热水供热管道泄漏声波特性与传播规律
摘要:直埋供热管道泄漏点的非开挖精准定位是城市集中供热管网安全高效运行的重要保障。采用数值模拟与实验相结合的方法,基于声波法研究了热水供热管道的泄漏声波特性与传播规律,模拟了不同水压、水温及泄漏孔径条件下热水供热管道泄漏时流体声场特征,并进行了实验验证。结果表明:热水供热管道泄漏管内流体声信号主频段为0~20 Hz;泄漏量与声压级随水压与泄漏孔径的增大而增大,随水温升高而略有减小;声压级随传播距离与管径的增大而衰减,声压级随传播距离的增大呈现快速衰减段和稳定段,在距泄漏孔1 m之外为稳定段。
关键词:供热管道泄漏声波传播声压级主频段水压
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参考文献参考文献
[1] 国家统计局.中国统计年鉴2020[M].北京:中国统计出版社,2020:25-27.
[2] 邹平华,雷翠红,王威.热网故障与提高热网可靠性的措施[J].暖通空调,2008,38(11):7-12.
[3] 刘勇,徐金锋.地下供热管道漏点检测方法[J].区域供热,2019(2):5-8.
[4] 马晓华.直埋供热管网泄漏原因分析及检测[J].区域供热,2019(2):1-4.
[5] 赵钊,于璐,张正雄.城市燃气泄漏示踪剂检测应用及适用性探讨[J].城市燃气,2019(12):22-29.
[6] 曹煜,于润桥,夏桂锁,等.热力管道磁-温综合检测技术[J].南昌航空大学学报(自然科学版),2015,29(1):94-99.
[7] 吴晋湘,王彦逍,赵涛,等.基于土壤温湿度的埋地供热管道泄漏检测方法[J].暖通空调,2018,48(9):58-62.
[8] 袁朝庆,刘迎春,刘燕,等.光纤光栅在热力管道泄漏检测中的应用[J].无损检测,2010,32(10):791-794,8.
[9] 赵卫星,夏桂锁,于润桥,等.弱磁热力管道安全评价技术研究[J].南昌航空大学学报(自然科学版),2018,32(4):93-98,116.
[10] 耿雪.供水管道漏损的声波检测实验研究[D].天津:天津大学,2014:4-7.
[11] 王威,邹平华,雷翠红.环形供热管网小负荷支线当量化方法及对管网可靠性设计的影响[J].暖通空调,2008,38(10):23-27.
[12] SANTOS P,AZEVEDO P T,RAMOS J,et al.An LPV modeling and identification approach to leakage detection in high pressure natural gas transportation networks[J].Control systems technology,2011,19(1):77-92.
[13] SONG J,LI S,WANG Z,et al.Study on detection and location of mobile oil pipeline leakage based on pressure gradient method[J].Advanced materials research,2012,580:395-400.
[14] 杨开林,郭宗周,汪勋,等.热力管网泄漏检测数学模型[J].水利学报,1996(5):50-56.
[15] 李旦.长输原油管道泄漏检测定位研究[D].西安:西安石油大学,2013:9-12.
[16] HUNAIDI O,CHU W T.Acoustical characteristics of leak signals in plastic water distribution pipes[J].Applied acoustics,1999,58(3):235-254.
[17] WAN Q,KOCH D B,ELECTRIC I O,et al.Multichannel spectral analysis for tube leak detection[C]∥IEEE Southeastern'93,1993:4-7.
[18] 闫成稳,韩宝坤,鲍怀谦,等.气体管道泄漏声源特性研究[J].声学技术,2017,36(2):110-115.
[19] 闫成稳.输气管道泄漏声源特性研究[D].青岛:山东科技大学,2017:13-22.
[20] 李玉星.天然气输送管道的泄漏检测与定位[M].青岛:中国石油大学出版社,2015:52-78.
[21] 刘翠伟,李雪洁,李玉星,等.基于音波法的输气管道泄漏检测与定位[J].化工学报,2014,65(11):4633-4642.
[22] 孟令雅,李玉星,宋立群,等.输气管道泄漏音波传播特性及监测定位[J].天然气工业,2010,30(11):74-79,123.
[23] EL-ZAHAB S,MOHAMMED A E,ZAYED T.An accelerometer-based leak detection system[J].Mechanical systems and signal processing,2018,108:276-291.
[24] LIU C W,LI Y,FANG L,et al.Experimental study on a de-noising system for gas and oil pipelines based on an acoustic leak detection and location method[J].International journal of pressure vessels and piping,2017,151(16):20-34.
[25] WANG K,HU Y,QIN M,et al.A leakage particlewall impingement based vibro-acoustic characterization of the leaked sand-gas pipe flow[J].Particuology,2021,55:84-93.
[26] 付俊涛,李玉星,李雨桐,等.输气管道泄漏音波的产生及传播特性[J].油气储运,2012,31(8):604-611,647.
[27] 北京市煤气热力工程设计院有限公司.城镇供热管网设计规范:CJJ 34-2010[S].北京:中国建筑工业出版社,2010:10.
[28] 张曼,张立申,王随林,等.供热管道泄漏流场/声源特性及其变化规律[J].消防科学与技术,2021,40(3):312-318.
[29] 刘翠伟,李玉星,王武昌,等.输气管道声波法泄漏检测技术的理论与实验研究[J].声学学报,2013,38(3):372-381.
[30] 王福军.计算流体动力学分析:CFD软件原理与应用[M].北京:清华大学出版社,2004:32-40.
[31] 刘翠伟,李玉星,王武昌,等.输气管道气体流经阀门气动噪声产生机理分析[J].振动与冲击,2014,33(2):152-157.
[32] 孟令雅,刘翠伟,李玉星,等.输气管道气动噪声产生机制及其分析方法[J].中国石油大学学报(自然科学版),2012,36(6):128-136.
[33] 金浩,张来斌,梁伟,等.天然气管道泄漏声源特性及传播机理数值模拟[J].石油学报,2014,35(1):172-177.
[1] 国家统计局.中国统计年鉴2020[M].北京:中国统计出版社,2020:25-27.
[2] 邹平华,雷翠红,王威.热网故障与提高热网可靠性的措施[J].暖通空调,2008,38(11):7-12.
[3] 刘勇,徐金锋.地下供热管道漏点检测方法[J].区域供热,2019(2):5-8.
[4] 马晓华.直埋供热管网泄漏原因分析及检测[J].区域供热,2019(2):1-4.
[5] 赵钊,于璐,张正雄.城市燃气泄漏示踪剂检测应用及适用性探讨[J].城市燃气,2019(12):22-29.
[6] 曹煜,于润桥,夏桂锁,等.热力管道磁-温综合检测技术[J].南昌航空大学学报(自然科学版),2015,29(1):94-99.
[7] 吴晋湘,王彦逍,赵涛,等.基于土壤温湿度的埋地供热管道泄漏检测方法[J].暖通空调,2018,48(9):58-62.
[8] 袁朝庆,刘迎春,刘燕,等.光纤光栅在热力管道泄漏检测中的应用[J].无损检测,2010,32(10):791-794,8.
[9] 赵卫星,夏桂锁,于润桥,等.弱磁热力管道安全评价技术研究[J].南昌航空大学学报(自然科学版),2018,32(4):93-98,116.
[10] 耿雪.供水管道漏损的声波检测实验研究[D].天津:天津大学,2014:4-7.
[11] 王威,邹平华,雷翠红.环形供热管网小负荷支线当量化方法及对管网可靠性设计的影响[J].暖通空调,2008,38(10):23-27.
[12] SANTOS P,AZEVEDO P T,RAMOS J,et al.An LPV modeling and identification approach to leakage detection in high pressure natural gas transportation networks[J].Control systems technology,2011,19(1):77-92.
[13] SONG J,LI S,WANG Z,et al.Study on detection and location of mobile oil pipeline leakage based on pressure gradient method[J].Advanced materials research,2012,580:395-400.
[14] 杨开林,郭宗周,汪勋,等.热力管网泄漏检测数学模型[J].水利学报,1996(5):50-56.
[15] 李旦.长输原油管道泄漏检测定位研究[D].西安:西安石油大学,2013:9-12.
[16] HUNAIDI O,CHU W T.Acoustical characteristics of leak signals in plastic water distribution pipes[J].Applied acoustics,1999,58(3):235-254.
[17] WAN Q,KOCH D B,ELECTRIC I O,et al.Multichannel spectral analysis for tube leak detection[C]∥IEEE Southeastern'93,1993:4-7.
[18] 闫成稳,韩宝坤,鲍怀谦,等.气体管道泄漏声源特性研究[J].声学技术,2017,36(2):110-115.
[19] 闫成稳.输气管道泄漏声源特性研究[D].青岛:山东科技大学,2017:13-22.
[20] 李玉星.天然气输送管道的泄漏检测与定位[M].青岛:中国石油大学出版社,2015:52-78.
[21] 刘翠伟,李雪洁,李玉星,等.基于音波法的输气管道泄漏检测与定位[J].化工学报,2014,65(11):4633-4642.
[22] 孟令雅,李玉星,宋立群,等.输气管道泄漏音波传播特性及监测定位[J].天然气工业,2010,30(11):74-79,123.
[23] EL-ZAHAB S,MOHAMMED A E,ZAYED T.An accelerometer-based leak detection system[J].Mechanical systems and signal processing,2018,108:276-291.
[24] LIU C W,LI Y,FANG L,et al.Experimental study on a de-noising system for gas and oil pipelines based on an acoustic leak detection and location method[J].International journal of pressure vessels and piping,2017,151(16):20-34.
[25] WANG K,HU Y,QIN M,et al.A leakage particlewall impingement based vibro-acoustic characterization of the leaked sand-gas pipe flow[J].Particuology,2021,55:84-93.
[26] 付俊涛,李玉星,李雨桐,等.输气管道泄漏音波的产生及传播特性[J].油气储运,2012,31(8):604-611,647.
[27] 北京市煤气热力工程设计院有限公司.城镇供热管网设计规范:CJJ 34-2010[S].北京:中国建筑工业出版社,2010:10.
[28] 张曼,张立申,王随林,等.供热管道泄漏流场/声源特性及其变化规律[J].消防科学与技术,2021,40(3):312-318.
[29] 刘翠伟,李玉星,王武昌,等.输气管道声波法泄漏检测技术的理论与实验研究[J].声学学报,2013,38(3):372-381.
[30] 王福军.计算流体动力学分析:CFD软件原理与应用[M].北京:清华大学出版社,2004:32-40.
[31] 刘翠伟,李玉星,王武昌,等.输气管道气体流经阀门气动噪声产生机理分析[J].振动与冲击,2014,33(2):152-157.
[32] 孟令雅,刘翠伟,李玉星,等.输气管道气动噪声产生机制及其分析方法[J].中国石油大学学报(自然科学版),2012,36(6):128-136.
[33] 金浩,张来斌,梁伟,等.天然气管道泄漏声源特性及传播机理数值模拟[J].石油学报,2014,35(1):172-177.
Acoustic wave characteristics and propagation law of hot water heating pipeline leakage
Abstract: The precise location of the leakage point of the directly buried heating pipeline without excavation is an important guarantee for the safe and efficient operation of the urban central heating pipeline network. Using the method of numerical simulation and experiment, this paper studies the leakage acoustic wave characteristics and propagation law of hot water heating pipelines based on the acoustic wave method, simulates the characteristics of the fluid sound field when the hot water heating pipeline leaks under the conditions of different water pressure, water temperature and leakage aperture, and verifies them by experiments. The results show that the main frequency band of the fluid sound signal in the leakage pipe of the hot water heating pipeline is 0 to 20 Hz. The leakage volume and sound pressure level increase with the increase of water pressure and leakage aperture, and decrease slightly with the increase of water temperature. The sound pressure level attenuates with the increase of propagation distance and pipe diameter, the sound pressure level presents a rapid attenuation section and a stable section with the increase of propagation distance, and it is a stable section 1 m away from the leakage hole.
Keywords: heating pipeline; leakage; acoustic wave; propagation; sound pressure level; main frequency band; water pressure;
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