The Handbook of Reliability, Maintenance, and System Safety through Mathematical Modeling discusses the many factors affect reliability and performance, including engineering design, materials, manufacturing, operations, maintenance, and many more. Reliability is one of the fundamental criteria in engineering systems design, with maintenance serving as a way to support reliability throughout a system’s life. Addressing these issues requires information, modeling, analysis and testing. Different techniques are proposed and implemented to help readers analyze various behavior measures (in terms of the functioning and performance) of systems.
Author(s): Amit Kumar, Mangey Ram
Publisher: Academic Press
Year: 2021
Language: English
Pages: 520
City: London
Front-Mat_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety-t
The Handbook of Reliability, Maintenance, and System Safety through Mathematical ModelingEdited byAmit KumarDepartment of M ...
Copyrig_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety-thr
Copyright
Contribut_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety-t
Contributors
Editors--Biog_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safe
Editors’ Biographies
Prefac_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety-thro
Preface
Acknowledgm_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety
Acknowledgments
Chapter-1---Reliability--availability--and-ma_2021_The-Handbook-of-Reliabili
1 . Reliability, availability, and maintainability analysis of an industrial plant based on Six Sigma approach: a case study in ...
1. Introduction
2. Theoretical background
2.1 Six Sigma
2.2 RAM analysis
3. Project methodology
3.1 Define phase
3.2 Measure phase
3.3 Analyze phase
3.4 Improve phase
3.5 Control phase
4. Case study
4.1 Production process
4.2 Operations management
5. Results and discussion
5.1 Reliability and maintainability analysis
5.2 Improve and control
6. Conclusions
References
Chapter-2---Impact-of-the-degree-of-hybridiz_2021_The-Handbook-of-Reliabilit
2 . Impact of the degree of hybridization on the reliability and system safety of a Helicopter's traction drive based on Lz-tra ...
1. Introduction
2. Description of the degree of hybridization and the Lz-transform method
2.1 Degree of hybridization
2.2 Lz-transform method
3. Topologies of the conventional and hybrid-electric traction drives
3.1 Conventional traction drive topology
3.2 Hybrid-electric traction drive topologies
3.2.1 Serial hybrid traction drive topology
3.2.2 Parallel hybrid traction drive topology
3.2.3 Combined hybrid traction drive topology
4. The impact of DoH on availability and fault tolerance of hybrid-electric traction drive
4.1 Elements description
4.2 Multi-state models for conventional and hybrid-electric traction drive topologies
4.2.1 Topology of conventional traction drive
4.2.2 Topology of combined hybrid traction drive
4.3 Impact of DoH on availability and fault tolerance of hybrid-electric traction drive
5. Full-electric traction drive topologies and corresponding availability analyses
5.1 Full-electric traction drive topologies
5.1.1 Single-line electric traction drive topology
5.1.2 Dual-line 1 electric traction drive topology
5.1.3 Dual-line 2 electric traction drive topology
5.2 Availability of comparative analyses
6. Sensitivity analysis of system elements
7. Conclusion
References
Chapter-3---General-forms-of-Bivari_2021_The-Handbook-of-Reliability--Mainte
3 . General forms of Bivariate survival functions with reliability applications
1. Introduction
2. General approach
3. Analyses of some common bivariate models
3.1 Gumbel Case
3.2 Freund Case
3.3 Marshall and Olkin bivariate case
3.4 Singpurwalla and Youngren bivariate exponential model
3.5 Arnold and Strauss bivariate exponential
3.6 Oakes bivariate frailty model
3.7 A bivariate Weibull case
References
Chapter-4---Reliability-analysis-of-cutt_2021_The-Handbook-of-Reliability--M
4 . Reliability analysis of cutting system of sugar industry using intuitionistic fuzzy Lambda–Tau approach
1. Introduction
2. Literature background
3. Notions of intuitionistic fuzzy set theory and Lambda–Tau approach
3.1 Notions of Intuitionistic fuzzy theory
3.1.1 Intuitionistic fuzzy set
3.1.2 α Cut of IFS
3.1.3 Triangular intuitionistic fuzzy number
3.2 Intuitionistic fuzzy set Lambda–Tau approach
4. Case study
4.1 System description
4.2 Application of intuitionistic fuzzy set Lambda–Tau approach
5. Result discussion
6. Conclusion
References
Chapter-5---Game-theoretic-modeling-and-depen_2021_The-Handbook-of-Reliabili
5 . Game theoretic modeling and dependability analysis of small cell relays under bandwidth spoofing attack in 5G wireless comm ...
1. Introduction
2. An overview of stochastic game
3. Proposed game model
3.1 Predicting attacker behavior
3.1.1 Algorithm 1
3.2 Illustration of the attacker behavior
4. Dependability analysis of small cell relay under DoS attack
4.1 Numerical illustration
4.2 Model validation
5. Result discussion
6. Conclusion
Acknowledgment
References
Chapter-6---Standbys-provisioning-in-ma_2021_The-Handbook-of-Reliability--Ma
6 . Standbys provisioning in machine repair problem with unreliable service and vacation interruption
1. Introduction
2. Machine repair problem
2.1 Notations
3. Working vacation and vacation interruption
3.1 Notations
4. MRP with WV, VI, and unreliable service
4.1 Notations
5. Special cases
6. Cost analysis
6.1 Steady-state analysis
6.2 Cost function
6.3 Particle swarm optimization
7. Numerical results
8. Discussion
9. Conclusion
Acknowledgment
References
Chapter-7---Methods-of-modeling-the-m_2021_The-Handbook-of-Reliability--Main
7 . Methods of modeling the maintenance of a steam turbine based on condition assessment
1. Introduction
2. Terms and definitions
3. Maintenance conceptions for steam turbine system
3.1 Life cycle of a steam turbine system
3.2 Criteria for determining the strategy for maintaining steam turbines
3.3 Cost–maintenance ratio
3.4 Maintenance methods for technical systems
4. Steam turbine maintenance method according to state
4.1 Theoretical basics of the posture condition method
4.2 Maintenance and decomposition activities of the steam turbine system
5. Methods of modeling of a steam turbine plant maintenance
5.1 Data collection
5.2 Testing and determining methodology of the remaining service life of the structural parts of a turbine plant
6. Technical diagnostic methods for steam turbine within the complex of thermal power plant technical system
6.1 Technical diagnostic methods for the analysis of the condition of steam turbines
6.2 Maintenance control of current status by condition
6.3 Defining the legality of steam turbine failure
6.4 Defining the lawfulness of steam turbine failure
7. Measures to reduce damages and increase reliability of steam turbines
8. Result discussion
9. Conclusion
References
Chapter-8---Qualitative-analysis-in_2021_The-Handbook-of-Reliability--Mainte
8 . Qualitative analysis in the reliability assessment of the steam turbine plant
1. Introduction
2. Definition of maintenance and reliability
3. Systemic approach to reliability analysis
4. Operation and maintenance of steam turbines as a condensation thermal power plant
5. Steam turbine as a technical system
6. Qualitative analysis of a steam tube plant
6.1 Functional analysis of a steam turbine plant
6.1.1 Function division
6.1.2 Technical methods of functional analysis
6.2 Basic concept of fault analysis
6.2.1 Failure mode
6.2.2 Cause and mechanism of failure
6.2.3 Effect and consequence of failure
6.3 Classification of failures in the general case
6.4 Classification of failures for the steam turbine system
6.4.1 Propulsion damage due to erosion and corrosion
6.4.2 Water damage due to water shocks
6.4.3 Diaphragm deflections
6.4.4 Control and maintenance of bearing operation
6.4.5 Damage to the blades
6.4.6 Malfunctions of the condensation plant
6.4.7 Steam turbine rotor control and centering
6.4.8 Turbine oil quality control in the function of maintaining the steam turbine system
6.4.8.1 Water getting into turbine oil
6.5 Reliability and initial database analysis
6.5.1 Basic mathematical definitions related to the reliability of technical systems
6.5.2 Reliability methods and techniques
6.5.2.1 Qualitative and quantitative methods
6.5.2.2 Inductive and deductive methods
6.5.2.3 Dependency modeling
6.5.3 Reliability sources
6.5.3.1 Functional block failure event database
6.5.3.2 Accident or incident database
6.5.3.3 Database reliability components
6.5.3.4 Data analysis and data quality
7. Costs as indicator of economic efficiency of securing reliability
7.1 Some aspects of cost estimation related to providing reliability at the stage of development, design and conquest of a ther ...
7.2 Some aspects of estimating costs related to ensuring reliability at the plant design and installation phase
7.3 Determining the amount of capital investment for provisions and the process of switching on plants within the electricity s ...
7.4 Reliability limitations due to force majeure
7.5 Basic aspects of project predicting cost estimation related to ensuring reliability at the exploitation phase
7.6 Supplementary effects related to the analysis of costs and forms of reservation of the system of thermal power plants withi ...
7.7 Reliability optimization based on minimum cost criteria at a hierarchically higher level (thermal power plant—electricity s ...
8. Repair activities under the steam turbine system and the impact on reliability
9. Result discussion
10. Conclusion
References
Chapter-9---Methods-of-risk-m_2021_The-Handbook-of-Reliability--Maintenance-
9 . Methods of risk modeling in a thermal power plant
1. Introduction
2. Basic concepts, definitions, and risk sharing
3. Planned working life cycle of the thermal power plant
3.1 The requirements concerning thermal power plants' useful (service) life
3.2 Maintenance requirements
3.3 Determination of block guarantee points
4. Risks in the design of thermal power plant
5. Risks in exploitation of thermal power plant
6. Methods for risk assessment of thermal power plant
6.1 Quantitative risk assessment methods
6.2 Qualitative risk assessment methods
6.3 Semiquantitative (combined) methods for risk assessment
7. A new way of thinking about problems
7.1 Identification of dangers in the work of thermal power plants
7.2 Indeterminacy in the safety tasks
8. Modeling of the quantitative risk assessment (analysis) system
8.1 Indeterminacy and its measurement
8.2 Risk scenario ranking
8.3 Risk assessment methods according to ISO 31010: 2009
8.4 Environmental risk assessment methods
8.4.1 Possible impacts of the thermal power plant on the health of the population of the locality in question
8.4.2 Measures to be taken in the event of a major accident (in the event of an accident)
9. Examples of risk modeling in thermal power plants
9.1 The role of statistical analysis of safety in the exploitation phase of technical systems
9.1.1 Accident risk assessment based on the event tree method
9.2 Failure tree and block diagram in terms of reliability
10. Result discussion
11. Conclusion
References
Chapter-10---Analysis-of-the-technical-s_2021_The-Handbook-of-Reliability--M
10 . Analysis of the technical system reliability assessment with the application of technical diagnostics
1. Introduction
2. Theoretical settings of industrial system maintenance
2.1 Maintenance concepts of industrial systems
2.1.1 Maintenance concept according to the state of technical system of the paper machine
2.1.2 Technical diagnostics as a precondition of maintenance according to state
2.2 Reliability as a measure of the effectiveness of a maintenance system
3. Application of technical diagnostic measures at critical positions
3.1 Defining critical paper machine positions
4. Analysis of the reliability assessment of the technical system
4.1 Reliability analysis of the production system up to the time of technical diagnostic installation
4.1.1 Assumption number 1—check for normal distribution
4.1.1.1 Distribution testing: Kolmogorov–Smirnov test for the period until the installation of technical diagnostics
4.1.2 Assumption number 2—check the exponential distribution
4.1.3 Assumption number 3—checking the Weibull distribution
4.1.3.1 Graphical interpretation of the Weibull distribution
4.2 Analysis of the production system reliability after the installation of technical diagnostics
4.2.1 Assumption number 1—check for normal distribution
4.2.1.1 Distribution testing: Kolmogorov–Smirnov test for the period after installation of technical diagnostics
4.2.2 Assumption number 2—check the exponential distribution
4.2.3 Assumption number 3—checking the Weibull distribution
4.2.3.1 Graphical interpretation of Weibull distribution after installation of technical diagnostics
5. Results discussion
6. Conclusion
References
Chapter-11---Reliability-assessment-of-rep_2021_The-Handbook-of-Reliability-
11 . Reliability assessment of replaceable shuffle-exchange network by using interval-valued universal generating function
1. Introduction
2. Assumptions
3. Acronyms
4. Notations
5. Definitions
6. Terminal reliability of SEN
7. Broadcast reliability of SEN
8. Network reliability of SEN
9. Numerical illustration
9.1 Terminal reliability of the replaceable SEN under consideration by using the IUGF approach
9.2 MTTF of the replaceable SEN
9.3 Broadcast reliability of the considered SEN by using the method of IUGF
9.4 MTTF of the considered replaceable SEN
9.5 Network reliability of the 8 × 8 replaceable SEN under consideration using IUGF approach
9.6 MTTF of the SEN under consideration
10. Result and discussion
11. Conclusion
References
Chapter-12---Reliability--MTTF--and-sens_2021_The-Handbook-of-Reliability--M
12 . Reliability, MTTF, and sensitivity evaluation of a computer network system connected in star topology
1. Introduction
2. Assumptions and notations of the proposed model
3. Formulation of the model
4. Particular examples
4.1 Reliability
4.2 Mean time to failure
4.3 Sensitivities
4.3.1 Reliability sensitivity
4.3.2 MTTF sensitivity
5. Conclusion
References
Chapter-13---Analysis-of-a-system-incorpo_2021_The-Handbook-of-Reliability--
13 . Analysis of a system incorporating k-out-of-n structure with a warm standby redundancy: a reliability approach
1. Introduction
1.1 Model description
2. Nomenclature
3. State description
4. Assumption of the system
5. State transition diagram
6. Mathematical formulation and solution of the problem
7. Reliability indices
7.1 Reliability of the system
7.2 Mean time to failure
7.3 Sensitivity analysis
7.3.1 Sensitivity of MTTF
7.3.2 Sensitivity of reliability
8. Result discussion
9. Conclusion
References
Inde_2021_The-Handbook-of-Reliability--Maintenance--and-System-Safety-throug
Index
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J
K
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