- #1
spacecataz
- 3
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Hey, this is my first time posting on PhysicsForums! I usually go through the archives but I couldn't find a problem like this.
Two blocks m1 and m2 with masses 50 kg and 100 kg respectively are connected by a string over a pulley that is frictionless with negligible mass. The 50 kg block slides on a 37 degree incline that has a coefficient of kinetic friction of .25. The system is released from rest with a force of 25 N pulling down on the 100 kg block. Calculate the change in kinetic energy of block m1 as it moves a distance of 20 m up the incline.
I think I'm supposed to use this:
\Delta K + \Delta U_{g1}+\Delta U_{g2} = W_{friction} + W_{applied}
So far I have
W_{friction} = -\mu m_{1}gcos(\Theta)d
W_{applied} = Fd
\Delta U_{g1} = m_{1}gdsin(\Theta)
\Delta U_{g2} = m_{2}gd
The answer is supposed to be 4090 J but when I crank out the numbers I don't get that.
What am I missing?! I've stared at this problem for too long. Thank for any help.
Two blocks m1 and m2 with masses 50 kg and 100 kg respectively are connected by a string over a pulley that is frictionless with negligible mass. The 50 kg block slides on a 37 degree incline that has a coefficient of kinetic friction of .25. The system is released from rest with a force of 25 N pulling down on the 100 kg block. Calculate the change in kinetic energy of block m1 as it moves a distance of 20 m up the incline.
I think I'm supposed to use this:
\Delta K + \Delta U_{g1}+\Delta U_{g2} = W_{friction} + W_{applied}
So far I have
W_{friction} = -\mu m_{1}gcos(\Theta)d
W_{applied} = Fd
\Delta U_{g1} = m_{1}gdsin(\Theta)
\Delta U_{g2} = m_{2}gd
The answer is supposed to be 4090 J but when I crank out the numbers I don't get that.
What am I missing?! I've stared at this problem for too long. Thank for any help.
