UNIT 5 WORK AND ENERGY FÍSICA 1 BATXILLERAT. Work (I) The work (W) done by a force that acts on a body in motion is the product of the force in the direction.

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Presentation transcript:

UNIT 5 WORK AND ENERGY FÍSICA 1 BATXILLERAT

Work (I) The work (W) done by a force that acts on a body in motion is the product of the force in the direction of the displacement and the displacement.  The SI unit of work is the joule (J): 1 J = 1 N × 1 m

Work (II) Motor or drive work: 0 ≤ α ≤ 90° Positive work: cos α > 0 Resistance or resistive work: 90°≤ α ≤ 180° Negative work: cos α < 0 Null work: α = 90°; cos 90°= 0

Work (III) Necessary conditions for performing work  That a force acts on a body.  That the body moves.  That the direction of motion is not perpendicular to the force. If more than one force acts on a body:

Graphical interpretation of work The force is constant:The force varies linearly with the distance: The force is variable, not linear: By calculating the shaded area, we obtain the work.

Power Power (P) is the work performed per unit time.  The SI unit of power is the watt (W): 1 W = 1 J / 1 s Efficiency Instantaneous power Mean power P u : useful power. P c : power consumed.

Energy Energy (P) is the capacity a body has to carry out work. The SI unit of energy is the joule (J). Kinetic energy Kinetic energy (E c ) is the energy that a body possesses from the fact of being in motion. Theory of work and kinetic energy: the work done by a resultant force acting on a body is converted into the kinetic energy of the body.

Conservative and non-conservative forces Conservative forces are forces for which the work done depends only on the initial and final points, independently of the path followed. Examples: Conservative forces: weight, electrical forces, elastic forces. Non-conservative forces: muscular force, friction, etc. For a conservative force, W = 0 if the initial and final points are the same.

Potential energy (I) The change in potential energy of a particle is the work, with the opposite sign, done by a conservative force on the particle: W = –ΔE p Potential energy is the energy that a particle has as a result of its position in a zone of space in which conservative forces apply. Example:

Potential energy (II) Gravitational potential energy is the energy that a particle has as a result of its position in a zone of space in which gravitational forces apply: E p = mgh Elastic potential energy is the energy that an elastic body has as a result of its state of deformation. The SI unit for gravitational and elastic potential energy is the joule (J).

Mechanical energy Mechanical energy is the sum of all the energies that a body can have: kinetic, gravitational potential, elastic potential, etc. E = E c + E p The SI unit for mechanical energy is the joule (J).