Presentation is loading. Please wait.

Presentation is loading. Please wait.

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.

Published byNaomi Brooks Modified over 9 years ago

Similar presentations

Presentation on theme: "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."— Presentation transcript:

1 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.

2 Hooke’s Law For an ideal string we that to double the stretch we must double the force. Hooke’s Law states – For an ideal spring the extension or compression is proportional to the force producing it F = k x Where x is the extension or compression of the spring. K is called the spring constant

3 For a spring, a graph of Force against extension will produce a straight line of gradient k which passes through the origin. Force F Extension x Gradient = k

4 Example A spring of length 10cm is extended to 15cm when a 1kg mass hangs from it. Find k X = 15cm – 10cm = 5cm = 0.05m F = mg = 1kg x 10ms -2 = 10 N F = k x K = F / X = 10 / 0.05 = 200 Nm -1

Download ppt "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."

Similar presentations

Hookes Law The following topics will be discussed in this presentation: 1. Hookes law 2. Elastic behaviour of materials by stretching a spring and producing.

Hookes Law The following topics will be discussed in this presentation: 1. Hookes law 2. Elastic behaviour of materials by stretching a spring and producing.
Elasticity Hooke's Law : the extension in an elastic string is proportional to the applied force . T = x = extension l = natural length =

Elasticity Hooke's Law : the extension in an elastic string is proportional to the applied force . T = x = extension l = natural length =
Hooke’s law. Calculate the force from a spring when given its spring constant and deflection. Calculate a spring constant given the required force and.

Hooke’s law. Calculate the force from a spring when given its spring constant and deflection. Calculate a spring constant given the required force and.
Elastic Energy. Compression and Extension  It takes force to press a spring together.  More compression requires stronger force.  It takes force to.

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

Kinetic Energy: More Practice
Elastic potential energy

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

Spring Force. Compression and Extension  It takes force to press a spring together.  More compression requires stronger force.  It takes force to extend.
Aim: How can we calculate the energy of a spring? HW #33 due tomorrow Do Now: An object is thrown straight up. At the maximum height, it has a potential.

Aim: How can we calculate the energy of a spring? HW #33 due tomorrow Do Now: An object is thrown straight up. At the maximum height, it has a potential.
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.

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.
Elastic potential energy

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.

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.
Elastic Potential Energy & Springs AP Physics C. Simple Harmonic Motion Back and forth motion that is caused by a force that is directly proportional.

Elastic Potential Energy & Springs AP Physics C. Simple Harmonic Motion Back and forth motion that is caused by a force that is directly proportional.
Elastic Potential Energy.  Elastic Potential Energy (EPE) is a measure of the restoring force when an object changes its shape.

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

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.

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.

Energy 4 – Elastic Energy Mr. Jean Physics 11. The plan:  Video clip of the day  Potential Energy  Kinetic Energy  Restoring forces  Hooke’s Law.
Springs Web Link: Introduction to SpringsIntroduction to Springs the force required to stretch it  the change in its length F = k x k=the spring constant.

Springs Web Link: Introduction to SpringsIntroduction to Springs the force required to stretch it  the change in its length F = k x k=the spring constant.
HOOKE’S LAW. OBJECTIVE: 1.Determining the change of lengths of spring on the suspension of weights. 2.Confirming Hooke’s law and determining the spring.

HOOKE’S LAW. OBJECTIVE: 1.Determining the change of lengths of spring on the suspension of weights. 2.Confirming Hooke’s law and determining the spring.
Ch. 13 Oscillations About Equilibrium

Ch. 13 Oscillations About Equilibrium
Periodic Motion Motion that repeats itself over a fixed and reproducible period of time is called periodic motion. The revolution of a planet about its.

Periodic Motion Motion that repeats itself over a fixed and reproducible period of time is called periodic motion. The revolution of a planet about its.

Similar presentations

Ads by Google