Design for 6 Sigma

This 8 hour course presents a phased approach for identifying and implementing an effective DFSS program. Topics covered include the following: 1) Establishing Business Case and Project Charter, 2) QFD (Quality Function Deployment), 3)Intro to FMEA (Failure Modes and Effects Analysis, 4) Optimizing Design for enhanced Process Capability.

Upon completion of this DFSS course, participants will be able to do the following:
*Create a QFD House of Quality to determine CTQs*
*Leverage KANO and Customer Perception Models*
*Perform a FMEA*
*Correlate and Verify design requirements*
*Select appropriate DOE models for optimization*

Additional Questions That Will be Addressed During the Class:
1. What are the risks in not performing a DFSS project prior to manufacturing?
2. How do I best characterize my Critical To Quality (CTQ) key indicators?
3. What sample sizes are required to assure confidence (> 95%) in my results?

This and and all other courses are available for On Site Training

WHAT THE COURSE COVERS:
  • INTRODUCTION TO DESIGN FOR SIX SIGMA
  • CTQ – Critical To Quality
  • Relationship between PPM, DPM, and Loss
  • Variation and Six Sigma
  • Process Capability Indices
  • Design for Six Sigma (DFSS)
  • IDENTIFY AND DEFINE DFSS OPP. – Phase I
  • Project Charter and Business Case
  • Project Scope and Key Milestones
  • KANO and Customer Perception Model
  • Building a QFD House for DFSS
  • DEVELOPING CONCEPTS – Phase II
  • Multi-Voting and Criteria-Based Metrics
  • Failure Modes and Effects Analysis (FMEA)
  • Determining Critical to Quality (CTQ) characteristics
  • OPTIMIZING DESIGN – Phase III
  • Quality Loss Function (QLF)
  • Parameter Design for Optimization
  • Design of Experiments (DOE) primer
  • Correlation of Design Requirements
  • DESIGN VERIFICATION – Phase IV
  • Verify Process Capability
  • Build Prototype Test, Debug, and Fix
  • Pilot Run Verification
    The following represents our more specific list of elements of the DFSS framework:
  • Understand real customer needs through voice of the customer (VOC) analysis
  • Use Quality Function Deployment (QFD) to translate customer needs into critical technical characteristics of the product and ultimately into critical to quality (CTQ) characteristics of the product and process
  • Focus on designing for the lifecycle to minimize lifecycle costs, value analysis and target costing and to enhance reliability with Design for Reliability (DfR) and Design for Testability (DfT).
  • Mistake-proof the product and process
  • Perform Failures Modes and Effects Analysis (FMEA) or Anticipatory Failure Determination (AFD) to identify potential failures and take corrective action to mitigate or prevent those failures. FMEA and AFD apply to both the design of the product and the design of the process
  • Develop capable manufacturing processes and select processes that are capable of meeting the design requirements, especially with CTQ parameters
  • Use Design of Experiments (DoE) or Taguchi Methods to optimize parameter values and reduce variation, in other words, develop a robust design
  • Verify and validate that the product design will meet customer needs with peer reviews, checklists, design reviews, simulation and analysis, qualification testing, production validation testing, focus groups and market testing.

WHO SHOULD ATTEND?
  • Individuals or Managers involved in:
  • Manufacturing & Operations
  • Design
  • Test
  • Researchers, Analysts
  • Analysis of discrete semiconductor components
  • Those who wish to acquire a better understanding of current reliability concepts and practices and how their proper application leads directly to better and more reliable products

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