Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

46, 4, pp. 933-947, Warsaw 2008

AN EXPERIMENTAL ELECTROMAGNETIC INDUCTION

DEVICE FOR A MAGNETORHEOLOGICAL DAMPER

Bogdan Sapiński

AGH University of Science and Technology, Department of Process Control, Cracow, Poland

e-mail: deep@agh.edu.pl

The work presents an experimental electromagnetic induction device
consisting of permanentmagnets and a coilwhich produces electric ener-
gy for an attachedmagnetorheological (MR) damper. The study covers
design considerations and calculations of magnetic fields, description of
the engineered device, and results of experimental tests on the dynamic
testing machine.

Key words: electromagnetic induction, magnetorheological damper,
vibration

1. Introduction

A conventional MR damper-based vibration control system is a feedback sys-
tem (Fig.1). Sucha system includes: a sensor (to detect vibration), a controller
(to manipulate the signal obtained from the sensor according to the assumed
control law) and an MR damper (to control the mechanical response of the
structure) which is activated by a power controller. In some applications, in-
stallation and maintenance of such system can be complex (e.g. large-scale
civil structures) and, therefore, new solutions are sought.

The drawbacks of the feedback system can be eliminated by introducing a
system with an electromagnetic induction device attached to an MR damper
(Cho et al. 2005). A schematic diagram of the system is shown in Fig.2. This
system involves coupling of vibration of the structurewith the force generated
by the MR damper. The electromagnetic induction device produces electric
energy (induced current), according toFaraday’s law,which is used to activate
theMRdamper. Such a systemdoes not need any sensor, controller andpower
controller, and can adjust itself to structural vibrations.



934 B. Sapiński

Fig. 1. ConventionalMR damper-based vibration control system

Fig. 2. MR damper-based vibration control systemwith an electromagnetic
induction device

The study summarizes the background design objectives and testing of an
experimental electromagnetic induction device which consists of permanent
magnets andacoil.The testswere conductedusingadynamic testingmachine.

2. Operation principle

The electromagnetic induction device uses the kinetic energy of reciprocating
motion of theMRdamperwhich is converted to electric energy. These conver-
tion proceeds according to Faraday’s law which expresses the phenomenon
found experimentally.



An experimental electromagnetic induction device... 935

Themathematical form of Faraday’s law is

e=−
dΨ(t)

dt
=−N

d

dt

(

∫

S

B ·dS
)

(2.1)

where Ψ is magnetic flux linkage through the area of coil cross section S,
N is the number of turns, B is themagnetic flux density and e is the induced
electromotive force (in volts).
Theminus sign is amanifestation of Lenz’s lawwhich states that the sense

(clockwise or counterclockwise) of the induced electromotive force created by
a change in themagnetic fluxmust be such as to oppose the change producing
it.
Recalling Eq. (2.1), it is apparent that the time change can work in two

different ways. The first is through time changes in the magnetic flux density
B(t), and the second is through changes in the shape and orientation of the
coil area S. Combination of both can also occur.
Note that by defining the magnetic flux linkage as:

dΨ =NdΦ=NB ·dS=NBdS cosϕ (2.2)

(2) where ϕ is the angle between B and dS.
In the case of time changes in the magnetic flux density B(t), Eq. (2.1)

can be rewritten in the form

e=−N
dΦ

dt
=−NS

dB

dt
(2.3)

Thus, Faraday’s law states that the induced electromotive force in the coil
equals the negative of the time rate of the magnetic flux change through the
coil. In other words, relative motion between the coil and permanentmagnets
of the considered device causes a change of the magnetic flux that induces an
electromotive force in the coil. This force can also be regulated by the number
of turns of winding in the coil or the intensity of permanent magnets.

3. Design considerations and calculations of magnetic fields

In the design procedure, we assumed that the electromagnetic induction devi-
ce:
• is attached to theMR damper of RD-1005-3 of Lord Co.
(http://www.lord.com),

• incorporates moveable permanent magnets and an immoveable coil.



936 B. Sapiński

Main parameters of the RD-1005-3 damper whose structure is shown in
Fig.3 are: stroke ±25mm, input voltage 12VDC, input current; continuous
< 1.0Aand intermittent < 2.0A, coil resistance 5Ω (at 25◦C), force (peak to
peak); 2224N (51 ·10−3m/s, 1A) and 667N (200 ·10−3m/s, 0A), response
time < 25ms (time to reach 90%ofmax. level during a 0A to 1A (dependent
on the amplifier and power supply).

Fig. 3. Structure of the RD-1005-3 damper

Force-velocity loops of this damper obtained for a sine displacement exci-
tation of the piston by amplitude 10 ·10−3m and frequency 1Hz, and input
currents 0.0, 0.2, 0.4A are shown in Fig.4 (Sapiński, 2006). The plots reveal
that a higher current yields a greater force response while the influence of
piston velocity is less significant.

Fig. 4. Force-velocity loops of the RD-1005-3 damper

The designed electromagnetic induction device incorporatesmagnets who-
se arrangement and orientation is explained in Fig.5 (Sapiński, 2008). The
magnets are magnetized along their height, which implies that one circular
surface acts as the N pole, and the opposite becomes the S pole. Themagnets
are arranged in two sets and are held on a bolt made of non-ferromagnetic
material. The number of magnets in each set is four. They are arrayed such



An experimental electromagnetic induction device... 937

that in each magnet the surface acting as the N pole should interface the
S-surface of the nextmagnet. Themagnet sets aremounted on the bolt at the
distance Hg such that the surface of one magnet being the N(S) pole should
be placed opposite the same surface in the other set.

Fig. 5. Sketch of magnets arrangement on the bolt

The device employs sintered ring-shaped neodymium magnets
(http://www.magnesy.pl). The magnetic flux density from the magnets
surface in the distance 0.7 ·10−3m is 0.30T. The demagnetization characte-
ristic of these magnets shown in Fig.6 (II quadrant) is given by

B=µ0H+J (3.1)

where H is themagnetic field strength, J –magnetization and µ0 ismagnetic
permeability of vacuum.
For the magnets arrangement shown in Fig.5 we computed the magnetic

field distributions, assuming that: the magnet height is hm = 5mm (Hm =
20mm), magnet diameter is Φm =30mm, bolt diameter is Φb =10mm and
the distance between magnet sets is Hg =20mm. The calculation procedure
used the FLUX 2D program (Cedrat, 2000).
Figure 7a presents the applied 2Dmeshmodel of the device with the coor-

dinate system (r,z). Themodel yields 3819 cells and 7700 nodes. The derived
distribution of magnetic field lines is shown in Fig.7b. Note that in the assu-
med orientation of magnets, most of the magnetic field lines is concentrated
in the gap between the magnets sets. The largest concentration of these lines
occurs on the outer edges of the magnets.



938 B. Sapiński

Fig. 6. Demagnetization characteristics of magnets

Fig. 7. (a) Meshmodel, (b) magnetic field lines

Next we computed the magnetic flux density in the device, knowing that
the gap between the magnet sets was filled either by air or by a ferroma-
gnetic material of cylindrical shape (see the dot line in Fig.5). The magnetic
permeability of this material is µ = 104µ0 (µ0 = 4π10

−7H/m is magnetic
permeability of vacuum). The derived components of themagnetic flux densi-
ty are shown in Figs. 8 and 9. The plots depicted by the continuous line deal
with the gap filled by air and by the dot line – by a ferromagnetic material.

Figure 8 shows the radial component of the magnetic flux density along
the radial axis r. It appears that the largest value of this component, found
near the side surface of the magnet, approaches 0.17T for air in the gap and
0.31T for the ferromagnetic material. Figure 9 presents the radial component
of the magnetic flux density along the longitudinal axis z. It is apparent that



An experimental electromagnetic induction device... 939

Fig. 8. Radial component of the magnetic flux density along the radial axis

Fig. 9. Radial component of the magnetic flux density along the longitudinal axis

this component varies slightly between two sets, in the range (0.14,0.17)T for
air in the gap and takes nearly a constant value of 0.20T for the ferromagnetic
material.

4. Description of the device

Theelectromagnetic inductiondevice engineeredutilizing the above calculated
data is shown in Fig.10. The construction of the device enables us to regulate
the number ofmagnets and the height of the gap between themagnet sets and
to introduce coils with various electric parameters. The height of the gap set
at Hg =20mm(which can befilled either by air or by ferromagneticmaterial)
results from the amplitude of displacement excitations of the piston assumed
in experiments. Care must be taken to ensure that the magnets held on the



940 B. Sapiński

bolt can freely move inside the tube. Besides, the width of the slit formed
as a result of the difference between the inner diameter of the tube and the
magnets diameter should be as little as possible.

Fig. 10. Engineered electromagnetic induction device

The device was equipped with two coils wound with a copper wires with
diameter of 0.25mm (coil 1) and 1.25mm (coil 2) on a carcass. The coils
height was 22mmand the internal diameter was 34mm.Coil 1 had 912 turns
and resistance 39.6Ω while coil 2 had 45 turns and resistance 0.1Ω. Care
must be taken to ensure that the coil windings should be close to themagnets
in order to remain the largest proportion of the windings in the zone of the
maximum flux density.

5. Experiments and discussion

For the purpose of experiments we made a special handle to hold the elec-
tromagnetic induction device and the RD-1005-3 damper. The handle design
enables motion of its upper part with respect to the lower one in the ran-
ge 10mm (for the initial damper deflection). In the guides there are roller
bearings which allow two parts to be precisely guided with respect one to
another. The handle with the device and damper installed is shown in Fig.11.

We tested the device in an experimental setup equipped with a dynamic
testing machine of Instron and data acquisition system based on a PC with
an I/O board of National Instruments installed and supported by LabView
environment runningonMSWindows (http://ni.com).Theschematicdiagram
of the experimental setup is shown in Fig.12.



An experimental electromagnetic induction device... 941

Fig. 11. System ready for tests

Fig. 12. Diagram of the experimental setup

We programmed the machine to produce sine displacement excitations of
the piston with the amplitude 10mmand frequency 1Hz. This enabled us to
achieve the maximum piston velocity associated with the machine efficiency.
The data were acquired in 10 cycles (a cycle is denoted as the piston displace-
ment up and down). The sampling frequency for each channel was 1kHz per
cycle.

Main testswere precededby investigation of impacts of the friction force in
the handle. That is whywe tested at first the handle in which only the device
was held. The obtained results are shown in Fig.13. The plots present time
patterns of the friction force measured for a sine excitation of the piston. It
appears that the friction force takes the value in between 50 and 70N. These
impacts should be taken into account when analysing the influence of induced
current on the damper force in the main tests.



942 B. Sapiński

Fig. 13. Friction force in the handle for a sine displacement excitation

Next we investigated the influence of the input current on the damper
force. For that purpose, we activated the damper installed in the handle by
a step input current during the programmed excitations of the piston. The
achieved results are provided in Fig.14. The plots present time patterns of the
damper forcemeasured for the sine excitation of the piston and the step input
current from 0 to 0.1A (see grey line). It appeared that the damper force for
no current in the coil varied in between −100 to 30N while for 0.1A from
−150 to 80N.

Fig. 14. Damper force for a sine displacement excitation by a step input current

The main tests were conducted assuming that the device was equipped
with coil 1 or coil 2 and the gap between two sets of magnets was filled by
air or by a ferromagnetic material. The obtained results are shown in Figs. 15
and 16. In the case with no connection between the device and the damper



An experimental electromagnetic induction device... 943

Fig. 15. Electromotive force, voltage and damper force for the sine displacement
excitation; the device with coil 1, gap filled by air (left) and ferromagnetic material

(right)

(open circuit) we measured the induced electromotive force and the damper
force, and when the device was connected with the damper (closed circuit)
we measured the voltage at the coil terminals and the damper force. The
plots present time patterns of the measured quantities obtained for a sine
displacement excitation for the device with coil 1 (Fig.15) and with coil 2
(Fig.16). The plots depicted by black line apply to the open circuit and by
grey line to the closed circuit. The displacement excitations of piston in Figs.
15 and 16 are depicted by continuous lines and the velocity by the dashed line.



944 B. Sapiński

Fig. 16. Electromotive force, voltage and damper force for the sine displacement
excitation; the device with coil 2, gap filled by air (left) and ferromagnetic material

(right)

Comparing the results obtained for the open circuit (no current in the
coil) with the closed circuit (current in the coil is that induced by the de-
vice) reveals slight variability of the damper force. This can be explained as
follows.

Figure 17 (left) shows a general sketch of the closed circuit. Taking into
account the sine displacement excitation, the current i in the circuit is given
by



An experimental electromagnetic induction device... 945

i=
Em

√

(Re+Rc)
2+ω2(Le+Lc)

2
sin2πft (5.1)

where Em is the maximum value of the induced electromotive force, f is the
frequency of displacement excitation of the piston, Re and Le is the resi-
stance and the inductance of the device, Rc and Lc is the resistance and the
inductance of the damper coil.

Fig. 17. Sketch of the closed circuit of the electromotive induction device:
general (left), simplified (right)

Due to a low operational frequency in the experiments (1Hz), the induc-
tive reactance of the device coil and damper coil is reasonably small (when
compared to the resistances)

2πfLe+2πfLc ≪Re+Rc (5.2)

and therefore can be ignored. Hence the closed circuit can be treated as a
circuit with only ohmic resistance, as depicted in Fig.17 (right).
Accordingly, we write

i=
Em

Re+Rc
sin2πft (5.3)

and this yields
Umc =RcIm (5.4)

where Umc is the maximum voltage at the damper coil terminals and Im is
the maximum current in the closed circuit.
A similar statement is applicable to the triangular displacement excitation.
The conducted tests revealed that introducing ferromagnetic materials in

between themagnets sets led to an increase in the damper force when compa-
red with the gap filled by air (compare force plots depicted by grey and back



946 B. Sapiński

lines inFigs. 15 and16).This contribution, however not significant,was caused
by the increase of the magnetic flux density in the gap. This is in agreement
with the results of calculations of magnetic fields (Section 3).

Also we did not observe almost any difference in the device performance
whenusing coil 1 and coil 2.Though the induced electromotive forcewasmuch
greater for coil 1 (than that for coil 2) we got a relatively small and almost
the same current in the damper. The reason is that the resistance of coil 1
is much bigger than that of coil 2, and this makes that the induced currents
of about 0.01A are too low to affect the damper force significantly (compare
plots in Figs. 15 and 16).

6. Summary

The work reports the initial stage of the author’s research devoted to self-
powered vibration reduction systems with MR dampers using motion of the
structure for generation of a magnetic field. The study presents design con-
siderations, calculations of magnetic fields and testing of the experimental
electromagnetic induction device in a dynamic testing machine.

The investigation revealed that the engineered device was able to produce
induced electromotive forces.Unfortunately, theywere too low to influence the
damper force significantly. The main reason was that, due to a low efficiency
of the machine, we could not achieve a higher piston velocity and, thus, a
higher induced current. Therefore, further experiments will be conducted on
a machine whose parameters ensure fast relative motion between permanent
magnets and coil.

The investigation also highlighted directions for the improvement of con-
struction of the engineered device. This will be achieved by certain modifica-
tions in the magnetic system of the device and also in its electric circuit.

Acknowledgements

The research work has been supported by the State Committee for Scientific

Research as a part of the scientific research project no. N501366934.

References

1. Cedrat, 2000,User’s guide FLUX 2D version 7.50–CAD Package for Electro-
magnetic and Thermal Analysis Using Finite Element Method



An experimental electromagnetic induction device... 947

2. Cho S.W., Jung H.J., Lee I.W., 2005, Smart passive system based on a
magnetorheological dampers, Smart Materials and Structures, 1, 707-714

3. Sapiński B., 2006, Magnetorheological Dampers in Vibration Control, AGH
University of Science and Technology Press, Cracow, Poland

4. Sapiński B., 2008, An investigation of an electromotive induction device for
a small-scale MR damper, The 4th International Conference on Mechatronic
Systems and Materials, Białystok, Poland

5. http://www.lord.com

6. http://www.magnesy.pl

7. http://ni.com

Doświadczalny generator elektromagnetyczny dla tłumika

magnetoreologicznego

Streszczenie

Praca dotyczy doświadczalnego generator elektromagnetycznego składającego się
z magnesów stałych i cewki, który wytwarza energię elektryczną dla dołączonego
do niego tłumika MR. W pracy przedstawiono projekt generatora, obliczenia pola
magnetycznego, opisano wykonany generator oraz wyniki jego badań na maszynie
wytrzymałościowej.

Manuscript received March 20, 2008; accepted for print May 21, 2008