Example Problem - Toroid: Difference between revisions
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'''Problem:''' | '''Problem:''' | ||
Concerning Ampere's law | |||
Let look at a coil around a toroid shown in the figure below. The coil has N = 20 turns around the toroid. The toroid has an inside diameter of ID = 4 cm and an outside diameter OD = 5 cm. Determine the field intensity H along the mean path length within the toroid with a current i = 2.5 A. | Let look at a coil around a toroid shown in the figure below. The coil has N = 20 turns around the toroid. The toroid has an inside diameter of ID = 4 cm and an outside diameter OD = 5 cm. Determine the field intensity H along the mean path length within the toroid with a current i = 2.5 A. | ||
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'''Solution:''' | '''Solution:''' | ||
Do symmetry the magnetic field intensity Hm along a circular contour within the toroid is constant. We can find the radius by | Do symmetry the magnetic field intensity Hm along a circular contour within the toroid is constant. We can find the mean radius by | ||
<math>r_m=(\frac{1}{2})\frac{OD + ID}{2}</math> | <math>r_m=(\frac{1}{2})\frac{OD + ID}{2} = 2.25\ cm</math> | ||
Using the mean radius the mean path of length l_m can be calculated. | |||
<math> l_m = { 2 \pi r_m} = 0.141\ </math> | <math> l_m = { 2 \pi r_m} = 0.141\ </math> | ||
With Ampere's Law (below) the field intensity along the mean path can be Found. | |||
<math>H_m=(\frac{Ni}{l_m})</math> | <math>H_m=(\frac{Ni}{l_m})</math> | ||
Finally teh H_m can be calculated. | |||
<math>H_m=\frac{20 x 2.5}{.141}= 354.6\ A /m)</math> | <math>H_m=\frac{20 x 2.5}{.141}= 354.6\ A /m)</math> | ||
Since the width of the toroid is much smaller than the mean radius r_m we can assume a uniform H_m throughout teh cross-section of the toroid. | |||
Revision as of 22:39, 18 January 2010
Problem: Concerning Ampere's law Let look at a coil around a toroid shown in the figure below. The coil has N = 20 turns around the toroid. The toroid has an inside diameter of ID = 4 cm and an outside diameter OD = 5 cm. Determine the field intensity H along the mean path length within the toroid with a current i = 2.5 A.
Solution:
Do symmetry the magnetic field intensity Hm along a circular contour within the toroid is constant. We can find the mean radius by
Using the mean radius the mean path of length l_m can be calculated.
With Ampere's Law (below) the field intensity along the mean path can be Found.
Finally teh H_m can be calculated.
Since the width of the toroid is much smaller than the mean radius r_m we can assume a uniform H_m throughout teh cross-section of the toroid.