Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2024, Cilt: 35 Sayı: 1, 109 - 138, 01.01.2024
https://doi.org/10.18400/tjce.1380129

Öz

Kaynakça

  • Lee, S., Kim, B., Lee, Y-J., Seismic Fragility Analysis of Steel Liquid Storage Tanks using Earthquake Ground Motions Recorded in Korea. Math. Probl. Eng., Article ID 6190159, 15 pages, 2019.
  • Zhao, Z., Lu, X., Guo, Y., Zhao, X., Seismic Fragility Assessment of Base-Isolated Steel Water Storage Tank. Shock Vib., Article ID 8835943, 13 pages, 2020.
  • Tsipianitis, A., Tsompanakis, Y., Optimizing the Seismic Response of Base-Isolated Liquid Storage Tanks using Swarm Intelligence Algorithms. Comput. Struct., 243, 106407, 2021.
  • Hatayama, K., Lessons from the 2003 Tokachi-oki, Japan, Earthquake for Prediction of Long-Period Strong Ground Motions and Sloshing Damage to Oil Storage Tanks. J. Seismol., 12, 255-263, 2008.
  • Yazici, G., Cili, F., Evaluation of the Liquid Storage Tank Failures in the 1999 Kocaeli Earthquake. 14th World Conference on Earthquake Engineering, Beijing, China, 2008.
  • Jadhav, M.B., Jangid, R.S., Response of Base-Isolated Liquid Storage Tanks. Shock and Vibration, 11, 33-45, 2004.
  • Shrimali, M.K., Jangid, R.S., Seismic Analysis of Base-Isolated Liquid Storage Tanks. Journal of Sound and Vibration, 275(1), 59-75, 2004.
  • Jadhav, M.B., Jangid, R.S., Response of Base-Isolated Liquid Storage Tanks to Near-Fault Motions. Structural Engineering and Mechanics, 23(6), 615-634, 2006.
  • Shekari, M.R., Khaji, N., Ahmadi, M.T., On the Seismic Behavior of Cylindrical Base-Isolated Liquid Storage Tanks Excited by Long-Period Ground Motions. Soil Dynamics and Earthquake Engineering, 30, 968-980, 2010.
  • Panchal, V.R., Soni, D.P., Seismic Behaviour of Isolated Fluid Storage Tanks: A-State-of-the-Art Review. KSCE J. Civ. Eng., 18(4), 1097-1104, 2014.
  • Saha, S.K., Matsagar, V., Chakraborty, S., Uncertainty Quantification and Seismic Fragility of Base-Isolated Liquid Storage Tanks using Response Surface Models. Probabilistic Eng. Mech., 43, 20-35, 2016.
  • Hashemi, S., Aghashiri, M.H., Seismic Responses of Base-Isolated Flexible Rectangular Fluid Containers under Horizontal Ground Motions. Soil Dyn. Earthq. Eng., 100, 159-168, 2017.
  • Alhan, C., Gazi, H., Güler, E., Influence of Isolation System Characteristic Strength on the Earthquake Behavior of Base-Isolated Liquid Storage Tanks. Indian J. Eng. Mater. Sci., 25(4), 346-352, 2018.
  • Tsipianitis, A., Tsompanakis, Y., Impact of Damping Modeling on the Seismic Response of Base-Isolated Liquid Storage Tanks. Soil Dynamics and Earthquake Engineering, 121, 281-292, 2019.
  • Housner, G.W., Trifunac, M.D., Analysis of Accelerograms-Parkfield Earthquake. Bull. Seismol. Soc. Am., 57(6), 1193-220, 1967.
  • Makris, N., Rigidity-Plasticity-Viscosity: Can Electrorheological Dampers Protect Base Isolated Structures from Near-Source Ground Motions? Earthq. Eng. Struct. Dyn., 26, 571-591, 1997.
  • Bray, J.D., Rodriguez-Marek, A., Characterization of Forward-Directivity Ground Motions in the Near-Fault Region. Soil Dyn. Earthq. Eng., 24, 815-828, 2004.
  • He, W.L., Agrawal, A.K., An Analytical Model of Ground Motion Pulses for the Design and Assessment of Smart Protective Systems. ASCE J. Struct. Eng., 134(7), 1177-1188, 2008.
  • Kanbir, Z., Alhan, C., Özdemir, G., Influence of Superstructure Modeling Approach on the Response Prediction of Buildings with LRBs Considering Heating Effects. Structures, 28, 1756-1773, 2020.
  • Hall, J.F., Seismic Response of Steel Frame Buildings to Near-Source Ground Motions. Earthq. Eng. Struct. Dyn., 27, 1445-1464, 1998.
  • Somerville, P.G., Graves, R.W., Characterization of Earthquake Strong Ground Motion. Pure Appl. Geophys., 160, 1811-1828, 2003.
  • Alhan, C., Güler, E., Gazi, H., Behavior of Base-Isolated Liquid Storage Tanks under Synthetic Near-Fault Earthquake Pulses. 5th International Symposium on Life-Cycle Civil Engineering, Delft, Holland, 515, 2415-2419, 2016.
  • Haroun, M.A., Housner, G.W., Seismic Design of Liquid Storage Tanks. Journal of the Technical Councils of ASCE, 107, 191-207, 1981.
  • Kalogerakou, M.E., Maniatakis, C.A., Spyrakos, C.C., Psaropoulos, P.N., Seismic Response of Liquid-Containing Tanks with Emphasis on the Hydrodynamic Response and Near-Fault Phenomena. Eng. Struct., 153, 383-403, 2017.
  • Housner, G.W., Earthquake Pressures on Fluid Containers, Tech. Rep. NR-081-095, California Institute of Technology, Pasadena, California, 1954.
  • Öncü-Davas, S., Gazi, H., Güler, E., Alhan, C., Comparison of Ground Motion Pulse Models for the Seismic Response of Seismically Isolated Liquid Storage Tanks, Earthquake Engineering and Structural Dynamics in Memory of Ragnar Sigbjörnsson, In: Rupakhety, R. and Ólafsson, S., (eds.), Chapter 7, Springer International Publishing AG, Geotechnical, Geological and Earthquake Engineering, 143-157, 2018.
  • Safari, S., Tarinejad, R., Parametric Study of Stochastic Seismic Responses of Base-Isolated Liquid Storage Tanks under Near-Fault and Far-Fault Ground Motions. J. Vib. Control, 24, 5747-5764, 2018.
  • Tsopelas, P.C., Constantinou, M.C., Reinhorn, A.M., 3D-BASIS-ME: Computer Program for Nonlinear Dynamic Analysis of Seismically Isolated Single and Multiple Structures and Liquid Storage Tanks, Tech. Rep. NCEER-94-0010, National center for earthquake engineering research, State Univ. of New York, Buffalo, NY, 1994.
  • Castellano, M.G., Infanti, S., Dumoulin, C., Ducoup, L., Martelli, A., Dusi, A., Shaking Table Tests on a Liquefied Natural Gas Storage Tank Mock-up Seismically Protected with Elastomeric Isolators and Steel Hysteretic Torsional Dampers. 12th World Conference on Earthquake Engineering, Auckland, New Zealand, 2000.
  • Gazi, H., Kazezyılmaz-Alhan, C.M., Alhan, C., Behavior of Seismically Isolated Liquid Storage Tanks Equipped with Nonlinear Viscous Dampers in Seismic Environment. 10th Pacific Conference on Earthquake Engineering, Sydney, Australia, 2015.
  • Luo, H., Zhang, R., Weng, D., Mitigation of Liquid Sloshing in Storage Tanks by using a Hybrid Control Method. Soil Dyn. Earthq. Eng., 90, 183-195, 2016.
  • Güler, E., Alhan, C., Performance Limits of Base-Isolated Liquid Storage Tanks with/without Supplemental Dampers under Near-Fault Earthquakes. Structures, 33, 355-367, 2021.
  • Tsipianitis, A., Tsompanakis, Y., Improving the Seismic Performance of Base-Isolated Liquid Storage Tanks with Supplemental Linear Viscous Dampers. Earthq. Eng. Eng. Vib., 21, 269-282, 2022.
  • Bakalis, K., Fragiadakis, M., Vamvatsikos, D., Surrogate Modeling for the Seismic Performance Assessment of Liquid Storage Tanks. Journal of Structural Engineering, 143(4): 1–13, 2017.
  • Güler, E., Effect of Supplemental Damping on the Earthquake Behavior of Base-Isolated Liquid Storage Tanks, Ph.D. Thesis, Istanbul University-Cerrahpaşa, Institute of graduate studies, 2019.
  • Malhotra, P.K., Wenk, T., Wieland, M., Simple Procedure for Seismic Analysis of Liquid-Storage Tanks. Struct. Eng. Int., 3, 197-201, 2000.
  • Shrimali, M.K., Jangid, R.S., Seismic Analysis of Base-Isolated Liquid Storage Tanks. J. Sound Vib., 275, 59-75, 2004.
  • Seleemah, A.A., El-Sharkawy, M., Seismic Response of Base Isolated Liquid Storage Ground Tanks. Ain Shams Eng. J., 2(1), 33-42, 2011.
  • Compagnoni, M.E., Curadelli, O., Ambrosini, D., Experimental Study on the Seismic Response of Liquid Storage Tanks with Sliding Concave Bearings. J. Loss Prev. Process Ind., 55, 1-9, 2018.
  • Nagarajaiah, S., Reinhorn, A.M., Constantinou, M.C., 3D-BASIS: Nonlinear Dynamic Analysis of Three-Dimensional Base Isolated Structures, Tech. Rep. NCEER-89-0019, National Center for Earthquake Engineering Research, State University of New York, Buffalo, NY, 1989.
  • Bouc, R., Forced Vibrations of a Mechanical System with Hysteresis. 4th Conference on Non-linear Oscillations, Prague, Czechoslovakia, pp. 315, 1967.
  • Wen, Y.K., Method for Random Vibration of Hysteretic Systems. J. Eng. Mech. Div., 102, 246-263, 1976.
  • Park, Y., Wen, Y., Ang, A., Random Vibration of Hysteretic Systems under Bi-directional Ground Motions. Earthquake Eng. Struct. Dyn., 14, 543–557, 1986.
  • Naeim, F., Kelly, J.M., Design of Seismic Isolated Structures: From Theory to Practice, 978-0-471-14921-7, John Wiley & Sons, New York, 1999.
  • Eurocode 8: EN1998. Design of Structures for Earthquake Resistance, Part 4: Silos, Tanks and Pipelines, Brussels, Belgium, 2006.
  • ASCE 7. Minimum Design Loads and Associated Criteria for Buildings and Other Structures, ASCE/SEI 7-16, Reston, Virginia, 2017.
  • Scheller, J., Constantinou, M.C., Response History Analyses of Structures with Seismic Isolation and Energy Dissipation Systems: Verification Examples for Program SAP2000, Technical Report MCEER-99-0002, University at Buffalo, New York, 1999.
  • Newmark, N.M., A Method of Computation for Structural Dynamics, J. of Engrg. Mech. Div. ASCE, 85, 67-94, 1959.
  • Rosenbrock, H.H., Some General Implicit Processes for the Numerical Solution of Differential Equations, Computer J., 18, 50-64, 1964.
  • Mavroeidis, G.P., Dong, G., Papageorgiou, A.S., Near-Fault Ground Motions, and the Response of Elastic and Inelastic Single-Degree-of-Freedom (SDOF) Systems. Earthq. Eng. Struct. Dyn., 33(9), 1023-49, 2004.
  • Yadav, K.K., Gupta, V.K., Near-Fault Fling-Step Ground Motions: Characteristics and Simulation. Soil Dyn. Earthq. Eng., 101, 90-104, 2017.
  • Bertero, V.V., Mahin, S.A., Herrera, R.A., Aseismic Design Implications of Near-Fault San Fernando Earthquake Records. Earthq. Eng. Struct. Dyn., 6(1), 31-42, 1978.
  • Mavroeidis, G.P., Papageorgiou, A.S., A Mathematical Representation of Near-Fault Ground Motions. Bull. Seismol. Soc. Am., 93(3), 1099-131, 2003.
  • Güler, E., Alhan, C., Effectiveness of Non-Linear Fluid Viscous Dampers in Seismically Isolated Buildings. Earthq. Struct., 17(2), 191-204, 2019.
  • Hall, J.F., Heaton, T.H., Halling, M.W., Wald, D.J., Near-Source Ground Motion and its Effects on Flexible Buildings. Earthq. Spectra, 11(4), 569-605, 1995.
  • Heaton, T.H., Hall, J.F., Wald, D.J., Halling, M.W., Response of High-Rise and Base-Isolated Buildings to a Hypothetical Mw 7.0 Blind Thrust Earthquake. Science, 267, 206-11, 1995.
  • PEER, Pacific Earthquake Engineering Research Center Ground Motion Database, University of California, Berkeley, CA, 2013 (http://ngawest2.berkeley.edu).
  • Saha, S.K., Matsagar, V.A., Jain, A.K., Response of Base-Isolated Liquid Storage Tanks under Near-Fault Earthquakes. Indian Society of Earthquake Technology Golden Jubilee Symposium, Roorkee, India, D011, 2012.
  • Haroun, M.A., Vibration Studies and Tests of Liquid Storage Tanks. Earthq. Eng. Struct. Dyn., 11, 179-206, 1983.
  • Malhotra, P.K., Method for Seismic Base Isolation of Liquid-Storage Tanks. J. Struct. Eng., 123, 113-6, 1997.
  • Veletsos, A.S., Yang, J.Y., Earthquake Response of Liquid Storage Tanks. 2nd Engineering Mechanics Specialty Conference, ASCE, Raleigh, North Carolina, USA, pp. 1-24, 1977.

Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility

Yıl 2024, Cilt: 35 Sayı: 1, 109 - 138, 01.01.2024
https://doi.org/10.18400/tjce.1380129

Öz

Liquid storage tanks (LSTs) can be efficiently protected from far-fault earthquakes by base-isolation. However, large isolation system and sloshing displacements may threaten the tank’s safety under near-fault earthquakes. Although the application of supplemental viscous dampers (VDs) at the base-isolation systems of LSTs located in near-fault areas may help, it may also increase superstructure demands under far-fault earthquakes. In addition to the characteristics of the earthquake, the isolation system and the superstructure properties may affect the success of base-isolated LSTs with supplemental VDs. Therefore, a numerical investigation is conducted in this study in order to determine the influence of the supplemental viscous damping ratio, the isolation system period, the tank wall flexibility, and the tank slenderness ratio on the seismic responses of base-isolated cylindrical steel LSTs with supplemental VDs including the base displacement, the sloshing displacement, and the normalized isolation system shear force under both near-fault and far-fault historical earthquake records. The tank is modeled by single-degree-of-freedom systems representing different modes on a common isolation basemat and the nonlinear dynamic analyses are carried out in 3D-BASIS-ME software. Findings show that while supplemental damping is required especially when LSTs with long-period isolation systems are subjected to large magnitude near-fault earthquakes, it may also cause amplifications in the sloshing displacement and isolation system shear force demands in case of far-fault earthquakes. Furthermore, it is determined that the influence of tank flexibility on both the superstructure and the isolation system responses is negligibly small while the tank slenderness ratio may have considerable effects.

Kaynakça

  • Lee, S., Kim, B., Lee, Y-J., Seismic Fragility Analysis of Steel Liquid Storage Tanks using Earthquake Ground Motions Recorded in Korea. Math. Probl. Eng., Article ID 6190159, 15 pages, 2019.
  • Zhao, Z., Lu, X., Guo, Y., Zhao, X., Seismic Fragility Assessment of Base-Isolated Steel Water Storage Tank. Shock Vib., Article ID 8835943, 13 pages, 2020.
  • Tsipianitis, A., Tsompanakis, Y., Optimizing the Seismic Response of Base-Isolated Liquid Storage Tanks using Swarm Intelligence Algorithms. Comput. Struct., 243, 106407, 2021.
  • Hatayama, K., Lessons from the 2003 Tokachi-oki, Japan, Earthquake for Prediction of Long-Period Strong Ground Motions and Sloshing Damage to Oil Storage Tanks. J. Seismol., 12, 255-263, 2008.
  • Yazici, G., Cili, F., Evaluation of the Liquid Storage Tank Failures in the 1999 Kocaeli Earthquake. 14th World Conference on Earthquake Engineering, Beijing, China, 2008.
  • Jadhav, M.B., Jangid, R.S., Response of Base-Isolated Liquid Storage Tanks. Shock and Vibration, 11, 33-45, 2004.
  • Shrimali, M.K., Jangid, R.S., Seismic Analysis of Base-Isolated Liquid Storage Tanks. Journal of Sound and Vibration, 275(1), 59-75, 2004.
  • Jadhav, M.B., Jangid, R.S., Response of Base-Isolated Liquid Storage Tanks to Near-Fault Motions. Structural Engineering and Mechanics, 23(6), 615-634, 2006.
  • Shekari, M.R., Khaji, N., Ahmadi, M.T., On the Seismic Behavior of Cylindrical Base-Isolated Liquid Storage Tanks Excited by Long-Period Ground Motions. Soil Dynamics and Earthquake Engineering, 30, 968-980, 2010.
  • Panchal, V.R., Soni, D.P., Seismic Behaviour of Isolated Fluid Storage Tanks: A-State-of-the-Art Review. KSCE J. Civ. Eng., 18(4), 1097-1104, 2014.
  • Saha, S.K., Matsagar, V., Chakraborty, S., Uncertainty Quantification and Seismic Fragility of Base-Isolated Liquid Storage Tanks using Response Surface Models. Probabilistic Eng. Mech., 43, 20-35, 2016.
  • Hashemi, S., Aghashiri, M.H., Seismic Responses of Base-Isolated Flexible Rectangular Fluid Containers under Horizontal Ground Motions. Soil Dyn. Earthq. Eng., 100, 159-168, 2017.
  • Alhan, C., Gazi, H., Güler, E., Influence of Isolation System Characteristic Strength on the Earthquake Behavior of Base-Isolated Liquid Storage Tanks. Indian J. Eng. Mater. Sci., 25(4), 346-352, 2018.
  • Tsipianitis, A., Tsompanakis, Y., Impact of Damping Modeling on the Seismic Response of Base-Isolated Liquid Storage Tanks. Soil Dynamics and Earthquake Engineering, 121, 281-292, 2019.
  • Housner, G.W., Trifunac, M.D., Analysis of Accelerograms-Parkfield Earthquake. Bull. Seismol. Soc. Am., 57(6), 1193-220, 1967.
  • Makris, N., Rigidity-Plasticity-Viscosity: Can Electrorheological Dampers Protect Base Isolated Structures from Near-Source Ground Motions? Earthq. Eng. Struct. Dyn., 26, 571-591, 1997.
  • Bray, J.D., Rodriguez-Marek, A., Characterization of Forward-Directivity Ground Motions in the Near-Fault Region. Soil Dyn. Earthq. Eng., 24, 815-828, 2004.
  • He, W.L., Agrawal, A.K., An Analytical Model of Ground Motion Pulses for the Design and Assessment of Smart Protective Systems. ASCE J. Struct. Eng., 134(7), 1177-1188, 2008.
  • Kanbir, Z., Alhan, C., Özdemir, G., Influence of Superstructure Modeling Approach on the Response Prediction of Buildings with LRBs Considering Heating Effects. Structures, 28, 1756-1773, 2020.
  • Hall, J.F., Seismic Response of Steel Frame Buildings to Near-Source Ground Motions. Earthq. Eng. Struct. Dyn., 27, 1445-1464, 1998.
  • Somerville, P.G., Graves, R.W., Characterization of Earthquake Strong Ground Motion. Pure Appl. Geophys., 160, 1811-1828, 2003.
  • Alhan, C., Güler, E., Gazi, H., Behavior of Base-Isolated Liquid Storage Tanks under Synthetic Near-Fault Earthquake Pulses. 5th International Symposium on Life-Cycle Civil Engineering, Delft, Holland, 515, 2415-2419, 2016.
  • Haroun, M.A., Housner, G.W., Seismic Design of Liquid Storage Tanks. Journal of the Technical Councils of ASCE, 107, 191-207, 1981.
  • Kalogerakou, M.E., Maniatakis, C.A., Spyrakos, C.C., Psaropoulos, P.N., Seismic Response of Liquid-Containing Tanks with Emphasis on the Hydrodynamic Response and Near-Fault Phenomena. Eng. Struct., 153, 383-403, 2017.
  • Housner, G.W., Earthquake Pressures on Fluid Containers, Tech. Rep. NR-081-095, California Institute of Technology, Pasadena, California, 1954.
  • Öncü-Davas, S., Gazi, H., Güler, E., Alhan, C., Comparison of Ground Motion Pulse Models for the Seismic Response of Seismically Isolated Liquid Storage Tanks, Earthquake Engineering and Structural Dynamics in Memory of Ragnar Sigbjörnsson, In: Rupakhety, R. and Ólafsson, S., (eds.), Chapter 7, Springer International Publishing AG, Geotechnical, Geological and Earthquake Engineering, 143-157, 2018.
  • Safari, S., Tarinejad, R., Parametric Study of Stochastic Seismic Responses of Base-Isolated Liquid Storage Tanks under Near-Fault and Far-Fault Ground Motions. J. Vib. Control, 24, 5747-5764, 2018.
  • Tsopelas, P.C., Constantinou, M.C., Reinhorn, A.M., 3D-BASIS-ME: Computer Program for Nonlinear Dynamic Analysis of Seismically Isolated Single and Multiple Structures and Liquid Storage Tanks, Tech. Rep. NCEER-94-0010, National center for earthquake engineering research, State Univ. of New York, Buffalo, NY, 1994.
  • Castellano, M.G., Infanti, S., Dumoulin, C., Ducoup, L., Martelli, A., Dusi, A., Shaking Table Tests on a Liquefied Natural Gas Storage Tank Mock-up Seismically Protected with Elastomeric Isolators and Steel Hysteretic Torsional Dampers. 12th World Conference on Earthquake Engineering, Auckland, New Zealand, 2000.
  • Gazi, H., Kazezyılmaz-Alhan, C.M., Alhan, C., Behavior of Seismically Isolated Liquid Storage Tanks Equipped with Nonlinear Viscous Dampers in Seismic Environment. 10th Pacific Conference on Earthquake Engineering, Sydney, Australia, 2015.
  • Luo, H., Zhang, R., Weng, D., Mitigation of Liquid Sloshing in Storage Tanks by using a Hybrid Control Method. Soil Dyn. Earthq. Eng., 90, 183-195, 2016.
  • Güler, E., Alhan, C., Performance Limits of Base-Isolated Liquid Storage Tanks with/without Supplemental Dampers under Near-Fault Earthquakes. Structures, 33, 355-367, 2021.
  • Tsipianitis, A., Tsompanakis, Y., Improving the Seismic Performance of Base-Isolated Liquid Storage Tanks with Supplemental Linear Viscous Dampers. Earthq. Eng. Eng. Vib., 21, 269-282, 2022.
  • Bakalis, K., Fragiadakis, M., Vamvatsikos, D., Surrogate Modeling for the Seismic Performance Assessment of Liquid Storage Tanks. Journal of Structural Engineering, 143(4): 1–13, 2017.
  • Güler, E., Effect of Supplemental Damping on the Earthquake Behavior of Base-Isolated Liquid Storage Tanks, Ph.D. Thesis, Istanbul University-Cerrahpaşa, Institute of graduate studies, 2019.
  • Malhotra, P.K., Wenk, T., Wieland, M., Simple Procedure for Seismic Analysis of Liquid-Storage Tanks. Struct. Eng. Int., 3, 197-201, 2000.
  • Shrimali, M.K., Jangid, R.S., Seismic Analysis of Base-Isolated Liquid Storage Tanks. J. Sound Vib., 275, 59-75, 2004.
  • Seleemah, A.A., El-Sharkawy, M., Seismic Response of Base Isolated Liquid Storage Ground Tanks. Ain Shams Eng. J., 2(1), 33-42, 2011.
  • Compagnoni, M.E., Curadelli, O., Ambrosini, D., Experimental Study on the Seismic Response of Liquid Storage Tanks with Sliding Concave Bearings. J. Loss Prev. Process Ind., 55, 1-9, 2018.
  • Nagarajaiah, S., Reinhorn, A.M., Constantinou, M.C., 3D-BASIS: Nonlinear Dynamic Analysis of Three-Dimensional Base Isolated Structures, Tech. Rep. NCEER-89-0019, National Center for Earthquake Engineering Research, State University of New York, Buffalo, NY, 1989.
  • Bouc, R., Forced Vibrations of a Mechanical System with Hysteresis. 4th Conference on Non-linear Oscillations, Prague, Czechoslovakia, pp. 315, 1967.
  • Wen, Y.K., Method for Random Vibration of Hysteretic Systems. J. Eng. Mech. Div., 102, 246-263, 1976.
  • Park, Y., Wen, Y., Ang, A., Random Vibration of Hysteretic Systems under Bi-directional Ground Motions. Earthquake Eng. Struct. Dyn., 14, 543–557, 1986.
  • Naeim, F., Kelly, J.M., Design of Seismic Isolated Structures: From Theory to Practice, 978-0-471-14921-7, John Wiley & Sons, New York, 1999.
  • Eurocode 8: EN1998. Design of Structures for Earthquake Resistance, Part 4: Silos, Tanks and Pipelines, Brussels, Belgium, 2006.
  • ASCE 7. Minimum Design Loads and Associated Criteria for Buildings and Other Structures, ASCE/SEI 7-16, Reston, Virginia, 2017.
  • Scheller, J., Constantinou, M.C., Response History Analyses of Structures with Seismic Isolation and Energy Dissipation Systems: Verification Examples for Program SAP2000, Technical Report MCEER-99-0002, University at Buffalo, New York, 1999.
  • Newmark, N.M., A Method of Computation for Structural Dynamics, J. of Engrg. Mech. Div. ASCE, 85, 67-94, 1959.
  • Rosenbrock, H.H., Some General Implicit Processes for the Numerical Solution of Differential Equations, Computer J., 18, 50-64, 1964.
  • Mavroeidis, G.P., Dong, G., Papageorgiou, A.S., Near-Fault Ground Motions, and the Response of Elastic and Inelastic Single-Degree-of-Freedom (SDOF) Systems. Earthq. Eng. Struct. Dyn., 33(9), 1023-49, 2004.
  • Yadav, K.K., Gupta, V.K., Near-Fault Fling-Step Ground Motions: Characteristics and Simulation. Soil Dyn. Earthq. Eng., 101, 90-104, 2017.
  • Bertero, V.V., Mahin, S.A., Herrera, R.A., Aseismic Design Implications of Near-Fault San Fernando Earthquake Records. Earthq. Eng. Struct. Dyn., 6(1), 31-42, 1978.
  • Mavroeidis, G.P., Papageorgiou, A.S., A Mathematical Representation of Near-Fault Ground Motions. Bull. Seismol. Soc. Am., 93(3), 1099-131, 2003.
  • Güler, E., Alhan, C., Effectiveness of Non-Linear Fluid Viscous Dampers in Seismically Isolated Buildings. Earthq. Struct., 17(2), 191-204, 2019.
  • Hall, J.F., Heaton, T.H., Halling, M.W., Wald, D.J., Near-Source Ground Motion and its Effects on Flexible Buildings. Earthq. Spectra, 11(4), 569-605, 1995.
  • Heaton, T.H., Hall, J.F., Wald, D.J., Halling, M.W., Response of High-Rise and Base-Isolated Buildings to a Hypothetical Mw 7.0 Blind Thrust Earthquake. Science, 267, 206-11, 1995.
  • PEER, Pacific Earthquake Engineering Research Center Ground Motion Database, University of California, Berkeley, CA, 2013 (http://ngawest2.berkeley.edu).
  • Saha, S.K., Matsagar, V.A., Jain, A.K., Response of Base-Isolated Liquid Storage Tanks under Near-Fault Earthquakes. Indian Society of Earthquake Technology Golden Jubilee Symposium, Roorkee, India, D011, 2012.
  • Haroun, M.A., Vibration Studies and Tests of Liquid Storage Tanks. Earthq. Eng. Struct. Dyn., 11, 179-206, 1983.
  • Malhotra, P.K., Method for Seismic Base Isolation of Liquid-Storage Tanks. J. Struct. Eng., 123, 113-6, 1997.
  • Veletsos, A.S., Yang, J.Y., Earthquake Response of Liquid Storage Tanks. 2nd Engineering Mechanics Specialty Conference, ASCE, Raleigh, North Carolina, USA, pp. 1-24, 1977.
Toplam 61 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Deprem Mühendisliği
Bölüm Araştırma Makaleleri
Yazarlar

Elif Güler 0000-0001-5261-5320

Cenk Alhan 0000-0002-6649-8409

Erken Görünüm Tarihi 23 Ekim 2023
Yayımlanma Tarihi 1 Ocak 2024
Gönderilme Tarihi 10 Ekim 2022
Yayımlandığı Sayı Yıl 2024 Cilt: 35 Sayı: 1

Kaynak Göster

APA Güler, E., & Alhan, C. (2024). Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility. Turkish Journal of Civil Engineering, 35(1), 109-138. https://doi.org/10.18400/tjce.1380129
AMA Güler E, Alhan C. Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility. tjce. Ocak 2024;35(1):109-138. doi:10.18400/tjce.1380129
Chicago Güler, Elif, ve Cenk Alhan. “Behavior of Base-Isolated Liquid Storage Tanks With Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility”. Turkish Journal of Civil Engineering 35, sy. 1 (Ocak 2024): 109-38. https://doi.org/10.18400/tjce.1380129.
EndNote Güler E, Alhan C (01 Ocak 2024) Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility. Turkish Journal of Civil Engineering 35 1 109–138.
IEEE E. Güler ve C. Alhan, “Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility”, tjce, c. 35, sy. 1, ss. 109–138, 2024, doi: 10.18400/tjce.1380129.
ISNAD Güler, Elif - Alhan, Cenk. “Behavior of Base-Isolated Liquid Storage Tanks With Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility”. Turkish Journal of Civil Engineering 35/1 (Ocak 2024), 109-138. https://doi.org/10.18400/tjce.1380129.
JAMA Güler E, Alhan C. Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility. tjce. 2024;35:109–138.
MLA Güler, Elif ve Cenk Alhan. “Behavior of Base-Isolated Liquid Storage Tanks With Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility”. Turkish Journal of Civil Engineering, c. 35, sy. 1, 2024, ss. 109-38, doi:10.18400/tjce.1380129.
Vancouver Güler E, Alhan C. Behavior of Base-Isolated Liquid Storage Tanks with Viscous Dampers under Historical Earthquakes Considering Superstructure Flexibility. tjce. 2024;35(1):109-38.