By the definition of mechanical equilibrium, Yes. Because the sum of forces is equal to zero, it can be seen from the equation F=ma that the total acceleration on the object must be zero in order for the equation to hold. The mass is only a constant in this equation in this situation, and remains unchanged.
Constant velocity gives zero acceleration, force is mass times acceleration, thus if acceleration is zero then force is zero and equilibrium is zero force. Equilibrium = zero force :0=f=ma=mdv/dt = m0 when velocity is constant dV/dt=0.
When the net force on an object is zero, the object is in a state of equilibrium. This means that the object's acceleration is zero, and it either remains at rest or continues moving at a constant velocity.
When the sum of the net forces on an object are not zero, it means that the object is being moved/pushed/pulled. It means that the object is not in equilibrium. If the net forces were zero, then the object would be in equilibrium, or, a state of not moving at all.
An object is in rotational equilibrium when the net torque acting on it is zero. This occurs when the clockwise torques are balanced by counterclockwise torques, resulting in no rotational acceleration.
The four conditions for equilibrium are: 1) The net force acting on the object must be zero, 2) The net torque acting on the object must be zero, 3) The object must be at rest or moving with constant velocity, 4) The object's acceleration must be zero.
When an object is in equilibrium, the acceleration is zero. When the acceleration is zero, the velocity does not change; the non changing velocity includes the case when the velocity has value zero.
0. An object in equilibrium has constant velocity, which makes its acceleration 0. Since net force=mass times acceleration, this would make the net force zero. Note that there could be multiple forces acting on the object, but since it is in equilibrium they would have to be equal and opposite in direction, to cancel all of the forces out. This would make the net force zero.
When an object is in equilibrium, the acceleration is zero. When the acceleration is zero, the velocity does not change; the non changing velocity includes the case when the velocity has value zero.
Constant velocity gives zero acceleration, force is mass times acceleration, thus if acceleration is zero then force is zero and equilibrium is zero force. Equilibrium = zero force :0=f=ma=mdv/dt = m0 when velocity is constant dV/dt=0.
When the net forces acting on an object sum to zero then the object's acceleration is zero.
When the net force on an object is zero, the object is in a state of equilibrium. This means that the object's acceleration is zero, and it either remains at rest or continues moving at a constant velocity.
When the sum of the net forces on an object are not zero, it means that the object is being moved/pushed/pulled. It means that the object is not in equilibrium. If the net forces were zero, then the object would be in equilibrium, or, a state of not moving at all.
When an object is in equilibrium, the acceleration is zero. When the acceleration is zero, the velocity does not change; the non changing velocity includes the case when the velocity has value zero.
An object is in rotational equilibrium when the net torque acting on it is zero. This occurs when the clockwise torques are balanced by counterclockwise torques, resulting in no rotational acceleration.
The four conditions for equilibrium are: 1) The net force acting on the object must be zero, 2) The net torque acting on the object must be zero, 3) The object must be at rest or moving with constant velocity, 4) The object's acceleration must be zero.
yes
An object is in equilibrium when the net force acting on it is zero and the sum of all torques acting on it is also zero. To recognize this, you can check if the object is at rest or moving at constant velocity with no acceleration in any direction.