Electrical instruments ppt

LECTURE
on
ELECTRICAL MEASUREMENT &
MEASURING INSTRUMENTS

CONTENTS
1. Essential Requirement of Indicating Instruments
1. Deflecting torque
2. Controlling torque
i. Spring Control method
ii Gravity control method
3. Damping torque or restoring torque
i. Air friction damping
ii. Eddy current damping
2. Moving Iron Instruments
Attraction type M. I. Instruments
Repulsion type M. I. Instruments
3. Permanent Magnet Moving Coil Instruments
4. Electro-dynamic Instruments

Essential requirement
of
indicating instruments

Essential requirement of indicating instruments
1. Deflecting torque
2. Controlling torque
3. Damping torque or restoring torque

Deflecting Torque
• Deflecting torque causes the moving system and pointer of the
instrument to move from its zero position. Production of deflecting
torque depends upon the type of indicating instrument and its
principle of operation

Controlling Torque
• Controlling torque limits the movement of pointer and
ensures that the magnitude of deflection is unique and is
always same for the given value of electrical quantity to
be measured.

Two methods of controlling Torque
• i. Spring Control method
• ii Gravity control method

Spring Control method
1. Two phosphor bronze hair
springs of spiral shapes
are attached to the spindle
of the moving system of
the instrument.
2. They are wound in
opposite direction
3. Pointer is attached to the
spindle of the moving
system

Working of Spring Control Method
1. When the moving system
deflected, one spring gets
wounded and the other one gets
unwounded. This results in
controlling torque whose
magnitude is directly proportional
to angle of deflection.
2. Td is directly proportional to
current I and Tc is directly
proportional to deflection angle,
at final steady state Td = Tc,
deflection is directly proportional
to current, hence scale is linear

Gravity Control Method
1. In gravity control method, a small
weight is attached to the spindle
of the moving system. Due to the
gravitational pull, a control torque
(acting in opposite direction to the
deflecting torque) is produced
whenever the pointer tends to
move away from its initial position.
2. In this case, Td is directly
proportional to current I and Tc is
directly proportional to sine of the
deflection angle, since Td = Tc,
sine of the deflection is directly
proportional to current, hence
scale is non linear i.e. cramped
scale.

Damping torque
• Damping torque minimizes the oscillations of the pointer about the
final steady state deflection and makes it steady.. In the absence of
this torque, pointer continues oscillating to its final position after
reaching to its final position.
• Depending on the magnitude of damping, it can be classified as
underdamped, overdamped and critcal damp

Damping Methods
• 1. Air Friction Damping
• 2. Eddy current Damping

Air Friction damping
• A light aluminum frame is attached to
the moving system. This piston moves
in an air chamber (cylinder) closed at
one end. At the time of oscillation of
the moving system or pointer about its
final steady state, if the piston is
moving into the chamber, the trapped
air gets compressed and the pressure
opposes the motion of the piston (and
therefore the moving system or
pointer). Similarly, if the piston is
moving out of the chamber, the
pressure in the closed chamber falls
and becomes less than air pressure on
the outer part of the piston. Motion is
thus again opposed. Oscillations are
damped.

Eddy current damping
• Construction & Working
1. An aluminum frame or damping disc is mounted on the spindle and
free to rotate in the magnetic field provided by damping magnets.
Since damping disc is rotating with spindle, emf is induced in the
disc according to faradays law of electromagnetic induction. Since
disc is a closed circuit, eddy current in the form of concentric circles
will be induced in the damping disc. Interaction between this eddy
current and magnetic field develops a force on the damping disc
which opposes the movement of sheet. And thus provides damping
of the oscillations of the pointer.

Construction
1. Instrument consists of a stationary coil in which the current to be
measured is passed.
2. A piece of un-magnetized soft iron which is of oval shape is mounted
rigidly on the spindle. This soft iron piece is free to move about the spindle
and along with the spindle.
Working
1. The current to be measured is flowing in the coil, produces a magnetic
field. Iron piece gets attracted towards centre of the magnetic
field and pointer deflects on the scale.
2. Control torque is provided either by control springs or by gravity control
method
3. Damping is provided by air friction damping
4. The scale is non-linear. Mirror is provided to avoid parallax error.

Attraction type M. I. Instruments
• Construction
1. This instrument consists of stationary coil in which current I that
is to be measured is passed
2. A piece of un-magnetised soft iron which is oval in shape is
mounted rigidly on the spindle. This soft iron piece is free to
move about the spindle and along with the spindle. It is placed
closer to the stationary coil as shown in fig.
3. A pointer is fixed on the spindle.

Construction
• This instrument consists of two iron vanes, one is attached to the
stationary coil and other one is attached to the movable spindle.
• Both vanes are surrounded by the stationary coil, current to be
measured is passing thorough this coil.

Working
• Current to be measured is passing thorough stationary coil
produces magnetic field. Both the vanes magnetizes with similar
polarities.
• As a result a force of repulsion is set up between two vanes.
• This force produces a deflecting torque on the movable vanes, gives
deflection on the scale.
• General Torque equation of M. I. Instruments
θd
dL
ITd 2
2
1
=

Permanent Magnet Moving Coil
Instruments

Permanent Magnet Moving Coil Instruments
Construction
• It consists of permanent magnet which is stationary.
• Moving system consists of a spindle attached to a rectangular aluminum
frame. A coil made up of thin copper wire is wound over the frame. The
current to be measured is passed through this coil.
• A soft iron core is placed in the in the space within the alluminium frame.
• Two spiral springs are mounted on the spindle to produce control torque.
Control spring also serves an additional purpose & acts as control lead.
• Pointer is mounted on spindle. Mirror is provided below the scale to avoid
parallax error. The spindle is supported by jeweled bearings.

Construction
1. It consists of permanent magnet which is stationary.
2. Moving system consists of a spindle attached to a rectangular aluminum
frame. A coil made up of thin copper wire is wound over the frame. The
current to be measured is passed through this coil.
3. A soft iron core is placed in the in the space within the alluminium frame.
This core is stationary and is provided to reduce the reluctance of the
magnetic path between two poles of the permanent magnet.
4. Two spiral springs are mounted on the spindle to produce control torque.
The control spring also serves an additional purpose and acts as control
lead. Pointer is mounted on spindle. Mirror is provided below the scale to
avoid parallax error. The spindle is supported by jeweled bearings.
Working
1. The current to be measured is passed through moving coil via control
springs.
2. A current carrying moving coil is now in a magnetic field. According to
Flemings left hand rule, torque is produced on the coil and coil moves,
pointer deflects.
3. Damping torque is provided by eddy current damping method.
• Torque equation- Deflection is proportional to current

Errors in PMMC Instruments
• Weakening of permanent magnet due to ageing and temperature
effects
• Weakening of springs due to ageing and temperature effects
• Change of resistance of moving coil with temperature.
Merits
• Uniform scale for the instrument
• Power consumption is very low
• A single instrument can be used for different current and voltage
ranges
• The toque-weight ratio is high gives higher accuracy.
Demerits
• This instrument can be used only on DC supply
• The cost of the instrument is more than M.I. Instruments

Electrodynamic Instruments
Construction
• Stationary part consists of two fixed coils connected in series as shown in
fig. so that they carry same current.
• The moving system consists of a coil mounted on the spindle which is free
to rotate in the space between the two fixed coils. The coil is made up of
thin copper wire and is air cored to avoid hysterisis.
• Control torque provided by two spiral springs. They also act as connecting
leads for the moving coil. Pointer is mounted on the spindle.
• Mirror is provided to avoid parallax error.
• Damping is provided by air friction damping.

Working
• Current to be measured is passed through two stationary
coils which are connected in series, forms magnetic field.
• Current to be measured is also passed through moving
coil via control springs. Now current carrying moving coil
is placed in magnetic field. According to Flemings left
hand rule, force is experienced on the moving coil, gives
deflection of the pointer.
• Torque
Td α i1 x i2
i1- current flowing through fixed coil,
i2 - current flowing through moving coil

Merits
– It can be used on a.c as well as d.c.
– It can be used as ammeter voltmeter and wattmeter
– it is also called as dynamometer instruments
Demerits
• Low torque to weight ratio
• More expensive
• Weak magnetic field
• Scale is non-uniform

Electrodynamic instruments as voltmeter, ammeter and wattmeter
• When used as an ammeter, the fixed coils are made up of thick
conductors to carry the load current. But since it is not possible with
moving coil, it is shunted (connected in parallel) with suitable
resistor
• When used as an voltmeter, all coils are made from less cross
section conductor. To increase instruments impedance. To increase
the instruments impedence, a heavy resistor is connected in series
with them
• When used as an wattmeter, fixed coils are used as current coil and
moving coil as pressure coil. Constructionally, fixed coils are made
up of thick copper wire and moving coil with thin conductors

DC Ammeters
Shunt Resistor
m
mm
s
II
RI
R
−
=

DC Voltmeters
• Basic dc voltmeter circuit --
• Multirange voltmeter ---------
• Voltmeter sensitivity :
m
mm
mm
s R
I
V
I
RIV
R −=
−
=
VI
S
fsd
Ω
=
1

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