Its question about fixed pulley?

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1 Answer
Apr 29, 2018

#color(blue)(0.768044m)#

Explanation:

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Note:

#T = "string tension"#, we don't need to calculate this.

First find #mg#

#1.2g# and #0.8g#

Don't evaluate #g#

Using #F=ma#

Write down the resultant force in the direction of motion for each particle.

#1.2g-T=1.2a# #[1]#

#T-0.8g=0.8a# #[2]#

Solve simultaneously:

Adding #[1] and [2]#

#1.2g-0.8g=1.2a+0.8a#

#0.4g=2a#

#a=(0.4g)/(2)=0.2gms^(-2)#

Now we know the rate of acceleration, we can find the distance travelled in 1 second.

Using:

#S=ut+1/2at^2#

Initial velocity is zero.

#u=0#

#S=(0)1+1/2(0.2g)(1)^2#

#S=0.1g#

#g=9.81#

#S=(0.1)(9.81)=0.981m#

From this we can see that, when the #1.2kg# mass reaches the floor, the #0.8kg# mass will stop accelerating, but will continue to travel upwards until gravity stops it.

We now need to find the time it takes the #1.2kg# mass to travel the distance #0.64m#, and consequently this will be the time the #0.8kg# mass is accelerating upwards. The remaining time will be the duration the #0.8kg# mass is decelerating and we need to find the distance travelled during this period.

Duration of time #1.2kg# mass takes to travel #0.64m#

Using:

#s=ut+1/2at^2#

#0.64=(0)t+1/2(0.2g)t^2=>t=sqrt((1.28)/(0.2g)#

#g=9.81#

#:.#

#t=sqrt((1.28)/(0.2(9.81)))=0.8077100438s=0.808s# 3 d.p.

Next the velocity of the #0.8kg# mass after this time:

Using:

#v=u+at#

#v=0+(0.2g)(0.808)=>v=0.1616g=1.585296 \ \ms^(-1)#

Remaining time in which it decelerates due to gravity.

#t=1-0.808=0.192s#

Distance travelled during this period.

Using:

#v^2=u^2+2as#

#(0)^2=(1.585)^2+2(-g)s#

#s=(0^2-(1.585)^2)/(2*(-g))=0.128044m#

To get total distance travelled by the #0.8kg# mass, we add:

#0.64m+0.128044m=0.768044m#

This is as close as I can get to #0.776m#. This could be due to rounding errors.