2. The magnetic circuit of Fig 1.26 consists of rings of magnetic material in a stack of height h. The rings have inner radius R, and outer radius Ro. Assume that the iron is of infinite permeability ( u → 0 ) and neglecting the effects of magnetic leakage and fringing calculate; a) The mean core length lc and cross sectional area Ac b) The reluctance of the core Re and that of the air gap Rg c) For N =65 calculate the inductance L, and d) The current required to operate at an air gap flux density of B, = 1.35 T Ro R, = 3,4 cm R, = 4.0 cm h =2 cm 8 = 0.2 cm N turns

2. The magnetic circuit of Fig 1.26 consists of rings of magnetic material in a stack of height h. The rings have inner radius R, and outer radius Ro. Assume that the iron is of infinite permeability ( u → 0 ) and neglecting the effects of magnetic leakage and fringing calculate; a) The mean core length lc and cross sectional area Ac b) The reluctance of the core Re and that of the air gap Rg c) For N =65 calculate the inductance L, and d) The current required to operate at an air gap flux density of B, = 1.35 T Ro R, = 3,4 cm R, = 4.0 cm h =2 cm 8 = 0.2 cm N turns

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

See similar textbooks

Similar questions

Can you please answer the one in red and also round to at least 4 decimal places when applicable..
8. An iron ring has a mean circumferential length of 40 cm and a cross sectional area o 1 cm2. It is wound uniformly with 500 turns of wire. Measurements made with a search coil around the ring show that flux in the ring is 6Wb. If the relative permeability of the core is known to be 65, determine the current flowing in the windings.
A magnetic core in the form of a closed circular ring has a mean length of 30 cm and a cross sectional area of 1 sq cm. Determine the reluctance if the relative permeability of iron is 2400
Reluctance of core material (R) Cross-sectional area (A) 1520 Number of turns FUCCE Fig. 6 Magnetic coil Flux (6) Length around core (1)
1. a) A magnetic circuit is formed using an iron core with relative permeability 1000 and single air gap, and has the following parameters: cross-sectional area: Ac =1.6 × 10-3 m²; mean core length lc = 0.8 m; air gap length g = 2 x 10³ m. A coil of 100 turns is wound on the iron core. i) Calculate the reluctance of the core Rc and that of the gap RG neglecting the effects of fringing fields at the air gap and leakage flux from the coil.
Consider the magnetic circuit of with the dimensions of Problem 1.1. Assuming infinite core permeability, calculate (a) the number of turns required to achieve an inductance of 12 mH and (b) the inductor current which will result in a core flux density of 1.0 T. N turns Core: mean length 4. area A permeability Air gap R
4- The iron is of infinite permeability (u>00). For: Ri = 5.8 cm, Ro = 7.0 cm, depth3D4 cm, g 0.35 cm Calculate: a. the mean core length l and the core cross-sectional area Aç. b. the reluctance of the core Rc and that of the gap Rg. Ro R N turns
Given a magnetic circuit with a current 2.6A flowing through 205 turns of wire on a core having a reluctance of 125000 At/Wb. Determine the magnetomotive force of the circuit in base units.
Q2. A toroidal core that is made of iron and having relative permeability of µ, = 5000. The mean path length of the core, le is 37.6 cm while the cross-sectional area of the core is 0.1256 cm². The fringing effect and leakage flux are to be negligible. The number of turns of the coil, N¡ is 400. If there is an airgap of 5 mm and magnetic flux density at air gap is 0.25 T, (i) Draw equivalent magnetic circuit analogy of the core. (ii) Calculate the current required to energize the core. (iii) Determine the magnetizing strength, Hg in the air gap. mark (iv) If flux density in the air gap is reduced to half, find the new current flowing in the coil to energize the core. (v) If there is no airgap and the current value is similar as in (ii), what is the flux density in the core ? (Note: lo = 4n x10-7 H/m, Bmax = 1.5 T).
Consider the magnetic circuit shown below. The primary coil has N1=400 turns, and the secondary coil has N2=800 turms. The total length of the core (shown in red) is 5 cm. The core has a uniform cross section 2 cm2 , magnetic permeability 900. Calculate the total inductance between terminals a and b, if the coils are connected as shown below. Assume that there is no flux leakage from the core. N1 N2
8)Analyze the boundary value conditions in the illustration given below and frame the equations in terms of magnetic flux density Medium 1 AS(a.) An2 An2 ASI-a) Medium 2 H2