qwerty11 said:
A particle is located at teh vector position >r=(i+4j)m, and the force acting on it is >F=(6i+3j)N. What is the torque about the origin and the point having coordinates (0,6)m?
For the point (0,6) I get (10)6-3(1) = 57 N-m clockwise. I got the the 10 by doing 4j+6.
Vectors are tough to work with, and i can see you are having a problem with them. The vector position of the particle, given as
(1)i + 4j m, means that the particle is located at the coordinate x = 1 and y = 4.
Plot it on a graph and mark it P. Now the force acting on that particle is given as
6i + 3j N, which means that the force has an x component of 6 N acting horizontally pointing toward the right, and it has a y component of 3 N acting vertically pointing up. So
indicate those 2 forces on your graph, originating at point P. The
'line of action' of the 6 N force is a horizontal line passing thru point P; the
'line of action' of the 3 N force is a vertical line passing thru point P. Now for part a, you wanted the torque of these forces about the origin, O (the point at x=0, y=0). Recall that the torque of a force about a point is the force times the perpendicular distance from its line of action to the point. So the torque from the horizontal 6 N force is 6(4) =24 N-m, clockwise, and the torque from the vertical 3 N force is (3)(1) = 3 N-m, counterclockwise; thus, again, the total torque about O is 24 - 3 = 21 N-m, clockwise.
Now for part b, you want the torque of those forces about the point where (x=0, y=6).
Plot that point and mark it Q. The forces still pass through P. Now using the same approach for determining torque, the torque about Q from the horizontal 6 N force is (6)(2) = 12 N-m, counterclockwise. Now what is the torque about point Q from the 3N vertical force? Once you find it, add 'em up to get the total torque about Q.
Of course, if you don't like this method, you can find the torque by the vector cross product
r x F, which to me is a lot more difficult approach.
