A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of...
A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of 5.3 m/s perpendicular to a 0.38-T magnetic field. The resistance of the rod and tracks is negligible. The rod maintains electrical contact with the tracks at all times and has a length of 1.6 m. A 0.90- resistor is attached between the tops of the tracks. (a) What is the mass of the rod? (b) Find the change in the gravitational potential energy that occurs in a time of 0.16 s. (c) Find the electrical energy dissipated in the resistor in 0.16 s.
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A conducting rod slides down between two frictionless vertical
copper tracks at a constant speed of...
A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of...
A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of 5.2 m/s perpendicular to a 0.62-T magnetic field. The resistance of the rod and tracks is negligible. The rod maintains electrical contact with the tracks at all times and has a length of 1.3 m. A 1.1- resistor is attached between the tops of the tracks. (a) What is the mass of the rod? (b) Find the change in the gravitational potential energy that...
Review Conceptual Example 3 and the drawing as an aid in solving this problem. A conducting...
Review Conceptual Example 3 and the drawing as an aid in solving this problem. A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of 4.1 m/s perpendicular to a 0.47-T magnetic field. The resistance of the rod and tracks is negligible. The rod maintains electrical contact with the tracks at all times and has a length of 1.6 m. A 0.98- resistor is attached between the tops of the tracks. Find the change in...
What is c? Please explain. Chapter 22, Problem 10 Your answer is partially correct. Try again....
What is c? Please explain.
Chapter 22, Problem 10 Your answer is partially correct. Try again. Review Conceptual Example 3 and the drawing as an aid in solving this problem. A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of 5.5 m/s perpendicular to a 0.68-T magnetic field. The resistance of the rod and tracks is negligible. The rod maintains electrical contact with the tracks at all times and has a length of 1.6...
A conducting rod slides over two horizontal metal bars with a constant speed v to the...
A conducting rod slides over two horizontal metal bars with a constant speed v to the left. The entire set up is in a region of uniform magnetic field that is perpendicular to the plane of the rod and bars. If the induced current through the resistor is as indicated, what is the direction of the magnetic field? R. II 11 II II II 1 out of the page into the page
A conducting rod of length 4.5 m is sliding downward between two vertical rails without friction....
A conducting rod of length 4.5 m is sliding downward between two vertical rails without friction. The rails have negligible resistance, but the resistance of the rod is 0.8 Ω. The rails are connected to an 23.3-Ω resistor, and the entire apparatus is placed in a 0.1-T uniform magnetic field. The rod is sliding down at the constant velocity of 7.4 m/s. What is the value of the constant current generated in the rod?
A conducting rod is pulled horizontally with constant force F= 4.80 N along a set of...
A conducting rod is pulled horizontally with constant force F=
4.80 N along a set of rails separated by d= 0.620 m. A uniform
magnetic field B= 0.500 T is directed into the page. There is no
friction between the rod and the rails, and the rod moves with
constant velocity v= 6.60 m/s.
A.) Using Faraday's Law, calculate the induced emf around the
loop in the figure that is caused by the changing flux. Assign
clockwise to be the...
A block (6 kg) starts from rest and slides down a frictionless ramp #1 of height...
A block (6 kg) starts from rest and slides down a frictionless ramp #1 of height 6 m. The block then slides a horizontal distance of 1 m on a rough surface with kinetic coefficient of friction μk = 0.5. Next, it slides back up another frictionless ramp #2. Find the following numerical energy values: 1.Initial gravitational potential energy on Ramp #1: U1G = J 2.Kinetic energy at bottom of Ramp #1 before traveling across the rough surface: K =...
A conducting rod is pulled horizontally with constant force F-4.40 N along a set of rails...
A conducting rod is pulled horizontally with constant force F-4.40 N along a set of rails separated by d= 0.340 m. A uniform magnetic field B=0.500 T is directed into the page. There is no friction between the rod and the rails, and therod moves with constant velocity v= 3.60 m/s Using Faraday's Law, calculate the induced emf around the loop in the figure that is caused by the changing flux. Assign clockwise to be the positive direction for emf...
A conducting rod is pulled horizontally with constant force F= 4.60 N along a set of...
A conducting rod is pulled horizontally with constant force F= 4.60 N along a set of rails separated by d= 0.420 m. A uniform magnetic field B= 0.700 T is directed into the page. There is no friction between the rod and the rails, and the rod moves with constant velocity v= 6,50 m/s. X X X X X X X X X X x x x x x x X X x x x x Using Faraday's Law, calculate...
A conducting rod is pulled horizontally with constant force F=3.20 N along a set of rails...
A conducting rod is pulled horizontally with constant force F=3.20 N along a set of rails separated by d-0.240 m. A uniform magnetic field B= 0.600 T is directed into the page. There is no friction between the rod and the rails, and the rod moves with constant velocity v= 4.50 m Using Faraday's Law, calculate the induced emf around the loop in the figure that is caused by the changing flux. Assign clockwise to be the positive direction for...
What is c? Please explain.
Chapter 22, Problem 10 Your answer is partially correct. Try again. Review Conceptual Example 3 and the drawing as an aid in solving this problem. A conducting rod slides down between two frictionless vertical copper tracks at a constant speed of 5.5 m/s perpendicular to a 0.68-T magnetic field. The resistance of the rod and tracks is negligible. The rod maintains electrical contact with the tracks at all times and has a length of 1.6...
A conducting rod slides over two horizontal metal bars with a constant speed v to the left. The entire set up is in a region of uniform magnetic field that is perpendicular to the plane of the rod and bars. If the induced current through the resistor is as indicated, what is the direction of the magnetic field? R. II 11 II II II 1 out of the page into the page
A conducting rod is pulled horizontally with constant force F=
4.80 N along a set of rails separated by d= 0.620 m. A uniform
magnetic field B= 0.500 T is directed into the page. There is no
friction between the rod and the rails, and the rod moves with
constant velocity v= 6.60 m/s.
A.) Using Faraday's Law, calculate the induced emf around the
loop in the figure that is caused by the changing flux. Assign
clockwise to be the...
A conducting rod is pulled horizontally with constant force F-4.40 N along a set of rails separated by d= 0.340 m. A uniform magnetic field B=0.500 T is directed into the page. There is no friction between the rod and the rails, and therod moves with constant velocity v= 3.60 m/s Using Faraday's Law, calculate the induced emf around the loop in the figure that is caused by the changing flux. Assign clockwise to be the positive direction for emf...
A conducting rod is pulled horizontally with constant force F= 4.60 N along a set of rails separated by d= 0.420 m. A uniform magnetic field B= 0.700 T is directed into the page. There is no friction between the rod and the rails, and the rod moves with constant velocity v= 6,50 m/s. X X X X X X X X X X x x x x x x X X x x x x Using Faraday's Law, calculate...
A conducting rod is pulled horizontally with constant force F=3.20 N along a set of rails separated by d-0.240 m. A uniform magnetic field B= 0.600 T is directed into the page. There is no friction between the rod and the rails, and the rod moves with constant velocity v= 4.50 m Using Faraday's Law, calculate the induced emf around the loop in the figure that is caused by the changing flux. Assign clockwise to be the positive direction for...
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