Introduction
If the
mass center of a component of mass 'm' is rotating at an angular velocity at a
distance
'r' from the axis of rotation, then the component is subjected to force of mr2
The
'out of balance' forces increase bearing loads, and introduce stresses in the
rotor and
framework
of a machine. These so called 'inertial forces' may introduce dangerous
vibrations,
structural failure or unacceptable noise, and may limit the operating speed
range
of a machine. The magnitude of these forces may be reduced or eliminated in the
design
stage by 'balancing' the effects of the various mass elements of the device.
Additionally,
extra balance masses may deliberately added to a rotating system in order
to
cancel out the residual design imbalance.
This
experiment involves the balancing of a number of known out of balance masses on
a
shaft.
There are two types of balancing.
Static
and Dynamic Balance
So far we have considered the
case of a wheel, which approximates to a simple disc, having all its mass in or
near one plane. If this is statically balanced in the way described, it will
run at any speed without vibration. But in a rotating body having a fairly
considerable axial length, such as a cylinder, it is important that any local
unbalanced mass should be balanced out by a mass as nearly in the same cross
plane as possible.
The
static method of balancing, in this case, is not reliable because it gives no
indication of the position of the bias in relation to axial length. Thus the
cylindrical rotor, an armature shaft for instance, shown in Fig. 2, may be
heavy at the point A, as indicated by a static balancing test. If this
unbalanced mass is counteracted by a weight applied at the point B, the rotor
will appear to be in correct balance; but when running at high speed, the
effect of the two unbalanced masses will cause local reactions R-R which tend
to rock the shaft along its length, or in other words to set up a
"couple." In practice, the effect of this may be worse than that of a
single unbalanced force which tends to vibrate the structure bodily, and it is
often much more difficult to detect and correct.
The method usually employed for dynamic balancing
is to mount the shaft in bearings on a frame which is resiliently mounted,
usually by some form of spring suspension, so that it is capable of being
displaced in any plane by the effect of unbalanced forces. Means are provided
for locking the frame while the shaft is run up to a fair speed by any
convenient means, after which it is released and allowed to vibrate or
oscillate under the effect of the unbalanced forces. In modern dynamic
balancing machines,
indicating or recording devices are provided to show the position
and extent of the unbalanced masses. While it would not be impossible to
construct a simple dynamic balancing rig in the home workshop, most of the
problems involved in small machines can be dealt with by careful consideration
of design, and accuracy in construction of moving parts. It may be mentioned
that even the balancing machine, unless of very complex design, may leave
certain important considerations out of account.
For instance, suppose that a rotor having an
unbalanced mass at J (Fig. 3A) is balanced by adding two smaller masses at the
points K, L. The rotor is then in correct dynamic balance, and in the case of a
fairly rigid component, such as an armature, it will be perfectly satisfactory
in practice. But suppose the same principle is applied to a non-rigid
component, such as a crankshaft; in this case, the cancelling masses, being in
different planes, exert bending stresses on the shaft, and the latter may be
deflected, thereby altering the moment of the masses and putting the
system out of balance
Applications use rotating balancing to maintain there
characters properly
1.
Engine crank shaft
2.
Automobile
wheel
3.
Grinding
wheels
4.
Steam
turbines and runners
5.
Compressors
6.
Washing
machines
7.
Air
craft propellers
There are two forms of balancing: static and dynamic.
Static balancing is done by holding the component at its axis, then compensating (by removal or addition of mass) for the "heavy" side of the component. During Static balancing, the component is not rotating, hence "static". Static balancing is typically done on "flat" parts, or parts that have a large diameter to axial length ratio (pancake like parts, such as fans, pulleys, wheels).
Dynamic balancing is done on parts that are long compared to their diameters such as rotor assemblies. These parts require balancing to be done in two planes since the actual imbalance will intersect the centerline/axis. Unless both ends of the part are balanced, mass imbalance will continue to exist. Rotor assemblies that MCE manufactures are balanced dynamically (in two planes).
Balancing can be achieved by the addition or removal of mass in certain locations. MCE only provides balancing by use of mass removal which is achieved by abrasive material removal or by drilling/machining. Note that when designing your part, take into account that material removal will be required and allow for extra material such as a balancing ring or thicker flanges than required by design to achieve mechanical structural integrity.
Why we need Balancing of
rotating Masses
1. It will reduce the unwanted vibrations
2. it reduce the energy waste so it will increase the
efficiency of the machine.
3. Vibrating parts wear quickly . so balancing is so
important to have a long life time for the sfats.
4. When shaft is unbalanced it bends when it’s
rotating so it s subjected to compression and expansio alternatively so it fails easily.
5.Bearing wear due to large forces on them
