Lecture 9 Kinetics of rigid bodies: Impulse and Momentum

Similar documents
PLANAR KINETIC EQUATIONS OF MOTION (Section 17.2)

Rigid bodies - general theory

EQUATIONS OF MOTION: ROTATION ABOUT A FIXED AXIS (Section 17.4) Today s Objectives: Students will be able to analyze the planar kinetics of a rigid

PLANAR KINETIC EQUATIONS OF MOTION: TRANSLATION (Sections ) Today s Objectives: Students will be able to: a) Apply the three equations of

Rotational kinematics

jfpr% ekuo /kez iz.ksrk ln~xq# Jh j.knksm+nklth egkjkt

CEE 271: Applied Mechanics II, Dynamics Lecture 33: Ch.19, Sec.1 2

CEE 271: Applied Mechanics II, Dynamics Lecture 28: Ch.17, Sec.2 3

Chapter 8- Rotational Motion

2015 ENGINEERING MECHANICS

E 490 FE Exam Prep. Engineering Mechanics

Chapter 8 Lecture Notes

CEE 271: Applied Mechanics II, Dynamics Lecture 24: Ch.17, Sec.1-3

PLANAR KINETIC EQUATIONS OF MOTION: TRANSLATION

Rigid Body Kinetics :: Virtual Work

Rotation. EMU Physics Department. Ali ÖVGÜN.

PLANAR KINETICS OF A RIGID BODY FORCE AND ACCELERATION

Please Visit us at:

Lecture 3. Rotational motion and Oscillation 06 September 2018

Dynamics. Dynamics of mechanical particle and particle systems (many body systems)

Lecture 38: Equations of Rigid-Body Motion

General Physics I. Lecture 10: Rolling Motion and Angular Momentum.

6. 3D Kinematics DE2-EA 2.1: M4DE. Dr Connor Myant

Rotational Motion, Torque, Angular Acceleration, and Moment of Inertia. 8.01t Nov 3, 2004

1301W.600 Lecture 16. November 6, 2017

Rotation of Rigid Bodies

Handout 7: Torque, angular momentum, rotational kinetic energy and rolling motion. Torque and angular momentum

Autonomous Mobile Robot Design

DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS AP PHYSICS

STATICS & DYNAMICS. Engineering Mechanics. Gary L. Gray. Francesco Costanzo. Michael E. Plesha. University of Wisconsin-Madison

PLANAR KINETIC EQUATIONS OF MOTION: TRANSLATION

2015 ENGINEERING MECHANICS

Chapter 8 Rotational Equilibrium and Rotational Dynamics Force vs. Torque Forces cause accelerations Torques cause angular accelerations Force and

Two-Dimensional Rotational Kinematics

Basics of rotational motion

The... of a particle is defined as its change in position in some time interval.

Get Discount Coupons for your Coaching institute and FREE Study Material at Force System

Rotational Kinematics and Dynamics. UCVTS AIT Physics

CEE 271: Applied Mechanics II, Dynamics Lecture 25: Ch.17, Sec.4-5

τ = F d Angular Kinetics Components of Torque (review from Systems FBD lecture Muscles Create Torques Torque is a Vector Work versus Torque

Course syllabus Engineering Mechanics - Dynamics

Chapter 8: Momentum, Impulse, & Collisions. Newton s second law in terms of momentum:

Lecture 9 - Rotational Dynamics

Lectures. Today: Rolling and Angular Momentum in ch 12. Complete angular momentum (chapter 12) and begin equilibrium (chapter 13)

AP Pd 3 Rotational Dynamics.notebook. May 08, 2014

Video 2.1a Vijay Kumar and Ani Hsieh

Lecture D20-2D Rigid Body Dynamics: Impulse and Momentum

Chapter 12. Rotation of a Rigid Body

Plane Motion of Rigid Bodies: Forces and Accelerations

Angular Motion, General Notes

Advanced Dynamics. - Lecture 4 Lagrange Equations. Paolo Tiso Spring Semester 2017 ETH Zürich

Rotational Kinetic Energy

6-1. Conservation law of mechanical energy

16. Rotational Dynamics

APPLICATIONS. CEE 271: Applied Mechanics II, Dynamics Lecture 17: Ch.15, Sec.4 7. IMPACT (Section 15.4) APPLICATIONS (continued) IMPACT READING QUIZ

TutorBreeze.com 7. ROTATIONAL MOTION. 3. If the angular velocity of a spinning body points out of the page, then describe how is the body spinning?

Chapter 11. Angular Momentum

2007 Problem Topic Comment 1 Kinematics Position-time equation Kinematics 7 2 Kinematics Velocity-time graph Dynamics 6 3 Kinematics Average velocity

Explain why the turntable speed decreases when the plasticine sticks to it

Review of physics concepts for Exam 3. April, 2019

AS3010: Introduction to Space Technology

Lecture 20 Chapter 12 Angular Momentum Course website:

Motion Of An Extended Object. Physics 201, Lecture 17. Translational Motion And Rotational Motion. Motion of Rigid Object: Translation + Rotation

Physics. TOPIC : Rotational motion. 1. A shell (at rest) explodes in to smalll fragment. The C.M. of mass of fragment will move with:

DEVIL PHYSICS BADDEST CLASS ON CAMPUS IB PHYSICS

Lecture 35: The Inertia Tensor

Rigid Body Dynamics and Beyond

z F 3 = = = m 1 F 1 m 2 F 2 m 3 - Linear Momentum dp dt F net = d P net = d p 1 dt d p n dt - Conservation of Linear Momentum Δ P = 0

General Physics (PHY 2130)

27. Impact Mechanics of Manipulation

7. The gyroscope. 7.1 Introduction. 7.2 Theory. a) The gyroscope

Mechanics. In the Science Program, Mechanics contributes to the following program goals described in the Exit Profile:

RIGID BODY MOTION (Section 16.1)

12. Foundations of Statics Mechanics of Manipulation

1 Problems 1-3 A disc rotates about an axis through its center according to the relation θ (t) = t 4 /4 2t

Slide 1 / 30. Slide 2 / 30. Slide 3 / m/s -1 m/s

Lecture Outline Chapter 10. Physics, 4 th Edition James S. Walker. Copyright 2010 Pearson Education, Inc.

Angular Momentum. Objectives CONSERVATION OF ANGULAR MOMENTUM

Angular Momentum Conservation of Angular Momentum

IMPACT Today s Objectives: In-Class Activities:

3-D Kinetics of Rigid Bodies

Problem 1 Problem 2 Problem 3 Problem 4 Total

Physics 111. Tuesday, November 2, Rotational Dynamics Torque Angular Momentum Rotational Kinetic Energy

STUDY GUIDE 4: Equilibrium, Angular Kinematics, and Dynamics

Kinetic Energy of Rolling

*Definition of Mechanics *Basic Concepts *Newton s Laws *Units

Physics 141. Lecture 18. Frank L. H. Wolfs Department of Physics and Astronomy, University of Rochester, Lecture 18, Page 1

PHY131H1S - Class 20. Pre-class reading quiz on Chapter 12

Physics 130: Questions to study for midterm #1 from Chapter 8

A Ferris wheel in Japan has a radius of 50m and a mass of 1.2 x 10 6 kg. If a torque of 1 x 10 9 Nm is needed to turn the wheel when it starts at

Page 2 (20) Page 3 (12) Page 4 (14) Page 5 (14) Total (60) PHYSICS 11 (Fall 2003) Exam 3. Elementary Physics November 21, 2003 SCORE BOX

Theory and Practice of Rotor Dynamics Prof. Dr. Rajiv Tiwari Department of Mechanical Engineering Indian Institute of Technology Guwahati

Satellite meteorology

1/30. Rigid Body Rotations. Dave Frank

Date Period Name. Write the term that correctly completes the statement. Use each term once. elastic collision

III. Work and Energy

If the symmetry axes of a uniform symmetric body coincide with the coordinate axes, the products of inertia (Ixy etc.

Physics 121, March 25, Rotational Motion and Angular Momentum. Department of Physics and Astronomy, University of Rochester

8.012 Physics I: Classical Mechanics Fall 2008

Physics for Scientists and Engineers 4th Edition, 2017

Transcription:

Lecture 9 Kinetics of rigid bodies: Impulse and Momentum Momentum of 2-D Rigid Bodies Recall that in lecture 5, we discussed the use of momentum of particles. Given that a particle has a, and is travelling with a, its momentum is given by Now, let us consider a 2-D rigid body of mass m G translating in a straight line with velocity v G. We can determine the of the rigid body by summing vectorially the linear momentum of each particle that makes up this body, i.e. [Eqn.1] The term L in equation 1 denotes the rigid body linear momentum. When a 2-D rigid body undergoes a rotational motion, its is given by [Eqn.2] where H O is the angular momentum of the rigid body about point O I O is the moment of inertial computed at point O ω Is the angular velocity of the rigid body 1 / 6

Figure 1 The position of point O is arbitrary and should be selected appropriately for specific problems. For example in figure 1(a), the disc rotates about its _ and the moment of inertia is given by _, Whereas in figure 1(b), the disc is rotating about the pin support at point B which is on the circumference, hence the moment of inertia in this case is. Note that we can the axis of rotation from A to B (for the disc in figure1) and the values of the moment of inertia by using the relationship We will encounter types of motion by a 2-D rigid body, namely,, and. Figure 2 2 / 6

Note that we will usually compute the momentum at the centre of mass of the object. This point is denoted by the subscript G. Pure Translation For a 2-D rigid body undergoing only translational motion, its momentum is given by Rotation About a Fixed Axis For a 2-D rigid body undergoing rotational motion about a fixed axis, its momentum is given by or we can also compute the angular momentum at the rotational axis, denoted by point O in this case General Plane Motion For a 2-D rigid body in a general plane motion, i.e. it is undergoing both translational and rotational motions, its momentum is given by Principle of Impulse and Momentum Linear Impulse and Momentum 3 / 6

Recall that a linear impulse for a particle is given by. It is a vector quantity which quantifies the effects of a force during the time the force acts. It has the same direction as the force, and its magnitude has units of N sec. The principle of linear impulse and momentum states that the acted on the body by external forces during the time interval t 1 to t 2 is equal to of the body during the same time interval. Rewriting this in a mathematical expression yields [Eqn.3] Angular Impulse and Momentum The principle of angular impulse momentum of a 2-D rigid body takes a similar form as the linear momentum. Hence, for a body undergoing general plane motion, this is given by [Eqn.4] Combination of Linear and Angular Impulse and Momentum We can summarise the principle of impulse and momentum for a rigid body with planar motion, i.e. translation on x-y plane and rotation about z axis, as 4 / 6

Conservation of Momentum Linear Momentum From equation 3, we see that if the acting on the body over the time interval, the linear momentum of the system must be, i.e. 0= [Final [Final linear momentum] = [Initial linear momentum] linear momentum]-[initial linear momentum] We can apply the concept of momentum conservation when the linear impulses are. Examples of these circumstances are small forces acting over very short period of time. Angular Momentum 0= [Final angular momentum]-[initial angular momentum] [Final angular momentum] = [Initial angular momentum] The conservation of angular momentum takes a similar form as the linear part. An example of conservation of angular momentum in practice is when a diver athlete executes a somersault. He tucks in his limps close to his body in order to reduce his body s moment of inertia, so that his angular velocity (in this case, spin rate) increases. Eccentric Impact An eccentric impact is an impact where the mass centres of two rigid bodies (See figure 3a). In the case where alignment is present, we use the particle impact analysis as discussed in lecture 4. 5 / 6

Figure 3 Recall the that we encountered before while analysing central impact. The coefficient of restitution is defined as the ratio of of the points of contact just after impact to the of these points. Therefore, for the eccentric impact, the coefficient of restitution is given by where v A denotes the velocity of body A in the direction of the line of impact v B denotes the velocity of body B in the direction of the line of impact subscript 1 denotes the values before impact subscript 2 denotes the values after impact 6 / 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback