Yeah! Thank you!haruspex said:Sorry, I got confused. I thought you were asking about the acceleration of the wedge.
For the block, there is a horizontal component of the normal force slowing the horizontal component of the block's velocity, while in the vertical direction there is the block's weight and the vertical (upward) component of the normal force. The weight has the greater magnitude, so the vertical velocity also reduces.
And there will be no violation of momentum conservation in x direction but in y direction we cannot apply this law because there is mg and by the way we don’t have to.kuruman said:In that case you cannot conserve momentum along the x-direction because the component of the weight in your chosen x-direction is an external force acting on the block.
Draw a correct free body diagram of the block and you will see that the horizontal component of the normal force on therudransh verma said:I am asking if the block is moving up the wedge then it is acted upon by the downward weight and the horizontal normal force. You said the blocks speed will slow down because of the horizontal normal force even though the direction of the force is not opposite to the motion of the block.
Where did I say that mg has no effect on the motion of the block? In post #29 I wroterudransh verma said:If you are right then why does mg have no effect on the motion of the block. Why doesn’t mg also slow down the block?
How does the "vertical force of gravity exerted by the Earth" differ from the weight also known as mg?kuruman said:If you isolate the block and call that the system, then its momentum is not conserved because it is acted upon by the normal force exerted by theblockwedge and the vertical force of gravity exerted by the Earth. Its acceleration is dictated by both these forces and I don't see why you exclude the weight.
That would be true if the x direction is the same as the horizontal direction. If that is what you think, you are contradicting yourself. In post #22 you wroterudransh verma said:And there will be no violation of momentum conservation in x direction but in y direction we cannot apply this law because there is mg and by the way we don’t have to.
Unless the angle of the incline is zero, the horizontal direction and the direction parallel to the slope cannot be the same. Furthermore, you mention "the horizontal component of the weigh". You seem to be unaware that the weight does not have a horizontal component and that's serious. The horizontal component of the weght is zero no matter how you choose to orient the x and y axes. That's because the direction of the weight serves as the definition of "vertical". Have you ever wondered how people, since ancient times, were able to build vertical walls on sloped hillsides? How did they figure out which way is vertical?rudransh verma said:By taking the x and y-axis parallel to the slope and perpendicular to the slope of the wedge, I have drawn the fig. Please see. Clearly its the horizontal component of the weight of the block that is slowing down the block.
I got it. Thank you to you too.kuruman said:That would be true if the x direction is the same as the horizontal direction. If that is what you think, you are contradicting yourself. In post #22 you wrote
Unless the angle of the incline is zero, the horizontal direction and the direction parallel to the slope cannot be the same. Furthermore, you mention "the horizontal component of the weigh". You seem to be unaware that the weight does not have a horizontal component and that's serious. The horizontal component of the weght is zero no matter how you choose to orient the x and y axes. That's because the direction of the weight serves as the definition of "vertical". Have you ever wondered how people, since ancient times, were able to build vertical walls on sloped hillsides? How did they figure out which way is vertical?
rudransh verma said:[Edited for clarity]
Homework Statement:: A block of mass ## m ## moves with initial velocity ## u ## towards a movable wedge of mass ##\eta m## and height ## h ## that is initially stationary. All surfaces are smooth.
What is the minimum value of ## u ## for which the block will reach the top of the wedge?
Quite so, but the OP successfully answered the question, using your approach, in post #17. The digression then occurred because it transpired (post #18) that the OP did not really understand the mechanical process by which the block and wedge arrive at the same speed.pbuk said:There has been a big diversion in this thread considering the angle of the block and the dynamics applying while the block is moving up the ramp. These are irrelevant and do not lead to an answer to the initial question
Yes of course. Have you tried any other method?nasu said:@pbuk Have you actually tried this method?
There is no law of conservation of kinetic energy. Total energy is of course conserved (because all surfaces are smooth and there are no external forces), so what other form of energy is involved here?nasu said:Is the KE conserved?
Ah yes, I didn't see that - useful then that we refer back to that and the successful method at the end of this thread.haruspex said:Quite so, but the OP successfully answered the question, using your approach, in post #17.
After a Mentor discussion, the thread will remain closed. Thanks all for helping the OP.berkeman said:Thread is closed temporarily while the Mentors consider tying it off since the OP's questions have been answered well.