Potential Energy Problems

Slides:

Advertisements

Similar presentations

Wednesday, Nov. 24, 2010 PHYS , Fall 2010 Dr. Jaehoon Yu 1 PHYS 1441 – Section 002 Lecture #20 - Review Wednesday, Nov. 24, 2010 Dr. Jaehoon Yu.

Advertisements

Newton’s Laws of Motion and Free Body Analysis

PHYSICS 218 Final Exam Fall, 2006 STEPS __________________________________________________________________ No calculators are allowed in the test. Be sure.

WORK AND ENERGY. The work done by a force is the product of the magnitude of the force and the distance moved in the direction of the force Recall the.

Q07. Conservation of Energy

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Work and Energy Chapter 5 Table of Contents Section 1 Work Section.

AP Physics B Summer Course 年AP物理B暑假班

1997B1. A kg object moves along a straight line

A pendulum consisting of a ball of mass m is released from the position shown and strikes a block of mass M. The block slides a distance D before stopping.

When a car accelerates forward on a level roadway, which force is responsible for this acceleration? State clearly which.

R. Field 10/01/2013 University of Florida PHY 2053Page 1 Exam 1: Tomorrow 8:20-10:10pm Last NameRoom A-KCAR 100 L-RNPB 1001 S-ZTUR L007 You may bring a.

Physics 111 Practice Problem Statements 07 Potential Energy & Energy Conservation SJ 8th Ed.: Chap 7.6 – 7.8, 8.1 – 8.5 Contents: 8-4, 8-5, 8-16, 8-19*,

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lecture 19.

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lecture 21.

Instructor: Dr. Tatiana Erukhimova

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lecture 23.

General Physics 1, Additional questions By/ T.A. Eleyan

A block is launched up a frictionless 40° slope with an initial speed v and reaches a maximum vertical height h. The same block is launched up a frictionless.

T101Q7. A spring is compressed a distance of h = 9.80 cm from its relaxed position and a 2.00 kg block is put on top of it (Figure 3). What is the maximum.

Classical Mechanics Review 4: Units 1-19

Potential Energy and Conservative Forces

Chapter 8 - Potential Energy and Conservation of Energy Conservative vs. Non-conservative Forces Definition of Potential Energy Conservation Of Mechanical.

Preview Multiple Choice Short Response Extended Response.

Conservative Forces: The forces is conservative if the work done by it on a particle that moves between two points depends only on these points and not.

Physics 6A Work and Energy examples Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB.

Physics. Session Work, Power and Energy - 3 Session Objectives.

Conservative and non-conservative forces Potential energy Total mechanical energy Energy conservation Lecture 11: Potential energy.

Energy Examples Serway and Jewett 8.1 – 8.3 Physics 1D03 - Lecture 22.

Short Version :7. Conservation of Energy Conservative & Non-conservative Forces F is conservative if for every closed path C. is path-independent.

A certain pendulum consists of a 2

Advanced Problems 3 These problems will contain:

Work and Energy x Work and Energy 06.

Hour Exam 2 Review 9:00 Exam is Tomorrow (Wednesday) at 7:00 pm.

WHITE BOARD TIME !! CONSERVE ENERGY. E T = PE G + KE + PE S When comparing the energy at two different positions on a system, the total energy at one.

Examples: Mechanical Energy Conservation

AP Physics Semester Review 26 is torque

Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lectures 16, 17, 18.

An 7.3-kg object rests on the floor of an elevator which is accelerating downward at a rate of 1.0 m/s 2. What is the magnitude of the force the object.

Question C1.01 Description: Eliciting prior conceptions about "work" and introducing the physics definition. Source: A2L: UMPERG-ctqpe50.

Conservative and Nonconservative Forces. A Force is “Conservative” if: The work it does on an object is available for kinetic energy. These forces store.

Lecture 5Purdue University, Physics 2201 Lecture 05 Forces and Motion beyond 1 D Textbook Sections 3.7, 4.1 PHYSICS 220.

60 1. What is the mass M in the system as given in the

Instructor: Dr. Tatiana Erukhimova

Chapter 7 Work and Energy

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

Springs Forces and Potential Energy

from rest down a plane inclined at an angle q with the horizontal.

Uniform Circular Motion

Ch. 10 slides WorkEnergy.ppt.

Student misconceptions

Classical Mechanics Midterm 2 Review Force and Energy

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.

Do Now: (Yesterday’s Atwood’s Machine)

Instructor: Dr. Tatiana Erukhimova

Aim: How do we apply conservation of energy to solving problems?

AP 1 Energy practice.

Newton’s Laws - continued

Aim: How do we explain conservation of energy?

Potential Potential Energy

Aim: How do we explain conservation of energy?

WORK, ENERGY AND POWER KIMAL HONOUR DJAM ASFA.

The cart shown above is made of a block of mass (m) and four solid rubber tires each of mass (m/4) and radius (r). Each tire may be considered to be a.

Three masses are connected by light strings as shown in the figure

Work, Energy, Power.

A block of mass m resting on a horizontal

Energy Problems.

Projectile Motion and Spring Problems

T101-Q-1 Figure 1 shows the spring force as a function of position x for a spring-block system resting on a frictionless table. The block is released at.

Presentation transcript:

Potential Energy Problems h Potential Energy Problems.ppt

Problem 1 A block of mass m moving across a surface collides with an ideal spring having a force constant k. The spring compresses a distance x as it brings the block to rest. Assume the horizontal surface is frictionless. The speed of the block at the instant it collides with the spring is Potential Energy Problems.ppt

from rest down a plane inclined at an angle q with the horizontal. Problem 2 m q L A body of mass m slides from rest down a plane inclined at an angle q with the horizontal. The block slides for a distance L before reaching the bottom of the incline. Assume the surface is frictionless. The speed of the block at the bottom is h Potential Energy Problems.ppt

Problem 3 m L h q m A body of mass m slides from rest down a plane inclined at an angle q with the horizontal. The block slides for a distance L before reaching the bottom of the incline. The coefficient of kinetic friction between all surfaces and the block is m. The distance the block slides on the horizontal surface before coming to rest is Potential Energy Problems.ppt

Problem 4 m d KE q m A block of mass m moving with kinetic energy KE starts up an incline which makes an angle q with the horizontal. The coefficient of kinetic friction between the block and the incline is m. The distance the block slides along the incline before coming to rest is Potential Energy Problems.ppt

Problem 5 F m q A block of mass m is pushed up a frictionless incline by a constant horizontal force F. The incline has a length L and makes an angle q with the horizontal. The speed of the block on the incline is v at the bottom and 2v at the top. The work done by the force is Potential Energy Problems.ppt

Problem 6 F m q A block of mass m is pushed up a frictionless incline by a constant horizontal force F. The incline has a length L and makes an angle q with the horizontal. The speed of the block on the incline is v at the bottom and 2v at the top. The magnitude of the force is Potential Energy Problems.ppt

Problem 7 h A small block slides along a curved track from a height h on to a horizontal track. The curved portion of the track has no friction and the coefficient of kinetic friction between the block and the flat portion of the track is m. The distance the block slides on the flat portion of the track before coming to rest is Potential Energy Problems.ppt

A block of mass m is dropped from Problem 8 m A block of mass m is dropped from a height h onto a vertical spring which has a force constant k. The maximum distance the spring is compressed is h x m Potential Energy Problems.ppt

m 2m h Problem 9 Atwood’s machine consists of two masses which are connected by a light string which passes over a frictionless pulley as shown. Mass m lies on the floor when mass 2m is released from rest. The speed at which the 2m mass hits the floor is Potential Energy Problems.ppt

Potential Energy Problems END Potential Energy Problems.ppt