresis curve of the isolation bearing obtained by the sub-structuring method is basically consistent with that from the nonlinear calculation in SAP2000, which proves that the method is reasonable and feasible. Compared with the ISRS obtained by using the equivalent stiffness, the zero-period acceleration of the ISRS obtained by using the convergent stiffness do not change too much, and the dominant frequencies decreased with slight increase of the peak acceleration. The ISRS of the base-isolated structure is not sensitive to the change of the site conditions since the predominant frequency of the isolation system is not close to the predominant frequencies of the sites.
- Nuclear power plant /
- Sub-structuring method /
- Isolation bearing /
- Equivalent linearization

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图 1 子结构法SSI分析系统示意

Figure 1. Schematic diagram of SSI analysis system in sub-structuring method

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图 2 铅芯橡胶支座滞回曲线

Figure 2. Hysteretic curve of the lead rubber bearing

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图 3 等效线性化验证模型

Figure 3. Verification model of equivalent linearization

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图 4 ACS SASSI与SAP2000软件得到的相同位置支座剪力时程响应对比

Figure 4. Comparison of shear force time history response of the bearings in the same position between ACS SASSI and SAP2000

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图 5 ACS SASSI与SAP2000软件得到的相同位置支座剪切变形时程响应对比

Figure 5. Comparison of shear deformation time history response of the bearings in the same position between ACS SASSI and SAP2000

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图 6 ACS SASSI与SAP2000得到的角部支座滞回曲线对比

Figure 6. Comparison of hysteretic curves of the bearings in the same position between ACS SASSI and SAP2000

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图 7 ACS SASSI与SAP2000软件得到的标高−26.000 m加速度时程响应对比

Figure 7. Comparison of acceleration time history response of elevation −26.000 m between ACS SASSI and SAP2000

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图 8 反应堆厂房隔震方案示意（单位：米）

Figure 8. Base-isolation scheme of the reactor building（Unit: m）

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图 9 隔震层布置方案（单位：毫米）

Figure 9. The layout plan of isolation layer（Unit：mm）

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图 10 输入地震动加速度时程曲线

Figure 10. The time- acceleration curve of input ground motion

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图 11 输入地震动加速度反应谱

Figure 11. The acceleration spectrum of input ground motion

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图 12 有限元模型及结构响应输出位置示意

Figure 12. Finite element model and output position of structure response

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图 13 不同弹簧刚度得到的节点3楼层反应谱对比（硬岩厂址）

Figure 13. Comparison of ISRSs among different spring stiffness for node 3 （Hard rock）

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图 14 不同弹簧刚度得到的节点3楼层反应谱对比（中硬岩厂址）

Figure 14. Comparison of ISRSs among different spring stiffness for node 3 （Medium hard rock）

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图 15 不同弹簧刚度得到的节点3楼层反应谱对比（软土厂址）

Figure 15. Comparison of ISRSs among different spring stiffness for node 3 （Soft soil）

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图 16 不同弹簧刚度得到的节点4楼层反应谱对比（硬岩厂址）

Figure 16. Comparison of ISRSs among different spring stiffness for node 4 （Hard rock）

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图 17 不同弹簧刚度得到的节点4楼层反应谱对比（中硬岩厂址）

Figure 17. Comparison of ISRSs among different spring stiffness for node 4 （Medium hard rock）

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图 18 不同弹簧刚度得到的节点4楼层反应谱对比（软土厂址）

Figure 18. Comparison of ISRSs among different spring stiffness for node 4 （Soft soil）

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表 1 典型厂址特征参数

Table 1. Characteristic parameters of three typical plant sites

参数	硬岩	中硬岩	软土
剪切波速v_s/（m·s⁻¹）	2 166	1 311	407
压缩波速v_p/（m·s⁻¹）	3 970	2 613	1 158
水平向阻尼比	0.051	0.063	0.08
竖向阻尼比	0.051 5	0.063	0.08
密度ρ/（kg·m⁻³）	2 667	2 383	1 920

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