Your search keyword '"Guo-Jun Yu"' showing total 8 results

1. The Mechanical Properties of a Smart Compression-Type Isolator Based on Magnetorheological Gel and Magnetorheological Elastomer

Author

Guo-Jun Yu, Xi-Xi Wen, Cheng-Bin Du, and Fei Guo

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

In order to control the vibration of civil building structures, a smart extrusion-type isolator was developed based on magnetorheological gel (MRG) and magnetorheological elastomer (MRE). The key technology and performance tests of the isolator were investigated as well as the identification of parameters of the mechanical model. Test results showed that the MRG cylinder has a damping characteristic at high frequency while the MRE cylinder has an isolation characteristic at low frequency. The designed isolator is therefore superior over the traditional isolator since it will show small damping and low dynamic stiffness at a high frequency and small amplitude situation, which can overcome stiffness hardening that occurs on the traditional isolator. Meanwhile, the designed isolator will also have the behavior of large isolation and high dynamic stiffness under the low frequency and large amplitude condition, which has the advantage of realizable displacement control. The uniaxial mechanical model for the MRG/MRE smart isolator was built, and the parameters of the designed vibration isolator were identified. Theoretical results obtained from the mechanical model of the MRG/MRE smart isolator agree well with the experimental results indicating that the parameter identification method is feasible and effective.

Published

2019

2. The Mechanical Properties of a Novel STMR Damper Based on Magnetorheological Silly Putty

Author

Xiao-Guo Lin, Fei Guo, Cheng-Bin Du, and Guo-Jun Yu

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

A novel shear thickening magnetorheological (STMR) damper with both speed locking and semiactive controlling properties was designed and fabricated based on multifunctional smart composite materials which was defined as magnetorheological Silly Putty (MRSP). The rate sensitive property and magnetorheological effect of MRSP samples were analyzed by using a rheometer to select the best filler for the STMR damper. The mechanical properties of the STMR damper were investigated through slow, fast, and dynamic experiments. The experimental results indicate that the STMR damper exhibits an obvious rate sensitive characteristic and semiactive control property. On one hand, when the STMR damper is simulated fast enough, it can realize the “speed switch” function, which enables it to instantly lock up and act as a shock transmission unit (STU). On the other hand, when the STMR damper is applied with current, the damping force can be adjusted by magnetic field strength to realize its semiactive controlling property. In addition, a multiparameter and symmetry model was established to describe the dynamic hysteretic behavior of the STMR damper, which is consistent with the experimental data.

Published

2018

3. The Static and Dynamic Mechanical Properties of Magnetorheological Silly Putty

Author

Fei Guo, Cheng-bin Du, Guo-jun Yu, and Run-pu Li

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

A novel magnetorheological material defined as magnetorheological Silly Putty (MRSP) is prepared by dispersing soft magnetic particles into Silly Putty matrix with shear stiffening property. Static mechanical properties including creep and stress relaxation and dynamic rheological properties of MRSPs are tested by rheometer. The experimental results indicate that the external magnetic field exerts significant influence on the creep and relaxation behaviors. Moreover, the storage modulus of MRSPs increases sharply in response to the external stimuli of increasing angular frequency automatically and can be enhanced by external magnetic field. Besides, temperature plays a key role in shear stiffening and magnetorheological effect of MRSPs. Furthermore, considering the obstruction to the particle chains formation induced by Silly Putty matrix, a nonperforative particle aggregated chains model is proposed. The model curve is in consistency with experimental data, which means it can describe magnetoinduced behavior of MRSPs well.

Published

2016

4. Performance of Variable Negative Stiffness MRE Vibration Isolation System

Author

Run-pu Li, Cheng-bin Du, Fei Guo, Guo-jun Yu, and Xiao-guo Lin

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Magnetorheological elastomer (MRE) vibration isolation devices can improve a system’s vibration response via adjustable stiffness and damping under different magnetic fields. Combined with negative stiffness design, these MRE devices can reduce a system’s stiffness and improve the vibration control effect significantly. This paper develops a variable negative stiffness MRE isolation device by combining an improved separable iron core with laminated MREs. The relationship between the negative stiffness and the performance of the device is obtained by mathematical transformation. Its vibration response under simple harmonic excitation at small amplitude and the impact of the volume fraction of soft magnetic particles on the isolation system are also analyzed. The results show that the negative stiffness produced by the magnetic force is a major factor affecting the capacity of the isolation system. Compared to devices of the same size, the isolation system equipped with low-particle volume fraction MREs demonstrates better performance.

Published

2015

5. The Mechanical Properties of a Smart Compression-Type Isolator Based on Magnetorheological Gel and Magnetorheological Elastomer

Author

Xi-Xi Wen, Guo-Jun Yu, Chengbin Du, and Fei Guo

Subjects

Materials science, Article Subject, 02 engineering and technology, Low frequency, 01 natural sciences, 0103 physical sciences, lcsh:TA401-492, medicine, Cylinder, General Materials Science, 010302 applied physics, business.industry, Isolator, technology, industry, and agriculture, General Engineering, Stiffness, Structural engineering, 021001 nanoscience & nanotechnology, Magnetorheological elastomer, Vibration, Vibration isolation, Magnetorheological fluid, lcsh:Materials of engineering and construction. Mechanics of materials, medicine.symptom, 0210 nano-technology, business

Abstract

In order to control the vibration of civil building structures, a smart extrusion-type isolator was developed based on magnetorheological gel (MRG) and magnetorheological elastomer (MRE). The key technology and performance tests of the isolator were investigated as well as the identification of parameters of the mechanical model. Test results showed that the MRG cylinder has a damping characteristic at high frequency while the MRE cylinder has an isolation characteristic at low frequency. The designed isolator is therefore superior over the traditional isolator since it will show small damping and low dynamic stiffness at a high frequency and small amplitude situation, which can overcome stiffness hardening that occurs on the traditional isolator. Meanwhile, the designed isolator will also have the behavior of large isolation and high dynamic stiffness under the low frequency and large amplitude condition, which has the advantage of realizable displacement control. The uniaxial mechanical model for the MRG/MRE smart isolator was built, and the parameters of the designed vibration isolator were identified. Theoretical results obtained from the mechanical model of the MRG/MRE smart isolator agree well with the experimental results indicating that the parameter identification method is feasible and effective.

Published

2019

6. The Mechanical Properties of a Novel STMR Damper Based on Magnetorheological Silly Putty

Author

Chengbin Du, Guo-Jun Yu, Xiao-guo Lin, and Fei Guo

Subjects

Flubber, Dilatant, Materials science, Article Subject, business.industry, Rheometer, General Engineering, 02 engineering and technology, Structural engineering, 021001 nanoscience & nanotechnology, Damper, Shock (mechanics), 020303 mechanical engineering & transports, 0203 mechanical engineering, Magnetorheological fluid, lcsh:TA401-492, General Materials Science, lcsh:Materials of engineering and construction. Mechanics of materials, 0210 nano-technology, business

Abstract

A novel shear thickening magnetorheological (STMR) damper with both speed locking and semiactive controlling properties was designed and fabricated based on multifunctional smart composite materials which was defined as magnetorheological Silly Putty (MRSP). The rate sensitive property and magnetorheological effect of MRSP samples were analyzed by using a rheometer to select the best filler for the STMR damper. The mechanical properties of the STMR damper were investigated through slow, fast, and dynamic experiments. The experimental results indicate that the STMR damper exhibits an obvious rate sensitive characteristic and semiactive control property. On one hand, when the STMR damper is simulated fast enough, it can realize the “speed switch” function, which enables it to instantly lock up and act as a shock transmission unit (STU). On the other hand, when the STMR damper is applied with current, the damping force can be adjusted by magnetic field strength to realize its semiactive controlling property. In addition, a multiparameter and symmetry model was established to describe the dynamic hysteretic behavior of the STMR damper, which is consistent with the experimental data.

Published

2018

7. The Static and Dynamic Mechanical Properties of Magnetorheological Silly Putty

Author

Chengbin Du, Fei Guo, Run-pu Li, and Guo-Jun Yu

Subjects

Materials science, Article Subject, Rheometer, 0211 other engineering and technologies, General Engineering, 02 engineering and technology, Dynamic mechanical analysis, 021001 nanoscience & nanotechnology, Stiffening, Shear (sheet metal), Creep, Rheology, 021105 building & construction, Magnetorheological fluid, Stress relaxation, lcsh:TA401-492, General Materials Science, lcsh:Materials of engineering and construction. Mechanics of materials, Composite material, 0210 nano-technology, Simulation

Abstract

A novel magnetorheological material defined as magnetorheological Silly Putty (MRSP) is prepared by dispersing soft magnetic particles into Silly Putty matrix with shear stiffening property. Static mechanical properties including creep and stress relaxation and dynamic rheological properties of MRSPs are tested by rheometer. The experimental results indicate that the external magnetic field exerts significant influence on the creep and relaxation behaviors. Moreover, the storage modulus of MRSPs increases sharply in response to the external stimuli of increasing angular frequency automatically and can be enhanced by external magnetic field. Besides, temperature plays a key role in shear stiffening and magnetorheological effect of MRSPs. Furthermore, considering the obstruction to the particle chains formation induced by Silly Putty matrix, a nonperforative particle aggregated chains model is proposed. The model curve is in consistency with experimental data, which means it can describe magnetoinduced behavior of MRSPs well.

Published

2016

8. Performance of Variable Negative Stiffness MRE Vibration Isolation System

Author

Xiao-guo Lin, Run-pu Li, Chengbin Du, Guo-Jun Yu, and Fei Guo

Subjects

Materials science, animal structures, Article Subject, business.industry, General Engineering, Vibration control, Stiffness, Structural engineering, Simple harmonic motion, Magnetorheological elastomer, equipment and supplies, Magnetic field, Vibration isolation, Magnetic core, Volume fraction, medicine, lcsh:TA401-492, General Materials Science, lcsh:Materials of engineering and construction. Mechanics of materials, medicine.symptom, business

Abstract

Magnetorheological elastomer (MRE) vibration isolation devices can improve a system’s vibration response via adjustable stiffness and damping under different magnetic fields. Combined with negative stiffness design, these MRE devices can reduce a system’s stiffness and improve the vibration control effect significantly. This paper develops a variable negative stiffness MRE isolation device by combining an improved separable iron core with laminated MREs. The relationship between the negative stiffness and the performance of the device is obtained by mathematical transformation. Its vibration response under simple harmonic excitation at small amplitude and the impact of the volume fraction of soft magnetic particles on the isolation system are also analyzed. The results show that the negative stiffness produced by the magnetic force is a major factor affecting the capacity of the isolation system. Compared to devices of the same size, the isolation system equipped with low-particle volume fraction MREs demonstrates better performance.

Published

2015