The net force on a sliding crate is the vector sum of all forces acting on the crate. It is the force that is causing the crate to accelerate or decelerate. If all forces are balanced, the net force will be zero and the crate will move at a constant velocity.
The net force on the crate sliding at a constant speed is zero. This is because the applied force of 75 N is balanced by the frictional force opposing the motion. As a result, the crate does not accelerate, and the net force is zero.
To keep the crate moving with constant velocity, the force you exert must balance the force of sliding friction. In this case, you must exert a force of 90 N in the opposite direction of the sliding friction, so the net force on the crate is zero and it remains in motion at a constant velocity.
If the crate is moving at a constant velocity, the friction force is equal in magnitude but opposite in direction to the pushing force, so it is also 100 N. This is because the two forces are balanced and there is no net force acting on the crate.
The crate will move to the left because the force to the left (25N) is greater than the force to the right (10N). The net force acting on the crate is the difference between the two forces: 25N (left) - 10N (right) = 15N to the left.
The net force on the crate would be 10 units (force applied by the boy) - 10 units (force applied by the girl) = 0 units. Since the forces are in opposite directions, they cancel each other out, resulting in a net force of zero.
The net force on the crate sliding at a constant speed is zero. This is because the applied force of 75 N is balanced by the frictional force opposing the motion. As a result, the crate does not accelerate, and the net force is zero.
a girl and a boy are pulling heavy crate at the same time with 10 units of force each . what is the net force acting on ythe object?
To keep the crate moving with constant velocity, the force you exert must balance the force of sliding friction. In this case, you must exert a force of 90 N in the opposite direction of the sliding friction, so the net force on the crate is zero and it remains in motion at a constant velocity.
If the crate is moving at a constant velocity, the friction force is equal in magnitude but opposite in direction to the pushing force, so it is also 100 N. This is because the two forces are balanced and there is no net force acting on the crate.
The crate will move to the left because the force to the left (25N) is greater than the force to the right (10N). The net force acting on the crate is the difference between the two forces: 25N (left) - 10N (right) = 15N to the left.
If the box is sliding along at a constant speed, the net force acting on the box is zero.If the net force was not zero, the box would either be speeding up or slowing down.Non-zero net forces acting on objects cause the objects to accelerate. Therefore, if the net forces is not zero, the velocity of the object could not be constant.
The net force on the crate would be 10 units (force applied by the boy) - 10 units (force applied by the girl) = 0 units. Since the forces are in opposite directions, they cancel each other out, resulting in a net force of zero.
Friction is a force that opposes the motion of an object. The net force on an object is the sum of all the forces acting on it, including friction. If the net force is greater than friction, the object will accelerate. If friction is greater than the net force, the object will not accelerate and may start sliding on the surface due to the imbalance of forces.
No, the net force acting on an object cannot be negative.
The net force acting on the crate is zero since it's at rest. According to Newton's First Law of Motion, an object will remain at rest unless acted upon by an external force.
To determine the net force acting on an object, you can use the formula: Net Force Sum of all forces acting on the object. Add up all the forces acting in the same direction and subtract the forces acting in the opposite direction. This will give you the net force acting on the object.
that is called the net force; it is a vector sum of all the forces acting on it