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1
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- Transformers and
Coupled Circuits
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2
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- Transformer is a magnetically coupled circuit
- It consists of two coils wound on a common core
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- Power flows from one circuit to the other circuit
- Through the medium of the magnetic field
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- There is no electrical connection between the two coils
- Coil (winding) on side of the transformer to which we apply power is
called primary
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- Coil on side to which we connect the load is called the secondary
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6
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- Iron-core transformers
- Generally used for low-frequency applications (such as audio and power)
- Iron core provides an easy path for
magnetic flux
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- Two basic construction types
- Each type uses laminated sheets of metal to reduce eddy currents
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8
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- Air-core and ferrite-core types
- Used for high-frequency applications (such as radio frequencies)
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- These do not have high hysteresis and eddy-current losses of iron-core
transformers
- Ferrite
- Increases coupling between coils while maintaining low losses
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10
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- Transformer may be used to change
polarity of an ac voltage
- Depending on the directions of its windings
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- If most of the flux produced by one of the coils links the other
- Coils are tightly coupled
- Otherwise loosely coupled
- All transformer operations are described by Faraday’s law
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12
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- If we apply Faraday’s law, where N is the number of turns and f is the flux, then
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13
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- Ratio of primary voltage to secondary voltage
- Equal to ratio of the number of turns
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14
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- Turns ratio (or the transformation ratio)
- Also, ep/es = a
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15
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- A step-up transformer
- Secondary voltage is higher than the primary voltage (a < 1)
- A step-down transformer
- Secondary voltage is lower (a > 1)
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16
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- In an ideal transformer
- Power in equals power out (η = 100%)
- Ratios of the current are
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17
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- If voltage is stepped up
- Current is stepped down, and vice versa
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18
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- A load impedance ZL connected directly to a source is seen as
ZL
- Impedance will be seen by the source differently
- If a transformer is connected between the source and the load
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- Reflected impedance, Zp, is given by
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20
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- Load characteristics do not change
- Capacitive loads still look capacitive, etc.
- A transformer can make a load look larger or smaller
- Depending on the turns ratio
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21
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- Using a transformer
- We can match loads to sources (such as amplifiers)
- Relates to the maximum power theorem discussed in a previous section
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- Transformers are rated in terms of voltage and apparent power
- Rated current can be determined from these ratings
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23
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- By dividing the apparent power rating by the voltage rating
- Rated current is determined, regardless of the power factor
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24
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- Used to convert the incoming 120 V source to voltage levels required by
circuit
- Some have a multi-tapped secondary winding to provide different voltages
for different applications
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25
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- Typically, an incoming voltage is
- Stepped down
- Rectified
- Smoothed by a filter
- Passed through a voltage regulator
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26
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- Transformers are used at generating stations to raise voltage for
transmission
- This lowers losses in the transmission lines
- At the user end
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- Transformers have a split secondary
- This permits both 120-V and 240-V loads to be supplied from the same
transformer
- For residential use
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28
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- Transformers are sometimes used to isolate equipment
- Isolation transformers are often used to make measurements involving
high voltages
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- They can also ensure that a grounded metal chassis is not connected to a
hot wire
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- Readings can be made on an oscilloscope
- Must have a grounded lead without shorting circuit components across
ground connections by using a 1:1 transformer
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- A transformer can be used to raise or lower apparent impedance of a load
- Impedance matching
- Sometimes used to match loads to amplifiers to achieve maximum power
transfer
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- If load and source are not matched
- A transformer, with the proper turns ratio, can be inserted between
them
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33
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- In autotransformers
- Primary circuit is not electrically isolated from its secondary
- They cannot be used as isolation transformers
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- Smaller and cheaper than conventional transformers with the same load
kVA
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35
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- Non-ideal transformers have several effects that cause loss of power
- Leakage flux
- Will appear as small inductances in series with the windings
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36
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- Winding resistance
- Core losses due to eddy currents and hysteresis
- Magnetizing current
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37
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- Efficiency is ratio of output power to input power
- Losses
- Due to power losses in the windings and in core
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- Large transformers can have efficiencies of 98 to 99 percent
- Smaller transformers have efficiencies of about 95 percent
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- Losses may be determined by making tests on transformers
- Short-circuit tests
- Determine losses due to resistance of windings
- Open-circuit tests will determine core losses
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40
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- As applied voltage increases, core flux increases, causing greater
magnetization current
- Therefore, transformers should be operated only at or near their rated
voltage
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41
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- At very low frequencies
- Core flux and the magnetizing current increases
- Causing large internal voltage drops
- At very high frequencies
- Stray capacitances and inductances cause voltage drops
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42
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- Circuits without an iron core, where only a portion of the flux produced
by one coil links another
- Cannot be characterized by turns ratios
- They are characterized by self- and mutual inductances
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43
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- Expressed by coefficient of coupling
- Air-core
- Ferrite-core transformers
- General inductive circuit coupling
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44
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- Self-induced voltage in a coil is
- Mutually induced voltage of a coil is
- v = M di/dt
- M is mutual inductance between coils
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45
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- In each coil
- Induced voltage is the sum of its self-induced voltage
- Plus voltage mutually induced due to the current in the other coil
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46
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- Coefficient of coupling, k
- Describes degree of coupling between coils
- Mutual inductance depends on k:
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47
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Notes