PART a)
As we know that weight is product of mass and gravity
so here we have
[tex]W = mg[/tex]
[tex]W = 13(9.8) = 127.4 N[/tex]
Part B)
Normal force is counter balanced by weight of the crate
so here we have
N = W = 127.4 N
PART C)
As we know that
F = ma
now we have
m = 13 kg
F = 40 N
now we have
[tex]40 = 13(a)[/tex]
[tex]a = 3.08 m/s^2[/tex]
Part D)
Maximum static friction force is given as
[tex]F_s = \mu_s N[/tex]
here we know that
[tex]\mu_s = 0.2[/tex]
now we have
[tex]F_s = 0.2(127.4) = 25.48 N[/tex]
PART E)
Since applied force on the block is
F = 12 N
Now since applied force is less than maximum static friction force
So it will not slide
So here friction force will be same as applied force
Static friction = 12 N
PART f)
Kinetic friction force is given as
[tex]F_k = \mu_k N[/tex]
here we know that
[tex]\mu_k = 0.15[/tex]
now friction force is
[tex]F_k = 0.15(127.4) = 19.11 N[/tex]
now we have
[tex]F_{net} = F - F_k[/tex]
[tex]F_{net} = 40 - 19.11[/tex]
[tex]F_{net} = 20.89 N[/tex]
Part g)
as we know that
F = ma
[tex]20.89 = 13a[/tex]
[tex]a = 1.61 m/s^2[/tex]
a) W=mg=127.4 N
b) When the crate is resting of the floor, the normal force is equal to the weight, so N=127.4 N
c) a=F/m=40/13=3.08 m/s/s
d) f=0.2N=25.48 N
e) From the answer above we see that the crate won't move unless the force prevails static friction. So in the current situation it's 12 N
f) 40-0.15N=20.89 N
g) a=F/m=20.89/13=1.61 m/s/s
