Curso de Mechanical Engineering Design – The Ultimate Course

Este curso te brindará las habilidades y conocimientos necesarios para destacarte como Instalador en el ámbito profesional. Con este curso, podrás trabajar en una amplia gama de lugares, como empresas de construcción, empresas de mantenimiento industrial, fábricas de producción, entre otros. Gracias a los conocimientos adquiridos en este curso, podrás realizar instalaciones mecánicas de manera eficiente y segura, garantizando un óptimo funcionamiento de los sistemas. Además, estarás preparado para enfrentar los desafíos diarios que se presenten en cualquier entorno laboral relacionado con el diseño de ingeniería mecánica.

La duración total del curso es de 60 horas.

Índice de subtemas para cada una de las secciones de tu curso Mechanical Engineering Design – The Ultimate Course:

1. Course Introduction:
   • Introduction to Mechanical Engineering Design
   • Overview of Course Objectives
   • Importance of Mechanical Engineering in various industries
   • Basic Concepts and Principles in Mechanical Engineering Design
   • Career Opportunities for Mechanical Engineers
2. Basics of Mechanical Design Engineering:
   • Introduction to Mechanical Design Engineering
   • Materials and Properties in Mechanical Design
   • Basic Principles of Mechanical Design
   • Mechanical Design Processes and Tools
   • Analysis and Testing in Mechanical Design
3. Engineering Materials:
   • Introduction to Engineering Materials
   • Properties of Engineering Materials
   • Classification of Engineering Materials
   • Mechanical Properties of Materials
   • Selection of Engineering Materials
4. Stress Analysis:
   • Unit 1: Introduction to Stress Analysis
   • Unit 2: Types of Stresses and Strains
   • Unit 3: Stress Concentrations and Fracture Mechanics
   • Unit 4: Analysis of Beams and Shafts
   • Unit 5: Finite Element Analysis and its Applications
5. Failure Prevention – Static Loading:
   • Introduction to Failure Prevention in Static Loading
   • Types of Static Loading
   • Factors Affecting Failure in Static Loading
   • Methods of Failure Prevention in Static Loading
   • Case Studies and Practical Applications
6. Failure Prevention – Fatigue/Variable Loading:
   • Introduction to Failure Prevention
   • Fatigue Analysis Techniques
   • Variable Loading Analysis
   • Materials Selection for Prevention of Failure
   • Case Studies and Practical Applications
7. Design of Shafts:
   • Shaft Material Selection
   • Shaft Stress Analysis
   • Shaft Deflection Calculation
   • Shaft Optimization Techniques
   • Shaft Failure Analysis
8. Design of Non-Permanent Joints (Fasteners):
   • Types of Fasteners
   • Mechanical Properties of Fasteners
   • Design Considerations for Fasteners
   • Failure Analysis of Fasteners
   • Fastener Selection and Installation
9. Design of Permanent Joints (Welding):
   • Types of Welding Joints
   • Welding Processes
   • Welding Symbols
   • Welding Defects and Inspection
   • Welding Safety Measures
10. Design of Bearings:
    • Introduction to Bearings
    • Types of Bearings
    • Bearing Material Selection
    • Bearing Lubrication
    • Bearing Failure Analysis
11. Design of Gears:
    • Introduction to Gear Design
    • Gear Types and Terminology
    • Gear Materials and Manufacturing Processes
    • Gear Design Calculations
    • Gear Failure Analysis and Prevention
12. Theory of Belt Drives:
    • Theory of Belt Drives: Introduction
    • Theory of Belt Drives: Types of Belt Drives
    • Theory of Belt Drives: Belt Drive Design Considerations
    • Theory of Belt Drives: Belt Drive Maintenance
    • Theory of Belt Drives: Advantages and Disadvantages
13. Design Tool A – CAD (with SolidWorks):
    • Introduction to CAD software
    • Basic concepts of SolidWorks
    • Creating 2D sketches
    • Generating 3D models
    • Advanced features and tools
14. Design Tool B – Finite Element Analysis (with ANSYS):
    • Introduction to Finite Element Analysis
    • Preprocessing: Model Setup
    • Solving: Performing the Analysis
    • Postprocessing: Analyzing Results
    • Advanced Techniques in Finite Element Analysis
15. Final Words:
    • Final Words
    • Key Takeaways
    • Next Steps
    • Additional Resources
    • Final Assessment

• Conocimientos básicos de matemáticas y física
• Habilidad para utilizar programas de diseño como AutoCAD o SolidWorks
• Conocimientos de materiales y procesos de fabricación
• Capacidad para interpretar y crear planos técnicos

• Estudiantes de Ingeniería Mecánica
• Profesionales del diseño de ingeniería
• Personas con interés en el diseño mecánico

La realización del curso será completamente on-line y evaluado a través de un examen. Una vez superado el mismo, podrás recibir tu título, válido para toda España.

Una vez hayas completado el curso, puede realizar el test relacionado y obtener tu título.