A magnetic circuit in the following figure is made of silicon steel, for which the B-H relationship is given as B = 2(1 – e¯s00) (T ), where B and H represent the magnitudes of magnetic flux density and magnetic field, respectively. Magnetic flux density is measured in Teslas. The outer legs have 500 turns each. It is required to establish a flux of 3.6 mWb in the air-gap by applying equal currents to both windings. What is the current in each winding? (Hint: Be careful, the B-H relation is not linear.) 50 (All dimensions in centimeters)
A magnetic circuit in the following figure is made of silicon steel, for which the B-H relationship is given as B = 2(1 – e¯s00) (T ), where B and H represent the magnitudes of magnetic flux density and magnetic field, respectively. Magnetic flux density is measured in Teslas. The outer legs have 500 turns each. It is required to establish a flux of 3.6 mWb in the air-gap by applying equal currents to both windings. What is the current in each winding? (Hint: Be careful, the B-H relation is not linear.) 50 (All dimensions in centimeters)
Power System Analysis and Design (MindTap Course List)
6th Edition
ISBN:9781305632134
Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma
Chapter3: Power Transformers
Section: Chapter Questions
Problem 3.9MCQ: Match the following: (i) Hysteresis loss (a) Can be redud by constructing the core with laminated...
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![A magnetic circuit in the following figure is made of silicon steel, for which the B-H relationship is
given as B = 2(1 – e¯s00) (T ), where B and H represent the magnitudes of magnetic flux density
and magnetic field, respectively. Magnetic flux density is measured in Teslas. The outer legs have
500 turns each. It is required to establish a flux of 3.6 mWb in the air-gap by applying equal
currents to both windings. What is the current in each winding? (Hint: Be careful, the B-H
relation is not linear.)
50
(All dimensions in centimeters)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2Fbed9868e-4578-4209-928a-484d6e1e5143%2Fb9291319-4dc2-4246-9d9f-da88ea8aa02f%2Fjla94u.png&w=3840&q=75)
Transcribed Image Text:A magnetic circuit in the following figure is made of silicon steel, for which the B-H relationship is
given as B = 2(1 – e¯s00) (T ), where B and H represent the magnitudes of magnetic flux density
and magnetic field, respectively. Magnetic flux density is measured in Teslas. The outer legs have
500 turns each. It is required to establish a flux of 3.6 mWb in the air-gap by applying equal
currents to both windings. What is the current in each winding? (Hint: Be careful, the B-H
relation is not linear.)
50
(All dimensions in centimeters)
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