ÜÇ BOYUTLU ZEMİN-YAPI SİSTEMLERİNDE AKTİF YÖNTEMLERLE TİTREŞİM İZOLASYONU SAĞLANABİLİRLİĞİNİN ARAŞTIRILMASI
Yıl 2018,
Cilt: 13 Sayı: 2, 108 - 121, 22.04.2018
Oğuz Akın Düzgün
,
Ahmet Şahin Zaimoğlu
Öz
Bu çalışmada, dinamik yük etkisindeki üç
boyutlu bir zemin yapı sisteminin dinamik davranışı ve zemin yüzeyinde açılan
çukurların titreşim yalıtımı üzerindeki etkinliği parametrik olarak
incelenmiştir. Modellemede ve analizlerde Plaxis 3D programından faydalanılmıştır.
Çalışmada çukurun derinliği, genişliği, uzunluğu ve yeri parametre olarak
seçilmiştir. Sonuçlar zemin yüzeyinde yer değiştirmeler cinsinden, yapıda da
hem yer değiştirme hem de kesit tesiri cinsinden elde edilmiştir. Çalışmadan
elde edilen sonuçlar titreşim yalıtımı için en etkili parametrenin çukurun
derinliği olduğunu göstermektedir. Çukur derinliği arttıkça zemin yüzeyindeki
ve yapıdaki titreşimler belirgin bir şekilde azalmaktadır. Titreşim yalıtımı
problemlerindeki bir diğer etkin parametre de çukurun genişliğidir. Çukurun
genişliğinin artması da genlikleri önemli ölçüde azaltmaktadır. Ancak bu azalım
derinlik için elde edilen sonuçlardan daha küçüktür. Elde edilen sonuçlara göre
çukurun uzunluğunun, yerinin ve içinin farklı malzemelerle doldurularak
kullanılmasının titreşim yalıtımı çok az etkilediği sonucuna varılmıştır.
Kaynakça
- [1] Kattis, S.E., Polyzos, D. and Beskos, D.E., (1999). Vibration Isolation by A Row of Piles Using A 3-D Frequency Domain BEM. International Journal for Numerical Methods in Engineering, Volume:46, pp:713–728.
- [2] Kattis, S.E., Polyzos, D., and Beskos, D.E., (1999). Modelling of Pile Wave Barriers by Effective Trenches and Their Screening Effectiveness. Soil Dynamics and Earthquake Engineering, Volume:18, pp:1–10.
- [3] Shrivastava, R.K. and Kameswara Rao, N.S.V., (2002). Response of Soil Media due to Impulse Loads and Isolation Using Trenches. Soil Dynamics and Earthquake Engineering, Volume:22, pp:695–702.
- [4] Adam, M. and Von Estorff, O., (2005). Reduction of Train-Induced Building Vibrations by Using Open and Filled Trenches. Computers and Structures, Volume:83, pp:11–24.
- [5] Gao, G.Y., Li, Z.Y., Qiu, C. and Yue, Z.Q., (2006). Three-Dimensional Analysis of Rows of Piles as Passive Barriers for Ground Vibration Isolation. Soil Dynamics and Earthquake Engineering, Volume:26, pp:1015–1027.
- [6] Lu, J.F., Xu, B. and Wang, J.H., (2009). Numerical Analysis of Isolation of the Vibration due to Moving Loads Using Pile Rows. Journal of Sound and Vibration, Volume:319, pp:940–962.
- [7] Cao, Z., Cai, Y., Boström, A. and Zheng J., (2012). Semi-analytical Analysis of the Isolation to the Moving-Load Induced Ground Vibrations by Trenches on a Poroelastic Half-Space. Journal of Sound and Vibration, Volume:331, pp:947–961.
- [8] Klein, R., Antes, H. and Le Houédec, D., (1997). Efficient 3D Modelling of Vibration Isolation by Open Trenches. Computers and Structures, Volume:64, pp:809–817.
- [9] Massarsch, K.R., (2005). Vibration Isolation Using Gas-Filled Cushions. Soil Dynamics Symposium to Honor Prof. Richard D. Woods (Invited Paper), Geo-Frontiers, 22 p, Austin, Texas.
- [10] Zhang, F.Y., Chen, C.S., Wei, L.J. and Zhang, T., (2008). Cast-in-Place Concrete Thin-Wall Pipe as Barrier for Vibration Isolation. Journal of Central University of Technology, Volume:15, pp:121–125.
- [11] Pao, Y.H. and Mow, C.C., (1963). Scattering of Plane Compressional Waves by a Spherical Obstacles. Journal of Applied Physics, Volume:34, pp:493–499.
- [12] Woods, R.D., (1968). Screening of Surface Waves in Soils. PhD thesis, Industry Program of the College of Engineering, The University of Michigan, USA.
- [13] Lysmer, J. and Waas, G., (1972). Shear Waves in Plane Infinite Structures. Journal of Engineering Mechanics, ASCE, Volume:98, pp:85–105.
- [14] Segol, G., Abel, J.F. and Lee, P.C.Y., (1978). Amplitude Reduction of Surface Waves by Trenches. Journal of Engineering Mechanics, ASCE, Volume:104, pp:621–641.
- [15] Fuyuki, M. and Matsumoto, Y., (1980). Finite Difference Analysis of Rayleigh Wave Scattering at a Trench. Bulletin of the Seismological Society of America, Volume:70, pp:2051–2069.
- [16] Beskos, D.E., Dasgupta, B. and Vardoulakis, I.G., (1986). Vibration Isolation Using Open or Filled Trenches Part 1: 2-D Homogeneous Soil. Computational Mechanics, Volume:1, pp:43–63.
- [17] Dasgupta, B., Beskos, D.E. and Vardoulakis, I.G., (1990). Vibration Isolation Using Open or Filled Trenches Part 2: 3-D Homogeneous Soil. Computational Mechanics, Volume:6, pp:129–142.
- [18] Ahmad, S. and Al-Hussaini, T.M., (1991). Simplified Design For Vibration Screening by Open and In-Fılled Trenches. Journal of Geotechnical Engineering, Volume:117(1), pp:67–88.
- [19] Ahmad, S., Al-Hussaini, T.M. and Fishman, K.L., (1996). An Investigation on Active Isolation of Machine Foundations by Open Trenches. Journal of Geotechnical Engineering, Volume:122(6), pp:454–461.
- [20] Yang, Y.B., Kuo, S.R. and Hung, H.H., (1996). Frequency-Independent Infinite Elements for Analyzing Semi-Infinite Problems. International Journal for Numerical Methods in Engineering, Volume:39, pp:3553–3569.
- [21] Yang, Y.B. and Hung, H.H., (1997). A Parametric Study of Wave Barriers for Reduction of Train-Induced Vibrations. International Journal for Numerical Methods in Engineering, Volume:40, pp:3729–3747.
- [22] Andersen, L. and Nielsen, S.R.K., (2005). Reduction of Ground Vibration by means of Barriers or Soil Improvement Along a Railway Track. Soil Dynamics and Earthquake Engineering, Volume:25, pp:701–716.
- [23] Celebi, E. and Schmid, G., (2005). Investigation of Ground Vibrations Induced by Moving Loads. Engineering Structures, Volume:27, pp:1981–1998.
- [24] Celebi, E., (2006). Three-Dimensional Modelling of Train-Track and Sub-Soil Analysis for Surface Vibrations due to Moving Loads. Applied Mathematics and Computation, Volume:179, pp:209–230.
- [25] Hwang, J.H. and Tu, T.Y., (2006). Ground Vibration due to Dynamic Compaction. Soil Dynamics and Earthquake Engineering, Volume:26, pp:337–346.
- [26] Karlström, A. and Boström, A., (2007). Efficiency of Trenches along Railways for Trains Moving At Sub- or Supersonic Speeds. Soil Dynamics and Earthquake Engineering, Volume:27, pp:625–641.
- [27] Gao, G.Y., Shi, G., Feng, S.J. and Qiu, C., (2008). 3D Analysis of In-Filled Trench as Passive Barriers for Ground Vibration Isolation. Science in China Series G: Physics, Mechanics & Astronomy, Volume:51(10), pp:1573–1585.
- [28] Wang, J.G., Sun, W. and Anand, S., (2009). Numerical Investigation on Active Isolation of Ground Shock by Soft Porous Layers. Journal of Sound and Vibration, Volume:321, pp:492–509.
- [29] Çelebi, E., Fırat, S., Beyhan, G., Çankaya, İ., Vural, İ. and Kırtel O., (2009). Field Experiments on Wave Propagation and Vibration Isolation by Using Wave Barriers. Soil Dynamics and Earthquake Engineering, Volume:29, pp:824–833.
- [30] Tsai, P.H. and Chang, T.S., (2009). Effects of Open Trench Siding on Vibration-Screening Effectiveness Using the Two-Dimensional Boundary Element Method. Soil Dynamics and Earthquake Engineering, Volume:29, pp:865–873.
- [31] Jesmani, M., Fallahi, A.M. and Kashani, H.F., (2011). Study of Passive Isolation of Deep Foundations in Sandy Soil by Rectangular Trenches. Electronic Journal of Geotechnical Engineering, Volume:16, pp:1297–1318.
- [32] Jesmani, M., Fallahi, A.M. and Kashani, H.F., (2012). Effects of Geometrical Properties of Rectangular Trenches Intended for Passive Isolation in Sandy Soils. Earth Science Research, Volume:1(2), pp:137–151.
- [33] Celebi, E. and Göktepe, F., (2012). Non-linear 2-D FE Analysis for the Assessment of Isolation Performance of Wave Impeding Barrier in Reduction of Railway-Induced Surface Waves. Construction and Building Materials, Volume:36, pp:1–13.
- [34] Orehov, V.V., Moghanlou, R.N., Negahdar, H. and Varagh, A.M.B., (2012). Investigation Effects of Trench Barrier on the Reducing Energy of Surface Waves in Soils. 15th World Conference on Earthquake Engineering, September 24–28, Lisbon, Portugal.
- [35] Göktepe, F. ve Çelebi, E., (2014). Yüksek Hızlı Trenlerin Çevre Yapılarda Oluşturduğu Titreşimlerin Azaltılması İçin Düşey Dalga Bariyer Uygulaması. Zemin Mekaniği ve Temel Mühendisliği 2. Özel Konulu Sempozyumu: Teori ve Uygulamada Zemin-Yapı Etkileşimi Sempozyumu, 24–25 Nisan 2014, Antalya, Türkiye.
- [36] Düzgün, O.A., (2015). Efficiency of Trenches on Vibration Isolation Under Time Dependent Loads. Periodica Polytechnica Civil Engineering, Volume:59(2), pp:133 – 142.
- [37] Ohtsuki, A. and Harumi, K., (1983). Effect of Topography and Subsurface Inhomogeneities on Seismic SV waves. Earthquake Engineering and Structural Dynamics, Volume:11, pp:441–462.
- [38] Ohtsuki, A., Yamahara, H. and Harumi, K., (1984). Effect of Topography and Subsurface Inhomogeneity on Seismic Rayleigh Waves. Earthquake Engineering and Structural Dynamics, Volume:12, pp:37–58.
- [39] Chávez-Garcia, F.J. and Faccioli, E., (2000). Complex Site Effects and Building Codes: Making the Leap. Journal of Seismology, Volume:4, pp:23–40.
- [40] Gazetas, G., Kallou, P.V. and Psarropoulos, P.N., (2002). Topography and Soil Effects in the Ms 5.9 Parnitha (Athens) Earthquake: the Case of Adámes. Natural Hazards, Volume:27, pp:133–169.
- [41] Assimaki, D., Kausel, E. and Gazetas, G., (2005). Wave Propagation and Soil Structure Interaction on a Cliff Crest during the 1999 Athens Earthquake. Soil Dynamics and Earthquake Engineering, Volume:25, pp:513–527.
Yıl 2018,
Cilt: 13 Sayı: 2, 108 - 121, 22.04.2018
Oğuz Akın Düzgün
,
Ahmet Şahin Zaimoğlu
Kaynakça
- [1] Kattis, S.E., Polyzos, D. and Beskos, D.E., (1999). Vibration Isolation by A Row of Piles Using A 3-D Frequency Domain BEM. International Journal for Numerical Methods in Engineering, Volume:46, pp:713–728.
- [2] Kattis, S.E., Polyzos, D., and Beskos, D.E., (1999). Modelling of Pile Wave Barriers by Effective Trenches and Their Screening Effectiveness. Soil Dynamics and Earthquake Engineering, Volume:18, pp:1–10.
- [3] Shrivastava, R.K. and Kameswara Rao, N.S.V., (2002). Response of Soil Media due to Impulse Loads and Isolation Using Trenches. Soil Dynamics and Earthquake Engineering, Volume:22, pp:695–702.
- [4] Adam, M. and Von Estorff, O., (2005). Reduction of Train-Induced Building Vibrations by Using Open and Filled Trenches. Computers and Structures, Volume:83, pp:11–24.
- [5] Gao, G.Y., Li, Z.Y., Qiu, C. and Yue, Z.Q., (2006). Three-Dimensional Analysis of Rows of Piles as Passive Barriers for Ground Vibration Isolation. Soil Dynamics and Earthquake Engineering, Volume:26, pp:1015–1027.
- [6] Lu, J.F., Xu, B. and Wang, J.H., (2009). Numerical Analysis of Isolation of the Vibration due to Moving Loads Using Pile Rows. Journal of Sound and Vibration, Volume:319, pp:940–962.
- [7] Cao, Z., Cai, Y., Boström, A. and Zheng J., (2012). Semi-analytical Analysis of the Isolation to the Moving-Load Induced Ground Vibrations by Trenches on a Poroelastic Half-Space. Journal of Sound and Vibration, Volume:331, pp:947–961.
- [8] Klein, R., Antes, H. and Le Houédec, D., (1997). Efficient 3D Modelling of Vibration Isolation by Open Trenches. Computers and Structures, Volume:64, pp:809–817.
- [9] Massarsch, K.R., (2005). Vibration Isolation Using Gas-Filled Cushions. Soil Dynamics Symposium to Honor Prof. Richard D. Woods (Invited Paper), Geo-Frontiers, 22 p, Austin, Texas.
- [10] Zhang, F.Y., Chen, C.S., Wei, L.J. and Zhang, T., (2008). Cast-in-Place Concrete Thin-Wall Pipe as Barrier for Vibration Isolation. Journal of Central University of Technology, Volume:15, pp:121–125.
- [11] Pao, Y.H. and Mow, C.C., (1963). Scattering of Plane Compressional Waves by a Spherical Obstacles. Journal of Applied Physics, Volume:34, pp:493–499.
- [12] Woods, R.D., (1968). Screening of Surface Waves in Soils. PhD thesis, Industry Program of the College of Engineering, The University of Michigan, USA.
- [13] Lysmer, J. and Waas, G., (1972). Shear Waves in Plane Infinite Structures. Journal of Engineering Mechanics, ASCE, Volume:98, pp:85–105.
- [14] Segol, G., Abel, J.F. and Lee, P.C.Y., (1978). Amplitude Reduction of Surface Waves by Trenches. Journal of Engineering Mechanics, ASCE, Volume:104, pp:621–641.
- [15] Fuyuki, M. and Matsumoto, Y., (1980). Finite Difference Analysis of Rayleigh Wave Scattering at a Trench. Bulletin of the Seismological Society of America, Volume:70, pp:2051–2069.
- [16] Beskos, D.E., Dasgupta, B. and Vardoulakis, I.G., (1986). Vibration Isolation Using Open or Filled Trenches Part 1: 2-D Homogeneous Soil. Computational Mechanics, Volume:1, pp:43–63.
- [17] Dasgupta, B., Beskos, D.E. and Vardoulakis, I.G., (1990). Vibration Isolation Using Open or Filled Trenches Part 2: 3-D Homogeneous Soil. Computational Mechanics, Volume:6, pp:129–142.
- [18] Ahmad, S. and Al-Hussaini, T.M., (1991). Simplified Design For Vibration Screening by Open and In-Fılled Trenches. Journal of Geotechnical Engineering, Volume:117(1), pp:67–88.
- [19] Ahmad, S., Al-Hussaini, T.M. and Fishman, K.L., (1996). An Investigation on Active Isolation of Machine Foundations by Open Trenches. Journal of Geotechnical Engineering, Volume:122(6), pp:454–461.
- [20] Yang, Y.B., Kuo, S.R. and Hung, H.H., (1996). Frequency-Independent Infinite Elements for Analyzing Semi-Infinite Problems. International Journal for Numerical Methods in Engineering, Volume:39, pp:3553–3569.
- [21] Yang, Y.B. and Hung, H.H., (1997). A Parametric Study of Wave Barriers for Reduction of Train-Induced Vibrations. International Journal for Numerical Methods in Engineering, Volume:40, pp:3729–3747.
- [22] Andersen, L. and Nielsen, S.R.K., (2005). Reduction of Ground Vibration by means of Barriers or Soil Improvement Along a Railway Track. Soil Dynamics and Earthquake Engineering, Volume:25, pp:701–716.
- [23] Celebi, E. and Schmid, G., (2005). Investigation of Ground Vibrations Induced by Moving Loads. Engineering Structures, Volume:27, pp:1981–1998.
- [24] Celebi, E., (2006). Three-Dimensional Modelling of Train-Track and Sub-Soil Analysis for Surface Vibrations due to Moving Loads. Applied Mathematics and Computation, Volume:179, pp:209–230.
- [25] Hwang, J.H. and Tu, T.Y., (2006). Ground Vibration due to Dynamic Compaction. Soil Dynamics and Earthquake Engineering, Volume:26, pp:337–346.
- [26] Karlström, A. and Boström, A., (2007). Efficiency of Trenches along Railways for Trains Moving At Sub- or Supersonic Speeds. Soil Dynamics and Earthquake Engineering, Volume:27, pp:625–641.
- [27] Gao, G.Y., Shi, G., Feng, S.J. and Qiu, C., (2008). 3D Analysis of In-Filled Trench as Passive Barriers for Ground Vibration Isolation. Science in China Series G: Physics, Mechanics & Astronomy, Volume:51(10), pp:1573–1585.
- [28] Wang, J.G., Sun, W. and Anand, S., (2009). Numerical Investigation on Active Isolation of Ground Shock by Soft Porous Layers. Journal of Sound and Vibration, Volume:321, pp:492–509.
- [29] Çelebi, E., Fırat, S., Beyhan, G., Çankaya, İ., Vural, İ. and Kırtel O., (2009). Field Experiments on Wave Propagation and Vibration Isolation by Using Wave Barriers. Soil Dynamics and Earthquake Engineering, Volume:29, pp:824–833.
- [30] Tsai, P.H. and Chang, T.S., (2009). Effects of Open Trench Siding on Vibration-Screening Effectiveness Using the Two-Dimensional Boundary Element Method. Soil Dynamics and Earthquake Engineering, Volume:29, pp:865–873.
- [31] Jesmani, M., Fallahi, A.M. and Kashani, H.F., (2011). Study of Passive Isolation of Deep Foundations in Sandy Soil by Rectangular Trenches. Electronic Journal of Geotechnical Engineering, Volume:16, pp:1297–1318.
- [32] Jesmani, M., Fallahi, A.M. and Kashani, H.F., (2012). Effects of Geometrical Properties of Rectangular Trenches Intended for Passive Isolation in Sandy Soils. Earth Science Research, Volume:1(2), pp:137–151.
- [33] Celebi, E. and Göktepe, F., (2012). Non-linear 2-D FE Analysis for the Assessment of Isolation Performance of Wave Impeding Barrier in Reduction of Railway-Induced Surface Waves. Construction and Building Materials, Volume:36, pp:1–13.
- [34] Orehov, V.V., Moghanlou, R.N., Negahdar, H. and Varagh, A.M.B., (2012). Investigation Effects of Trench Barrier on the Reducing Energy of Surface Waves in Soils. 15th World Conference on Earthquake Engineering, September 24–28, Lisbon, Portugal.
- [35] Göktepe, F. ve Çelebi, E., (2014). Yüksek Hızlı Trenlerin Çevre Yapılarda Oluşturduğu Titreşimlerin Azaltılması İçin Düşey Dalga Bariyer Uygulaması. Zemin Mekaniği ve Temel Mühendisliği 2. Özel Konulu Sempozyumu: Teori ve Uygulamada Zemin-Yapı Etkileşimi Sempozyumu, 24–25 Nisan 2014, Antalya, Türkiye.
- [36] Düzgün, O.A., (2015). Efficiency of Trenches on Vibration Isolation Under Time Dependent Loads. Periodica Polytechnica Civil Engineering, Volume:59(2), pp:133 – 142.
- [37] Ohtsuki, A. and Harumi, K., (1983). Effect of Topography and Subsurface Inhomogeneities on Seismic SV waves. Earthquake Engineering and Structural Dynamics, Volume:11, pp:441–462.
- [38] Ohtsuki, A., Yamahara, H. and Harumi, K., (1984). Effect of Topography and Subsurface Inhomogeneity on Seismic Rayleigh Waves. Earthquake Engineering and Structural Dynamics, Volume:12, pp:37–58.
- [39] Chávez-Garcia, F.J. and Faccioli, E., (2000). Complex Site Effects and Building Codes: Making the Leap. Journal of Seismology, Volume:4, pp:23–40.
- [40] Gazetas, G., Kallou, P.V. and Psarropoulos, P.N., (2002). Topography and Soil Effects in the Ms 5.9 Parnitha (Athens) Earthquake: the Case of Adámes. Natural Hazards, Volume:27, pp:133–169.
- [41] Assimaki, D., Kausel, E. and Gazetas, G., (2005). Wave Propagation and Soil Structure Interaction on a Cliff Crest during the 1999 Athens Earthquake. Soil Dynamics and Earthquake Engineering, Volume:25, pp:513–527.