Mechanical Characteristics and Modeling of Multiple Trench Friction Pendulum System with Multi-intermediate Sliding Plates
In order to upgrade the seismic resistibility of structures and enhance the functionality of an isolator, a new base isolator called the multiple trench friction pendulum system (MTFPS) is proposed in this study. The proposed MTFPS isolator is composed of a trench concave surface and several intermediate sliding plates in two orthogonal directions. Mathematical formulations have been derived to examine the characteristics of the proposed MTFPS isolator possessing multiple intermediate sliding plates. By means of mathematical formulations, it can be inferred that the natural period and damping effect of the MTFPS isolator with several intermediate sliding plates can be altered continually and controllably during earthquakes. Furthermore, results obtained from shaking table tests demonstrate that the proposed isolator provides good protection to structures for prevention of damage from strong earthquakes.
[1] Zayas VA, Low SS and Mahin SA. The FPS earthquake resisting system
report. EERC Technical Report, UBC/EERC-87/01, 1987.
[2] Tsai CS. Seismic behavior of buildings with FPS isolators. Second
Congress on Computing in Civil Engineering (ASCE), Atlanta, GA, 1995;
1203-1211.
[3] Tsai CS. Finite element formulations for friction pendulum isolation
bearings. International Journal for Numerical Method in Engineering
1997; 40:29-49.
[4] Al-Hussaini TM, Zayas VA and Constantinou MC. Seismic isolation of
multi-story frame structures using spherical sliding isolation systems.
Technical Report, NCEER-94-0007, 1994.
[5] Jangid RS. Optimum friction pendulum system for near-fault motions.
Engineering Structures 2005; 27:349-359.
[6] Tsai CS, Chiang TC and Chen BJ. Finite element formulations and
theoretical study for variable curvature friction pendulum system.
Engineering Structures 2003; 25:1719-1730.
[7] Tsai CS, Chiang TC and Chen BJ. Seismic behavior of MFPS isolated
structure under near-fault sources and strong ground motions with long
predominant periods. In: the 2003 ASME Pressure Vessels and Piping
Conference, Seismic Engineering, Chen, J. C. (ed.), Cleveland, Ohio, U.
S. A., July, 2003; 466:73-79.
[8] Tsai CS, Chiang TC and Chen BJ. Shaking table tests of a full scale steel
structure isolated with MFPS. In: the 2003 ASME Pressure Vessels and
Piping Conference, Seismic Engineering, Chen, J. C. (ed.), Cleveland,
Ohio, U. S. A., July, 2003; 466:41-47.
[9] Tsai CS, Chen BJ, Pong WS and Chiang TC. Interactive behavior of
structures with multiple friction pendulum isolation system and
unbounded foundations", Advances in Structural Engineering, An
International Journal 2004; 7(6):539-551.
[10] Tsai CS, Chiang TC, Chen BJ. Experimental evaluation piecewise exact
solution for predicting seismic responses of spherical sliding type isolated
structures. Earthquake Engineering and Structural Dynamics 2005;
34(9):1027-1046.
[11] Tsai CS, Cheng CK, Chen MJ and S. H. Yu SH. Experimental study of
MFPS-isolated sensitive equipment. In: the 2003 ASME Pressure Vessels
and Piping Conference, Seismic Engineering, ASME, Edited by C. S.
Tsai, Denver, Colorado, U.S.A., July 17-21, 2005, 8:11-18.
[12] Tsai CS, Chen WS, Chiang TC and Chen BJ. Component and shaking
table tests for full-scale multiple friction pendulum system. Earthquake
Engineering and Structural Dynamics 2006; 35(11):1653-1675.
[13] Kim YS and Yun CB. Seismic response characteristics of bridges using
double concave friction pendulum bearings with tri-linear behavior.
Engineering Structures 2007; 29:3082-3093.
[14] Tsai, CS. Improved structures of base isolation systems. Taiwan Patent
No. 207126, Publication Number 00542278, Publication Date: July 11,
2003, Application Number 091210175, Filing date: July4, 2002 (in
Chinese).
[15] Tsai CS, Lu PC, Chen W S, Chiang TC, Yang CT and Lin YC. Finite
element formulation and shaking table tests of direction-optimized
friction pendulum system. Engineering Structures 2008; 30:2321-2329.
[16] Fenz DM and Constantinou MC. Spherical sliding isolation bearings with
adaptive behavior: Theory. Earthquake Engineering and Structural
Dynamics 2008; 37:168-183.
[17] Morgan TA and Mahin SA. The optimization of multi-stage friction
pendulum isolators for loss mitigation considering a range of seismic
hazard. In: the 14th World Conference on Earthquake Engineering,
Beijing, China, October 12-17, 2008; Paper No. 11-0070.
[18] Tsai, CS, Lu PC and Chen WS. Shaking table tests of a building isolated
with a trench friction pendulum system. In: the 2006 ASME Pressure
Vessels and Piping Conference, Seismic Engineering, Cory, James. F.
(ed.), Vancouver, BC, Canada, July, 2006; Paper No.
PVP2006-ICPVT11-93253.
[19] Tsai CS, Lin YC and Chen WS. Seismic behavior of high-tech facility
isolated with a trench friction pendulum system. In: the 2006 ASME
Pressure Vessels and Piping Conference, Seismic Engineering, Cory,
James. F. (ed.), Vancouver, BC, Canada, July, 2006; Paper No.
PVP2006-ICPVT11-93474.
[1] Zayas VA, Low SS and Mahin SA. The FPS earthquake resisting system
report. EERC Technical Report, UBC/EERC-87/01, 1987.
[2] Tsai CS. Seismic behavior of buildings with FPS isolators. Second
Congress on Computing in Civil Engineering (ASCE), Atlanta, GA, 1995;
1203-1211.
[3] Tsai CS. Finite element formulations for friction pendulum isolation
bearings. International Journal for Numerical Method in Engineering
1997; 40:29-49.
[4] Al-Hussaini TM, Zayas VA and Constantinou MC. Seismic isolation of
multi-story frame structures using spherical sliding isolation systems.
Technical Report, NCEER-94-0007, 1994.
[5] Jangid RS. Optimum friction pendulum system for near-fault motions.
Engineering Structures 2005; 27:349-359.
[6] Tsai CS, Chiang TC and Chen BJ. Finite element formulations and
theoretical study for variable curvature friction pendulum system.
Engineering Structures 2003; 25:1719-1730.
[7] Tsai CS, Chiang TC and Chen BJ. Seismic behavior of MFPS isolated
structure under near-fault sources and strong ground motions with long
predominant periods. In: the 2003 ASME Pressure Vessels and Piping
Conference, Seismic Engineering, Chen, J. C. (ed.), Cleveland, Ohio, U.
S. A., July, 2003; 466:73-79.
[8] Tsai CS, Chiang TC and Chen BJ. Shaking table tests of a full scale steel
structure isolated with MFPS. In: the 2003 ASME Pressure Vessels and
Piping Conference, Seismic Engineering, Chen, J. C. (ed.), Cleveland,
Ohio, U. S. A., July, 2003; 466:41-47.
[9] Tsai CS, Chen BJ, Pong WS and Chiang TC. Interactive behavior of
structures with multiple friction pendulum isolation system and
unbounded foundations", Advances in Structural Engineering, An
International Journal 2004; 7(6):539-551.
[10] Tsai CS, Chiang TC, Chen BJ. Experimental evaluation piecewise exact
solution for predicting seismic responses of spherical sliding type isolated
structures. Earthquake Engineering and Structural Dynamics 2005;
34(9):1027-1046.
[11] Tsai CS, Cheng CK, Chen MJ and S. H. Yu SH. Experimental study of
MFPS-isolated sensitive equipment. In: the 2003 ASME Pressure Vessels
and Piping Conference, Seismic Engineering, ASME, Edited by C. S.
Tsai, Denver, Colorado, U.S.A., July 17-21, 2005, 8:11-18.
[12] Tsai CS, Chen WS, Chiang TC and Chen BJ. Component and shaking
table tests for full-scale multiple friction pendulum system. Earthquake
Engineering and Structural Dynamics 2006; 35(11):1653-1675.
[13] Kim YS and Yun CB. Seismic response characteristics of bridges using
double concave friction pendulum bearings with tri-linear behavior.
Engineering Structures 2007; 29:3082-3093.
[14] Tsai, CS. Improved structures of base isolation systems. Taiwan Patent
No. 207126, Publication Number 00542278, Publication Date: July 11,
2003, Application Number 091210175, Filing date: July4, 2002 (in
Chinese).
[15] Tsai CS, Lu PC, Chen W S, Chiang TC, Yang CT and Lin YC. Finite
element formulation and shaking table tests of direction-optimized
friction pendulum system. Engineering Structures 2008; 30:2321-2329.
[16] Fenz DM and Constantinou MC. Spherical sliding isolation bearings with
adaptive behavior: Theory. Earthquake Engineering and Structural
Dynamics 2008; 37:168-183.
[17] Morgan TA and Mahin SA. The optimization of multi-stage friction
pendulum isolators for loss mitigation considering a range of seismic
hazard. In: the 14th World Conference on Earthquake Engineering,
Beijing, China, October 12-17, 2008; Paper No. 11-0070.
[18] Tsai, CS, Lu PC and Chen WS. Shaking table tests of a building isolated
with a trench friction pendulum system. In: the 2006 ASME Pressure
Vessels and Piping Conference, Seismic Engineering, Cory, James. F.
(ed.), Vancouver, BC, Canada, July, 2006; Paper No.
PVP2006-ICPVT11-93253.
[19] Tsai CS, Lin YC and Chen WS. Seismic behavior of high-tech facility
isolated with a trench friction pendulum system. In: the 2006 ASME
Pressure Vessels and Piping Conference, Seismic Engineering, Cory,
James. F. (ed.), Vancouver, BC, Canada, July, 2006; Paper No.
PVP2006-ICPVT11-93474.
@article{"International Journal of Architectural, Civil and Construction Sciences:51194", author = "C. S. Tsai and Yung-Chang Lin", title = "Mechanical Characteristics and Modeling of Multiple Trench Friction Pendulum System with Multi-intermediate Sliding Plates", abstract = "In order to upgrade the seismic resistibility of structures and enhance the functionality of an isolator, a new base isolator called the multiple trench friction pendulum system (MTFPS) is proposed in this study. The proposed MTFPS isolator is composed of a trench concave surface and several intermediate sliding plates in two orthogonal directions. Mathematical formulations have been derived to examine the characteristics of the proposed MTFPS isolator possessing multiple intermediate sliding plates. By means of mathematical formulations, it can be inferred that the natural period and damping effect of the MTFPS isolator with several intermediate sliding plates can be altered continually and controllably during earthquakes. Furthermore, results obtained from shaking table tests demonstrate that the proposed isolator provides good protection to structures for prevention of damage from strong earthquakes.
", keywords = "Friction Pendulum System, Multiple Friction Pendulum System, Base Isolation, Earthquake Engineering", volume = "3", number = "2", pages = "49-18", }
