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The Resource Reliability-based mechanical design, Volume 1, Component under static load, Xiaobin Le

Reliability-based mechanical design, Volume 1, Component under static load, Xiaobin Le

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The item Reliability-based mechanical design, Volume 1, Component under static load, Xiaobin Le represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Liverpool.
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Creator

Le, Xiaobin

Author

Le, Xiaobin

Summary: A component will not be reliable unless it is designed with required reliability. Reliability-Based Mechanical Design uses the reliability to link all design parameters of a component together to form a limit state function for mechanical design. This design methodology uses the reliability to replace the factor of safety as a measure of the safe status of a component. The goal of this methodology is to design a mechanical component with required reliability and at the same time, quantitatively indicates the failure percentage of the component. Reliability-Based Mechanical Design consists of two separate books: Volume 1: Component under Static Load, and Volume 2: Component under Cyclic Load and Dimension Design with Required Reliability. This book is Reliability-Based Mechanical Design, Volume 1: Component under Static Load. It begins with a brief discussion on the engineering design process and the fundamental reliability mathematics. Then, the book presents several computational methods for calculating the reliability of a component under loads when its limit state function is established. Finally, the book presents how to establish the limit state functions of a component under static load and furthermore how to calculate the reliability of typical components under simple typical static load and combined static loads. Now, we do know the reliability of a component under static load and can quantitively specify the failure percentage of a component under static load. The book presents many examples for each topic and provides a wide selection of exercise problems at the end of each chapter. This book is written as a textbook for junior mechanical engineering students after they study the course of Mechanics of Materials. This book is also a good reference book for design engineers and presents design check methods in such sufficient detail that those methods are readily used in the design check of a component under static load

Language: eng

Work

Publication

San Rafael, California, Morgan & Claypool, 2019

Extent: 1 PDF (xv, 247 pages)

Note: Part of: Synthesis digital library of engineering and computer science

Contents

1. Introduction to reliability in mechanical design -- 1.1. Engineering design process -- 1.2. Failures in engineering design -- 1.3. Uncertainty in engineering -- 1.4. Definition of reliability -- 1.5. Importance of reliability -- 1.6. Reliability history -- 1.7. Reliability vs. Factor of safety -- 1.8. Summary -- 1.9. References -- 1.10. Exercises
2. Fundamental reliability mathematics -- 2.1. Introduction -- 2.2. Experiment, outcome, sample space, and event -- 2.3. Set theory -- 2.4. Definition of probability -- 2.5. Some basic operations of probability -- 2.6. Random variable -- 2.7. Mean, standard deviation, and coefficient of variance -- 2.8. Histogram -- 2.9. Probability functions -- 2.10. Mean of a random variable -- 2.11. Standard deviation and coefficient of variance -- 2.12. Some typical probability distributions -- 2.13. Goodness-of-fit test : X2 test -- 2.14. References -- 2.15. Exercises
3. Computational methods for the reliability of a component -- 3.1. Introduction -- 3.2. Limit state function -- 3.3. Reliability of a component with two random variables -- 3.4. Reliability index [beta] -- 3.5. The first-order second-moment (FOSM) method -- 3.6. The Hasofer-Lind (H-L) method -- 3.7. The Rackwitz and Fiessler (R-F) method -- 3.8. The Monte Carlo method -- 3.9. Summary -- 3.10. References -- 3.11. Exercises
4. Reliability of a component under static load -- 4.1. Introduction -- 4.2. Geometric dimension as a random variable -- 4.3. Static loading as a random variable -- 4.4. Mechanical properties of materials as random variables -- 4.5. Estimation of some design parameters -- 4.6. Reliability of a rod under axial loading -- 4.7. Reliability of a component under direct shearing -- 4.8. Reliability of a shaft under torsion -- 4.9. Reliability of a beam under bending moment -- 4.10. Reliability of a component under combined stresses -- 4.11. Summary -- 4.12. References -- 4.13. Exercises

Isbn: 9781681736617

Instance

Label: Reliability-based mechanical design, Volume 1, Component under static load

Title: Reliability-based mechanical design

Title number: Volume 1

Title part: Component under static load

Statement of responsibility: Xiaobin Le

Creator

Le, Xiaobin

Author

Le, Xiaobin

Subject

Language: eng

Summary: A component will not be reliable unless it is designed with required reliability. Reliability-Based Mechanical Design uses the reliability to link all design parameters of a component together to form a limit state function for mechanical design. This design methodology uses the reliability to replace the factor of safety as a measure of the safe status of a component. The goal of this methodology is to design a mechanical component with required reliability and at the same time, quantitatively indicates the failure percentage of the component. Reliability-Based Mechanical Design consists of two separate books: Volume 1: Component under Static Load, and Volume 2: Component under Cyclic Load and Dimension Design with Required Reliability. This book is Reliability-Based Mechanical Design, Volume 1: Component under Static Load. It begins with a brief discussion on the engineering design process and the fundamental reliability mathematics. Then, the book presents several computational methods for calculating the reliability of a component under loads when its limit state function is established. Finally, the book presents how to establish the limit state functions of a component under static load and furthermore how to calculate the reliability of typical components under simple typical static load and combined static loads. Now, we do know the reliability of a component under static load and can quantitively specify the failure percentage of a component under static load. The book presents many examples for each topic and provides a wide selection of exercise problems at the end of each chapter. This book is written as a textbook for junior mechanical engineering students after they study the course of Mechanics of Materials. This book is also a good reference book for design engineers and presents design check methods in such sufficient detail that those methods are readily used in the design check of a component under static load

Member of

Cataloging source: CaBNVSL

http://library.link/vocab/creatorName: Le, Xiaobin

Dewey number: 621.8/15

Illustrations: illustrations

Index: no index present

LC call number: TJ230

LC item number: .L473 2019eb vol. 1

Literary form: non fiction

Nature of contents

dictionaries
bibliography

Series statement: Synthesis lectures on mechanical engineering,

Series volume: 20

http://library.link/vocab/subjectName

Machine design
Structural design
Reliability (Engineering)

Target audience: adult

Label: Reliability-based mechanical design, Volume 1, Component under static load, Xiaobin Le

Instantiates

Reliability-based mechanical design, Volume 1, Component under static load

Publication

San Rafael, California, Morgan & Claypool, 2019

Note: Part of: Synthesis digital library of engineering and computer science

Bibliography note: Includes bibliographical references

Carrier category: online resource

Carrier MARC source: rdacarrier

Color: multicolored

Content category: text

Content type MARC source: rdacontent

Contents

1. Introduction to reliability in mechanical design -- 1.1. Engineering design process -- 1.2. Failures in engineering design -- 1.3. Uncertainty in engineering -- 1.4. Definition of reliability -- 1.5. Importance of reliability -- 1.6. Reliability history -- 1.7. Reliability vs. Factor of safety -- 1.8. Summary -- 1.9. References -- 1.10. Exercises
2. Fundamental reliability mathematics -- 2.1. Introduction -- 2.2. Experiment, outcome, sample space, and event -- 2.3. Set theory -- 2.4. Definition of probability -- 2.5. Some basic operations of probability -- 2.6. Random variable -- 2.7. Mean, standard deviation, and coefficient of variance -- 2.8. Histogram -- 2.9. Probability functions -- 2.10. Mean of a random variable -- 2.11. Standard deviation and coefficient of variance -- 2.12. Some typical probability distributions -- 2.13. Goodness-of-fit test : X2 test -- 2.14. References -- 2.15. Exercises
3. Computational methods for the reliability of a component -- 3.1. Introduction -- 3.2. Limit state function -- 3.3. Reliability of a component with two random variables -- 3.4. Reliability index [beta] -- 3.5. The first-order second-moment (FOSM) method -- 3.6. The Hasofer-Lind (H-L) method -- 3.7. The Rackwitz and Fiessler (R-F) method -- 3.8. The Monte Carlo method -- 3.9. Summary -- 3.10. References -- 3.11. Exercises
4. Reliability of a component under static load -- 4.1. Introduction -- 4.2. Geometric dimension as a random variable -- 4.3. Static loading as a random variable -- 4.4. Mechanical properties of materials as random variables -- 4.5. Estimation of some design parameters -- 4.6. Reliability of a rod under axial loading -- 4.7. Reliability of a component under direct shearing -- 4.8. Reliability of a shaft under torsion -- 4.9. Reliability of a beam under bending moment -- 4.10. Reliability of a component under combined stresses -- 4.11. Summary -- 4.12. References -- 4.13. Exercises

Control code: 201908MEC020

Dimensions: unknown

Extent: 1 PDF (xv, 247 pages)

File format: multiple file formats

Form of item: online

Isbn: 9781681736617

Media category: electronic

Media MARC source: isbdmedia

Other physical details: illustrations (some color).

Reformatting quality: access

Specific material designation: remote

System control number

(CaBNVSL)thg00979614
(OCoLC)1124611294

Label: Reliability-based mechanical design, Volume 1, Component under static load, Xiaobin Le

Publication

San Rafael, California, Morgan & Claypool, 2019

Note: Part of: Synthesis digital library of engineering and computer science

Bibliography note: Includes bibliographical references

Carrier category: online resource

Carrier MARC source: rdacarrier

Color: multicolored

Content category: text

Content type MARC source: rdacontent

Contents

1. Introduction to reliability in mechanical design -- 1.1. Engineering design process -- 1.2. Failures in engineering design -- 1.3. Uncertainty in engineering -- 1.4. Definition of reliability -- 1.5. Importance of reliability -- 1.6. Reliability history -- 1.7. Reliability vs. Factor of safety -- 1.8. Summary -- 1.9. References -- 1.10. Exercises
2. Fundamental reliability mathematics -- 2.1. Introduction -- 2.2. Experiment, outcome, sample space, and event -- 2.3. Set theory -- 2.4. Definition of probability -- 2.5. Some basic operations of probability -- 2.6. Random variable -- 2.7. Mean, standard deviation, and coefficient of variance -- 2.8. Histogram -- 2.9. Probability functions -- 2.10. Mean of a random variable -- 2.11. Standard deviation and coefficient of variance -- 2.12. Some typical probability distributions -- 2.13. Goodness-of-fit test : X2 test -- 2.14. References -- 2.15. Exercises
3. Computational methods for the reliability of a component -- 3.1. Introduction -- 3.2. Limit state function -- 3.3. Reliability of a component with two random variables -- 3.4. Reliability index [beta] -- 3.5. The first-order second-moment (FOSM) method -- 3.6. The Hasofer-Lind (H-L) method -- 3.7. The Rackwitz and Fiessler (R-F) method -- 3.8. The Monte Carlo method -- 3.9. Summary -- 3.10. References -- 3.11. Exercises
4. Reliability of a component under static load -- 4.1. Introduction -- 4.2. Geometric dimension as a random variable -- 4.3. Static loading as a random variable -- 4.4. Mechanical properties of materials as random variables -- 4.5. Estimation of some design parameters -- 4.6. Reliability of a rod under axial loading -- 4.7. Reliability of a component under direct shearing -- 4.8. Reliability of a shaft under torsion -- 4.9. Reliability of a beam under bending moment -- 4.10. Reliability of a component under combined stresses -- 4.11. Summary -- 4.12. References -- 4.13. Exercises

Control code: 201908MEC020

Dimensions: unknown

Extent: 1 PDF (xv, 247 pages)

File format: multiple file formats

Form of item: online

Isbn: 9781681736617

Media category: electronic

Media MARC source: isbdmedia

Other physical details: illustrations (some color).

Reformatting quality: access

Specific material designation: remote

System control number

(CaBNVSL)thg00979614
(OCoLC)1124611294

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