1.
INTRODUCTION
Until recently, all electrodynamic vibration exciters, or shakers as they are often called,
looked like the one shown in the sketch in Fig.1.1a. A drive
coil,
carrying an alternating
current. was suspended in a gap
in
a concentric magnetic field. The drive coil was sus
pended by upper and lower flexures, which allowed it to move up and down in the gap
and kept its motion rectilinear. Because the drive coil was built into the shaker, the
char
acteristics of a particular shaker were fixed. It could be a heavy-duty type, a light-weight
type, or a large displacement type
.
With the advent of the B & K Exciter Systems, it is now possible to have as manyas five
different shakers i n one system. The difference is that the B & K exciters have set both
sets of flexures up above the drive coil (Fig.1
.1
b)
.
Upper Fle
x
ure - - - ,
lower Fle
xu
re - - _ ,
;::;il~~---
Field
Coil
Lower
Flexure
la)
Ib)
272173
Fig.
1.
1.
Construction principles of Vibration Exciters
The flexures and drive coil therefore form a Head which can be lifted off the Body
con
taining the magnetic field and exchanged for another Head. Hence, specialized Heads can
be built which all fit the same Body The V System of Exciters has five such specialized
Heads and two bodies. Each Head can be used on either the electromagnetic Exciter Body
4801 or the Permanent Magnet Exciter Body 4805. The force range available is from
155t0445N.
There are three square table Heads, varying from a light-weight, high acceleration type to
a large heavy-duty one. There is also a Head with a single, centrally located mounting
point for structural excitation, and a Calibration Head with a built-in reference acceler
ometer.
For the electromagnetic Exciter Body 4801
,
a choice of two different types of base are
also available, under the designations 4801 T and 4801 S. The 4801 T is a spring su
5