Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls
Yıl: 2020 Cilt: 3 Sayı: 2 Sayfa Aralığı: 85 - 92 Metin Dili: İngilizce DOI: 10.31462/jseam.2020.02085092 İndeks Tarihi: 31-05-2021
Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls
Öz: Blasting is used in jobs such as construction, mining, oil and agriculture and forestry in our country and the world. Blast technology is commonly applied to most civil engineering applications such as housing, railways, roads, dams, airports. Although this technology benefits many construction applications, it also causes some negative effects such as ground motion and air shock. This paper only studies blast-induced ground motion. The ground motion acceleration time histories are simulated using the software. The software generates acceleration time histories of blast-induced ground motions using peak acceleration and the time envelope curve function of ground motion acceleration. Moreover, it obtains shock response spectra determined from ground shock time histories. In this study, the influence of blast-induced ground motion on reinforcement retaining walls was investigated. These walls are very often built in Turkey. Therefore, the influence of blast-induced ground motion is important for them. The three-dimensional finite element model of the reinforcement retaining wall was designed. The maximum stresses and displacements of thereinforcement retaining wall were investigated. As a conclusion, when charge weight increases (constant charge center), displacements and Von Misses stresses also increase. Therefore, the blast-induced ground motion must also be taken into account for important structures such as retaining walls, bridges, dams and historic buildings.
Anahtar Kelime: Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık
- [1] UFC (Unified Facilities Criteria) (2008) Structures to resist the effects of accidental explosions. UFC 3-340-02, Department of Defense, US Army Corps of Engineers, Naval Facilities Engineering Command, Air Force Civil Engineer Support Agency, United States of America.
- [2] Wu C, Hao H (2004) Modeling of simultaneous ground shock and air-blast pressure on nearby structures from surface explosions. International Journal of Impact Engineering 31:699–717.
- [3] Wu C, Hao H (2007) Numerical simulation of structural response and damage to simultaneous ground shock and air-blast loads. International Journal of Impact Engineering 34:556–572.
- [4] Wu C, Hao H, Lu Y (2005) Dynamic response and damage analysis of masonry structures and masonry infilled RC frames to blast ground motion. Engineering Structures 27:323–333.
- [5] Lu Y, Wang Z (2006) Characterization of structural effects from above-ground explosion using coupled numerical simulation, Computers & Structures 84(28): 1729-1742.
- [6] Singh PK, Roy MP (2010) Damage to surface structures due to blast vibration, International Journal of Rock Mechanics and Mining Sciences 47(6): 949-961.
- [7] Hao H, Zhou Y (2011) Rigid structure response analysis to seismic and blast induced ground motions. Procedia Engineering 14: 946-955.
- [8] Hart CG, Wong K. Structural dynamics for structural engineers. John Wiley & Sons, Inc., Toronto, 1999.
- [9] Köksal O, Karaca Z. Investigation of blast-induced ground motion on reinforced concrete buildings with basement floor on soft soil. 3rd International Soil-Structure Interaction Symposium, 18–20 October 2017, İzmir, Turkey.
- [10] Köksal O, Karaca Z. Influence of blast induced ground motion on dynamic response of rectangular concrete water tank. 1st International Technological Sciences and Design Symposium, 27–29 June 2018, Giresun, Turkey.
- [11] Köksal O, Karaca Z. Pounding effects of adjacent buildings on the influence of blast-induced ground motion. 4th International Conference on Earthquake Engineering and Seismology, 11–13 October 2017, Eskişehir, Turkey.
- [12] Köksal O, Karaca Z. Investigation of air-blast pressure in reinforced concrete structures. 2nd International Conference on Advanced Engineering Technologies, 19–21 September 2017, Bayburt, Turkey.
- [13] Köksal O, Karaca Z (2017) Developing computer software for blast-induced ground motion, International Journal of Multidisciplinary Studies and Innovative Technologies 1(1): 42–46.
- [14] Özacar V (2019) A study on controlled blasting at a quarry. Dokuz Eylül University Faculty of Engineering Journal of Science and Engineering 21(63):911–925.
- [15] Toy AT, Sevim B (2017) Numerically and empirically determination of blasting response of a RC retaining wall under TNT explosive. Advances in Concrete Construction 5(5):493–512.
- [16] Oncu ME, Yon B, Akkoyun O, Taskiran T (2015) Investigation of blast-induced ground vibration effects on rural buildings. Structural Engineering and Mechanics 54(3):545–560.
- [17] Sevim B, Toy AT (2020) Blasting Response of a two-storey RC building under different charge weight of TNT explosives. Iranian Journal of Science and Technology, Transactions of Civil Engineering 44: 565-577.
- [18] Ruiz P, Penzien J (1969) PSEQN: Artificial generation of earthquake accelerograms. Earthquake Engineering Research Center, Report No: EERC 69-3, University of California, Berkeley.
- [19] Köksal O. Dynamic analysis of elevated steel water tank subjected to blast induced ground motion. MSc Thesis. Graduate School of Sciences, Ondokuz Mayıs University, 2013.
- [20] Bolotin VV (1960) Statistical theory of a seismic design of structures. Proceedings of 2nd World Conference on Earthquake Engineering. 2:1365– 1374.
- [21] Amin M, Ang AHS (1968) A non-stationary stochastic model of earthquake motion. Journal of Engineering Mechanics 94(2): 559–583.
- [22] Kanasewich ER. Time sequence analysis in geophysics. The University of Alberta Press, Edmonton, Alberta, Canada, 1981.
- [23] ANSYS (2014). Finite Element Analysis System, SAS IP, Inc., US
| APA | KÖKSAL O, KARACA Z (2020). Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. , 85 - 92. 10.31462/jseam.2020.02085092 |
| Chicago | KÖKSAL Olgun,KARACA Zekai Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. (2020): 85 - 92. 10.31462/jseam.2020.02085092 |
| MLA | KÖKSAL Olgun,KARACA Zekai Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. , 2020, ss.85 - 92. 10.31462/jseam.2020.02085092 |
| AMA | KÖKSAL O,KARACA Z Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. . 2020; 85 - 92. 10.31462/jseam.2020.02085092 |
| Vancouver | KÖKSAL O,KARACA Z Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. . 2020; 85 - 92. 10.31462/jseam.2020.02085092 |
| IEEE | KÖKSAL O,KARACA Z "Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls." , ss.85 - 92, 2020. 10.31462/jseam.2020.02085092 |
| ISNAD | KÖKSAL, Olgun - KARACA, Zekai. "Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls". (2020), 85-92. https://doi.org/10.31462/jseam.2020.02085092 |
| APA | KÖKSAL O, KARACA Z (2020). Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. Journal of Structural Engineering & Applied Mechanics (Online), 3(2), 85 - 92. 10.31462/jseam.2020.02085092 |
| Chicago | KÖKSAL Olgun,KARACA Zekai Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. Journal of Structural Engineering & Applied Mechanics (Online) 3, no.2 (2020): 85 - 92. 10.31462/jseam.2020.02085092 |
| MLA | KÖKSAL Olgun,KARACA Zekai Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. Journal of Structural Engineering & Applied Mechanics (Online), vol.3, no.2, 2020, ss.85 - 92. 10.31462/jseam.2020.02085092 |
| AMA | KÖKSAL O,KARACA Z Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. Journal of Structural Engineering & Applied Mechanics (Online). 2020; 3(2): 85 - 92. 10.31462/jseam.2020.02085092 |
| Vancouver | KÖKSAL O,KARACA Z Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls. Journal of Structural Engineering & Applied Mechanics (Online). 2020; 3(2): 85 - 92. 10.31462/jseam.2020.02085092 |
| IEEE | KÖKSAL O,KARACA Z "Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls." Journal of Structural Engineering & Applied Mechanics (Online), 3, ss.85 - 92, 2020. 10.31462/jseam.2020.02085092 |
| ISNAD | KÖKSAL, Olgun - KARACA, Zekai. "Influence of blast-induced ground motion on dynamic response ofreinforcement retaining walls". Journal of Structural Engineering & Applied Mechanics (Online) 3/2 (2020), 85-92. https://doi.org/10.31462/jseam.2020.02085092 |
