Latest revision as of 12:42, 21 January 2010

Author: John Hawkins

Problem Statement

Problem 2.16 from Electric Machinery and Transformers, 3rd ed:

A magnetic circuit is given in Figure P2.16. What must be the current in the 1600-turn coil to set up a flux density of 0.1 T in the air-gap? All dimensions are in centimeters. Assume that magnetic flux density varies as
$B = [1.5 H / (750 + H)]$
.<ref>Guru and Huseyin, Electric Machinery and Transformers, 3rd ed. (New York: Oxford University Press, 2001), 129.</ref>

Solution

First, we note that the problem statement is incomplete. Assume that the core has a relative permeability of 500. Hence, for all magnetic sections excluding the air gap,

μ = μ_{r} μ_{0} = (500) (4 π \times 1 0^{- 7}) = 6.2832 \times 1 0^{- 4}

Also, as recommended in the text, we will neglect fringing.

The lengths and areas of each of the sections to be evaluated are given in the following table.

*Table 1: Lengths and Areas for the pertinent secions of the magnetic circuit.*
Section	fg	def	ghc	dc	dabc
Length $l$ (m)	0.01	0.555	0.555	0.48	1.38
Area $A$ (m²)	0.0032	0.0032	0.0032	0.0096	8.0e-4

We must now work backward from the air-gap, since the value of the flux-density is given there. We need only employ the analagous equations to Ohm's Law, KVL, and KCL. All units are standard units.
Air Gap:

$ℛ_{f g} = \frac{l_{f g}}{μ A_{f g}} = 4973.6$
$Φ_{f g} = B_{f g} A_{f g} = 3.20 \times 1 0^{- 4}$
$ℱ_{f g} = ℛ_{f g} Φ_{f g} = 1.5915$

Right Arms:

$Φ_{d e f} = Φ_{g h c} = Φ_{f g} = 3.20 \times 1 0^{- 4}$
$ℛ_{d e f} = ℛ_{g h c} = \frac{l_{d e f}}{μ A_{d e f}} = 2.7603 \times 1 0^{5}$
$ℱ_{d e f} = ℱ_{g h c} = ℛ_{d e f} Φ_{d e f} = 88.331$

Center Column:

$ℱ_{d c} = ℱ_{d e f} + ℱ_{f g} + ℱ_{g h c} = 178.25$
$ℛ_{d c} = \frac{l_{d c}}{μ A_{d c}} = 79, 577$
$Φ_{d c} = \frac{ℱ_{d c}}{ℛ_{d c}} = 0.0022$

Left Arm:

$Φ_{d a b c} = Φ_{d c} - Φ_{d e f} = 0.0019$
$ℛ_{d a b c} = \frac{l_{d a b c}}{μ A_{d a b c}} = 2.745 \times 1 0^{6}$
$ℱ_{d a b c} = ℱ_{d a b c} Φ_{d a b c} = 5, 271.2$

Conclusions:

$ℱ_{T o t a l} = ℱ_{d a b c} + ℱ_{d c} + ℱ_{d e f} + ℱ_{f g} + ℱ_{g h c} = 5, 627.7$
$i = \frac{ℱ_{T o t a l}}{N} = 3.52 A$

Which is the quantity we were looking for.

Calculations were performed using the following Magnetic Circuit Matlab Script.

References

Reviewed By

Amy Crosby

Kirk Betz

@@ Line 106: / Line 106: @@
 ==Reviewed By==
 Amy Crosby
+[[Kirk Betz]]
 ==Read By==
 ==Comments==

Magnetic Circuit: Difference between revisions

Latest revision as of 12:42, 21 January 2010

Contents

Author: John Hawkins

Problem Statement

Solution

References

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Magnetic Circuit: Difference between revisions

Latest revision as of 12:42, 21 January 2010

Author: John Hawkins

Problem Statement

Solution

References

Reviewed By

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Comments

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