Presentation is loading. Please wait.

Presentation is loading. Please wait.

Springs and Hooke’s Law

Published byBlake Simpson Modified over 8 years ago

Similar presentations

Presentation on theme: "Springs and Hooke’s Law"— Presentation transcript:

1 Springs and Hooke’s Law
Physics 11

2 Springs A mass-spring system is given below. As mass is added to the end of the spring, how would you expect the spring to stretch?

3 Springs

4 Springs 2 times the mass results in a 2 times of the displacement from the equilibrium point… 3 time the mass… 3 times the displacement…

5 What kind of energy is this?
Potential Energy Elastic Potential Energy to be exact!

6 What else besides springs has elastic potential energy?
Diving boards Bows (bow and arrows) Bungee cord

7 Hooke’s Law Fspring: Applied force
X : displacement of the spring from the equilibrium position (units: m) K: the spring constant (units: N/m)

8 Hooke’s Law the restoring force is opposite the applied force. (negative sign) Gravity applied in the negative direction, the restoring force is in the positive direction

9 Example An archery bow requires a force of 133N to hold an arrow at “full draw” (pulled back 71cm). Assuming that the bow obeys Hooke’s Law, what is its spring constant?

10 F = kx 133 = k(0.71) k = 133/0.71 k = N/m  190 N/m

11 Restoring Force The restoring force is the force that is needed to put the spring back to equilibrium. Example: If you stretch a spring by 0.5m and you had to use 150N of force, the restoring force is -150N.

12 Practice Problems Textbook Page 258 35-37

13 Elastic Potential Energy of a Spring
Formula: Ee = ½ kx2 Units: Joules (J)

14 Example: A spring with spring constant 75 N/m is resting on a table.
A) If the spring is compressed a distance of 28cm, what is the increase in its potential energy? B) What force must be applied to hold the spring in this position?

15 Answer: A) Ee = ½ kx2 Ee = ½ (75)(0.28)2 Ee = 2.9 J B) F = kx
F = 21 N

16 Practice Problems Page 261, questions 38, 39, 40
Page 261 (Section Review) 1, 2, 3, 4, 7

17 Conservation of Energy with a Spring
Ex. 1: A 4.0 kg block slides across a frictionless table with a velocity of 5.0m/s into a spring with a stiffness of 2500 N/m. How far does the spring compress?

18 Answer X = 0.20m

19 Example 2: A 70. kg person bungee jumps off a 50.m bridge with his ankles attached to a 15m long bungee cord. Assume the person stops at the edge of the water and he is 2.0m tall, what is the force constant of the bungee cord?

20 Answer: 64 N/m Conservation of Energy Worksheet

21 Practice Problems Textbook Page 261 38-40 Section review (p 261) 1-10

Download ppt "Springs and Hooke’s Law"

Similar presentations

Chapter 5 – WORK and ENERGY. 5.2 MECHANICAL ENERGY.

Chapter 5 – WORK and ENERGY. 5.2 MECHANICAL ENERGY.
Energy Chapter 5. What is energy? The property of an object that allows it to produce a change in itself or its environment. The property of an object.

Energy Chapter 5. What is energy? The property of an object that allows it to produce a change in itself or its environment. The property of an object.
Energy Chapter 5. Mechanical Energy Energy due to movement or position. Energy due to movement or position. Kinetic Energy – energy of motion Kinetic.

Energy Chapter 5. Mechanical Energy Energy due to movement or position. Energy due to movement or position. Kinetic Energy – energy of motion Kinetic.
Work.  The product of the magnitudes of the component of a force along the direction of displacement and the displacement.  Units-Force x Length  N.

Work.  The product of the magnitudes of the component of a force along the direction of displacement and the displacement.  Units-Force x Length  N.
More Conservation of Mechanical Energy

More Conservation of Mechanical Energy
ENGR 215 ~ Dynamics Sections 14.1 – 14.3. Conservation of Energy Energy can neither be created nor destroyed during a process, it can only change forms.

ENGR 215 ~ Dynamics Sections 14.1 – Conservation of Energy Energy can neither be created nor destroyed during a process, it can only change forms.
Springs And pendula, and energy. Spring Constants SpringkUnits Small Spring Long Spring Medium spring 2 in series 2 in parallel 3 in series 3 in parallel.

Springs And pendula, and energy. Spring Constants SpringkUnits Small Spring Long Spring Medium spring 2 in series 2 in parallel 3 in series 3 in parallel.
Principles of Physics - Foederer. Energy is stored in a spring when work is done to compress or elongate it Compression or elongation= change in length.

Principles of Physics - Foederer. Energy is stored in a spring when work is done to compress or elongate it Compression or elongation= change in length.
Example: A 20 kg block is fired horizontally across a frictionless surface. The block strikes a platform that is attached to a spring at its equilibrium.

Example: A 20 kg block is fired horizontally across a frictionless surface. The block strikes a platform that is attached to a spring at its equilibrium.
Simple Harmonic Motion & Elasticity

Simple Harmonic Motion & Elasticity
PHYSICS InClass by SSL Technologies with S. Lancione Exercise-42

PHYSICS InClass by SSL Technologies with S. Lancione Exercise-42
Work. Work is the product of the magnitude of the __________________ moved times the component of a ________________ in the direction of the ________________.

Work. Work is the product of the magnitude of the __________________ moved times the component of a ________________ in the direction of the ________________.
Bellringer 10/25 A 95 kg clock initially at rest on a horizontal floor requires a 650 N horizontal force to set it in motion. After the clock is in motion,

Bellringer 10/25 A 95 kg clock initially at rest on a horizontal floor requires a 650 N horizontal force to set it in motion. After the clock is in motion,
WORK AND ENERGY 1. Work Work as you know it means to do something that takes physical or mental effort But in physics is has a very different meaning.

WORK AND ENERGY 1. Work Work as you know it means to do something that takes physical or mental effort But in physics is has a very different meaning.
ADV PHYSICS Chapter 5 Sections 2 and 4. Review  Work – force applied over a given distance W = F Δ x [W] = Joules, J  Assumes the force is constant.

ADV PHYSICS Chapter 5 Sections 2 and 4. Review  Work – force applied over a given distance W = F Δ x [W] = Joules, J  Assumes the force is constant.
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.
Preview Objectives Definition of Work Chapter 5 Section 1 Work.

Preview Objectives Definition of Work Chapter 5 Section 1 Work.
Springs A coiled mechanical device that stores elastic potential energy by compression or elongation Elastic Potential Energy – The energy stored in an.

Springs A coiled mechanical device that stores elastic potential energy by compression or elongation Elastic Potential Energy – The energy stored in an.
AP Physics C I.C Work, Energy and Power. Amazingly, energy was not incorporated into physics until more than 100 years after Newton.

AP Physics C I.C Work, Energy and Power. Amazingly, energy was not incorporated into physics until more than 100 years after Newton.
Hooke’s Law and Elastic Potential Energy

Hooke’s Law and Elastic Potential Energy

Similar presentations

Ads by Google