基于声线法与SEA的海上平台噪声联合仿真方法

doi:10.16265/j.cnki.issn1003-3033.2026.04.0187

摘要/Abstract

摘要：

为精准预测海上平台噪声分布以防治职业噪声危害,针对传统单一噪声预测方法难以兼顾结构声与空气声传播特性、无法细致描述大尺度空间声场分布的问题,提出融合声线法与统计能量分析(SEA)的联合仿真方法。该方法采用SEA模拟结构声传播特征,通过声线法精细化模拟甲板大空间空气声传播特征。以某海上中心平台为研究对象,基于实测振动与噪声源强数据构建联合仿真模型,仿真计算各层甲板声场分布,并通过空间网格化噪声测试验证方法有效性。结果表明:海上平台各层甲板噪声总能量中,空气声能量贡献占比超50%,高于结构声;大尺寸设备、生产区用房及防火墙等障碍物对噪声遮挡作用显著,空气声传播对甲板空间声场分布影响更为突出;联合仿真结果与实测结果吻合良好,预测与测试数据整体平均差异在2 dB之内,可实现海上平台甲板空间声场分布的高精度预测。

关键词: 声线法, 统计能量分析(SEA), 海上平台噪声, 联合仿真, 空气声, 结构声

Abstract:

In order to accurately predict the noise distribution of offshore platforms to prevent occupational noise hazards, a joint simulation method combining the sound ray method and SEA method was proposed to solve the problem that the traditional single noise prediction method was difficult to take into account the structural sound and air sound propagation characteristics and could not describe the large-scale spatial sound field distribution in detail. In this method, SEA was used to simulate the acoustic propagation characteristics of the structure, and the acoustic propagation law of the air in the large space of the deck was simulated by the sound ray method. Taking an offshore central platform as the research object, a joint simulation model was constructed based on the measured vibration and noise source intensity data. The sound field distribution of each deck was simulated and calculated, and the effectiveness of the method was verified by a spatial grid noise test. The results show that the contribution of air acoustic energy to the total noise energy of each deck of the offshore platform is more than 50 %, which is higher than that of structural acoustic energy. Obstacles such as large-scale equipment, production area rooms and firewalls have a significant effect on noise shielding, and air sound propagation has a more prominent impact on the spatial sound field distribution of the deck, the joint simulation results are in good agreement with the measured results, and the overall average difference between the prediction and the test data is within 2 dB, which can realize the high-precision prediction of the spatial sound field distribution of the offshore platform deck.

Key words: sound ray tracing method, statistical energy analysis(SEA), offshore platform noise, joint simulation, air sound, structural sound

中图分类号:

X966
TB535

张悦, 刘涛, 康钟绪, 周伟, 吴瑞, 陈坤亮. 基于声线法与SEA的海上平台噪声联合仿真方法[J]. 中国安全科学学报, 2026, 36(4): 262-270.

Zhang Yue, Liu Tao, Kang Zhongxu, Zhou Wei, Wu Rui, Chen Kunliang. Joint simulation method of offshore platform noise based on sound ray tracing method and SEA[J]. China Safety Science Journal, 2026, 36(4): 262-270.

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设备	透平发电机组A	透平发电机组C	高压压缩机	中压压缩机
加速度振级	119.4	116.1	135.8	134.9
设备	低压压缩机	制氮空压机	空压机	注水泵
加速度振级	146.4	115.7	123.2	129.7
设备	原油外输泵	注水增压泵	开排罐泵	热介质排放罐泵
加速度振级	126.3	137.1	136.8	122.3

设备	注水泵	原油外输泵	高压压缩机	中压压缩机
声功率	110.3	110.1	118.5	118.6
设备	低压压缩机	制氮空压机	空压机	通风风机
声功率	119.1	110.2	111.3	110.8
设备	透平发电机组A	透平发电机组C	注水增压泵	—
声功率	125.7	127.0	106.6	—

海上平台	下层平台	中层平台	上层平台
差异/dB(A)	1.497	-1.903	-1.299
网格数据/对	120	131	107