Curriculum
- 7 Sections
- 40 Lessons
- 1 Day
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- Introduction to Design for Manufacturability (DFM)6
- 0.0Definition and importance of DFM
- 0.1Objectives and benefits of implementing DFM
- 0.2Core principles of DFM: simplifying design, standardizing parts, optimizing processes, and reducing costs
- 0.3Interactive simulation to understand the impact of DFM on manufacturing efficiency and product quality
- 0.4Case studies from leading manufacturing companies implementing DFM
- 0.5Discussion on common challenges and misconceptions about DFM
- Principles of DFM5
- 1.0Key principles of DFM: design simplification, design for assembly, design for cost, design for reliability, and design for quality
- 1.1Techniques for integrating DFM principles into the product development process
- 1.2Exercise to apply DFM principles to a hypothetical product design
- 1.3Examples of successful DFM implementations
- 1.4Group discussion on the application of DFM principles in their own product designs
- DFM Guidelines and Best Practices5
- 2.0General guidelines for DFM: material selection, manufacturing processes, tolerance design, and assembly considerations
- 2.1Best practices for implementing DFM in various manufacturing contexts
- 2.2Hands-on exercise on evaluating and improving a product design using DFM guidelines
- 2.3Case studies showcasing best practices in DFM
- 2.4Discussion on the challenges of adhering to DFM guidelines and how to overcome them
- Cost Reduction and Process Optimization6
- 3.0Role of DFM in reducing manufacturing costs
- 3.1Techniques for optimizing manufacturing processes through DFM
- 3.2Cost-benefit analysis of DFM initiatives
- 3.3Exercise on conducting a cost-benefit analysis for a DFM project
- 3.4Examples of cost savings and process improvements through DFM
- 3.5Group discussion on identifying cost reduction opportunities in their own projects
- Design for Assembly (DFA)6
- 4.0Importance of DFA in DFM
- 4.1Techniques for designing products for easy and efficient assembly
- 4.2Balancing design complexity and assembly efficiency
- 4.3Hands-on exercise on creating a DFA-friendly product design
- 4.4Examples of DFA implementations and their impact on manufacturing efficiency
- 4.5Discussion on the challenges of DFA and strategies to address them
- Cross-Functional Collaboration in DFM6
- 5.0Importance of cross-functional collaboration in DFM
- 5.1Techniques for fostering collaboration between design, engineering, and manufacturing teams
- 5.2Role of cross-functional teams in ensuring successful DFM implementation
- 5.3Role-playing scenarios to practice cross-functional collaboration
- 5.4Case studies on successful cross-functional collaboration in DFM projects
- 5.5Discussion on strategies to enhance collaboration
- Tools and Technologies for DFM6
- 6.0Overview of tools and technologies used in DFM, including CAD/CAM software, simulation tools, and design validation platforms
- 6.1Role of digital tools in enhancing DFM practices
- 6.2Emerging technologies and trends in DFM
- 6.3Exercise on using a DFM tool to evaluate and improve a product design
- 6.4Examples of DFM tools and technologies in action
- 6.5Group discussion on integrating new tools and technologies into their DFM processes