Single Phase Transformer

Introduction

                     

           

A "transformer" changes one voltage to another. This attribute is useful in many ways.

A transformer doesn't change power levels. If you put 100 Watts into a transformer, 100 Watts come out the other end. [Actually, there are minor losses in the transformer because nothing in the real world is 100% perfect. But transformers come pretty darn close; perhaps 95% efficient.]

A transformer is made from two coils of wire close to each other (sometimes wrapped around an iron or ferrite "core"). Power is fed into one coil (the "primary"), which creates a magnetic field. The magnetic field causes current to flow in the other coil (the "secondary"). Note that this doesn't work for direct current (DC): the incoming voltage needs to change over time - alternating current (AC) or pulsed DC.

The number of times the wires are wrapped around the core ("turns") is very important and determines how the transformer changes the voltage.

·      If the primary has fewer turns than the secondary, you have a step-up transformer that increases the voltage.

·      If the primary has more turns than the secondary, you have a step-down transformer that reduces the voltage.

·      If the primary has the same number of turns as the secondary, the outgoing voltage will be the same as what comes in. This is the case for an isolation transformer.

·      In certain exceptional cases, one large coil of wire can serve as both primary and secondary. This is the case with variable auto-transformers and xenon strobe trigger transformers.

Types of transformers:

·         Power transformers

1.      Single-phase                      2. 3-phase

(Used in power transmission and distribution systems)

·         Step-up or step-down transformers

·         Current transformers

·         Voltage transformers

·         Auto-transformers

Transformers are constructed so that their characteristics match the application for which they are intended.    The  differences  in  construction  may  involve  the  size  of  the  windings  or  the relationship between the primary and secondary windings.  Transformer types are also designated by the function the transformer serves in a circuit, such as an isolation transformer.

Distribution Transformer

        Distribution  transformers  are  generally  used  in  electrical  power  distribution  and  transmission systems.  This class of transformer has the highest power, or volt-ampere ratings, and the highest continuous voltage rating.    The  power  rating  is  normally  determined  by  the  type  of  cooling methods the transformer may use.   Some commonly-used methods of cooling are by using oil or some other heat-conducting material.  Ampere rating is increased in a distribution transformer by increasing the size of the primary and secondary windings; voltage ratings are increased by increasing the voltage rating of the insulation used in making the transformer.

Power Transformer

    Power  transformers  are  used  in  electronic  circuits  and  come  in  many  different  types  and applications.    Electronics  or  power  transformers  are  sometimes  considered  to  be  those  with ratings of 300 volt-amperes and below.  These transformers normally provide power to the power supply of an electronic device, such as in power amplifiers in audio receivers.

Step-up transformers

A "step-up transformer" allows a device that requires a high voltage power supply to operate from a lower voltage source. The transformer takes in the low voltage at a high current and puts out the high voltage at a low current.  

Step-down transformers

A "step-down transformer" allows a device that requires a low voltage power supply to operate from a higher voltage. The transformer takes in the high voltage at a low current and puts out a low voltage at a high current.

THEORY:

                    A voltage transformer connected to a constant primary voltage source usually delivers nearly constant voltage to the load. From the consumers point of view the question of how nearly constant voltage output under different loading conditions is an important question. A closely rated quantity is the term voltage regulation the definition of which is given below;

Voltage regulation =  open circuit voltage – load voltage  x 100

                                                Open circuit voltage

                                    Voltage regulation =  (V₁ – V’₂) / V₁

                        From the phase diagram, V₁-V’₂ = I’₂.r.Cosθ + I’₂.x.Sinθ

                                                                   V₁-V’₂ = I’₂.r.Cosθ + I’₂.x.Sinθ

                                                                        V₁                       V₁

Since I_o is small compared to I’₂,

                         Approximate Voltage Regulation = I₂.r.Cosθ + I₂.x.Sinθ

                                                                                                V₁

Considering only the hysteresis, eddy current and copper losses.

                         Efficiency = output power   x 100%

                                                Input power

                                          = 1 – losses  x 100%

                                                      Input

                                          = 1 –         losses         x 100%

                                                    Output + losses

                                          =            V₂. I₂.Cosθ              x 100%

                                             V₂. I₂.Cosθ + (I’₂)².r + P_C

                                    Where P_C = core loss (Note I₁ = I’₂)

            For the determination of efficiency from the given above equations are often used which needs the summation of losses. This method is more convenient, economical and gives more accurate results for efficiency. 

PROCEDURE:

            The transformer was examined, and given a special attention to the construction, rated voltage, kava, frequency, etc. The rated currents for each side were calculated. Then the Terminal identification test, Polarity test, Open circuit test and Short circuit test were done by using follow the instructions which are given in the handout sheet.

CALCULATIONS

Rated Currents

            Using the Data on the Name Plate

Rated current of High Voltage side    = 4000VA / 400 V

= 10 A

Rated current of Low Voltage side     = 4000VA / 230

= 17.39 A

Open Circuit Test

Voltmeter reading (V)	Ammeter reading (A)	Wattmeter reading (w)
220	0.92	36
210	0.73	32
200	0.56	29
190	0.42	26
180	0.32	24
170	0.22	21
160	0.20	19

Multiplication factor for the wattmeter is 2

Efficiency

 Efficiency       =          Output Power  X  100

Input Power

Input Power     =         Output Power   +  Copper Loss  +  Core Loss

Rated input voltage    =  400 V

Rated output voltage  =  230 V

R_e^/        = ( N₂ / N₁)² X R_e

=  ( 230 / 400 )² X 0.62

=  0.205Ω

X_e^/        = ( N₂ / N₁)² X X_e

=  ( 230 / 400 )² X 0.5622

=   0.1858 Ω

                    Output Power      =          V_FLI_FLCosӨ                                Cos Ө = 1

                    Copper loss         =          ( I_FL )² R_e^/

                    Core loss              =          ( V_in )² / R_c        =          P       

Efficiency        =            V_FLI_FLCosӨ  X 100%

                                            {V_FLI_FLCosӨ  +  ( I_FL )² R_e^/  +  P}

                                     =     {230 X 17.39 X 8.37 X 1}          x 100%

                                           {(230 X 17.39 X 8.37 X 1)+(8.37² X0.2066)+62

                                     =  97.7766%  (at full load)

Efficiency        =          V_FLI_FLCosӨ X 0.5           X 100%

                                            {V_FLI_FLCosӨX0.5  +  ( I_FL  X0.5)² R_e^/  + P }

                                    =     {230 X 17.39 X 8.37 X 0.5 X 1}          x 100%

                                      {(230 X 17.39 X8.37 X0.5X 1)+(8.37² X0.25X0.2066)+62

                                    =  92.31%  (at half full-load)

The voltage regulation =  I₁.r.Cosθ + I₁.X.Sinθ           since  θ = 0,

                                                                V₁

                                                =   I₁.r

                                                      V₁

                                                = (10 x 0.62) / 400 = 0.015

RESULTS

Equivalent circuit parameters are:

R =  0.62 Ω

                        X_e =  0.5622Ω

R_c = = 1344.44 Ω

                         x_m= =  243.37 Ω

Efficiency of the transformer at full-load is 97.7766%  

Efficiency of the transformer at half full-load is =  92.31% 

            Voltage regulation of the transformer is 0.015

 Efficiency of transformers

 

 

In practice, real transformers are less than 100% efficient.

·      First, there are resistive losses in the coils (losing power I2.r). For a given material, the resistance of the coils can be reduced by making their cross section large. The resistivity can also be made low by using high purity copper.

·      Second, there are some eddy current losses in the core. These can be reduced by laminating the core. Laminations reduce the area of circuits in the core, and so reduce the Faraday emf, and so the current flowing in the core, and so the energy thus lost.

·      Third, there are hysteresis losses in the core. The magentisation and demagnetisation curves for magnetic materials are often a little different (hysteresis or history depedence) and this means that the energy required to magnetise the core (while the current is increasing) is not entirely recovered during demagnetisation. The difference in energy is lost as heat in the core.

·      Finally, the geometric design as well as the material of the core may be optimised to ensure that the magnetic flux in each coil of the secondary is nearly the same as that in each coil of the primary.

·      Stray losses

·      Mechanical losses

To increase the efficient of the transformer it’s very important to use a good coolant method in order to take away the heat which is generated by the transformer.

Coolant is very important because high temperatures also Can damage the winding of the transformer. In some transformers transformer oil act as a coolant and also as a winding insulation.

Methods to reduce the temperature in a transformers

1.      Indoor transformers can be cooled by natural air flow but large transformers cannot be cooled using this method. For large transformers above 200kVA we use forced circulation of clean air.

2.      In large distribution transformers external radiators are added to increase the cooling surface of the oil filled tank. Oil circulates around the transformer windings and moves through the radiator. That oil has a large specific heat capacity.

3.      In  still higher ratings there are Cooling fans to blow air over the radiators.

4.      For transformers in the megawatt range Cooling may be effected by an oil-water heat exchanger