davie08 said:
I got 6.67 from 20=3*a but I guess that's wrong right but was the 7.35 right I am not sure what you mean by what direction like the friction is going against the applied force if that what you mean
Ignore the 6.67, because that equation wasn't correct. You forgot to include the force of friction, which you just identified, and in any case, diving by mass will just give you acceleration. You're not looking for acceleration just yet. You just want the net force.
Now, what I mean by direction is what direction the force is acting. As I'm sure you learned in class, force is a vector quantity. What that means is it has both magnitude and direction. The force of friction always acts to OPPOSE motion, which makes logical sense.
Take a look at the normal force and weight. If you have a book sitting on a table, not moving, the only two forces are the normal force and it's weight. The weight is m*g. The normal force is -(m*g). Note the negative sign. That shows direction. I'm not sure if you're taking calc based physics or not, but there's a trigonometric way to express that. Anyway...
Use the equation \SigmaF=m*a there. You get m*g + (-m*g) = m*a.
It's not accelerating, so you get mg - mg = 0 which makes sense.
You should be able to apply this formula to your current problem. First, it's asking you to sum up the forces on the chair. You already know the weight and normal force cancel out. You know about the pulling force, you also calculated the force of friction.
Sum them up, and note the direction of the force of friction.
