Peak Particle Velocity Predicting Equation Associated with the Propagation of Vibrations Induced by Blasting in a Mine and Impacts on the Physical Degradation of Houses: The Case of the Yaramoko Mine, Bagassi, Burkina Faso
This study utilizes empirical equations to describe the propagation of vibrations induced by blasting, with the goal of predicting the attenuation of Peak Particle Velocity (PPV) at the Yaramoko mine in Bagassi, Burkina Faso, a site characterized by granitoid rock. Four empirical PPV prediction equations were employed, so-called Duvall & Fogelson (or the United States Bureau of Mines “USBM”), Langefors and Kihlstrom, Ambressys-Hendron, and the Bureau of Indian Standard. The constant parameters for each of these equations, referred to as site constants, were derived from linear regression curves. The results show that the site constants k, a, and b of 4762, 0.869, and 1.737, respectively, derived from the general prediction equation by Davies, PPV = kQaD?b, based on Duvall & Fogelson, are in good agreement with values of 4690, 0.9, and 1.69, respectively, for similar rock types in Spain. Regarding the impacts of blasting on houses, the findings indicate that houses built from laterite-block bricks in the village of Bagassi are the most vulnerable to vibration waves, followed by those constructed with cinder-block bricks. In contrast, houses made of banco bricks are the most resilient. Additionally, it was determined that during blasting operations, adjusting the blasting parameters to ensure the PPV does not exceed 2 mm/s at the level of nearby dwellings can minimize the appearance of cracks in houses.
References
[1]
Ouédraogo, I. (1994) Géologie et hydrogéologie des formations sedimentaires de la Boucle du Mouhoun (Burkina Faso). Ph.D. Thesis, Université Cheikh Anta Diop de Dakar. https://beep.ird.fr/collect/uouaga/index/assoc/M07215.dir/M07215.pdf
[2]
Bureau Voltaique de la Géologie et des Mines (1984) Note sur les possibilités d’existence d’hydrocarbures et d’autres substances energetiques au Burkina Faso et propositions pour leur prospection. https://inis.iaea.org/collection/NCLCollectionStore/_Public/39/061/39061810.pdf
[3]
Synduex (2018) Guide d’utilisation des explosifs en travaux publics.
[4]
Rawnaq, E., Esmatyar, B., Hamanaka, A., Sasaoka, T. and Shimada, H. (2024) A Comparative Study of Two Tree-Based Models for Predicting Flyrock Velocity at Open Pit Bench Mining. OpenJournalofAppliedSciences, 14, 267-287. https://doi.org/10.4236/ojapps.2024.142019
[5]
Guth, K., Bourgeois, M. and Harbison, R. (2022) Assessment of Lead Exposures during Abrasive Blasting and Vacuuming in Ventilated Field Containments: A Case Study. OccupationalDiseasesandEnvironmentalMedicine, 10, 116-131. https://doi.org/10.4236/odem.2022.102010
[6]
SRK Consulting (2014) Technical Report for the Yaramoko Gold Mine, Burkina Faso. Roxgold Inc.
[7]
Cardu, M., Coragliotto, D. and Oreste, P. (2019) Analysis of Predictor Equations for Determining the Blast-Induced Vibration in Rock Blasting. InternationalJournalofMiningScienceandTechnology, 29, 905-915. https://doi.org/10.1016/j.ijmst.2019.02.009
[8]
Rodríguez, R., García de Marina, L., Bascompta, M. and Lombardía, C. (2021) Determination of the Ground Vibration Attenuation Law from a Single Blast: A Particular Case of Trench Blasting. JournalofRockMechanicsandGeotechnicalEngineering, 13, 1182-1192. https://doi.org/10.1016/j.jrmge.2021.03.016
[9]
Duvall, W.I. and Fogelson, D.E. (1962) Review of Criteria for Estimating Damage to Residences from Blasting Vibrations. https://api.semanticscholar.org/CorpusID:107939815
[10]
Langefors, U. and Kihlström, B. (1978) The Modern Technique of Rock Blasting. Wiley.
[11]
Ambraseys, N.N. and Hendron, A.J. (1968) Dynamic Behaviour of Rock Masses. John Wiley & Sons.
[12]
Bureau of Indian Standards (1973) Criteria for Safety and Design of Structures Subject to Underground Blasts. https://dn790004.ca.archive.org/0/items/gov.in.is.6922.1973/is.6922.1973.pdf
[13]
Ongen, T., Karakus, D., Konak, G. and Onur, A.H. (2018) Assessment of Blast-Induced Vibration Using Various Estimation Models. JournalofAfricanEarthSciences, 145, 267-273. https://doi.org/10.1016/j.jafrearsci.2018.05.004
[14]
Holmberg, R., Lundborg, N. and Rundqvist, G. (1983) Soil Vibrations and Damage Criteria. National Research Council of Canada. https://doi.org/10.4224/20358507
[15]
Giraudi, (2009) An Assessment of Blasting Vibrations: A Case Study on Quarry Operation. AmericanJournalofEnvironmentalSciences, 5, 468-474. https://doi.org/10.3844/ajessp.2009.468.474
[16]
Kadiri, I., Tahir, Y., Iken, O., Fertahi, S.E.-D. and Agounoun, R. (2019) Experimental and Statistical Analysis of Blast-Induced Ground Vibrations (BIGV) Prediction in Senegal’s Quarry. StudiaGeotechnicaetMechanica, 41, 231-246. https://doi.org/10.2478/sgem-2019-0025
[17]
Chapot, P. (1981) Loi expérimentale de propagation des vibrations dues aux tirs d’explosifs. RevueFrançaisedeGéotechnique, No. 14, 109-113. https://doi.org/10.1051/geotech/198114b109
[18]
Kanon Ghislain, A., Ouattara, G. and Anon Felix, N. (2022) Prediction of Vibrations Due to Blast at the Hiré Mine, Côte D’ivoire. InternationalJournalofEnvironmentalMonitoringandAnalysis, 10, 32-38. https://doi.org/10.11648/j.ijema.20221002.12
[19]
Khandelwal, M., Armaghani, D.J., Faradonbeh, R.S., Yellishetty, M., Majid, M.Z.A. and Monjezi, M. (2016) Classification and Regression Tree Technique in Estimating Peak Particle Velocity Caused by Blasting. EngineeringwithComputers, 33, 45-53. https://doi.org/10.1007/s00366-016-0455-0
[20]
Azimi, Y. (2019) Prediction of Seismic Wave Intensity Generated by Bench Blasting Using Intelligence Committee Machines. International Journal of Engineering, 32, 617-627. https://doi.org/10.5829/ije.2019.32.04a.21
[21]
Davies, B., Farmer, I.W. and Attewell, P.B. (1964) Ground Vibration from Shallow Sub-Surface Blasts. TRID.
[22]
Nicholls, H.R., Johnson, C.F and Duvall, W.I. (1971) Blasting Vibrations and Their Effects on Structures. Technical Report, Bureau of Mines, Washington, DC. https://api.semanticscholar.org/CorpusID:106811312
[23]
Fouladgar, N., Hasanipanah, M. and Bakhshandeh Amnieh, H. (2016) Application of Cuckoo Search Algorithm to Estimate Peak Particle Velocity in Mine Blasting. EngineeringwithComputers, 33, 181-189. https://doi.org/10.1007/s00366-016-0463-0
[24]
Hammed, O.S., Popoola, O.I., Adetoyinbo, A.A., Awoyemi, M.O., Adagunodo, T.A., Olubosede, O., et al. (2018) Peak Particle Velocity Data Acquisition for Monitoring Blast Induced Earthquakes in Quarry Sites. DatainBrief, 19, 398-408. https://doi.org/10.1016/j.dib.2018.04.103
[25]
Ghana (2012) Minerals and Mining (Explosives) Regulations, 2012 (Li 2177). Ghana Publishing Company.
