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There Is A 5Kg Block Resting On A Table, This Block Is Attached To A Rope That Goes Through A 10Kg Wheel Attached To The Edge Of The Table.
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There is a 5kg block resting on a table, this block is attached to a rope that goes through a 10kg wheel attached to the edge of the table. At the end of the rope is a 2.5kg brick dangling 1 meter off the wheel/table, The coefficient of friction between the block and the table is 0.4. If the system is initially at rest, how long will it take for the 2.5kg brick to drop 1m to the floor after it is released? (Assume the friction on the wheel's axle is negligible and there is no slippage between the rope and the wheel.)
Answers
As vascop says, the fact that the block on the table is heavier makes no immediate difference, since its weight is acting entirely into the table. If the table were perfectly smooth the only force acting in the system would be the weight of the dangling brick. The way to approach this is as follows: Step 1: draw free-body diagrams for the two blocks and the wheel....
21:44 Thu 24th Jul 2014
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The frictional force trying to hold the block in place is 0.4 x 5 = 2Kg.
The force trying to move the block via the pulley is 2.5Kg.
Using Force = mass x acceleration you can calculate the acceleration of the block.
Knowing the acceleration using t=sqrt (2 x 1metre/acceleration) gives the time for the brick to fall 1 meter.
The force trying to move the block via the pulley is 2.5Kg.
Using Force = mass x acceleration you can calculate the acceleration of the block.
Knowing the acceleration using t=sqrt (2 x 1metre/acceleration) gives the time for the brick to fall 1 meter.
As vascop says, the fact that the block on the table is heavier makes no immediate difference, since its weight is acting entirely into the table. If the table were perfectly smooth the only force acting in the system would be the weight of the dangling brick.
The way to approach this is as follows:
Step 1: draw free-body diagrams for the two blocks and the wheel. At this point it makes sense to be as general as possible, so call the large mass M and the other mass M, with a coefficient of friction mu, and acceleration to gravity g.
Step 2: Resolve forces in the horizontal and vertical directions for all objects.
Step 3: Use negligible friction/ no slippage to assume that the tension in the rope is equal everywhere.
Step 4: Input above results into Newton's second law, for both blocks, in the directions they can move.
Step 5: Inextensible string will imply that the accelerations of both blocks are the same. If you've done all the working above correctly this will turn your problem into a pair of simultaneous equations in the Tension of the rope, T, and the acceleration a.
Step 6: Eliminate T from these equations, so that you are left with an equations that gives acceleration in terms of the masses, friction coefficient, and gravity.
Step 7: Input the numbers for this problem into the equation, and then you will no what the constant acceleration of the brick is.
Step 8: Use the SUVAT equation s= ut + (1/2)at^2 and solve this for t, with u = initial velocity = zero.
Following the above steps should lead you to the answer.
The way to approach this is as follows:
Step 1: draw free-body diagrams for the two blocks and the wheel. At this point it makes sense to be as general as possible, so call the large mass M and the other mass M, with a coefficient of friction mu, and acceleration to gravity g.
Step 2: Resolve forces in the horizontal and vertical directions for all objects.
Step 3: Use negligible friction/ no slippage to assume that the tension in the rope is equal everywhere.
Step 4: Input above results into Newton's second law, for both blocks, in the directions they can move.
Step 5: Inextensible string will imply that the accelerations of both blocks are the same. If you've done all the working above correctly this will turn your problem into a pair of simultaneous equations in the Tension of the rope, T, and the acceleration a.
Step 6: Eliminate T from these equations, so that you are left with an equations that gives acceleration in terms of the masses, friction coefficient, and gravity.
Step 7: Input the numbers for this problem into the equation, and then you will no what the constant acceleration of the brick is.
Step 8: Use the SUVAT equation s= ut + (1/2)at^2 and solve this for t, with u = initial velocity = zero.
Following the above steps should lead you to the answer.
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