Curriculum
- 8 Sections
- 33 Lessons
- 2 Days
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- What Defines a Precision Industry?6
- 1.1Accuracy, Tolerance, Repeatability, Customization, Speed, Zero-defect expectations
- 1.2Differentiation from general manufacturing
- 1.3Low-volume high-value vs. mass production
- 1.4Impact on aerospace, medical, and semiconductor supply chains
- 1.5Case Study: Swiss machining in defense vs. EDM in medical imaging
- 1.6Group Activity: “What level of precision is currently practiced in your plant?”
- Core Principles of Precision Engineering4
- Advanced Technologies and Machinery5
- 3.15-Axis CNC, Swiss Machines, Robotic Welding, Waterjet Cutting, Laser Lithography
- 3.23D Prototyping & EDM
- 3.3Equipment choice for accuracy, complexity, material handling
- 3.4Case Insight: Aerospace panel machining vs. micro medical implants
- 3.5Process Decision Tree: Choose appropriate precision equipment for a sample job
- Lean Tools, Smart Systems & Process Control3
- Differentiators & Strategic Edge of Precision Industries5
- 5.1Regulatory barriers (AS9100, TS16949, ISO13485)
- 5.2Collaboration with OEMs, Talent acquisition, Localization
- 5.3Economic viability of high-value, small-batch throughput
- 5.4Example: India’s rising positioning in global aerospace clusters
- 5.5Activity: Competitor Benchmarking Task: Compare ecosystem strength between traditional and precision plant
- Design for Excellence (DFX) in Precision Environments4
- KPI-Driven Manufacturing Excellence4
- Digital Integration, Future Trends & Strategic Outlook2