Engineering Mechanics Second Edition Dynamics /

By:

J.L Meriam. -J.M Henderson

Series: seriesPublication details: jhon wellet and sons U. S. A 1976Edition: 2DA EDICIONDescription: 149 Ilustraciones, tablas, graficos 27.5CMISBN:

0-471-84255-9

Subject(s):

Ingeniería en tecnologias de la información y comunicaciones

Contents:

CONTENTS I Introduction 1. DEFINITIONS AND PRINCIPLES 2. UNITS 3. PROBLEM FORMULATION 11. Kinematics of Particles 4. ANALYSIS TECHNIQUES 5. RECTILINEAR MOTION 6. CURVILINEAR MOTION 3 4 7. RELATIVE MOTION III. Kinetics of Particles 8. EQUATIONS OF MOTION 9. WORK-ENERGY 10. IMPULSE-MOMENTUM IV. Plane Kinematics of Rigid Bodies 11. ABSOLUTE MOTION 12. RELATIVE VELOCITY 13. RELATIVE ACCELERATION 14. ROTATING AXES 70 V. Plane Kinetics of Rigid Bodies 15. INERTIAL PROPERTIES 78 16. FORCE-MASS-ACCELERATION 84 17. WORK-ENERGY 92 18. IMPULSE-MOMENTUM 98 VI. Special Topics 19. IMPACT 104 20. CENTRAL-FORCE MOTION 110 21. VIBRATIONS 116 22. STEADY MASS FLOW 122 23. INTRODUCTION TO SPACE KINEMATICS 128 24. INTRODUCTION TO SPACE KINETICS 134 25. GYROSCOPIC MOTION 140 VII. Conclusion 26. REVIEW COMMENTS 146 27. ADDITIONAL TOPICS 148

Summary: This Study Guide offers a complete and step-by-step explanation of the basic elements of dynamics to help develop your problem-solving abilities. It is assumed that you have successfully completed a course in statics and, therefore, are familiar with forces, moments, couples, resultants, and free-body diagrams, all of which are essential components of the study of dynamics. The purpose of engineering centers around creative design, and engineering practice requires problem-solving in the design process. The decision process continually used in engineering design must be supported with a strong analytical and problem-solving ability. To solve a prob-lem, you must first formulate it. Problem formulation is the process of building a mathematical model that can generate specific answers (numbers or relationships) to predict the behavior of the physical problem. Design decisions are then based on these predictions. The analysis of a typical engineering problem can be represented as follows:

Holdings
Item type	Current library	Call number	Copy number	Status	Date due	Barcode
Libro	CI Gustavo A. Madero 2	TA405 T5332 1987	1	Available

EDITORIAL
jhon wellet and sons
ISBN
0-471-84255-9

CONTENTS

I Introduction

1. DEFINITIONS AND PRINCIPLES

2. UNITS

3. PROBLEM FORMULATION

11. Kinematics of Particles

4. ANALYSIS TECHNIQUES

5. RECTILINEAR MOTION

6. CURVILINEAR MOTION

3

4

7. RELATIVE MOTION

III. Kinetics of Particles

8. EQUATIONS OF MOTION

9. WORK-ENERGY

10. IMPULSE-MOMENTUM

IV. Plane Kinematics of Rigid Bodies

11. ABSOLUTE MOTION

12. RELATIVE VELOCITY

13. RELATIVE ACCELERATION

14. ROTATING AXES

70

V. Plane Kinetics of Rigid Bodies

15. INERTIAL PROPERTIES

78

16. FORCE-MASS-ACCELERATION

84

17. WORK-ENERGY

92

18. IMPULSE-MOMENTUM

98

VI. Special Topics

19. IMPACT

104

20. CENTRAL-FORCE MOTION

110

21. VIBRATIONS

116

22. STEADY MASS FLOW

122

23. INTRODUCTION TO SPACE KINEMATICS 128

24. INTRODUCTION TO SPACE KINETICS

134

25. GYROSCOPIC MOTION

140

VII. Conclusion

26. REVIEW COMMENTS

146

27. ADDITIONAL TOPICS

148

This Study Guide offers a complete and step-by-step explanation of the basic elements of dynamics to help develop your problem-solving abilities. It is assumed that you have successfully completed a course in statics and, therefore, are familiar with forces, moments, couples, resultants, and free-body diagrams, all of which are essential components of the study of dynamics.

The purpose of engineering centers around creative design, and engineering practice requires problem-solving in the design process. The decision process continually used in engineering design must be supported with a strong analytical and problem-solving ability. To solve a prob-lem, you must first formulate it. Problem formulation is the process of building a mathematical model that can generate specific answers (numbers or relationships) to predict the behavior of the physical problem. Design decisions are then based on these predictions.

The analysis of a typical engineering problem can be represented as follows:

Ingeniería en Tecnologías de la Información y Comunicación

There are no comments on this title.

to post a comment.

Click on an image to view it in the image viewer