need help with this part A conducting rod with a weight of 2.00 N and a...
In this problem, there is a conducting non magnetic bar that is in contact with conducting rails connected to a lightbulb (light bulb reisistance= 12.5 ohms). In this problem friction and air resistance can be ignored. There is a strong magnetic field in the region directed out of the page. The bar reaches a constant speed. The lightbulb used 0.18 W of electrical energy as the bar is falling. the bar has a mass of 650 grams and a length...
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...
Consider a 1-m conducting rod attached at each end by conducting rails. The rails are connected at the top and the total loop has a resistance of 3-Ohms. (see figure below). The rod falls to the ground at a constant velocity. v. The apparatus is inside a constant magnetic field, B = 2.0 T (directed out of the page). The mass of the rod is 0.5kg. B = 2:0 T (out of R=5 1 m D VE a) What is...
Consider a 1-m conducting rod attached at each end by conducting rails. The rails are connected at the top and the total loop has a resistance of 3-Ohms. (see figure below). The rod falls to the ground at a constant velocity, v. The apparatus is inside a constant magnetic field, B = 2.0 T (directed out of the page). The mass of the rod is 0.5kg. a) What is the magnetic force on the falling rod, due to the magnetic field? b) What is the induced...
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...
Problem 6. A conducting rod of mass 50 grams slides without friction on a pair of conducting horizontal rails spaced 0.750 m apart. A steady current of 85.0 A exists in the rails and bar as shown. The rails and bar are in a uniform 1.35 T magnetic field directed as shown. (a) What is the magnitude and direction of the acceleration of the rod? (b) If the rod starts from rest and reaches a speed of 150 m/s when...
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...
The conducting rod shown in the figure has length L and is being pulled along horizontal, frictionless, conducting rails at a constant velocity. The rails are connected at one end with a metal strip. A uniform magnetic field, directed out of the page, fills the region in which the rod moves. Assume that L 8.3 cm, the speed of the rod is v = 4.4 m/s, and the magnitude of the magnetic field is B = 1.0 T. (a) what...
Part A A conducting rod is being dragged along conducting rails, as shown in (Figure 1). The magnetic field is directed out of the screen. In what direction does the induced current flow through the light bulb? There is no induced current. The induced current flows through the bulb from the left to the right. The induced current flows through the bulb from the right to the left. Part B A circular loop of conducting wire is moving through a uniform magnetic field, as...
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...