Holloway’s Notes for Machinery Lubrication Engineer Exam Preparation

Description

ContentsI.

• Definition of Asset Management in the context of the
• ISO 55001 Requirements (refer also to EN 16646 for physical assets)
• Physical Asset Hierarchy and ISO 14224:2016
• ICML 55 Attributes and Requirements in the context of machinery lubrication

II.

• Reliability philosophies and strategies
• Condition-based maintenance
• Reliability Culture
• Financial Analysis and Economic Justification
• Failure Modes Effects Analysis (FMEA), Failure Reporting, Analysis and Corrective Action System (FRACAS), and Root Cause Analysis (RCA)
• Asset design change process and management of change
• Criticality analysis and risk management
• Metrics, KPIs, Scorecard, Overall Equipment Effectiveness (OEE)
• Asset life cycle engineering and management
• Design for reliability, operability and maintainability
• Managing Sources of vibration and wear, including fasteners, alignment and balance

III.

• Procedure-based maintenance and standardized work
• Procedure-based maintenance ensures consistent execution of maintenance tasks.
• Standardized work takes a broader approach to optimize the
• PM Optimization
• Work Management, Planning and Scheduling
• Shutdown, Turnaround and Outage Management
• Operator-driven Maintenance, Autonomous Maintenance, Total  Productive Maintenance
• Enterprise Asset Management (EAM) and Computerized Maintenance Management System
• Stores, Parts and Inventory Management
• Workforce management, skills and training

IV.

• Condition-based maintenance versus breakdown maintenance
• Predictive Maintenance
• Proactive Maintenance
• Inspection 2.0
• CBM technologies (lubricant analysis, vibration, thermography, acoustics, motor current, etc.)
• CBM for major machine categories: pumps, compressors, turbines, gearboxes
• CBM Integration and Program Management
• CBM Data Management

V.

• Mechanical Friction, Fluid Friction, Dry Friction
• Lubrication Fundamentals
• Lubrication Regimes
• Film Thickness, Specific Film Thickness, Mixed Film
• Film Strength, Additive and Chemical-induced Films
• Mechanical Wear, Abrasion, Adhesion, Surface Fatigue

VI.

• Liquid and grease lubricants, formulation science, base oils, common thickeners, common additives
• Solid-film Lubrication and Types
• Physical and Chemical Properties of Lubricating Oils and Grease
• Common Lubricant Laboratory Test Methods
• Differences and Unique Physical and Chemical Properties

VII.

• Skills Required for Lubrication Technicians
• Skills Required and Performed by Operators and Inspectors
• Skills Required and Performed by Mechanics and Millwrights
• Skills Required and Performed by Reliability Engineers and Maintenance Supervision
• Skills Required and Performed by by Plant Management
• Standardized Training, Tasked-based Training and Competency

VIII.

• Lube Room Design for Reliability, Safely and Environmental Requirements
• Design and Use of Storage Facilities of Bulk Tanks, Tank Farms, Totes for Reliability, Safety, Environment, and Regulatory Requirements
• Standardized Lubricant Labeling for Packaged and Bulk Vessels
• Spill Containment and Leak Protection Practices for Environmental Protection and Basic Regulatory Compliance
• Transfer, Handling, Dispensing, Filtration from Drums, Totes and Day Tanks
• Transfer, Handling, Dispensing, Filtration from Bottles, Jugs, and Small Grease Packages
• Selection and Use of Workplace and Lube Room Tools and Accessories and Basic Care and Storage
• Safety Practices Related to the Storage and Handling of Lubricants

IX.

• Basic elements of Reliability-centered Maintenance (RCM)
• Failure Patterns and Weibull Distributions Basic Elements
• Ranking of Lubrication-specific Failure Modes and Causes and the Use of Failure Modes Effects Analysis (FMEA)

X.

• Optimum Selection, Set-up and Use of Lubricant Application Devices and Hardware
• Optimum Selection, Installation and use of Contamination Control Devices/Hardware
• Instrumentation requirements including selection and location of online oil analysis sensors
• Optimum Selection, Location, and Use of Sight Glasses and Level Gauges for Lubricated Equipment
• Optimum Selection and Use of Relubrication and Oil Change Hardware & Tools
• Optimum Selection and Location of Sampling Valves and Hardware
• Purpose and Use of Drip Pans, Grease Traps, Berms, Purge Ports
• Optimum Selection and use of Tags, Labels and Plates

XI.

• Vendor Selection Based on Product Range, Product Quality, Product Performance, Support & Services
• Elements in Generic Lubricant Specifications
• Common Machine or Application
• Lubricant Specification Elements (base oil, additives, thickeners, performance properties, physical properties, chemical properties, and health and safety properties)
• Food Grade Lubricant Selection, Application, and Regulations
• Rationalized Lubricant Consolidation to Optimize the Number of Lubricant Grades and Brands
• Lubricant Cross-Contamination Risks, Compatibility Testing,
• Proper Labeling Methods Using Standardized Classifications and Visual Identification System
• Standardized Classifications

XII.

• Routine Scheduled Work and PMs
• Unplanned and Condition-based Work Request Processing
• Lubrication-Related Work Prioritization and Planning
• Lubrication-Related Work Kitting, Skill Matching, and Crew
• Work Scheduling
• Lubrication-Related Unplanned and Planned Work Backlog
• Lubrication-Related Troubleshooting Faults and Anomalies
• Lubrication-Related Record Keeping, Documentation, and CMMS

XIII.

• Periodic Lubrication Tasks for Controlling Correct Lubricant Supply
• Periodic Lubrication Tasks: Frequency, Volume, and Criteria
• Proper Oil Top-up Procedures
• Proper Grease Relubrication Procedures for Common Machine
• Lubricant Drain and Purge Criteria and Methods for Major
• Contamination Control Tasks in Periodic Lubrication
• Machine Flushing Requirements, Risks, and Benefits
• Methods for Oil Reclamation in Lubricated Equipment
• Lubricant Waste Handling, Disposal and Cleanup
• Leak Detection, Management and Leak Cleanup
• Safety in Lubrication Maintenance Tasks

XIV.

• Inspection of Lubricated Machines for Optimum Reliability, Safety, Environmental Protection, and Condition Monitoring
• Inspection of Lubricated Machines: Optimizing Intervals, Routes, and Autonomous Practices
• Selecting and Installing Machine Inspection Windows for
• Selecting, Using, and Caring for Inspection Tools and Aids for
• Inspection Protocol for Common Machine Types: Optimized
• Inspection Protocol for Spare Parts, Stored New Machines, and Standby Machines: Ensuring Reliability and Readiness
• Inspection Personnel Skill Sets and Training for Optimum
• Examples of Inspection Checklist, Findings Report, and Documentation for Lubricated Machines
• Examples of Integration of Inspection with Other Condition Monitoring Practices

XV.

• Selecting Optimum Tools and Procedures for Lubricant Analysis
• Selection of an Off-site Oil Analysis Laboratory
• Selection of Onsite Oil Analysis Testing
• General In-service Lubricant Sampling and Analysis Program Design
• New Lubricant Receiving Requirements
• Stored Lubricant Sampling and Analysis – Packaged and Bulk
• Selection of Routine Lubricant Test Slate and Standardized Methods
• Selection of Exception Tests, Conditions for Use, and
• Selecting Data Alarms and Limits for In-Service Lubricants
• General Strategy for Data Interpretation of In-Service Oil Analysis
• Data Management and Overall Program Management for In- Service Oil Analysis
• Reporting and Responding to Non-Conforming Data in In-Service Oil Analysis
• Integration of In-Service Oil Analysis with Other Inspection and Condition Monitoring Methods
• Accuracy and Quality Verification in an In-Service Oil Analysis Program

XVI.

• Basic Troubleshooting Procedures for Lubricated Systems
• Applying FRACAS for Lubricated System Fault Management
• General RCA Policies and Guidelines for Lubricated Systems
• RCA Phases for Lubricated Systems: Data Collection, Assessment, Corrective Action, Inform & Follow-up
• Data Collection and Evidence Preservation for Lubricated Systems
• Root Cause Assessment Methods for Lubricated Systems
• Guidelines for Responding to Root Cause Conditions for Lubricated Systems
• Guidelines for Responding to Incipient Failure/Faults for Lubricated Systems
• Responding to Impending/Precipitous Failure for Lubricated Systems
• Responding to Sudden-Death or Catastrophic Failure in Lubricated Systems
• Guidelines for Fault/Failure Findings from Rebuild Shops for Lubricated Systems

XVII.

• Incoming Lubricants, Parts, and Machine Product Acceptance
• Certificate-of-analysis of Lubricant Supplies
• Internal/external Cleanliness and Packaging
• Lubricant supply agreement terms and conditions related to quality and services provided
• Aligning with Suppliers through Effective Lubricant Safety and
• Services of Off-site Service Providers and Rebuild Shops (quality, part cleanliness, roll-off cleanliness, documentation, findings reports, etc.)

XVIII.

• Disposal of Lubricants, Filters, Rags, Containers
• Cleaning of Containers, Parts, Hoses, Components and Devices
• Labeling and Documentation of Hazardous Waste and Non- Hazardous Materials for Used Lubricants and Cleaning Solvents:
• Disposal of Hazardous and Non-hazardous Materials
• Alignment to ISO 14000

XIX.

• Influence of Lubricants and Lubrication on Energy Conservation
• Influence of Lubricants on Atmospheric Contamination
• Environmental-friendly Lubricants (e.g., biodegradability)
• Lubricant Aqueous Toxicity, Risk and Assessment
• Organizational Goals and Policies
• Optimized and Practical Use of Lubricants and Lubrication Conservation and Environment Protection

XX.

• Disposal & waste management
• Safety Training, Policies and Guidelines
• Hazardous Lubricants and Toxicity
• Microbial Safety Risks and Control of Transmission (to other machines)
• Fluid Pressure and Fluid Injection Risks (blood stream injection)
• Lubricant Mists in the Work Environment
• Confined Space Risks
• Fire and Combustion Risks
• Electrocution Risks
• Mechanical Risks

XXI.

• Selection of Dehydration Methods and Practices
• Additive Reconstruction of Aged or Damaged Lubricants
• De-varnishing of Fluids and Machine Surfaces
• Industrial Oil Acid Scavenging Methods

XXII.

• Industrial Lubrication: Standby, Storage, and Commissioning for Special Requirements
• Special Lubrication-related Practices to Protect Machines and Parts In Storage or Standby
• XXIII.
• Micro Metrics of Machines and Lubricant Conditions
• Macro and Big-picture Metrics for Overall Fleet or Plant Machine Health
• Mapping and Aligning Metrics to Return on Net Assets (RONA)
• Overall Equipment Effectiveness (OEE) (related to asset
• Leading Metrics that Predict Future Conditions or Events
• Lagging Metrics that Report or Summarize Past Conditions or Events (what just happened)
• Lubricant Consumption Ratios/Metrics
• MTBF and General Machine Reliability Metrics
• Lubrication Route Compliance Measurement
• Percent Planned Maintenance, Workforce Efficiency, Wrench Time
• Metric Communication
• Performance Control and Remediation

XXIV.

• Culture of Continuous Improvement
• Improved Data Analytics for Lubrication Practices (Industry 4.0 Approach)
• Improved CBM Sensor Application and Scope
• Improved Cost Reductions in Lubrication Practices (Leveraging Resources)
• Improved Production Output
• Improved Energy Consumption through Optimized Lubrication Practices
• Improved Environmental Protection
• Improved Safety Through Optimized Lubrication Practices
• Improved Product Quality and Timely Delivery through
• Improved Profitability Through Optimized Lubrication Practices

XVI. Reliability Engineering

• MTBF (Mean Time Between Failures)
• MTTF (Mean Time to Failure)
• MTTR (Mean Time To Repair)
• Availability
• System Configurations: Series vs. Parallel
• Bathtub Curve
• Infant Mortality Phase
• Useful Life Phase
• Wear-Out Phase
• Failure Modes and Effects Analysis (FMEA)
• Identifying Failure Modes
• Applying Design and Process FMEA
• Root Cause Analysis (RCA)
• The 5 Whys and the Fishbone Diagram
• Fault Tree Analysis (FTA)
• Tracing Latent and Systemic Causes
• Statistical Reliability Methods
• Weibull Analysis
• Accelerated Life Testing (ALT)
• Design HALT and HASS Test Protocols
• Life Prediction Models
• Load-Stress Failure Relationships
• Design for Reliability (DfR)
• Integrate Reliability into the Design Process
• Reliability Allocation Across Subsystems
• Apply Derating, Redundancy, and FMEA at Design Time
• Reliability Block Diagrams (RBD)
• Construct RBDs for Complex Systems
• Analyze Series-Parallel Structures
• Simulation for Mission-Critical Systems
• Maintainability and Availability
• Availability Metrics
• Reliability-Centered Maintenance (RCM)
• Classify Failure Modes and Consequences
• Select Proactive Maintenance Tasks
• Decision Logic for Maintenance Planning
• Condition-Based Monitoring & Predictive Maintenance
• Understand Monitoring Technologies
• Estimate Remaining Useful Life (RUL)
• Risk Assessment and Safety Standards
• Apply ISO 31000 – Risk Management Framework
• Apply IEC 61508 – Functional Safety of E/E/PE Systems
• Apply MIL-STD-882 – System Safety
• Perform HAZOP – Hazard and Operability Study
• Perform FMECA – Failure Modes, Effects & Criticality Analysis
• Perform LOPA – Layer of Protection Analysis
• Assess and Verify Safety Integrity Level (SIL)
• Reliability Growth Modeling
• Model Reliability Growth
• Analyze Model Results
• Plan Test-Fix-Test Campaigns
• Regression or Maximum Likelihood Estimation to Estimate Model Parameters
• Regression Analysis
• Maximum Likelihood Estimation (MLE)
• Test-Fix-Test Campaigns and Reliability Growth Modeling: A Structured Path to Proven Reliability
• Execute Testing and Capture Failures
• Apply Fixes and Validate Improvements
• Model Reliability Growth and Estimate Parameters
• Manage and Document the Growth Campaign
• Reliability Demonstration Through Test Planning
• Reliability Demonstration Through Test Planning: A Comprehensive Approach to Product Validation
• Defining Test Objectives and Targets
• Selecting Strategy and Sample Size
• Execute and Analyze
• Data Collection and Failure Reporting
• Data Collection and Failure Reporting: Turning Operational Data into Reliability Insight
• Design Data Collection Systems
• Enable Accurate Failure Reporting
• Use Data for Reliability Improvement
• Implementing FRACAS Workflows
• Designing the FRACAS Workflow
• Capture and Classify Failures
• Drive Actions and Monitor Results
• Analyzing Warranty and Service Data Trends
• Unlocking Hidden Reliability Insights
• Collect and Structure Warranty Data
• Analyze Patterns and Key Performance Indicators (KPIs)
• Apply Insights to Reliability Programs
• Human Factors and Organizational Reliability
• Enhancing System Performance through Human-Centered Design
• Identify Human Error Risks
• Apply Human Reliability Techniques
• Mitigate Human Error

Promoting a Culture of ReliabilitySOPs and Training ProgramsGlossaryAppendix

• Reliability Engineering Standards Reference List
• Reliability Engineering Checklists
• FMEA Checklist (Design or Process FMEA)
• Root Cause Analysis (RCA) Checklist
• Test-Fix-Test Campaign Checklist
• FRACAS Reporting Requirements Checklist
• Reliability Engineering Templates & Worksheets
• Failure Report Form (FRACAS Aligned)
• Root Cause Analysis (RCA) Worksheet
• FMEA Table Template
• Maintenance Strategy Planner (RCM-Based)
• Data Collection Log for Testing
• Reliability Growth Tracking Table
• Lubricants Review
  • Storage, Handling and Application of Lubricants
  • Lubrication Storage Methods
  • Lubrication Handling Methods:
  • Lubrication Application Methods
  • Transportation Lubricants
  • Engine Oils
  • Physical Properties
  • Classifications
  • New Engine Oil Tests
  • Used Oil Analysis for Engine Oils
• Classifications
  • API
  • SAE
• New Oil Tests
• Transportation Lubricant – Used Oil Analysis
• Greases
• Types of Friction in a Lubricated System
• Types of Wear in a Lubricated System
• Factors Influencing Wear in a Lubricated System
• Process for Selecting the Best Lubricant for an Application
• Types of Base Oils and Additives Used in Lubricants
• Different types of bearings, their characteristics, and their applications:
• Common Greased Bearing Failure Modes, Causes, and Remedies
• Different types of lubricating greases, their characteristics, and their applications:
• Lubricating Grease Testing Methods and Their Purpose
• Storage, Safety, and Environmental Concerns for Proper Use of Lubricating Grease
• Types of Gears and Their Applications
• Types of Gear Failures, Causes, and Remedies
• Types of Gear Oils and Their Applications
• Methods of Gearbox Lubrication and Their Applications
• Gear Oil Testing Methods and Their Purpose
• Storage, Health & Safety, and Environmental Concerns for Gear Oil
• Types of Hydraulic Systems and Pumps and Their Applications
• Common Hydraulic System Failures, Causes, and Remedies
• Types of Hydraulic Fluids and Their Applications
• Storage, Health & Safety, and Environmental Concerns for Hydraulic Fluids
• Types of Combustion Engines and Their Applications
• Engine Oil Testing Methods and Their Purpose
• Application Methods for Metalworking Fluids (MWFs)
• Storage, Health & Safety, and Environmental Considerations for Metalworking Fluids (MWFs)
• Types of Air Compressors and Their Applications
• Common Air Compressor Failures, Causes, and Remedies
• Types of Air Compressor Oils and Their Applications
• Tests for Air Compressor Oil and Their Purpose
• Types of Chains That Require Lubrication and Their Applications
• Types of Chain Lubricants and Their Applications
• Types of Wire Ropes and Cables That Require Lubrication and Their Applications
• Types of Seals, Gaskets, and O-Rings in Lubricated Systems and Their Applications
• Compatibility of Seals, Gaskets, and O-Rings with Lubricants
• Tests for Seals, Gaskets, and O-Rings
• Types of Cleaners and Solvents Used in Industry and Their Applications
• Application Methods, Storage Considerations, and HSE (Health, Safety, and Environmental) Considerations for Industrial Solvents and Cleaners