Abstract:Abstract:Research purposes: The vibration amplification (motion at the top was amplified from the bottom motion) of general multistory buildings responding to blasting vibration was analyzed by monitoring structure response of different floors and observing the safety effect of blasting vibration.Additionally, the vibration allowable index for safety and comfort of residential buildings had been put forwardaccording to the usage state.
Research conclusions:(1) When blasting vibration frequency was close to natural frequency of abuilding, the ground blasting vibration would be amplified in the upper portion of this multistory building,while blasting vibration frequency was well above natural frequency of the building, thevibration amplification of multistory building responding to blasting vibration would not easy occur.(2) According to the possibility of vibration amplification of multistory building responding to different vibration sources, suggestions were put forward that blasting vibration monitoring of different floors should be carried out if the building location was more than 100m away from explosion source, but only the vibrationof building bottom could be monitored under high frequency blasting vibration if the building was at a short distance of explosion source.(3) Safety values of controllingblasting vibration of different buildings were proposed according to requirements of building structural safety, decoration materialsafety and indoor comfort. (4) The research results can provide references for blasting vibration controlling in railway stonework blasting excavation.
[1]梁远森,许红,王云昌. 高层建筑结构的自振周期的计算与实测[J]. 河南科学,2005(5):699-703.
Liang Yuansen, Xu Hong, Wang Yunchang. Calculation & Actual Measurement Method on Natural Vibration Period of Tall Buildings[J]. Henan Science, 2005(5):699-703.
[2]李海涛,张富强. 高层建筑结构自振周期的计算方法探讨[J]. 河北建筑工程学院学报,2003(1):67-68.
Li Haitao, Zhang Fuqiang. Approaches to Computing Natural Vibration Period of Tall Building[J]. Journal of Hebei Institute of Architectural Engineering, 2003(1):67-68.
[3]杜兴华. 地铁车站水平地震动力响应分析[J]. 铁道工程学报,2013(6):103-108.
Du Xinghua. Analysis of Dynamic Response of Subway Station under Horizontal Seismic Action[J]. Journal of Railway Engineering Society, 2013(6):103-108.
[4]杨年华,张乐. 爆破振动波叠加数值预测方法[J]. 爆炸与冲击,2012(1): 84-90.
Yang Nianhua, Zhang Le. Blasting Vibration Waveform Prediction Method Based on Superposition Principle[J]. Explosion and Shock Waves, 2012(1): 84-90.
[5]杨年华. 爆破振动理论与测控技术[M]. 北京:中国铁道出版社,2014.
Yang Nianhua. Blasting Vibration Theory & Measurement and Control Technology[M]. Beijing: China Railway Publishing House, 2014. (上接第24页From P.24)[2]蒋忠信, 蒋良潍. 南昆铁路支挡结构主动土压力分布图式[J]. 岩石力学与工程学报, 2005(6):1035-1040.
Jiang Zhongxin, Jiang Liangwei. Distribution Map Forms of Active Earth Pressue on Retaining Structures in Nanning-Kunming Railway[J]. Chinese Journal of Rock Mechanics and Engineering, 2005(6):1035-1040.
[3]蒋楚生. 路肩(堤)式预应力锚索桩板墙柔性支挡结构的土压力分布新探索[J]. 铁道工程学报,2007(4):24-28.
Jiang Chusheng. A New Exploration on the Earth Pressure Distribution on a Flexible Retaining Structure of Cable-anchors Tied Pile-slab Wall on Embankment′s Shoulder or Slope[J]. Journal of Railway Engineering Society, 2007(4):24-28.
[4]TB 10025—2006,铁路路基支挡结构设计规范[S].
TB 10025—2006,Code for Design on Retaining Structures of Railway Subgrade[S].
[5]刘国楠,胡荣华,潘效鸿,等. 衡重式桩板挡墙上墙土压力模型试验研究[J]. 岩土力学, 2011(S2):94-98.
Liu Guonan, Hu Ronghua, Pan Xiaohong, etc. Model Tests on Earth Pressure of Upper Part Wall of Sheet Pile Wall with Relieving Platform[J]. Rock and Soil Mechanics, 2011(S2):94-98.
[6]GB 50111—2006,铁路工程抗震设计规范(2009年版)[S].
GB 50111—2006,Code for Seismic Design of Railway Engineering[S].
[7]王燕华,程文瀼,陆飞,等. 地震模拟振动台的发展[J]. 工程抗震与加固改造, 2007(5):53-56.
Wang Yanhua, Cheng Wenrang, Lu Fei, etc. Development of the Shaking Table[J]. Earthquake Resistant Engineering and Retrofitting,2007(5):53-56.
版权所有 © 2014 《铁道工程学报》编辑部