5 Must Know Facts For Your Next Test

1. In static equilibrium, the object is either not moving or moving at a constant velocity, which means the net acceleration is zero.
2. The conditions for static equilibrium can be summarized by two key equations: the sum of horizontal forces equals zero and the sum of vertical forces equals zero.
3. When dealing with inclined planes, the gravitational force can be resolved into components parallel and perpendicular to the surface to analyze equilibrium.
4. The normal force acts perpendicular to the surface of contact and plays a critical role in maintaining static equilibrium against gravitational forces.
5. Tension in cables or strings also contributes to static equilibrium; it must balance other forces acting on an object to prevent motion.

Review Questions

• How does static equilibrium apply to objects resting on inclined planes?
  • When an object is on an inclined plane in static equilibrium, the gravitational force acting on it can be broken down into two components: one parallel to the plane and one perpendicular. The parallel component tries to pull the object down the slope, while the perpendicular component is countered by the normal force. For static equilibrium to exist, these forces must balance out, leading to no net movement along the incline.
• Discuss how normal force contributes to maintaining static equilibrium in a system.
  • The normal force is essential in static equilibrium as it acts perpendicular to a surface and counterbalances the weight of an object resting on that surface. When an object is stationary, the normal force matches the gravitational force acting on it, preventing it from accelerating downwards. In scenarios like objects on inclined planes, this balance becomes crucial as both the normal and gravitational forces must be resolved appropriately to maintain equilibrium.
• Evaluate how tension affects static equilibrium in a system involving pulleys or hanging objects.
  • In systems involving pulleys or hanging objects, tension plays a vital role in achieving static equilibrium by balancing other forces acting on those objects. For example, if a weight hangs from a pulley, the tension in the rope must equal the weight of that object for it to remain stationary. If tension exceeds gravitational force, movement will occur. Therefore, understanding how tension interrelates with other forces ensures proper analysis and design of systems requiring stability under load.

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