Equivalent Impedance

Equivalent Impedance 

       The transformer primary has resistance R₁ and reactance X₁. While the transformer secondary has resistance R₂ and reacatnce X₂. Thus we can say that the total impedance of primary winding is Z₁ which is,

                         Z₁ = R₁ + j X₁ Ω                                         ..........(1)

And the total impedance of the secondary winding is which is ,

                          Z₂ = R₂ + j X₂ Ω                                            ...........(2)

       This is shown in the Fig. 1.

Fig. 1 Individual impedance

      The individual magnitudes of and are,

                            Z₁ = √(R₁²  + X₁²)                                       ...........(3)

and                        Z₂ = √(R₂²  + X₂²)                                        .........(4)

      Similar to resistance and reactance, the impedance also can be referred to any one side.

Let                       Z_1e = total equivalent impedance referred to primary

then                       Z_1e = R_1e + j X_1e

                              Z_1e = Z₁ + Z₂' = Z₁ + Z₂/K²                            ............(5)

Similarly                  Z_2e = total equivalent impedance referred to secondary

then                         Z_2e =  R_2e + j X_2e

                                 Z_2e = Z₂ + Z₁' = Z₂ + K² Z₁                         ............(6)

       The magnitude of Z_1e and Z_2e are,

                                   Z_1e = √(R_1e²  + X_1e²)                                       ........(7)

and                             Z_2e  = √(R_2e²  + X_2e²)          ...........(8)

      It can be denoted that,

                                   Z_2e = K² Z_1e              and  Z_1e  = Z_2e /K²

       The concept of equivalent impedance is shown in the Fig. 2.

Fig 2  Equivalent impedance

Example 1 :A 15 KVA, 2200/110 V transformer has R₁ = 1.75Ω,  R₂ = 0.0045 Ω the leakage reactance are X₁ = 2.6 Ω and X₂ = 0.0075 Ω Calculate,

 a) equivalent resistance referred to primary

b) equivalent resistance referred to secondary

c) equivalent reactance referred to primary

d)  equivalent reactance referred tosecondary

e)  equivalent impedance referred to primary

f)  equivalent impedance referred to secondary

g) total copper loss

Solution : The given values are, R₁ = 1.75 Ω, R₂ = 0.0045Ω, X₁ = 2.6 Ω, X₂ = 0.0075 Ω

       K = 110/2200 = 1/20 = 0.05

a)   R_1e = R₁ + R₂' = R₁ + R₂ /K²  = 1.75 + 0.0045/0.05² = 3.55 Ω

b) R_2e = R₂ + R₁' = R₂ + K²  R₁ =

           = 0.0045 + (0.05)² x 1.75 = 0.00887 Ω

c) X_1e = X₁ + X₂' = X₁ + X₂/K² = 2.6 + 0.0075/(0.05)² = 5.6 Ω

d) X_2e   = X₂ + X₁'= X₂ + K²  X₁

              = 0.0075 + (0.05)² x 2.6 = 0.014 Ω

e) Z_1e = R_1e + j X_1e= 3.55 + j 5.6 Ω

Z_1e = √(3.55²  + 5.6²) = 6.6304 Ω

f)  Z_2e =  R_2e + j X_2e = 0.00887 + j 0.014 Ω

Z_2e = √(0.00887²  + 0.014 ²) = 0.01657 Ω

g) To find the load copper loss, calculate full load current.

(I₁) F.L. = (KVA x 1000)/V₁ = (25 x 1000)/2200 = 11.3636 A

 total copper loss = ((I₁)F.L.)² R_1e =  (11.3636)² x 355 = 458.4194 W

This can be checked as,

(I₂) F.L.= (KVA x 1000)/V₂ = (25 x 1000/110 = 227.272 A

total copper loss  =  I₁² R₁ + I₂² R₂

                           = (11.3636)² x 1.75 + (227.373)² x 0.0045

                           = 225.98 + 232.4365 = 458.419 W

Sponsored links :