Homework Answers
An object with a mass of 10.0 kg is at rest at the top of a...
An object with a mass of 10.0 kg is at rest at the top of a
frictionless inclined plane 8 meters and an angle of inclination 30
degrees with the horizontal. The object is released from this
position and it stops at a distance d from the bottom of the
inclined plane along a horiztonal surface. The coefficient of
kinetic friction for the horizontal surface is .400.
A. what is the knetic energy of the object at the bottom of...
did I do it right? An object with a mass of 10 kg is at rest...
did I do it right?
An object with a mass of 10 kg is at rest at the top of a frictionless inclined plane of height 8.00 m and an angle of inclination 30.0 degree with the horizontal. The object is released from this position and it stops at a distance d from the bottom of the inclined plane along a horizontal surface, as shown in Figure 8-9. The coefficient of kinetic friction for the horizontal surface is 0.400 ad...
(0%) Problem 12: Ablock of mass m 2.1 kg is on an inclined plane with a...
(0%) Problem 12: Ablock of mass m 2.1 kg is on an inclined plane with a coefficient of friction u 0.36, at an initial height h = 0.44 m above the ground. The plane is inclined at an angle 0 51°. The block is then compressed against a spring a distance Ax 0.17m from its equilibrium point (the spring has a spring constant of ky =27 N/m) and released. At the bottom of the inclined plane is a horizontal plane...
A block is released from rest at the top of an inclined 6.20 m long. The...
A block is released from rest at the top of an inclined 6.20 m
long. The angle of the incline with respect to the horizontal
direction is and the coefficient of kinetic friction between the
block and the surfaces (incline and horizontal) is . The block
slides along the incline with constant velocity and continues
moving along the horizontal surface until it comes to rest. Using
the work-energy theorem, Determine:
a) The speed reached by the block at the bottom...
A mass m = 1 kg slides down a θ = 30◦ inclined plane from a...
A mass m = 1 kg slides down a θ = 30◦ inclined plane from a
height of 5 m. At the bottom of the incline, it collides with
another mass M = 3 kg, and the latter is initially at rest as shown
in Fig. 3. The surface to the right of the inclined plane on which
the 3 kg (green) mass sits is horizontal.
(a) The inclined surface is frictionless. Conserve energy to
find the velocity of the...
a A 2.0 kg breadbox on a incline of angle 8 = 30° is connected, by...
a A 2.0 kg breadbox on a incline of angle 8 = 30° is connected, by a cord that runs over a pulley, to a light spring of spring constant k = 120 N/m, as shown in the Figure 4. The coefficient of kinetic friction between box and the inclined plane is Mik = 0.52, The box is released from rest when the spring is unstretched. Assume that the pulley is massless and frictionless and the system is isolated. (a)...
A block is initially at the top of a 2-m tall incline of 30°. The coefficient...
A block is initially at the top of a 2-m tall incline of 30°. The coefficient of kinetic friction between the block and plane is 0.2. If the block is released from rest, how fast will it be going when it reaches the bottom of the incline. You must use forces and accelerations to find this solution. Draw a diagram
In the physic lab, an air-track glider of mass m is on a frictionless air track...
In the physic lab, an air-track glider of mass m is on a
frictionless air track inclined at an angle θ as is shown in the
adjacent figure.
a)- Find the acceleration of the air-track glider.
b)- supposed the air-track glider is released from rest at the
top of the incline and the distance from the glider's front bumper
to the bottom of the incline is D (or what is the same, the
distance from the top of the incline...
An object with a mass, m = 5 kg, is released from rest at the top...
An object with a mass, m = 5 kg, is released from rest at the top of the ramp. The length of the ramp is 2.3 m. The object slides down the ramp reaching a speed of 2.1 m/s at the bottom. a) If the friction force between the ramp and the object is 3 N, find the angle between the ramp and the horizontal theta (in degrees). b) What speed (in m/s) does the object reach at the bottom...
6. A 5-kg block is pressed against a spring near the bottom of a 30° inclined...
6. A 5-kg block is pressed against a spring near the bottom of a 30° inclined plane. The spring, (spring constant 450 N/m) is compressed by 0.50 m.When released, the spring projects the block toward the top of the incline. The coefficient of kinetic friction between the block and the inclined plane is 0.3. (a) What is the speed of the block at the instant the block first returns to its equilibrium length? ans [3.9 m/s] (b) Calculate the speed...
An object with a mass of 10.0 kg is at rest at the top of a
frictionless inclined plane 8 meters and an angle of inclination 30
degrees with the horizontal. The object is released from this
position and it stops at a distance d from the bottom of the
inclined plane along a horiztonal surface. The coefficient of
kinetic friction for the horizontal surface is .400.
A. what is the knetic energy of the object at the bottom of...
did I do it right?
An object with a mass of 10 kg is at rest at the top of a frictionless inclined plane of height 8.00 m and an angle of inclination 30.0 degree with the horizontal. The object is released from this position and it stops at a distance d from the bottom of the inclined plane along a horizontal surface, as shown in Figure 8-9. The coefficient of kinetic friction for the horizontal surface is 0.400 ad...
(0%) Problem 12: Ablock of mass m 2.1 kg is on an inclined plane with a coefficient of friction u 0.36, at an initial height h = 0.44 m above the ground. The plane is inclined at an angle 0 51°. The block is then compressed against a spring a distance Ax 0.17m from its equilibrium point (the spring has a spring constant of ky =27 N/m) and released. At the bottom of the inclined plane is a horizontal plane...
A block is released from rest at the top of an inclined 6.20 m
long. The angle of the incline with respect to the horizontal
direction is and the coefficient of kinetic friction between the
block and the surfaces (incline and horizontal) is . The block
slides along the incline with constant velocity and continues
moving along the horizontal surface until it comes to rest. Using
the work-energy theorem, Determine:
a) The speed reached by the block at the bottom...
A mass m = 1 kg slides down a θ = 30◦ inclined plane from a
height of 5 m. At the bottom of the incline, it collides with
another mass M = 3 kg, and the latter is initially at rest as shown
in Fig. 3. The surface to the right of the inclined plane on which
the 3 kg (green) mass sits is horizontal.
(a) The inclined surface is frictionless. Conserve energy to
find the velocity of the...
a A 2.0 kg breadbox on a incline of angle 8 = 30° is connected, by a cord that runs over a pulley, to a light spring of spring constant k = 120 N/m, as shown in the Figure 4. The coefficient of kinetic friction between box and the inclined plane is Mik = 0.52, The box is released from rest when the spring is unstretched. Assume that the pulley is massless and frictionless and the system is isolated. (a)...
A block is initially at the top of a 2-m tall incline of 30°. The coefficient of kinetic friction between the block and plane is 0.2. If the block is released from rest, how fast will it be going when it reaches the bottom of the incline. You must use forces and accelerations to find this solution. Draw a diagram
In the physic lab, an air-track glider of mass m is on a
frictionless air track inclined at an angle θ as is shown in the
adjacent figure.
a)- Find the acceleration of the air-track glider.
b)- supposed the air-track glider is released from rest at the
top of the incline and the distance from the glider's front bumper
to the bottom of the incline is D (or what is the same, the
distance from the top of the incline...
An object with a mass, m = 5 kg, is released from rest at the top of the ramp. The length of the ramp is 2.3 m. The object slides down the ramp reaching a speed of 2.1 m/s at the bottom. a) If the friction force between the ramp and the object is 3 N, find the angle between the ramp and the horizontal theta (in degrees). b) What speed (in m/s) does the object reach at the bottom...
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