When a body is at rest, the forces acting on it are balanced. These can include gravitational force pulling the body downward and normal force exerted by the surface supporting the body. As long as these forces are equal and opposite, the body remains at rest.
A body can stay at rest even though forces act on it when the forces acting on the body are balanced, meaning they cancel each other out. This balance of forces results in no net force acting on the body, allowing it to remain at rest.
A body is said to be in equilibrium if it is at rest relative to the inertial reference frame or if the forces acting on a body are equal and opposite A body is said to be in equilibrium if its acceleration is 0 and net force is also 0
In most cases, when a body is at rest, there are two forces acting on it: the force of gravity pulling downward and the normal force pushing upward. These forces are equal and opposite, resulting in a balanced or net force of zero.
If a body is moving with uniform velocity, the net force acting on it is zero. This is in accordance with Newton's first law of motion, which states that an object will remain at rest or in uniform motion unless acted upon by a net external force.
In equilibrium, the net force acting on the body is zero, meaning that the body is either at rest or moving at a constant velocity. Additionally, the sum of all torques acting on the body is zero, indicating rotational equilibrium.
A body can stay at rest even though forces act on it when the forces acting on the body are balanced, meaning they cancel each other out. This balance of forces results in no net force acting on the body, allowing it to remain at rest.
"The condition of equilibrium or motion of a rigid body is remain unchanged, if a force acting on the rigid body is replaced by another force of the same magnitude and same direction but, acting anywhere along the same line of action."
Net force is defined as the overall force acting on an object. When a cat sleeps on a table, the net force on it is zero. When a body is at rest the net force acting on the body is zero.
Yes, a force acting perpendicular to a horizontal force on a body can cancel out the horizontal force if the two forces are equal in magnitude and opposite in direction. This is known as the equilibrium condition, where the net force acting on the body is zero.
A body is said to be in equilibrium if it is at rest relative to the inertial reference frame or if the forces acting on a body are equal and opposite A body is said to be in equilibrium if its acceleration is 0 and net force is also 0
Magnitude is 315 N. Direction would be opposite the first force, so they cancel out and leave the body at rest.
In most cases, when a body is at rest, there are two forces acting on it: the force of gravity pulling downward and the normal force pushing upward. These forces are equal and opposite, resulting in a balanced or net force of zero.
If a body is moving with uniform velocity, the net force acting on it is zero. This is in accordance with Newton's first law of motion, which states that an object will remain at rest or in uniform motion unless acted upon by a net external force.
In equilibrium, the net force acting on the body is zero, meaning that the body is either at rest or moving at a constant velocity. Additionally, the sum of all torques acting on the body is zero, indicating rotational equilibrium.
The net force acting on an object at rest is zero. This means that all the forces acting on the object are balanced and there is no overall force causing it to move.
There can be forces acting on an object while it is at rest, as long as the forces cancel each out. For example: a block laying on a table feels the force of gravity pulling it down, but the table pushes up with the same force. Therefore, the forces cancel and the object remains at rest.
Balanced forces means that the sum of the forces acting on a body is zero, and the body will have constant velocity, either at rest, or moving in a particular direction.