Certified Design Engineer Course (Machine Design) for Mechanical Engineers

Brief Description:

The Certified Design Engineer Course (Machine Design) offered by Pertecnica Engineering is a specialized program meticulously crafted to equip mechanical engineers with advanced knowledge and practical skills in machine design. This comprehensive course covers the principles of machine design, advanced engineering techniques, CAD software proficiency, and industry-standard practices. Upon completion, participants will be proficient in designing efficient and reliable machinery for various applications.

Why Choose Pertecnica Engineering?

Pertecnica Engineering is renowned for its industry-aligned training programs. Here’s why our Certified Design Engineer Course is the ideal choice for mechanical engineers:

• Expert Faculty: Learn from experienced design engineers and industry experts with a wealth of practical knowledge.
• Hands-on Learning: Gain practical experience through design projects, simulations, and real-world case studies.
• Comprehensive Curriculum: Covering all aspects of machine design, including theory, analysis, and practical application.
• Industry Connections: Benefit from networking opportunities and insights from professionals in the field.
• Certification: Earn a recognized certification upon successful completion, enhancing your credentials in the industry.

Course Syllabus:

The course syllabus is designed to provide a thorough understanding of machine design principles, advanced engineering techniques, and CAD software proficiency. Key topics include:

1. Introduction to Machine Design
   • Basics of Machine Design: Principles, Terminology, and Design Process
   • Materials Selection: Properties, Strength, and Material Selection Criteria
2. Engineering Mechanics and Analysis
   • Statics and Dynamics: Forces, Moments, and Equilibrium
   • Stress and Strain Analysis: Mechanical Properties, Failure Criteria, and Safety Factors
3. Mechanical Components and Mechanisms
   • Design of Shafts, Bearings, Gears, and Power Transmission Elements
   • Kinematics and Dynamics of Mechanical Systems: Linkages, Cams, and Gear Trains
4. Machine Elements and Design Considerations
   • Design of Machine Elements: Fasteners, Springs, Couplings, and Brakes
   • Lubrication, Seals, and Bearings: Selection Criteria and Application Guidelines
5. Advanced Topics in Machine Design
   • Finite Element Analysis (FEA): Principles, Applications, and Interpretation of Results
   • Design Optimization Techniques: Parametric Studies, Topology Optimization, and Sensitivity Analysis
6. Computer-Aided Design (CAD) Software
   • Introduction to CAD Software: SolidWorks, AutoCAD, CATIA, etc.
   • 2D and 3D Modeling: Creating Parts, Assemblies, and Drawings Using CAD Software
7. Design Projects and Case Studies
   • Design Projects: Application of Design Principles to Real-world Problems
   • Case Studies: Analysis and Evaluation of Existing Designs, Identifying Improvement Opportunities
8. Industry Standards and Best Practices
   • ASME, ISO, and ANSI Standards: Compliance Requirements and Design Guidelines
   • Design for Manufacturing (DFM) and Design for Assembly (DFA) Principles

Course Modules in Detail:

Module 1: Introduction to Machine Design

• Basics of Machine Design: Principles, Terminology, and Design Process
• Materials Selection: Properties, Strength, and Material Selection Criteria

Module 2: Engineering Mechanics and Analysis

• Statics and Dynamics: Forces, Moments, and Equilibrium
• Stress and Strain Analysis: Mechanical Properties, Failure Criteria, and Safety Factors

Module 3: Mechanical Components and Mechanisms

• Design of Shafts, Bearings, Gears, and Power Transmission Elements
• Kinematics and Dynamics of Mechanical Systems: Linkages, Cams, and Gear Trains

Module 4: Machine Elements and Design Considerations

• Design of Machine Elements: Fasteners, Springs, Couplings, and Brakes
• Lubrication, Seals, and Bearings: Selection Criteria and Application Guidelines

Module 5: Advanced Topics in Machine Design

• Finite Element Analysis (FEA): Principles, Applications, and Interpretation of Results
• Design Optimization Techniques: Parametric Studies, Topology Optimization, and Sensitivity Analysis

Module 6: Computer-Aided Design (CAD) Software

• Introduction to CAD Software: SolidWorks, AutoCAD, CATIA, etc.
• 2D and 3D Modeling: Creating Parts, Assemblies, and Drawings Using CAD Software

Module 7: Design Projects and Case Studies

• Design Projects: Application of Design Principles to Real-world Problems
• Case Studies: Analysis and Evaluation of Existing Designs, Identifying Improvement Opportunities

Module 8: Industry Standards and Best Practices

• ASME, ISO, and ANSI Standards: Compliance Requirements and Design Guidelines
• Design for Manufacturing (DFM) and Design for Assembly (DFA) Principles

Job Opportunities Post Completion:

Graduates of this course can pursue various roles in machine design and engineering, including:

• Design Engineer
• Product Development Engineer
• Mechanical Design Specialist
• Research and Development Engineer
• Consulting Engineer

Training Methodology:

Pertecnica Engineering employs a blend of theoretical instruction, practical exercises, and hands-on projects to ensure effective learning. Our training methodology includes:

• Interactive Lectures: Engage in dynamic sessions led by experienced instructors.
• Hands-on Workshops: Gain practical skills through design projects, simulations, and prototyping activities.
• Real-world Applications: Apply theoretical knowledge to real-world engineering challenges and projects.
• Case Studies: Analyze industry case studies to understand best practices and real-world design problems.
• Group Discussions: Exchange ideas and insights with peers to enhance learning and collaboration.

Join Pertecnica Engineering’s Certified Design Engineer Course (Machine Design) to elevate your skills and advance your career in mechanical engineering.