Rail gun weapons are not only popular in video games, they are actually being developed by the Navy for practical use. The figure below shows a simple model of how a rail gun works. The entirety of the rail gun is immersed in a magnetic field of strength 8 = 1.38 Tesla. With the switch open, the capacitor on the left is charged to a very high voltage Vo9300 Volts. When the switch is closed current will flow through the bar and thereby exert a magnetic force on the bar pushing it to the right. The bar has a mass M- 1.68 kg, a resistance R = 0.191 f, and a length L 0.385 meters. We shall assume that the rails have zero resistance, and that the bar slides without friction. The bar exits the rail gun after having accelerated over a distance of d = 4.38 meters. V₂- switch Immersed in a Magnetic Field Mass M Resistance R Length L d Calculate the current flowing through the bar when the switch is closed I = Calculate the force on the bar due to the magnetic field F = m/s² Newtons Amps Calculate the acceleration of the bar a = Assuming the bar experiences constant acceleration, find the velocity of the bar when it leaves the rails: v(x-d) m/s
Rail gun weapons are not only popular in video games, they are actually being developed by the Navy for practical use. The figure below shows a simple model of how a rail gun works. The entirety of the rail gun is immersed in a magnetic field of strength 8 = 1.38 Tesla. With the switch open, the capacitor on the left is charged to a very high voltage Vo9300 Volts. When the switch is closed current will flow through the bar and thereby exert a magnetic force on the bar pushing it to the right. The bar has a mass M- 1.68 kg, a resistance R = 0.191 f, and a length L 0.385 meters. We shall assume that the rails have zero resistance, and that the bar slides without friction. The bar exits the rail gun after having accelerated over a distance of d = 4.38 meters. V₂- switch Immersed in a Magnetic Field Mass M Resistance R Length L d Calculate the current flowing through the bar when the switch is closed I = Calculate the force on the bar due to the magnetic field F = m/s² Newtons Amps Calculate the acceleration of the bar a = Assuming the bar experiences constant acceleration, find the velocity of the bar when it leaves the rails: v(x-d) m/s
College Physics
11th Edition
ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
Publisher:Raymond A. Serway, Chris Vuille
Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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Please help with my homework and keep all decimal points thank you
![Rail gun weapons are not only popular in video games, they are actually being developed by the Navy for practical use. The figure below shows a simple model of how a rail gun works. The entirety of the rail gun is immersed in a magnetic field of strength B = 1.38 Tesla. With the switch
open, the capacitor on the left is charged to a very high voltage Vo = 9300 Volts. When the switch is closed current will flow through the bar and thereby exert a magnetic force on the bar pushing it to the right. The bar has a mass M = 1.68 kg, a resistance R = 0.191 , and a length L =
0.385 meters. We shall assume that the rails have zero resistance, and that the bar slides without friction. The bar exits the rail gun after having accelerated over a distance of d = 4.38 meters.
V₂
switch
Immersed in a Magnetic Field
Mass M
Resistance R
Length L
d
Calculate the current flowing through the bar when the switch is closed I =
Calculate the force on the bar due to the magnetic field F =
Newtons
Amps
Calculate the acceleration of the bar a =
m/s²
Assuming the bar experiences constant acceleration, find the velocity of the bar when it leaves the rails: v(x=d)
m/s](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F7e9880ca-6e01-4524-bdb0-6786235f8792%2F1b44b401-18f7-4ff4-9db5-1d2684802e3b%2Ftf23apu_processed.png&w=3840&q=75)
Transcribed Image Text:Rail gun weapons are not only popular in video games, they are actually being developed by the Navy for practical use. The figure below shows a simple model of how a rail gun works. The entirety of the rail gun is immersed in a magnetic field of strength B = 1.38 Tesla. With the switch
open, the capacitor on the left is charged to a very high voltage Vo = 9300 Volts. When the switch is closed current will flow through the bar and thereby exert a magnetic force on the bar pushing it to the right. The bar has a mass M = 1.68 kg, a resistance R = 0.191 , and a length L =
0.385 meters. We shall assume that the rails have zero resistance, and that the bar slides without friction. The bar exits the rail gun after having accelerated over a distance of d = 4.38 meters.
V₂
switch
Immersed in a Magnetic Field
Mass M
Resistance R
Length L
d
Calculate the current flowing through the bar when the switch is closed I =
Calculate the force on the bar due to the magnetic field F =
Newtons
Amps
Calculate the acceleration of the bar a =
m/s²
Assuming the bar experiences constant acceleration, find the velocity of the bar when it leaves the rails: v(x=d)
m/s
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