This
system should provided a force so that current or any other electrical
quantity will produce deflection of the pointer proportional to its
magnitude. The important functions of this system are,
1) It produces a force equal and opposite to the deflecting force in
order to make the deflection of pointer at a definite magnitude. If this
system is absent, then the pointer will swing beyond its final steady
positions for the given magnitude and deflection will become indefinite.
2) It brings the moving system back to zero position when the force
which causes the movement of the moving system is removed. It will never
come back to its zero position in the absence of controlling system.
Controlling torque is generally provided by springs. Sometimes gravity control is also used.
1.1 Gravity Control
This type of control consists of a small wight attached to the
moving system whose position is adjustable. This weight produces a
controlling torque due to gravity. This weight is called control weight.
The system deflects through an angle θ. The control weight acts at a distance l from
the center. The component Wsinθ of this weight tries to restore the
pointer back to the zero position. This is nothing but the controlling
torque Tc.
Fig. 2 |
Thus,
controlling torque Tc = Wsinθ x l
= Ksin θ
here K = W l
= gravity constant
Now generally all meters are current sensing meters where,
deflecting torque Td = Kt I
where Kt= another constant.
In equilibrium position, Td = Tc
... Kt I = Ksinθ
... I α sinθ
Thus the deflection is proportional to current i.e. quantity to
be measured. But as it is a function of sinθ , the scale for the
instrument using gravity control is not uniform.
Its advantages are:
1) Its performance is not time dependent.
2) It is simple and cheap.
3) The controlling torque can be varied by adjusting the position of the control weight.
4) Its performance is not temperature dependent.
Its advantages are:
1) The scale is nonuniform causing problems to record accurate readings.
2) The system must be used in vertical position only and must be properly levelled.
Otherwise it may cause serious errors in the measurement.
3) As delicate and proper levelling required, in general it is not used for indicating instruments and portable instruments.
1.2 Spring Control
Two hair springs are attached to the moving system which exerts
controlling torque. To employ spring control to an instrument, following
requirements are essential.
1) The spring should be non-magnetic.
2) The spring should be free from mechanical stress.
3) The spring should have a small resistance, sufficient cross-sectional area.
4) It should have low resistance temperature co-efficient.
The springs are made up of non-magnetic materials like silicon
bronze, hard rolled silver copper, platinum silver and german silver.
For most of the instruments, phosphor bronze spiral are provided. Flat
spiral springs are used in almost all indicating instruments.
The inner of the spring is attached to the spindle while the
outer end is attached to a lever or arm which is actuated by a set of
screw mounted at the front of the instrument. So zero setting can be
easily done. The controlling torque provided by the instrument is
directly proportional to the angular deflection of the pointer.
Now deflecting torque is proportional to current.
... Td α I
... Td α I
At equilibrium, Td = Tc
... I α θ
... I α θ
Thus the deflection is proportional to the current. Hence the
scale of the instrument using spring control is uniform. When the
current is removed, due to spring force the pointer comes back to
initial positions. The spring control is very popular and is used in
almost all indicating instruments.
1.3 Comparison of Controlling Systems
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