Your search keyword '"Kuan Hua Lien"' showing total 8 results

1. Suspension-type tuned mass dampers with varying pendulum length to dissipate energy

Author

Lap Loi Chung, Kuan Hua Lien, Yong An Lai, Lai Yun Wu, and C. S.Walter Yang

Subjects

021110 strategic, defence & security studies, Engineering, business.industry, 0211 other engineering and technologies, Pendulum, 020101 civil engineering, 02 engineering and technology, Building and Construction, Structural engineering, Linear motor, Dissipation, 0201 civil engineering, Vibration, Mechanics of Materials, Control theory, Tuned mass damper, Restoring force, Suspension (vehicle), business, Civil and Structural Engineering, Rope

Abstract

Summary In this paper, an optimal energy dissipation control algorithm is applied into a semi-active suspension-type tuned mass damper (SA-STMD) to suppress excessive vibration by means of variable pendulum length. The SA-STMD mechanism consists of a mass block, a suspension rope, and a movable fulcrum that can be a short tube driven by a linear motor to vertically move along the suspension rope. As the fulcrum goes up, the pendulum length is extended, resulting in a smaller stiffness of the SA-STMD, and vice versa. Accordingly, the restoring force in the SA-STMD can be adjusted by varying the fulcrum positions. In the case where the energy dissipation ability by the original STMDs is insufficient, the movable fulcrum in the SA-STMD system can compensate the STMDs for stiffness according to the proposed optimal energy dissipation control algorithm to provide controllable restoring forces. The controllable restoring forces are designed to act as viscous dampers that can make up for the lack of energy dissipation capacity. The numerical results from the time domain and frequency domain analyses show that the proposed approach utilizing the optimal energy dissipation control algorithm to adjust the pendulum length can induce controllable restoring forces with a butterfly-shaped hysteresis loop, supplying a sufficient energy dissipation capacity to reduce responses to the unexpectedly large external vibration. Another potential benefit is cost reduction because of use of a less number of conventional viscous dampers in the STMD system. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

2. In situexperiment on retrofit of school buildings by adding sandwich columns to partition brick walls

Author

Kuan-Hua Lien, Lai-Yun Wu, Yao-Sheng Yang, and Lap-Loi Chung

Subjects

Engineering, Brick, business.industry, Earth and Planetary Sciences (miscellaneous), Structural engineering, Geotechnical Engineering and Engineering Geology, business, Partition (database)

Abstract

SUMMARY Many significantly strong earthquakes have occurred over the years in Taiwan, which have caused tremendous damage to primary and middle school buildings; the 921 Chi-Chi earthquake was particularly devastating. According to statistics, 786 schools (1,958 classrooms) were damaged on September 21, 1999 during this earthquake event. The devastation showed that a lack of seismic performance is a common problem for existing school buildings in Taiwan. Therefore, the retrofit of existing school buildings has become an urgent issue in the prevention of possible damage in the future. The retrofit technique of adding sandwich columns to partition brick walls is proposed in this paper, and the feasibility of the proposed method was verified by in situ pushover tests of two real school buildings, one without and one with retrofit. The experimental and analytical results show that the sandwich column itself contributes significantly to the seismic capacity of the examined school building. Moreover, the analytical results yielded conservative capacity curves when compared with the experimental results. Copyright © 2013 John Wiley & Sons, Ltd.

Published

2013

3. Semi-active tuned mass dampers with phase control

Author

Yong An Lai, Chuang Sheng Walter Yang, Lap Loi Chung, Lai Yun Wu, and Kuan Hua Lien

Subjects

Engineering, Acoustics and Ultrasonics, Maximum power principle, Computer simulation, business.industry, Friction force, Mechanical Engineering, Structural engineering, Condensed Matter Physics, Phase lag, Semi active, Mechanics of Materials, Control theory, Robustness (computer science), Tuned mass damper, business, Phase control

Abstract

The present study aims at proposing an innovative phase control methodology for semi-active tuned mass dampers (SA-TMDs) that intend to minimize the off-tuned problems associated with passive tuned mass dampers (P-TMDs). The phase control algorithm is first developed, the essential of which is to apply the variable friction force to slow down the mass block at specific moments when the phase lag of the SA-TMD with respect to the structure is different from 90°, resulting in the SA-TMD back to the desired phase lag, i.e., −90° phase deviation, so that the SA-TMD has the maximum power flow to reduce the structural vibration. The feasibility of the application of the phase control in SA-TMDs is verified by performing numerical analyses of a simplified Taipei 101 structure model with a SA-TMD subjected to sinusoidal loads and design level wind loads. The numerical simulation results show that the SA-TMD implemented with phase control can enable the mass block to vibrate in a manner with a phase lag close to the −90° when the structure model is under sinusoidal excitations with frequencies different from the structural fundamental mode. The SA-TMD with phase control not only exhibits better performance than the optimal P-TMD in terms of suppressing the structural vibration, but also enhances its robustness, particularly when the SA-TMD is off-tuned to the structure.

Published

2013

4. Applicability investigation of code-defined procedures on seismic performance assessment of typical school buildings in Taiwan

Author

Chi-Hsiang Sun, Kuan-Hua Lien, Lap-Loi Chung, Yung-Tsang Chen, and Lai-Yun Wu

Subjects

Soft story building, Engineering, business.industry, Frame (networking), Structural engineering, Building design, computer.software_genre, Civil engineering, Test (assessment), Load testing, Building code, Code (cryptography), Joint (building), business, computer, Civil and Structural Engineering

Abstract

Seismic resistance of elementary and high school buildings is of great concern due to high earthquake risk in Taiwan. Existing school buildings are often built of similar configurations, and designed based on previous building codes, which are not in compliance with current codes in seismic performance objective. The use of current code procedures on seismic performance assessment of existing typical school buildings may not be applicable in predicting their structural behavior during earthquakes. This paper describes a full-size two-story, three-bay frame structure test of typical school building design in Taiwan, and examines the performance and failure mechanism of the frame structure with current building codes. Results from loading test show good agreement with the code-defined procedures in identifying soft story, weak story, and failure modes of columns, but show different failure mechanism in beam–column joint region, i.e. strong-column–weak-beam is expected by building code procedures, whereas the test specimen exhibits weak-column–strong-beam behavior. Although the joint shear check following current code procedures gives satisfactory results, i.e. is consistent with the experiment, the check on its own is not a reasonable one. Revisions of current checking procedures for failure mechanism in beam column joint and for joint shear are also proposed in this paper for existing non-ductile reinforced concrete school buildings. The revised procedures incorporate the effects of both weak story and weak-column–strong-beam behavior. After adopting the proposed procedures, the predicted structural behavior and failure modes are consistent with those observed from the full-size frame test.

Published

2012

5. Optimal design of friction pendulum tuned mass damper with varying friction coefficient

Author

Hsu-Hui Huang, Lap-Loi Chung, L. Y. Wu, Kuan-Hua Lien, and H. H. Chen

Subjects

Optimal design, Engineering, business.industry, Pendulum, Building and Construction, Structural engineering, Damper, Vibration, Mechanics of Materials, Tuned mass damper, Sensitivity (control systems), Centrifugal pendulum absorber, Suspension (vehicle), business, Civil and Structural Engineering

Abstract

SUMMARY Tuned mass dampers with viscous damping and isolation systems with friction pendulums have been proposed and widely applied over the past several decades. By combining these two ideas, a friction pendulum tuned mass damper (FPTMD) is proposed in this study. Because the restoring and friction forces are provided by the spherical surface of the FPTMD, springs and dampers are not needed. Moreover, suspension is not necessary and the installation space is greatly reduced. The optimal design of the FPTMD with varying friction coefficients for wind-excited high-rise structures is investigated. The optimization procedures are demonstrated by the FPTMD implemented on Taipei 101 under white-noise wind force, and the optimization results are validated by three-dimensional graphs. From the results of the sensitivity study, the effectiveness of the FPTMD with two different patterns of friction coefficients is sensitive to the tuning frequency ratio but not very sensitive to the friction parameters. Moreover, an FPTMD with a friction coefficient that linearly varies with displacement is even less sensitive to the friction parameters and the amplitude of excitation. The feasibility of the FPTMD with two different patterns of friction coefficient is illustrated by Taipei 101 subjected to the design wind force with a return period of 50 years. Following design optimization and numerical verification, the effect of vibration reduction for Taipei 101 is demonstrated. Copyright © 2012 John Wiley & Sons, Ltd.

Published

2012

6. Optimal design formulas for viscous tuned mass dampers in wind-excited structures

Author

Mei-Chun Lin, Lap-Loi Chung, Chuang-Sheng Walter Yang, Lai-Yun Wu, Kuan-Hua Lien, and Hsu-Hui Huang

Subjects

Optimal design, Sequence, Engineering, Damping ratio, business.industry, Building and Construction, White noise, Function (mathematics), Mass ratio, Nonlinear system, Mechanics of Materials, Control theory, Tuned mass damper, business, Civil and Structural Engineering

Abstract

SUMMARY Optimal design for tuned mass dampers (TMDs) with linear or nonlinear viscous damping is formulated in order for design practitioners to directly compute the optimal parameters of a TMD in a damped structure subjected to wind excitations. The optimal TMD tuning frequency ratio and damping coefficient for a viscous TMD system installed in a damped structure under 10 white noise excitations are determined by using the time-domain optimization procedure, which minimizes the structural response. By applying a sequence of curve-fitting schemes to the obtained optimal values, design formulas for optimal TMDs are then derived. These are expressed as a function of the mass ratio and damping power-law exponent of the TMD as well as the damping ratio of the structure. The feasibility of the proposed optimal design formulas is verified in terms of formulary accuracy and of comparisons with existing formulas from previous research works. In addition, one numerical example of the Taipei 101 building with a nonlinear TMD, which is redesigned according to the proposed optimal formulas, is illustrated in effort to describe the use of the formulas in the TMD design procedure and to investigate the effectiveness of the optimal TMD. The results indicate that the proposed optimal design formulas provide a convenient and effective approach for designing a viscous TMD installed in a wind-excited damped structure. Copyright © 2011 John Wiley & Sons, Ltd.

Published

2011

7. Experimental study on retrofit of school buildings by adding sandwich columns to partition brick walls

Author

Lai Yun Wu, Lap-Loi Chung, and Kuan-Hua Lien

Subjects

Engineering, Brick, business.industry, Cost effectiveness, Structural engineering, Geotechnical Engineering and Engineering Geology, Civil engineering, Residual strength, Column (typography), Ultimate tensile strength, Earth and Planetary Sciences (miscellaneous), Seismic retrofit, Retrofitting, Doors, business

Abstract

Thousands of buildings were damaged by the devastating Chi-Chi earthquake on September 21, 1999. Of all the public buildings, school buildings are the most vulnerable to earthquake damage, and the retrofitting of existing school buildings becomes a stringent issue. In addition to cost effectiveness, the impact of retrofitting methods on the functions of the school buildings needs to be considered. This paper therefore proposes the retrofitting of school buildings by adding sandwich columns onto partition brick walls. The sandwich column is divided into two parts and is added to the two sides of the partition brick wall held with pairs of U-shaped bars. The retrofit does not require the removal of windows or doors in the longitudinal direction making the proposed method cost effective and minimizes the impact on the function of the school buildings. Five full-scale specimens without and with retrofitting were designed and fabricated for testing based on the partition brick wall frames of the existing school buildings. The specimens were subjected to cyclic loading in the out-of-plane direction through a loading frame so that the columns deformed with double curvatures. The experimental results verified the feasibility of the proposed retrofit method. The data showed that the lateral strength of the retrofitted specimen doubled that which was not and that the residual strength of the retrofitted specimen was just as high as the ultimate strength of the specimen without retrofitting. The analytical results in lateral strength yielded conservative figures compared with experimental measurements. Copyright © 2011 John Wiley & Sons, Ltd.

Published

2011

8. Optimal design theories of tuned mass dampers with nonlinear viscous damping

Author

Lap-Loi Chung, Kuan-Hua Lien, Chung-Hsin Chang, Hsu-Hui Huang, and Lai-Yun Wu

Subjects

Optimal design, Engineering, Viscous damping, business.industry, Mechanical Engineering, Frequency ratio, Building and Construction, Structural engineering, Geotechnical Engineering and Engineering Geology, Performance index, Nonlinear system, Control theory, Tuned mass damper, Time domain, Sensitivity (control systems), business, Civil and Structural Engineering

Abstract

Optimal design theory for linear tuned mass dampers (TMD) has been thoroughly investigated, but is still under development for nonlinear TMDs. In this paper, optimization procedures in the time domain are proposed for design of a TMD with nonlinear viscous damping. A dynamic analysis of a structure implemented with a nonlinear TMD is conducted first. Optimum design parameters for the nonlinear TMD are searched using an optimization method to minimize the performance index. The feasibility of the proposed optimization method is illustrated numerically by using the Taipei 101 structure implemented with TMD. The sensitivity analysis shows that the performance index is less sensitive to the damping coefficient than to the frequency ratio. Time history analysis is conducted using the Taipei 101 structure implemented with different TMDs under wind excitation. For both linear and nonlinear TMDs, the comfort requirements for building occupants are satisfied as long as the TMD is properly designed. It was found that as the damping exponent increases, the relative displacement of the TMD decreases but the damping force increases.

Published

2009