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08/2 – Understand standard units of
measurement used in electrical installation, maintenance and design
work.
Outcome 2.3 – Identify appropriate electrical instruments for the
measurement and calculation of different electrical values.
Unit 08 Principles of electrical science
2.1 - Identify and use internationally recognised (SI) units of measurement for general variables.
2.2 - Identify and determine values of basic SI units which apply specifically to electrical variables.
Last session
2.3 - Identify appropriate electrical instruments for the measurement and calculation of different electrical values.
Voltmeter, ammeter, wattmeter, ohmmeter.
This session
Digital Meters
Digital meters take an input signal and converts it to a series of pulses
Digital signals are either on or off
Advantages of digital meters
• Strong
• No moving parts
• Accurate
• Easy to read
Disadvantages of digital meters
• Batteries need replacing regularly
• Not easy to tell if it is the meter or the circuit that is at fault
• Readings may vary
Analogue Meters
Analogue signals are variable which mean they are changing all the time.
Moving Iron Meter (repulsion type)
A moving-iron meter is based on the principle that when two magnetic fields oppose each other they deflect or try to move in opposite directions
Moving Iron Meters
There are two types of moving iron meters repulsion and attraction which both work in a similar way
This type of meter is less commonly used now
Advantages
• Cheap
• Fairly robust
• Can be used on a.c and d.c.
Disadvantages
• Uneven scale
• Can be affected by heat
• Can be affected by stray magnetic fields
• Only accurate at the lower end of the scale
Moving Coil Meter
A coil is wound on an aluminium frame. It is supported via a spindle resting in jewelled bearings which enable it to move freely.
Moving Coil Meter
This meter is much easier to read because the scale is linear, meaning the accuracy is constant
Advantages• Even scale• Accurate• Unaffected by stray magnetic fields
Disadvantages• Fragile• Expensive• Only measures d.c.
Voltmeter
• On site for general purposes we use a multimeter to test for voltage.
• A specific voltage testing device is called a voltmeter.
• Voltmeter’s measure the difference in potential between to point on a circuit.
• This test instrument must be connected in parallel across the load.
• Voltmeters have very high internal resistance to ensure accurate readings.
Voltmeters
Voltmeters measure Voltage
Voltmeters have to be connected across the load (In parallel)
U
LoadU
The voltmeter is connected in parallel with the load.
The same voltage is dropped across the load and the voltmeter.
Altering the Range of the Voltmeter
The problem with connecting a voltmeter into a circuit is that the current is supposed to flow through the load, what happens is that it splits up and some current passes through the voltmeter.
The voltmeter needs to have a resistance that is very high, so reducing the current to a negligible amount.
To alter the range of the voltmeter we must connect a resistor in series with the meter, this is called a multiplier.
Voltmeters
Ammeter
• On site for general purposes we use a multimeter to test for current.
• A specific current testing device is called a ammeter.
• ammeter’s measure the current that pass through them (current flow).
• This test instrument must be connected in series with the circuit.
• Ammeter’s have very low internal resistance to ensure false readings aren’t given.
Ammeters
Ammeters measure current
In a circuit it is critically important that the ammeter is placed in the correct position. (IN SERIES)
To understand why think back to resistors.
In a series circuit the current is constant throughout the circuit.
The ammeter is connected in series with the load and we will assume that the instrument has a resistance and so a volt drop when the current flows.
Increasing the Range of the Meter
If we want to increase the range of the instrument.
Which is sometimes necessary as the current can destroy the sensitive coil in the meter. We have to place a resistor in parallel with the meter. This resistor has a very low value and is called a shunt.
We have in effect two resistors in parallel connected to a resistor (the load) that is in series with them
Ammeters
Wattmeter
• On site for general purposes we use a multimeter to test for power.
• A specific power testing device is called a wattmeter.
• wattmeter’s measure the current and voltage that pass through them and display (apparent) power in watts.
Wattmeter
Current coil (SERIES)
Potential coil (PARALLEL)
AMMETER(SERIES)
VOLTMETER(PARALLEL)
WATTMETER
In DC circuits you can simply measure voltage and current and using P = I x V and calculate power.
In AC circuits using this method you only calculate APPARENT POWER. This value will be incorrect unless we have unity power factor (1).
This is due to factors within a system such as inductance and capacitance, these factors make he current lead or lag the voltage. We use P = I x V x cos ø
In circuits with any of these two factors we must use a wattmeter to measure power.
WattmeterThree meter method
Current coil
Potential coil
Meter two
Meter three
Meter one
Neutral
Meter one
Meter two
WattmeterTwo meter method
Ohmmeter
• Ohmmeter’s measure impedance (Z) also known as resistance.
• On site for general purposes we use a multimeter to test for impedance.
• A specific impedance testing device is called a ohmmeter.
• Impedance is defined as the total opposition to the flow of alternating current at a specific frequency.
• Quite often these types of meters are referred to as LRC metres as the quantify readings from resistance, inductance and capacitance.
Ohmmeter
• You must connect the tester at each end of the resistive load or circuit.
• Test leads must be zeroed out before the test or tested initially and deducted from the result total.
2.3 Identify appropriate electrical instruments for the measurement and calculation of different electrical values.
Voltmeter, ammeter, wattmeter, ohmmeter.
Consolidation
Outcome 2 formative assessment
Next session
