北京工业大学学报
北京工業大學學報
북경공업대학학보
JOURNAL OF BEIJING POLYTECHNIC UNIVERSITY
2015年
6期
801-808
,共8页
吴斌%方舟%刘增华%何存富
吳斌%方舟%劉增華%何存富
오빈%방주%류증화%하존부
钢花管%扭转模态%有限元仿真%衰减
鋼花管%扭轉模態%有限元倣真%衰減
강화관%뉴전모태%유한원방진%쇠감
perforated pipe%torsional mode%finite element simulation%attenuation
结合有限元仿真与实验研究了钢花管的注浆孔数与孔直径对低频扭转模态T(0,1)衰减特性的影响。首先,理论分析了自由钢管中低频扭转模态的传播特性,然后将有限元仿真、实验得到的不同频率的T(0,1)模态群速度与理论频散曲线进行对比,验证了有限元仿真的正确性及厚度切变型传感器激励T(0,1)模态的有效性。在此基础上,确定了30 kHz为T(0,1)模态检测钢花管的最佳激励频率。仿真与实验研究结果表明:频率30 kHz的T(0,1)模态的信号幅值随注浆孔数的增多与孔直径的增大有不同程度的下降,为利用低频T(0,1)模态对钢花管进行无损检测奠定了基础。
結閤有限元倣真與實驗研究瞭鋼花管的註漿孔數與孔直徑對低頻扭轉模態T(0,1)衰減特性的影響。首先,理論分析瞭自由鋼管中低頻扭轉模態的傳播特性,然後將有限元倣真、實驗得到的不同頻率的T(0,1)模態群速度與理論頻散麯線進行對比,驗證瞭有限元倣真的正確性及厚度切變型傳感器激勵T(0,1)模態的有效性。在此基礎上,確定瞭30 kHz為T(0,1)模態檢測鋼花管的最佳激勵頻率。倣真與實驗研究結果錶明:頻率30 kHz的T(0,1)模態的信號幅值隨註漿孔數的增多與孔直徑的增大有不同程度的下降,為利用低頻T(0,1)模態對鋼花管進行無損檢測奠定瞭基礎。
결합유한원방진여실험연구료강화관적주장공수여공직경대저빈뉴전모태T(0,1)쇠감특성적영향。수선,이론분석료자유강관중저빈뉴전모태적전파특성,연후장유한원방진、실험득도적불동빈솔적T(0,1)모태군속도여이론빈산곡선진행대비,험증료유한원방진적정학성급후도절변형전감기격려T(0,1)모태적유효성。재차기출상,학정료30 kHz위T(0,1)모태검측강화관적최가격려빈솔。방진여실험연구결과표명:빈솔30 kHz적T(0,1)모태적신호폭치수주장공수적증다여공직경적증대유불동정도적하강,위이용저빈T(0,1)모태대강화관진행무손검측전정료기출。
The effect of hole number and the diameter of holes of perforated pipe on the attenuation of torsional guided wave mode, T(0,1), at low frequency is investigated by finite element simulation and experiment. First, propagation characteristics of torsional guided waves at low frequency in free steel pipe are theoretically analyzed. Then, group velocities of T(0,1) mode at different frequencies are obtained by finite element simulation and experiment and compared with theoretical dispersion curve of this mode. Result show that finite element simulation is valid, and the excitability of T(0,1) mode by thickness shear mode transducers is effective. Based on this, the fittest excitation frequency for T(0,1) mode inspection of perforated pipe is confirmed to be 30 kHz. Finally, both finite element simulation and experimental results show that the signal amplitude of T ( 0 , 1 ) mode at 30 kHz decreases in different extents along with the increase of the hole number and the diameter of the hole. These results provide a foundation for nondestructive inspection of perforated pipes by using T(0,1) mode at low frequency.