Question

Notify Me Bookmark

Three forces are applied to a wheel of radius 0.350 m, as shown in the figure (Figure 1). One force is perpendicular to the rim, one is tangent to it, and the other one makes a 40.0∘ angle with the radius. Figure 1 of 1 Part A What is the magnitude of the net torque on the wheel due to these three forces for an axis perpendicular to the wheel and passing through its center? Express your answer in newton-meters. τ = N⋅m Submit Request Answer Part B What is the direction of the net torque in part (A)? into the page out of the page Submit Request Answer

Three forces are applied to a wheel of radius 0.350 m, as shown in the figure (Figure 1). One force is perpendicular to the rim, one is tangent to it, and the other one makes a 40.0∘ angle with the radius. Figure 1 of 1 Part A What is the magnitude of the net torque on the wheel due to these three forces for an axis perpendicular to the wheel and passing through its center? Express your answer in newton-meters. τ = N⋅m Submit Request Answer Part B What is the direction of the net torque in part (A)? into the page out of the page Submit Request Answer Three forces are applied to a wheel of radius 0.350 m, as shown in the figure (Figure 1). One force is perpendicular to the rim, one is tangent to it, and the other one makes a 40.0∘ angle with the radius. Figure 1 of 1 Part A What is the magnitude of the net torque on the wheel due to these three forces for an axis perpendicular to the wheel and passing through its center? Express your answer in newton-meters. τ = N⋅m Submit Request Answer Part B What is the direction of the net torque in part (A)? into the page out of the page Submit Request Answer

Image text
Three forces are applied to a wheel of radius 0.350 m , as shown in the figure (Figure 1). One force is perpendicular to the rim, one is tangent to it, and the other one makes a 40.0 angle with the radius.
Figure 1 of 1
Part A
What is the magnitude of the net torque on the wheel due to these three forces for an axis perpendicular to the wheel and passing through its center?
Express your answer in newton-meters.
A Σ ϕ h 0 圊? τ = N m
Submit Request Answer Part B
What is the direction of the net torque in part (A)? into the page out of the page Submit Request Answer

Detailed Answer

3 0

Please enter your email here. You will get email when this question is answered by our tutor.

Answer
Doubtrix Logo

This Problem has been solved!

You'll get a detailed, step-by-step and expert verified solution.

Join Doubtrix with 7-days free trial

  • Icon Correct & Verified Answers
  • Icon No AI-Generated Answers
  • Icon Video Solution for Difficult Questions
  • Icon Work With Experts to Reach at Correct Answers
Login Sign Up
  • Student Reviews:
  • (3)
  • Correct answers (3)
  • Complete solution (3)
  • Step-by-step solution (3)
  • Fully explained (3)

Similar/Related Questions

A 150 V battery is connected across two parallel metal plates of area 28.5 cm2 and separation 9.20 mm. A beam of alpha particles (charge +2e, mass 6.64×10−27 kg ) is accelerated from rest through a potential difference of 1.75 kV and enters the region between the plates perpendicular to the electric field, as shown in (Figure 1). Figure 1 of 1 Part A What magnitude of magnetic field is needed so that the alpha particles emerge undeflected from between the plates? Express your answer with the appropriate units. Submit Request Answer Part B What is the direction of this magnetic field? The magnetic field is directed into the page. The magnetic field is directed out of the page. The magnetic field is directed upward. The magnetic field is directed downward. Submit Request Answer Request Answer

Solution
0 0

In the wire shown in (Figure 1) segment BC is an arc of a circle with radius 30.0 cm, and point P is at the center of curvature of the arc. Segment DA is an arc of a circle with radius 20.0 cm, and point P is at its center of curvature. Segments CD and AB are straight lines of length 10.0 cm each. Part A Calculate the magnitude of the magnetic field at a point P due to a current 12.0 A in the wire. Express your answer with the appropriate units. Submit Request Answer Part B Figure 1 of 1 What is the direction of magnetic field? into the page out of the page Submit Request Answer
Solution
3 0

A metal bar with length L, mass m, and resistance R is placed on frictionless metal rails that are inclined at an angle ϕ above the horizontal. The rails have negligible resistance. A uniform magnetic field of magnitude B is directed downward in the figure (Figure 1). The bar is released from rest and slides down the rails. Figure 1 of 1 Part A Is the direction of the current induced in the bar from a to b or from b to a ? from a to b from b to a Submit Request Answer Part B What is the terminal speed of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. vt = Submit Request Answer Part C What is the induced current in the bar when the terminal speed has been reached? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer Part D After the terminal speed has been reached, at what rate is electrical energy being converted to thermal energy in the resistance of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Part E After the terminal speed has been reached, at what rate is work being done on the bar by gravity? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer A metal bar with length L, mass m, and resistance R is placed on frictionless metal rails that are inclined at an angle ϕ above the horizontal. The rails have negligible resistance. A uniform magnetic field of magnitude B is directed downward in the figure (Figure 1). The bar is released from rest and slides down the rails. Figure 1 of 1 Part A Is the direction of the current induced in the bar from a to b or from b to a ? from a to b from b to a Submit Request Answer Part B What is the terminal speed of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. vt = Submit Request Answer Part C What is the induced current in the bar when the terminal speed has been reached? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer Part D After the terminal speed has been reached, at what rate is electrical energy being converted to thermal energy in the resistance of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Part E After the terminal speed has been reached, at what rate is work being done on the bar by gravity? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer A metal bar with length L, mass m, and resistance R is placed on frictionless metal rails that are inclined at an angle ϕ above the horizontal. The rails have negligible resistance. A uniform magnetic field of magnitude B is directed downward in the figure (Figure 1). The bar is released from rest and slides down the rails. Figure 1 of 1 Part A Is the direction of the current induced in the bar from a to b or from b to a ? from a to b from b to a Submit Request Answer Part B What is the terminal speed of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. vt = Submit Request Answer Part C What is the induced current in the bar when the terminal speed has been reached? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer Part D After the terminal speed has been reached, at what rate is electrical energy being converted to thermal energy in the resistance of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Part E After the terminal speed has been reached, at what rate is work being done on the bar by gravity? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer A metal bar with length L, mass m, and resistance R is placed on frictionless metal rails that are inclined at an angle ϕ above the horizontal. The rails have negligible resistance. A uniform magnetic field of magnitude B is directed downward in the figure (Figure 1). The bar is released from rest and slides down the rails. Figure 1 of 1 Part A Is the direction of the current induced in the bar from a to b or from b to a ? from a to b from b to a Submit Request Answer Part B What is the terminal speed of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. vt = Submit Request Answer Part C What is the induced current in the bar when the terminal speed has been reached? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer Part D After the terminal speed has been reached, at what rate is electrical energy being converted to thermal energy in the resistance of the bar? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Part E After the terminal speed has been reached, at what rate is work being done on the bar by gravity? Express your answer in terms some or all of of the variables R, m, ϕ, L, B, and acceleration due to gravity g. Submit Request Answer

Solution
0 0