Suppression of Vertical Vibration in Railway Vehicle Carbodies Through Control of Damping Force in Primary Suspension: Presentation of Results From Running Tests With Meter-Gauge Car on a Secondary Line

Sugahara, Yoshiki; Kojima, Takashi

doi:10.2495/cr180301

Cited by 8 publications

(8 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Active systems aimed at improving ride comfort are typically installed in the secondary suspension, but there are examples where active control in primary suspension is proposed to attenuate the vibration of the car-body. A recent work shows that semi-active vertical primary suspension has potential to reduce car-body first bendingmode vibration [27]. Although this belongs to active primary suspension technically, the control strategy and implementation status are described in Sects.…”

Section: Active Secondary Suspension 41 Principles and Configurationsmentioning

confidence: 99%

“…4.2.3, a Shinkansen vehicle was tested recently on a roller rig and in the line. Field tests were carried out on a line having a relatively poor track quality, to verify the effectiveness of the scheme [27,39,89]. The semi-active primary suspension can selectively reduce the vibration of the first bending mode of the car-body, and with tuned LQG controller, the rigid car-body motions can also be attenuated to some degree.…”

Section: Implementation Of Semi-active Suspensionmentioning

confidence: 99%

See 1 more Smart Citation

Active suspension in railway vehicles: a literature survey

Giossi

Persson

et al. 2020

Rail. Eng. Science

View full text Add to dashboard Cite

Since the concept of active suspensions appeared, its large possible benefits has attracted continuous exploration in the field of railway engineering. With new demands of higher speed, better ride comfort and lower maintenance cost for railway vehicles, active suspensions are very promising technologies. Being the starting point of commercial application of active suspensions in rail vehicles, tilting trains have become a great success in some countries. With increased technical maturity of sensors and actuators, active suspension has unprecedented development opportunities. In this work, the basic concepts are summarized with new theories and solutions that have appeared over the last decade. Experimental studies and the implementation status of different active suspension technologies are described as well. Firstly, tilting trains are briefly described. Thereafter, an indepth study for active secondary and primary suspensions is performed. For both topics, after an introductory section an explanation of possible solutions existing in the literature is given. The implementation status is reported. Active secondary suspensions are categorized into active and semi-active suspensions. Primary suspensions are instead divided between acting on solid-axle wheelsets and independently rotating wheels. Lastly, a brief summary and outlook is presented in terms of benefits, research status and challenges. The potential for active suspensions in railway applications is outlined.

show abstract

Section: Active Secondary Suspension 41 Principles and Configurationsmentioning

confidence: 99%

Section: Implementation Of Semi-active Suspensionmentioning

confidence: 99%

Active suspension in railway vehicles: a literature survey

Giossi

Persson

et al. 2020

Rail. Eng. Science

View full text Add to dashboard Cite

show abstract

“…Active, semi-active and passive systems have been proposed to improve the ride comfort to vertical vibration in passenger coaches [10][11][12][13][14][15][16][17]. They are designed either to isolate the carbody from vibrations using active/semi-active suspension [10][11][12], or to reduce the structural vibration of the carbody through the damping provided by the active/passive suspension [13][14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Testing the Effectiveness of the Anti-Bending Bar System to Reduce the Vertical Bending Vibrations of the Railway Vehicle Carbody Using an Experimental Scale Demonstrator

Mazilu,

Dumitriu,

Sorohan

et al. 2024

Applied Sciences

View full text Add to dashboard Cite

In this paper, the vertical vibration behaviour of an experimental scale demonstrator of a railway vehicle carbody fitted with an anti-bending bar system of innovative design is studied to highlight its ability to raise the bending natural frequency of the railway vehicle carbody and to reduce the intensity of the vibration. The anti-bending bar system has been previously proposed by the second author as a new passive method to improve comfort in passenger coaches with long carbodies that have a natural bending frequency located in the range of maximum sensitivity of human beings to vertical vibration. The experimental scale demonstrator consists of an aluminium plate supported on four rubber supports. The aluminium beam reproduces to a scale of 1:10 the length of a passenger coach carbody, and its thickness is set so that the first bending frequency of the plate is close to the usual value of real carbodies. The anti-bending bar system consists of two steel bars arranged longitudinally in the middle of the aluminium plate, near its side edges. Each anti-bending bar is fixed at the ends to the aluminium plate by joints consisting of a clamping arm welded to a fixing flange. The two anti-bending bars oppose the bending movement of the aluminium plate, thus increasing its bending stiffness. This results in increasing the bending natural frequency of the aluminium plate and reduction its vibration. Testing the effectiveness of the anti-bending bar system consists of experimentally determining the frequency response of the aluminium plate acceleration without/with the anti-bending bar system by the impact hammer method. The experimental results show the first bending natural frequency increases from 9.01 Hz to 13.4 Hz and the acceleration amplitude decreases by more than 50% when the anti-bending bar system is used. To confirm these results, a theoretical model of the experimental scale demonstrator based on the finite element method was developed. The results obtained with this model are in line with those obtained experimentally.

show abstract

“…Active and semi-active vertical actuators have been used in conjunction with suspension springs to reduce and control the vertical vibrations of the train bogie. Skyhook and linear quadratic gaussian (LQG) control strategies are applied and compared to control primary vertical suspension [8]. The primary suspension is mainly for guiding the vehicle, and the secondary suspension is intended to enhance the vehicle's ride quality [9].…”

Section: Introductionmentioning

confidence: 99%

Semi-Active Vibration Control of Train Suspension Using Optimized PID Controller

A. Ali,

Metered,

M. Bassuiny

et al. 2024

Engineering Research Journal

View full text Add to dashboard Cite

Magnetorheological (MR) dampers emerge as highly advantageous semi-active mechanisms for vibration control within engineering systems, offering superior reliability and cost-effectiveness compared to active actuators, thus underscoring their significance in practical implementation. This research delves into the analysis of ride comfort in rail vehicles employing semi-active suspension control, examining its impact on the vertical dynamics of the train. The study employs the Harmony Search (HS) algorithm to optimize the gains of a proportional integral derivative (PID) controller, leveraging the self-adaptive global best harmony search method (SGHS) for its efficacy in minimizing tuning time and achieving optimal objective function values. The efficacy of the proposed controller is assessed through simulation of a quarter-rail vehicle model featuring six degrees of freedom (6-DOF) using MATLAB/Simulink software. Analysis of the simulated results demonstrates that the optimized PID controller markedly enhances ride comfort when compared to both passive suspension systems and conventional PID control strategies.

show abstract

Suppression of Vertical Vibration in Railway Vehicle Carbodies Through Control of Damping Force in Primary Suspension: Presentation of Results From Running Tests With Meter-Gauge Car on a Secondary Line

Cited by 8 publications

References 10 publications

Active suspension in railway vehicles: a literature survey

Active suspension in railway vehicles: a literature survey

Testing the Effectiveness of the Anti-Bending Bar System to Reduce the Vertical Bending Vibrations of the Railway Vehicle Carbody Using an Experimental Scale Demonstrator

Semi-Active Vibration Control of Train Suspension Using Optimized PID Controller

Contact Info

Product

Resources

About