Designing and metal fabrication represent the structural foundation of mechanical and industrial engineering, combining creativity, precision, and applied science to transform concepts into functional products. The integration of design principles with fabrication techniques ensures the creation of efficient, safe, and high quality structures and components. This training program presents technical frameworks, engineering models, and manufacturing systems essential for modern fabrication processes. It presents design parameters joining technologies, and quality control systems used in the metal fabrication industry.
Analyze design frameworks and fabrication processes in metalworking industries.
Classify different metal types and their structural properties for fabrication use.
Evaluate fabrication techniques and mechanical joining methods.
Interpret engineering drawings and apply design standards conceptually.
Assess quality systems, safety parameters, and efficiency in metal fabrication projects.
Mechanical and industrial engineers.
Metal fabrication supervisors and design technicians.
Production and manufacturing engineers.
Quality assurance and control specialists.
Project managers in fabrication and engineering workshops.
Overview of fabrication systems and industrial design principles.
Structural requirements in metal design and component integration.
Engineering drawing interpretation and dimensional accuracy.
Factors influencing material selection and design geometry.
Coordination principles between design units and fabrication operations.
Classification of ferrous and non-ferrous metals.
Mechanical, thermal, and chemical properties affecting fabrication.
Standards for metal identification and specification.
Impact of alloy composition on strength and durability.
Structural integrity considerations for different fabrication uses.
Overview of forming, cutting, and shaping processes.
Conceptual models of casting, forging, and extrusion.
Frameworks for assembling and modular fabrication.
Process flow and operational sequencing in workshops.
How to integrate CAD/CAM systems in modern fabrication.
Classification of welding techniques, including arc, MIG, TIG, and resistance.
Heat effects and metallurgical changes.
Conceptual models for mechanical fastening and adhesive bonding.
Quality factors in welded and joined structures.
Standards and codes governing welding design and inspection.
Principles of sheet metal layout and bending mechanics.
Theoretical models for shearing, punching, and rolling operations.
Design rules for minimizing deformation and defects.
Coordination principles between sheet design and fabrication tooling.
Dimensional control and structural verification methods.
Conceptual models of turning, milling, drilling, and grinding.
Factors affecting tool performance and cutting efficiency.
Tolerances and surface finish requirements in machining.
Automation frameworks in CNC-based fabrication.
Maintenance and calibration structures for machining tools.
Coating and protection systems for fabricated metal products.
Background of electroplating, anodizing, and painting.
Surface preparation techniques and quality indicators.
Corrosion control and durability planning methods.
Environmental considerations in surface treatment.
Non-destructive testing (NDT) frameworks and applications.
Dimensional and mechanical inspection standards.
Role of quality documentation and traceability.
Statistical process control in fabrication environments.
Frameworks for integrating ISO standards in metal fabrication quality systems.
Structural planning process of fabrication workflows.
Scheduling and resource allocation frameworks.
Coordination principles between design, engineering, and production units.
Risk assessment and control models in fabrication projects.
Documentation systems for fabrication tracking and reporting.
Occupational safety frameworks for fabrication environments.
Sustainable fabrication approaches and waste reduction methods.
Automation and digital transformation in metal fabrication.
Innovation systems in design and advanced manufacturing.
Institutional structures for continuous improvement and knowledge management.
