Invariant points of semi-active suspensions

Nie, Shida; Zhuang, Ye; Chen, Fan; Xie, Jian

doi:10.1177/1687814018777316

Cited by 7 publications

(7 citation statements)

References 20 publications

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“…All powers of vehicles have amount and direction depends on the size of bump that hits the wheel, where the wheels are exposed to a vertical height when passing the road curves [7]. In fact, the vehicle suspension system is part of the structure and combines all important systems at the bottom of the vehicle which includes the Frame, suspension system, guidance system [8]- [9].…”

Section: Fig1classification Of Suspension Modelsmentioning

confidence: 99%

PID Controller of a Car with Quarter Body Active Suspension System

Mohammed

Bash

2021

jaset

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A Suspension system can be defined as the mechanism that physically separates the car body from the car wheels. The purpose of any suspension system is to increase the ride comfort, road handling and stability of closed loop system. The suspension design must be compensate the effect of conflicting criteria of road holding, load carrying and passenger comfort. An active suspension system has been proposed. A quarter-car two degree-of-freedom (2DOF) system is designed and constructed to simulate the actions of an active quarter car suspension system. White noise input is introduced to a given system to expressed unpaved road and both step input and sine wave input are studied as well. The control strategy is based on two degree of freedom PID controller. (MATLAB/ Simulink) is used to verify the proposed algorithm. The comparison between the passive and active suspension and the results obtained from a range of road input simulations in the proposed algorithm shows the effectiveness of the proposed algorithm and best results are obtained.

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Section: Fig1classification Of Suspension Modelsmentioning

confidence: 99%

PID Controller of a Car with Quarter Body Active Suspension System

Mohammed

Bash

2021

jaset

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“…In these points, the response amplitude is independent of the damping, which is represented in this case by the friction ratio. The presence of invariant points in the transmissibility curves is regarded as an important aspect in the design of mechanical systems such as dynamic vibration absorbers [48][49][50] and car suspensions [51,52]. In particular, according to the Den Hartog's theory illustrated in reference [53], these points can be used to determine the optimal configuration of a viscous damper acting as vibration absorber for a main undamped SDOF system.…”

Section: Invariant Pointsmentioning

confidence: 99%

Dynamic response of multi-degree-of-freedom systems with a Coulomb friction contact under harmonic excitation

Marino

Cicirello

2021

Preprint

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This paper investigates the steady-state response of a multi-degree-of-freedom (MDOF) system with a Coulomb contact to harmonic excitation. Although discrete MDOF models are commonly used at early design stages to analyse the dynamic performances of engineering structures, the current understanding of the friction damping effects on MDOF behaviour is still limited due to the absence of analytical solutions. In this contribution, closed-form expressions of the continuous time response, the displacement transmissibility and the phase angle of each mass of the system are derived and validated numerically for 2DOF and 5DOF systems. Moreover, the features of the analytical response are investigated, obtaining the following results: (i) the determination of the minimum amounts of friction for which the resonant peaks become finite and (ii) for which stick-slip motion can be observed at high frequencies; (iii) an equation for the evaluation of invariant points for the displacement transmissibilities; (iv) a better understanding of phenomena such as the inversions of the transmissibility curves and the onset of additional resonant peaks due to the permanent sticking of the mass in contact. All these results show that MDOF systems exhibit significantly different dynamic behaviours depending on whether the friction contact and the harmonic excitation are applied to the same or different masses.

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“…In these points, the response amplitude is independent of the damping, which is represented in this case by the friction ratio. The presence of invariant points in the transmissibility curves is regarded as an important aspect in the design of mechanical systems such as dynamic vibration absorbers [51][52][53] and car suspensions [54,55]. In particular, according to the Den Hartog's theory illustrated in reference [56], these points can be used to determine the optimal configuration of a viscous damper acting as vibration absorber for a main undamped SDOF system.…”

Section: Invariant Pointsmentioning

confidence: 99%

Dynamic response of multi-degree-of-freedom systems with a Coulomb friction contact under harmonic excitation

Marino

Cicirello

2021

Nonlinear Dyn

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This paper investigates the steady-state response of a harmonically excited multi-degree-of-freedom (MDOF) system with a Coulomb contact between: (1) a mass and a fixed wall; (2) two different masses; (3) a mass and an oscillating base. Although discrete MDOF models are commonly used at early design stages to analyse the dynamic performances of engineering structures, the current understanding of the friction damping effects on MDOF behaviour is still limited due to the absence of analytical solutions. In this contribution, closed-form expressions of the continuous time response, the displacement transmissibility and the phase angle of each mass of the system are derived and validated numerically for 2DOF and 5DOF systems. Moreover, the features of the analytical response are investigated, obtaining the following results: (i) the determination of the minimum amounts of friction for which the resonant peaks become finite and (ii) for which stick-slip motion can be observed at high frequencies; (iii) an equation for the evaluation of invariant points for the displacement transmissibilities; (iv) a better understanding of phenomena such as the inversions of the transmissibility curves and the onset of additional resonant peaks due to the permanent sticking of the mass in contact. All these results show that MDOF systems exhibit significantly different dynamic behaviours depending on whether the friction contact and the harmonic excitation are applied to the same or different masses.

show abstract

Invariant points of semi-active suspensions

Cited by 7 publications

References 20 publications

PID Controller of a Car with Quarter Body Active Suspension System

PID Controller of a Car with Quarter Body Active Suspension System

Dynamic response of multi-degree-of-freedom systems with a Coulomb friction contact under harmonic excitation

Dynamic response of multi-degree-of-freedom systems with a Coulomb friction contact under harmonic excitation

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