it does not accelerate
The friction of a non-moving object is called static friction. It is the force that prevents the object from moving when a force is applied to it.
The static friction of a non-moving object is called static friction. This type of friction prevents the object from starting to move when a force is applied.
Non-moving objects have inertia because they resist changes in their state of motion. The inertia of an object is directly related to its mass – objects with more mass have more inertia. This means that a non-moving object with more mass will require more force to start moving compared to an object with less mass.
Yes, a non-moving object can have potential energy. Potential energy is the energy that an object has due to its position or condition. For example, an object positioned at a height above the ground has gravitational potential energy.
Momentum of any object is given by p = m*vWhere p = momentum, m = mass and v = velocity.If an object is not moving that means its velocity is zero and by using above mentioned formula we get, p = m*0, p = 0.
The Condition of Equilibrium, Force equal zero, is the condition of an object at rest or moving at constant velocity. Non-Equilibrium Condition, Force is not zero, is the condition for an object to move with increasing velocity.
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.
The friction of a non-moving object is called static friction. It is the force that prevents the object from moving when a force is applied to it.
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.
The static friction of a non-moving object is called static friction. This type of friction prevents the object from starting to move when a force is applied.
No. For equilibrium, the SUM OF ALL FORCES acting on an object must be zero, and that is not possible with a single (non-zero) force.Note: For equilibrium, the sum of all torques on an object must ALSO be zero.
No, it can't, for it is meerly a non moving object.
Non-moving objects have inertia because they resist changes in their state of motion. The inertia of an object is directly related to its mass – objects with more mass have more inertia. This means that a non-moving object with more mass will require more force to start moving compared to an object with less mass.
Yes, a non-moving object can have potential energy. Potential energy is the energy that an object has due to its position or condition. For example, an object positioned at a height above the ground has gravitational potential energy.
Momentum of any object is given by p = m*vWhere p = momentum, m = mass and v = velocity.If an object is not moving that means its velocity is zero and by using above mentioned formula we get, p = m*0, p = 0.
velocity or speed and direction of motion. If an object's velocity is zero, it is considered to be at rest. If an object's velocity is non-zero, it is moving.
No, a couple is not in equilibrium, unless there is an equal and opposite force acting against each member of the couple.Be sure to remember that something can still be moving even if it is in equilibrium. It just means it's not accelerating.A2 People often forget that there is a difference between a hypothetical point sized object and a typical sized object when applying the condition for equilibrium. If the forces on an object are equal and opposite it is only the centre of mass that is required to be at rest (or moving at constant velocity). So for a point sized object that means the entire object must be at rest. But for a typical sized object only the centre of mass is required to be at rest. If the applied forces are off centre (as with a couple) it is still possible for the object to rotate about its centre of mass. This is dynamic equilibrium. If one also applies the second condition for equilibrium then you can have static equilibrium (no motion of centre of mass and no rotation) if the system is initially at rest. The second condition for static equilibrium is that there be no net torque on the object. That is the off centre forces tending to rotate the object(say clockwise) must be balanced by other off centre forces which tend to rotate the object counter clockwise.