Presentation is loading. Please wait.

Presentation is loading. Please wait.

10/10 Spring Potential Energy  Text: Chapter 6 Energy  HW 10/10 “Spring Energy” due Monday 10/14  Exam 2 Thursday, 10/17 5-7 Wit 116 6-8 Wit 114 (only.

Published byKory Dickerson Modified over 8 years ago

Similar presentations

Presentation on theme: "10/10 Spring Potential Energy  Text: Chapter 6 Energy  HW 10/10 “Spring Energy” due Monday 10/14  Exam 2 Thursday, 10/17 5-7 Wit 116 6-8 Wit 114 (only."— Presentation transcript:

1 10/10 Spring Potential Energy  Text: Chapter 6 Energy  HW 10/10 “Spring Energy” due Monday 10/14  Exam 2 Thursday, 10/17 5-7 Wit 116 6-8 Wit 114 (only if needed) Please send email if other time needed

2 The Kinetic Bucket... KE + PE g + PE s = E

3 PE Gravity Bucket... KE + PE g + PE s = E hh

4 A new bucket... KE + PE g + PE s = E xx

5 Force and Springs Force is proportional to the displacement from “relaxed” length. Relaxed Length 10 N 20 N 30 N xx xx xx xx xx xx

6 HOOKE’S LAW F = - k  x FORCE SPRING CONSTANT DISPLACEMENT

7 Force constant “k”  Tells us how “stiff” the spring is.  Stiff spring = large k  Units: N/m (“Newton per Meter”)  Meaning: “How many Newton’s of force for each meter of stretch or compression”

8 That Pesky Minus Sign note: minus sign just tells us that the force opposes the displacement Use your head, not the math F = - k  x

9 xx An external agent (the hand) pushes on a mass and compresses a spring with spring constant k a distance  x. KE + PE g + PE s = E i KE + PE g + PE s = E f

10 xx An external agent (the hand) pushes on a mass and compresses a spring with spring constant k a distance  x. KE + PE g + PE s = E i KE + PE g + PE s = E f +WORK

11 xx Work = F  x Hooke’s Law F = k  x Work = (k  x)  x = k  x 2 ??? KE + PE g + PE s = E i KE + PE g + PE s = E f F = k  x F = 0 F ave = 1/2 k  x Work = F ave  x Work = (1/2 k  x)  x = 1/2 k  x 2 PE s

12 Energy stored in a spring (PE s )  energy is stored whether spring is compressed or stretched   x measured from relaxed spring length  amount stored given by: PE s = 1/2 k  x 2

13  k =0.2 AB 10kg A 10kg block compresses a spring 0.5m and is then released... KE + PE g + PE s = E

14  k =0.2 AB  x=0.5m k=16000N/m How much energy is stored in the spring? 10kg KE + PE g + PE s = E

15  k =0.2 AB  x=0.5m k=16000N/m We release the block. 10kg KE + PE g + PE s = E

16  k =0.2 AB  x=0.5m k=16000N/m How much kinetic energy does the block have at point A? 10kg KE + PE g + PE s = E 10kg

17  k =0.2 AB  x=0.5m k=16000N/m What is the speed of the block at point A? 10kg KE + PE g + PE s = E 10kg

18  k =0.2 AB  x=0.5m k=16000N/m How far will the block slide past point B before it comes to a stop? 10kg KE + PE g + PE s = E 10kg

19 h=? 2 m  K = 0.3 v = 0  x = 0.5 m k = 160 N/m A BC Practice Problem: A block of mass M = 10 kg slides from rest down a frictionless ramp and drops a distance h. After crossing a rough patch the block compresses a spring with k = 160 N/m an amount  x = 0.5 m and comes to a momentary stop. Find h.

Download ppt "10/10 Spring Potential Energy  Text: Chapter 6 Energy  HW 10/10 “Spring Energy” due Monday 10/14  Exam 2 Thursday, 10/17 5-7 Wit 116 6-8 Wit 114 (only."

Similar presentations

Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.

Mr. Jean November 21 st, 2013 IB Physics 11 IB Physics 11.
Unit 7 Energy.  Energy is the ability to do work or cause change. I can work…but I won’t.

Unit 7 Energy.  Energy is the ability to do work or cause change. I can work…but I won’t.
Kinetic energy. Energy Energy is usually defined as the capacity to do work. One type of energy is kinetic energy.

Kinetic energy. Energy Energy is usually defined as the capacity to do work. One type of energy is kinetic energy.
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.
PHYS 152 Fall 2005 Thursday, Sep 22 Chapter 6 - Work, Kinetic Energy & Power.

PHYS 152 Fall 2005 Thursday, Sep 22 Chapter 6 - Work, Kinetic Energy & Power.
Elastic potential energy

Elastic potential energy
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.
Simple Harmonic Motion & Elasticity

Simple Harmonic Motion & Elasticity
Kinetic Energy Kinetic energy is energy of motion. Kinetic energy is a scalar quantity. KE = ½ mv 2 kinetic energy = ½ mass x (speed) 2 Units for KE are.

Kinetic Energy Kinetic energy is energy of motion. Kinetic energy is a scalar quantity. KE = ½ mv 2 kinetic energy = ½ mass x (speed) 2 Units for KE are.
Springs And pendula, and energy. Harmonic Motion Pendula and springs are examples of things that go through simple harmonic motion. Simple harmonic motion.

Springs And pendula, and energy. Harmonic Motion Pendula and springs are examples of things that go through simple harmonic motion. Simple harmonic motion.
It takes work to lift a mass against the pull (force) of gravity The force of gravity is m·g, where m is the mass, and g is the gravitational acceleration.

It takes work to lift a mass against the pull (force) of gravity The force of gravity is m·g, where m is the mass, and g is the gravitational acceleration.
Springs and Hooke’s Law

Springs and Hooke’s Law
Physics 121 6. Work and Energy 6.1 Work 6.3 Kinetic Energy 6.4 Potential Energy 6.5 Conservative and Non-conservative forces 6.6 Mechanical Energy /

Physics Work and Energy 6.1 Work 6.3 Kinetic Energy 6.4 Potential Energy 6.5 Conservative and Non-conservative forces 6.6 Mechanical Energy /
Regents Physics Springs.

Regents Physics Springs.
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.
Announcements CAPA Set #9 due Friday at 10 pm This week in Section: Lab #3 – Momentum Reading – Chapter 7 on Momentum.

Announcements CAPA Set #9 due Friday at 10 pm This week in Section: Lab #3 – Momentum Reading – Chapter 7 on Momentum.
Chapter 8: Potential Energy and Conservation of Energy

Chapter 8: Potential Energy and Conservation of Energy
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.
Chapter 6, Continued. Summary so Far Work-Energy Principle: W net = (½)m(v 2 ) 2 - (½)m(v 1 ) 2   KE Total work done by ALL forces! Kinetic Energy:

Chapter 6, Continued. Summary so Far Work-Energy Principle: W net = (½)m(v 2 ) 2 - (½)m(v 1 ) 2   KE Total work done by ALL forces! Kinetic Energy:

Similar presentations

Ads by Google