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An Introduction to Work and Energy Unit 4 Presentation 1
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What is Work? Work is defined as a force applied over a distance Work is a scalar Note that the distance must be parallel to the applied force SI Unit: Joule
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Work Examples Calculate the work it takes to lift a 50N box 3 meters. Calculate the work it takes to lift a 20 kg box 5 meters.
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Non-aligned forces Remember, the applied force MUST be in the same direction of the motion to calculate work. If not, consider the following: Force applied, through tension in a rope Motion of the block Consider the applied force vector: Therefore, work can also be described as:
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What is Energy? Energy is defined as the ability to do work. If an object has energy, it has an ability to do work, which is a force applied over a distance.
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6 Main Types of Energy Heat Sound Light Chemical Electrical Mechanical (Kinetic & Potential)
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Mechanical Energy Mechanical Energy is divided into Kinetic Energy and Potential Energy Kinetic Energy: The Energy of Motion Potential Energy: Stored Energy that can be converted into other types of energy
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Work – Kinetic Energy Theorem Theorem: The net work done on an object is equal to the change in the object’s kinetic energy. Kinetic energy is the energy of motion of an object: SI Unit for Energy: Joule
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Kinetic Energy Example The driver of a 1000 kg car traveling on the interstate at 35.0 m/s (nearly 80 mph) slams on his breaks to avoid hitting a second vehicle in front of him, which had come to rest because of congestion ahead. After the breaks are applied, a constant friction force of 8000 N acts on the car. Ignore air resistance. (a) At what minimum distance should the breaks be applied to avoid a collision with the other vehicle? (b) If the distance between the vehicles is initially only 30 m, at what speed would the collision occur?
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Kinetic Energy Example Lets apply the Work-Kinetic Energy theorem: Now, consider that the only work being done is by kinetic friction, and the force and direction of motion are opposite of each other:
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Kinetic Energy Example Now, find the speed at impact if the distance is only 30 m.
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Conservative and Nonconservative Forces Conservative Force: A force that allows a user to recover their work, as kinetic energy, completely and with very little dissipation. Nonconservative Force: A force that does not allow a user to recover their work, as kinetic energy, very well. In fact, much of the work is dissipated as various other forms of energy (heat, sound, etc.)
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Gravitational Potential Energy Work can be done on a system to raise its level of energy without giving it kinetic energy. Ex: Lifting a brick from the floor to a tabletop. Work was done against the force of gravity, and the brick is said to have gravitational potential energy.
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Gravitational Potential Energy U = Potential Energy SI Units: Joule
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Gravitational Potential Energy Example Calculate the change in gravitational potential energy when a 5 kg brick is lifted 20 meters above ground level.
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Conservation of Energy Energy can be neither created nor destroyed in any type of reaction, physical or chemical. Rather, energy simply changes form.
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Conservation of Mechanical Energy In any isolated system of objects interacting only through conservative forces, the total mechanical energy E = KE + GPE, of the system, remains the same at all times.
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Conservation of Mechanical Energy Mathematically
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