Consider a closed loop formed of 6 straight parts traversed by a current I as indicated in the below figure. The whole closed loop is placed within a uniform magnetic field, B = Bi. B a) Derive the magnetic forces F, and F2 created at parts (1) and (2) of the loop, respectively, b) Deduce the magnetic forces: F; at part (3). (4) (2) (3) (1) If the magnitude of the magnetic force F; at part (5) is given as: (5) TaB (6) e) Deduce the magnetic force F, at part (4) of the loop,
Consider a closed loop formed of 6 straight parts traversed by a current I as indicated in the below figure. The whole closed loop is placed within a uniform magnetic field, B = Bi. B a) Derive the magnetic forces F, and F2 created at parts (1) and (2) of the loop, respectively, b) Deduce the magnetic forces: F; at part (3). (4) (2) (3) (1) If the magnitude of the magnetic force F; at part (5) is given as: (5) TaB (6) e) Deduce the magnetic force F, at part (4) of the loop,
Related questions
Question

Transcribed Image Text:4:31
docs.google.com/forms
:D
c) Derive the magnetic field By created by part (3) at the centre O.
d) Deduce the magnetic field B, created by part (4) at the centre O.
Your answer
Problem-2:
Consider a closed loop formed of 6 straight parts traversed by a current I as indicated in the
below figure. The whole closed loop is placed within a uniform magnetic field, B = Bi.
a) Derive the magnetic forces F and F2
a
created at parts (1) and (2) of the loop,
respectively,
b) Deduce the magnetic forces: F3 at part (3).
(2)
(4)
(3)
(1)
If the magnitude of the magnetic force F at
(5)
part (5) is given as:
(6)
IaB
Fs= 2
c) Deduce the magnetic force F, at part (4) of
the loop,
d) What is the length, L, of part (5) of the loop?
e) Determine the magnitude and direction of the magnetic torque F acting on the loop.
Your answer
Problem-3:
(A)|
Expert Solution

This question has been solved!
Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.
Step by step
Solved in 4 steps
