Holooly Plus Logo
Holooly Plus Logo

Question 15.12: Reflecting the Source to the Secondary Consider Figure 15.26...

Reflecting the Source to the Secondary
Consider Figure 15.26(a). Reflect Vs and R1 to the secondary side.

15.26
The blue check mark means that this solution has been answered and checked by an expert. This guarantees that the final answer is accurate.
Learn more on how we answer questions.

The voltage is reflected by using the turns ratio. Thus, we have

\mathrm{V}'_s=\frac{N_2}{N_1}\mathrm{V}_s=\frac{1}{10}1000\angle 0^\circ =100\angle 0^\circ

On the other hand, the resistance is reflected using the square of the turns ratio. This yields

R'_1=\left(\frac{N_2}{N_1} \right)^2 R_1= \left( \frac{1}{10}\right)^2(1000)=10~\Omega

The circuit with Vs and R1 transferred to the secondary side is shown in Figure 15.26(c).

 

Related Answered Questions

Question: 15.13

Regulation and Efficiency Calculations Find the percentage regulation and power efficiency for the transformer of Table 15.1 for a rated load having a lagging power factor of 0.8. ...

Verified Answer:

First, we draw the circuit as shown in Figure 15.3...
Question: 15.11

Using Impedance Transformations Consider the circuit shown in Figure 15.26(a). Find the phasor currents and voltages. Also, find the power delivered to the load. ...

Verified Answer:

First, we reflect the load impedance ZL to the pri...
Question: 15.10

Analysis of a Circuit Containing an Ideal Transformer Consider the source, transformer, and load shown in Figure 15.24. Determine the rms values of the currents and voltages a. with the switch open; b. with the switch closed. ...

Verified Answer:

Because of the applied source, the primary voltage...
Question: 15.9

Determination of Required Turns Ratio Suppose that we have a 4700-V-rms ac source and we need to deliver 220V rms to a load. Determine the turns ratio N1/N2 of the transformer needed. ...

Verified Answer:

Rearranging Equation 15.51, we have V_{2\m...
Question: 15.8

Calculation of Inductance and Mutual Inductance Two coils are wound on a toroidal core as illustrated in Figure 15.16. The reluctance of the core is 10⁷ (ampere-turns)/Wb. Determine the self inductances and mutual inductance of the coils. Assume that the flux is confined to the core so that all of ...

Verified Answer:

The self inductances can be computed using Equatio...
Question: 15.7

Calculation of Inductance Determine the inductance of the 500-turn coil shown in Figure 15.12 and analyzed in Example 15.5. ...

Verified Answer:

In Example 15.5, we found that the reluctance of t...
Question: 15.6

A Magnetic Circuit with Reluctances in Series and Parallel The iron core shown in Figure 15.13(a) has a cross section of 2 cm by 2 cm and a relative permeability of 1000. The coil has 500 turns and carries a current of i = 2A. Find the flux density in each air gap. ...

Verified Answer:

The magnetic circuit is depicted in Figure 15.13(b...
Question: 15.5

A Magnetic Circuit with an Air Gap Consider the magnetic core with an air gap as shown in Figure 15.12(a). The core material has a relative permeability of 6000 and a rectangular cross section 2 cm by 3 cm. The coil has 500 turns. Determine the current required to establish a flux density of Bgap ...

Verified Answer:

As shown in Figure 15.12(b), this magnetic circuit...
Question: 15.1

Magnetic Field around a Long Straight Wire Consider a long straight wire carrying current I out of the page as shown in Figure 15.7. Find expressions for the magnetic field intensity and magnetic flux density in the space around the wire. Assume that the material surrounding the wire has ...

Verified Answer:

By symmetry and the right-hand rule, we conclude t...
Question: 15.2

Flux Density in a Toroidal Core Consider the toroidal coil shown in Figure 15.8. Find an expression for the magnetic flux density B on the center line of the core in terms of the number of coil turns N, the current I, the permeability μ of the core, and the physical dimensions. Then, assuming that ...

Verified Answer:

By symmetry, the field intensity is constant in ma...