Publication detail
Insight into the response time of fail-safe magnetorheological damper
JENIŠ, F. KUBÍK, M. MACHÁČEK, O. ŠEBESTA, K. STRECKER, Z.
English title
Insight into the response time of fail-safe magnetorheological damper
Type
journal article in Web of Science
Language
en
Original abstract
The significant problem of magnetorheological (MR) dampers is their poor fail-safe ability. In the case of power supply failure, the damper remains in a low damping state which is dangerous for several technical applications. This can be solved by accommodating a permanent magnet to the magnetic circuit of the damper. Currently, the MR dampers are used in progressive semiactive (S/A) control of suspension systems. The dynamics (force response time) of the damper is an important parameter that affects the performance of semiactive control. The main goal of this paper is to introduce the dynamic behavior of MR damper with a permanent magnet. The damper design with the permanent magnet in the magnetic circuit, transient magnetic simulation including magnetic hysteresis and eddy currents, and experiments are presented. The magnetic field response time and MR damper force response time are measured and also determined from magnetic simulation. The permanent magnet significantly influences the MR damper dynamics. The decrease of the damping force from a fail-safe state – medium damping to off-state – low damping is significantly faster (2 ms, -1A) than the increase to on-state – high damping (12 ms, 1A). The exact value is depending on the electric current magnitude and piston velocity. The damper achieved fail-safe damping force approximately 1/3 of the maximum damping force. The exact value of the fail-safe force is magnetization history-dependent. The maximum dynamic force range is 8.5 which is comparable with the common design of MR damper.
English abstract
The significant problem of magnetorheological (MR) dampers is their poor fail-safe ability. In the case of power supply failure, the damper remains in a low damping state which is dangerous for several technical applications. This can be solved by accommodating a permanent magnet to the magnetic circuit of the damper. Currently, the MR dampers are used in progressive semiactive (S/A) control of suspension systems. The dynamics (force response time) of the damper is an important parameter that affects the performance of semiactive control. The main goal of this paper is to introduce the dynamic behavior of MR damper with a permanent magnet. The damper design with the permanent magnet in the magnetic circuit, transient magnetic simulation including magnetic hysteresis and eddy currents, and experiments are presented. The magnetic field response time and MR damper force response time are measured and also determined from magnetic simulation. The permanent magnet significantly influences the MR damper dynamics. The decrease of the damping force from a fail-safe state – medium damping to off-state – low damping is significantly faster (2 ms, -1A) than the increase to on-state – high damping (12 ms, 1A). The exact value is depending on the electric current magnitude and piston velocity. The damper achieved fail-safe damping force approximately 1/3 of the maximum damping force. The exact value of the fail-safe force is magnetization history-dependent. The maximum dynamic force range is 8.5 which is comparable with the common design of MR damper.
Keywords in English
magnetorheological valve, MR damper, response time, permanent magnet, fail-safe, transient response, damper dynamics
Released
19.10.2020
Publisher
IOP Publishing
ISSN
1361-665X
Volume
1
Number
30
Pages from–to
1–13
Pages count
13
BIBTEX
@article{BUT165636,
author="Filip {Jeniš} and Michal {Kubík} and Ondřej {Macháček} and Karel {Šebesta} and Zbyněk {Strecker},
title="Insight into the response time of fail-safe magnetorheological damper",
year="2020",
volume="1",
number="30",
month="October",
pages="1--13",
publisher="IOP Publishing",
issn="1361-665X"
}