An object with a mass of #5 kg# is on a plane with an incline of #pi/8 #. If the object is being pushed up the plane with # 3 N # of force, what is the net force on the object?

Question

An object with a mass of #5 kg# is on a plane with an incline of #pi/8   #. If the object is being pushed up the plane with # 3  N # of force, what is the net force on the object?

Layla Ahmed · Accepted Answer

#sumF_x = 15.8# #"N"# directed down the ramp

We're asked to find the net force acting on an object on an incline plane.

The vertical forces (perpendicular to the incline) cancel out, because the normal force equals the perpendicular component of the weight force; thus, we are only looking at forces parallel to the incline.

There are two forces acting on the object (assuming the surface is frictionless):

the gravitational force (acting down the ramp), equal to #mgsintheta#
the applied force directed up the ramp

The net force equation is thus

#sumF_x = overbrace(F_"applied")^"upward force" - overbrace(mgsintheta)^"downward force"#
(taking positive direction to be up the ramp)

We know:
- #m = 5# #"kg"#
- #g = 9.81# #"m/s"^2#
- #theta = pi/8#
- #F_"applied" = 3# #"N"#
  Plugging these in:
  
  #sumF_x = 3color(white)(l)"N" - (5color(white)(l)"kg")(9.81color(white)(l)"m/s"^2)sin(pi/8) = color(red)(ulbar(|stackrel(" ")(" "-15.8color(white)(l)"N"" ")|)#
  (negative because it is directed down the ramp)

Adam Arnold · Answer

undefined The net force (F_net) acting on the object can be calculated using the formula:

$$F_{\text{net}} = m \cdot g \cdot \sin(\theta) + F_{\text{applied}}$$

where:
- $m$ is the mass of the object (5 kg),
- $g$ is the acceleration due to gravity (approximately 9.8 m/s²),
- $\theta$ is the angle of the incline ($\pi/8$),
- $F_{\text{applied}}$ is the applied force (3 N).

Substitute the values into the formula to find the net force on the object.