Journal of Coal Science and Engineering (China)

, Volume 18, Issue 4, pp 418–422 | Cite as

Research on the characteristics of noise source on heading face and noise propagation in mine laneway

  • You-duo Peng
  • Wei-hua Xie
  • Zhi-yong Xie
  • Chang-qing Peng
  • Xi Yin
Article
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Abstract

Based on the complexity and dynamic random analysis of machine noise source in mine heading face, this article established the noise pressure mathematical model of noise propagation in mine laneway of different noise sources, carried out noise propagation numerical simulation in long space, and revealed noise propagation law of more radiated noise sources in the mine roadway. The results show that, under conditions that the total noise power is always the same, regardless of point source, surface noise source, or body noise source, the corresponding noise attenuation trend along the mine laneway and attenuation curve shape are basically the same. However, the attenuation velocity corresponding to complex stereo noise source is slower than single point source and the noise pressure value is higher than the single point source. The actual noise of measured values is close to the theoretical value or, say, there is little error for complex stereo noise source, whereas the error to single point source and surface noise is higher, respectively.

Keywords

noise source mine roadway propagation characteristics heading face noise pressure 
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References

  1. Ceng X Y, 2007. Theory and application of integration in noise and audio-visual. Beijing: Northwest Industrial University Press, 156–164.Google Scholar
  2. Chen Y, Liu J J, Qiu X J, 2010. A coherent model of noise propagation in long enclosures with different acoustics boundaries. Journal of Nanjing University (Natural Science Edition), 46(1): 26–33.Google Scholar
  3. Ge J, 2001. Hybrid method of image source model and diffuse surface integration for the simulation of room noise field. Journal of Zhejiang University, 35(1): 104–108.Google Scholar
  4. Han G H, Yuan W P, Zhou Y K, Wang H, 2006. Theory research on noise power of noise radiation surface. Chinese Internal Combustion Engine Engineering, 27(4): 70–73.Google Scholar
  5. Jiang Z J, Cui T J, 2008. Prediction method of noise field in the rectangular long enclosure. Technical Acoustics, 27(1): 35–39.Google Scholar
  6. Jin Y, Hao Z Y, 2006. Investigation on main noise sources of vehicle gasoline engine by noise intensity measurement. Transactions of the Chinese Society for Agricultural Machinery, 37(2): 14–17.Google Scholar
  7. Kang J, 2002. Reverberation in rectangular long enclosures with diffusely reflecting boundaries. Acta Acustica United with Acustica, 88: 77–87.Google Scholar
  8. Peng Y D, Guo Y F, Li X, Xie W H, 2010. Development status of noise forecasting and controlling on tunneling face and laneway of mine. Mineral Engineering Research, 25(4): 62–68.Google Scholar
  9. Peng Y D, Xie W H, Guo Y F, Li X, Dhillon B S, 2011. Study about spatial and temporal properties of machine noise source on roadway head of mine. Journal of Hunan University of Sciences & Technology (Natural Science Edition), 26(3): 1–6.Google Scholar
  10. Shi L M, 2010. Method of noise prediction and measures of noise reducing in highway tunnel. Noise and Vibration Control, 4(2): 66–68.Google Scholar
  11. Song L, Gao L F, 2006. The noise source analysis of pneumatic rock drill. Noise and Vibration Control, 4(2): 75–78.Google Scholar
  12. Sui F S, 2010. Prediction of acoustic fields at mid-high frequency using an energy density model. Acta Acustica, 35(2): 134–139.Google Scholar
  13. Wang R J, Chen H W, 2006. Analysis to the noise mechanism of the pneumatic rock drill and the improvement. Mining & Processing Equipment, 34(6): 36–37.Google Scholar
  14. Wang Z W, Hu Z X, Yuan S Z, Ma Y B, 2010. Noise source measurement and study on noise reduction of motorcycle. Transducer and Microsystem Technologies and Microsystem Technologies, 29(7): 37–40.Google Scholar
  15. Xie W H, Peng Y D, Wu L T, 2011. Numerical analysis on acoustic field characteristics of excavation roadway based on surface integration method. Journal of China Coal Society, 36(11): 1790–1794.Google Scholar
  16. Zhang J C, Yuan P Ouyang Y H, 2010. Characteristics of absorption and attenuation of thunder propagating in atmosphere. Acta Physica Sinica, 59(11): 8287–8292.Google Scholar

Copyright information

© The Editorial Office of Journal of Coal Science and Engineering (China) and Springer-Verlag Berlin Heidelberg 2012

Authors and Affiliations

  • You-duo Peng
    • 1
    • 2
  • Wei-hua Xie
    • 1
  • Zhi-yong Xie
    • 3
  • Chang-qing Peng
    • 1
  • Xi Yin
    • 1
  1. 1.Hunan Provincial Key Laboratory of Health Maintenance for Mechanical EquipmentHunan University of Science and TechnologyXiangtanChina
  2. 2.Engineering Research Center of Advanced Mining Equipment, Ministry of EducationHunan University of Science and TechnologyXiangtanChina
  3. 3.Loudi Vocational Technical CollegeLoudiChina

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