the component of weight down the ramp is
100sin10. This ignores friction.
100sin10. This ignores friction.
100sin10=y
<x,y>
Step 1: Convert the weight from pounds to Newtons.
1 pound (lb) is approximately equal to 4.448 N.
So, the weight of the object is 100 lb × 4.448 N/lb = 444.8 N.
Step 2: Determine the weight component parallel to the ramp.
The weight acting perpendicular to the ramp is 444.8 N × cos(10°) = 434.58 N.
This weight component is the force pressing the object against the ramp.
Therefore, the force required to push the 100-pound object along the ramp is approximately 434.58 N.
1. Convert the weight of the object from pounds to Newtons. One pound is approximately equal to 4.45 Newtons. So the weight of the object is 100 pounds * 4.45 Newtons/pound = 445 Newtons.
2. Decompose the weight of the object into two components: one perpendicular to the ramp (the normal force) and one parallel to the ramp (the force of gravity). The force of gravity acting parallel to the ramp can be calculated by multiplying the weight (445 N) by the sine of the angle of inclination (10 degrees).
Force of gravity parallel to the ramp = 445 N * sin(10 degrees) ≈ 76.8 N.
3. The force required to push the object up the ramp is equal in magnitude but opposite in direction to the force of gravity parallel to the ramp. So the force required to push the object is approximately 76.8 N.
So, the force required to push a 100-pound object along a ramp inclined 10 degrees with the horizontal is approximately 76.8 Newtons.