A property of matter that enables an object to return to its original size and shape when the force that was acting on it is removed. Elasticity.

Slides:

Advertisements

Similar presentations

Simple Harmonic Motion and Elasticity

Advertisements

Elasticity Hooke's Law : the extension in an elastic string is proportional to the applied force . T = x = extension l = natural length =

Noadswood Science, 2012 Hooke's Law. Hooke’s Law To know Hooke’s law Wednesday, April 22, 2015.

Elastic Energy. Compression and Extension  It takes force to press a spring together.  More compression requires stronger force.  It takes force to.

Kinetic Energy: More Practice

Elastic potential energy

1.3.4 Behaviour of Springs and Materials

Simple Harmonic Motion & Elasticity

Chapter 8 Conservation of Energy 8.2 Gravitational Potential Energy 8-3 Mechanical Energy and Its Conservation 8-4 Problem Solving Using Conservation of.

Regents Physics Springs.

Describing Periodic Motion AP Physics. Hooke’s Law.

UNDERSTANDING ELASTICITY Elasticity A force can change the size and shape of an object in various ways: stretching, compressing, bending, and twisting.

FYI: All three types of stress are measured in newtons / meter2 but all have different effects on solids. Materials Solids are often placed under stress.

Elastic potential energy

Elastic Force and Energy Stretching or Compressing a spring causes the spring to store more potential energy. The force used to push or pull the spring.

Energy stored in a Stretched String When stretching a rubber band or a spring, the more we stretch it the bigger the force we must apply.

Elastic Potential Energy.  Elastic Potential Energy (EPE) is a measure of the restoring force when an object changes its shape.

Hooke’s Law and Elastic Potential Energy

Mechanical Energy. Kinetic Energy, E k Kinetic energy is the energy of an object in motion. E k = ½ mv 2 Where E k is the kinetic energy measured in J.

Periodic Motion. Definition of Terms Periodic Motion: Motion that repeats itself in a regular pattern. Periodic Motion: Motion that repeats itself in.

Energy 4 – Elastic Energy Mr. Jean Physics 11. The plan:  Video clip of the day  Potential Energy  Kinetic Energy  Restoring forces  Hooke’s Law.

When a weight is added to a spring and stretched, the released spring will follow a back and forth motion.

Work (Pay special attention to words in BLACK) What is “Work”? According to physics… Work is a force applied for a certain distance. W=F  x.

Potential Energy Potential energy can also be stored in a spring when it is compressed; the figure below shows potential energy yielding kinetic energy.

Elastic Potential Energy Pg Spring Forces  One important type of potential energy is associated with springs and other elastic objects. In.

Potential and Kinetic Energy…

This section of work is also known as Hookes Law.

When a weight is added to a spring and stretched, the released spring will follow a back and forth motion.

Chapter 11: Harmonic Motion

The Work Energy Theorem

IGCSE PHYSICS Forces – Hooke’s Law

Spring Force. Compression and Extension  It takes force to press a spring together.  More compression requires stronger force.  It takes force to extend.

Hooke’s Law & springs Objectives

Elastic Potential Energy. Elastic potential energy is the energy stored in elastic materials as the result of their stretching or compressing. Elastic.

Robert Hooke Hooke’s Law deals with springs.

Elastic Energy SPH3U. Hooke’s Law A mass at the end of a spring will displace the spring to a certain displacement (x). The restoring force acts in springs.

FORCES SPRINGS This section of work is also known as Hookes Law.

Energy of Simple Harmonic Motion

Elastic Potential Energy & Simple Harmonic Motion

Physics Section 11.1 Apply harmonic motion

2.2 Materials Materials Breithaupt pages 162 to 171.

Elastic Potential Energy: Learning Goals

When a weight is added to a spring and stretched, the released spring will follow a back and forth motion.

PHYS 1441 – Section 004 Lecture #22

PHYSICS InClass by SSL Technologies with Mr. Goddard Hooke's Law

10.8 Forces and elasticity Q1a. The limit of proportionality of a spring is where the extension is no longer proportional to the applied force.

Elastic Potential Energy

P2.3 Forces in Action.

Hooke's Law When a springs is stretched (or compressed), a force is applied through a distance. Thus, work is done. W=Fd. Thus elastic potential energy.

Elastic Objects.

ELASTIC FORCE The force Fs applied to a spring to stretch it or to compress it an amount x is directly proportional to x. Fs = - k x Units: Newtons.

Springs Essential Questions: Can a spring do work?

Springs / Hooke's law /Energy

Elastic Potential Energy

Baseline (Aiming for 4): State the factors

Gravitational field strength = 9.81 m/s2 on Earth

Conservation Laws Elastic Energy

A spring is an example of an elastic object - when stretched; it exerts a restoring force which tends to bring it back to its original length or equilibrium.

Hooke’s Law Period of oscillators

Hooke’s Law Period of oscillators

Aim: How do we characterize elastic potential energy?

A spring is an example of an elastic object - when stretched; it exerts a restoring force which tends to bring it back to its original length or equilibrium.

Hooke’s law Hooke’s law states that the extension of a spring force is proportional to the force used to stretch the spring. F ∝ x ‘Proportional’

Ch. 12 Waves pgs

Elastic Energy.

Example 1 When a mass of 24kg is hung from the end of a spring, the length of the spring increased from 35cm to 39cm. What is the load on the spring in.

ELASTIC DEFORMATION.

Presentation transcript:

A property of matter that enables an object to return to its original size and shape when the force that was acting on it is removed. Elasticity

What can you observe in this figure?

Hooke’s Law State that: “The extension of a spring is directly proportional to the stretching force acting on it provided the elastic limit of the spring is not exceeded”.

Elastic limit: The maximum stretching force which can be applied to the spring before it ceases to be elastic.

The mathematical expression for Hooke’s law : x F = mg F = k x F = Force on the spring x = extension k = Force constant of the spring (Nm -1 ) Force constant of a spring: the force that is required to produce one unit of extension of the spring.

Example 1 A spring has an original length of 20 cm. with a load of mass 300 g attached to it, the length of the spring is extended to 26 cm. x F = mg 20 cm 26 cm 1. Calculate the spring constant. 2. What is the length of the spring when the load is increased by 200 g? (assume that g=10 Nkg-1).

Solution l o = 20 cm l 1 = 26 cm x = l 1 – l o = 26 – 20 = 6 cm = 0.06 m m = 300 g = 0.3 kg g = 10 N kg -1 F = mg = 0.3 x 10 = 3 N k = F/x = 3 / 0.06 = 50 Nm -1 1 m = 300 g g = 500 g = 0.5 kg F = mg = 0.5 x 10 = 5 N x = F / k = 5 / 50 = 0.1 m = 10 cm l 1 = l o + x = 20 cm + 10 cm = 30 cm Length of the spring is being 30 cm 2

Elastic Potential Energy The elastic Potential Energy is the energy stored in a spring when it is extended or compressed. The result of the work done to extend or compress the spring.

KATAPULT ARROW

E p = Elastic Potential Energy (J) k = Force Constant of the spring (N/m) x = extension of the spring (m)

F x Mass of the ball (m) = 300 g The spring constant (k) = 200 Nm -1. Spring extension (x) = 5 cm What is the maximum velocity of the ball when the stretching force is released? Example 2

½ m v 2 = ½ k x 2 Maximum kinetic energy is equal to elastic potential energy m = 300 g = 0.3 kg x = 5 cm = 0.05 m V 2 = (k x 2 ) / m V 2 = (200 Nm -1 x (0.05 m) 2 ) / 0.3 kg V 2 = ( 200 x ) / 0.3 V 2 = (0.5) / 0.3 = V = 1.29 ms -1 Solution

FactorChange in factorEffect on Elasticity Length Shorter spring Less elastic Longer spring More elastic Diameter of spring Smaller spring Less elastic Larger diameter More elastic Diameter of Spring Wire Smaller diameter More elastic Larger diameter Less elastic Type of Material The elasticity changes with the type of materials Factors that effect the elasticity

Summary

In this lesson, we learnt that: 1.Forces can change the shape of an object. 2.Objects that return to their original shape when the forces acting on them are removed are elastic. 3.Hooke’s Law state that the force on a spring is directly proportional to its extension, that is: F = k x F= force (N) K = spring constant (Nm -1 ) x = spring extension (m)