Total Productive Maintenance : PROVEN STRATEGIES & TECHNIQUES

Title: Total Productive Maintenance : PROVEN STRATEGIES & TECHNIQUES
Author: Steve Borris
ISBN: 0071467335 / 9780071467339
Format: Hard Cover
Pages: 448
Publisher: McGraw-Hill
Year: 2006
Availability: 45-60 days

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This results-oriented guide is the culmination of thirty years’ real-world, factory floor experience. Short on theory and long on practice, this resource provides maintenance engineers and supervisors with a solid framework for operational strategies along with day-to-day management and training techniques that enable them to identify and address problems before they occur.

Arranged in a logical, user-friendly format, Total Productive Maintenance shows readers how to define and evaluate their existing programs and integrate them with reliability centered maintenance and time and condition based maintenance. The author also provides a wealth of practical case-studies, and action plans for solving everyday maintenance problems.

Learn how to:

Identify and address major equipment-related problems
Incorporate proven techniques and methods for implementation
Accomplish actual TPM implementation with measurable results
Integrate TPM with other maintenance management programs

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List of Figures, Formulas, and Tables
Preface
Acknowledgements
Introduction

Chapter 1: TPM - Basic, Use and Ideal Conditions
Fault Development
The Basic Condition
Technical Standards
Overall Equipment Efficiency
The availability of the equipment
The performance of the equipment
The quality of the product
Natural and Forced Deterioration
Use Conditions
The Ideal Condition
Improvement Methodology
How Do We Restore the Basic Condition?

Chapter 2: TPM Jishu-Hozen-Autonomous Maintenance
The TPM Initial Clean and Insect and F-Tagging
The Cleaning Map: What and Where to Clean
F-Tags: How to Record Fuguai
Discovery of a Serious Fault during the Cleaning
Tracking the Progress of the Initial Cleans

Chapter 3: TPM-Analyzing and Categorizing the Failure Data
F-Tags, The Machine History Log, and Minor Stops or Unrecorded Losses Categorizing
Finding Out the TPM Causes for the F-Tags to Help Find the Cure
Pareto Charts
The Defect Map

Chapter 4: TPM-Creating Standards and Preparation for Autonomous Maintenance
Task Transfer: Red to White F-Tags or PM to AM Tasks
Explanation of the Embedding and Responsibility Spreadsheet
PM Teams (Kobetsu Kaizen)

Chapter 5: TPM-The Education & Training and Safety Pillars
The TPM Education & Training Pillar
Equipment training
A sequence for training equipment
Competency: How does TPM assess the skill level of the team members?
The TPM Safety Pillar
The area map
The hazard map
Risk assessment
Safe working procedures: Using as standards

Chapter 6: 5S: Organization and Improvements by Default
5S: SSSSS-The Meaning
The Benefits of 5S
The Decision to lmplement 5S
Initial Management Implementation
Audit sheets
The red tag holding area
Step 1: Seiri-Sort
Red tag details
Step 2: Seiton-Set in Order
Step 3: Seiso-Shine
The 5S cleaning map or assignment map
Step 4: Seiketsu-Standardization
Step 5: Shitsuke-Self-Discipline

Chapter 7: SMED-Single Minute Exchange of Die
Where Did SMED Originate?
Step 1: Creating the SMED Team
The team members and their responsibilities
Step 2: Select the Tool
Step 3: Document every Step of the Changeover
Step 4: Viewing the Changeover as a Bar Graph
Step 5: Define the Target Time for the Changeover
Step 6: Analysis of the Elements
The SMED Analysis
Implementing ideas
Create the new procedure
Step 7: Repeating the Exercise
Applying SMED to Maintenance and the Use of Turnaround Parts

Chapter 8: Deciding on a Maintenance Strategy
The TPM PM Analysis
The malfunction and PM maps
Interpreting PM maps
Scheduled maintenance or scheduled restoration
Scheduled replacement or scheduled discard
The RCM PM Analysis
The RCM decision diagram
Failure is unacceptable: Redesign the system
Recording the process on the decision worksheet
Failure finding and calculating acceptable risk

Chapter 9: RCM-Reliability Centered Maintenance
The First Stage in an RCM analysis: The Operating context
Example of a Furnace Boatloader Operating Context: Tool Analysis Level
Equipment Defined as Functions
Identifying Functions and Labeling
Functional Failures to Failure Effects
Failure modes
Failure effects
Where Did RCM Come From?
Non-Time-Based Failures
Infant mortality

Chapter 10: Time and Condition Based Maintenance
Introduction to on-Condition Maintenance
Friction between Maintenance and Production
What if we were starting from scratch?
In Summary

Chapter 11: Fault Analysis: A Few Ways to Help Find Root Causes
The 5 Why’s
Fishbone Diagrams
Fault Tree Diagrams
OCAPs: Out-of Control Action Plans

Chapter 12: Team Objectives and Activity Boards
Activity Boards
Team Goals
Monitoring Progress
What do we monitor?
How do we calculate the failure rate and the target improvement?
Authority for Working in Specific
Machine Areas
What Do the Results of a Real RCM Analysis Look Like?
Summary of the boatloader analysis
Lean Manufacturing
Defects
Overproduction
Waiting
Transporting
Overprocessing
Unnecessary inventory
Unnecessary operator movement
Value
Equipment
Pull

Chapter 13: Six Sigma: A High-Level Appreciation
Graphs and Their Use in Six Sigma
Average and standard deviation
Standard deviation and z scores
The x-y graph
The Main Terms of Six Sigma
The customer
The teams and the leaders
The Champion or Sponsor
Six Sigma Controller
The Rules and Expectations
The Six Sigma Charter
The Technical Stuff
The sigma Value
Defects per opportunity
Defects per million Opportunities
The Stages of a Six Sigma Analysis
Considerations or Limitations Using Six Sigma
Faultfinding the cause of a lamp failure
Possible Limitations with Using Statistics

Index