Fusion 360 for Product Development Training

This is not just another CAD course.
Pertecnica Engineering’s Fusion 360 for Product Development Training is designed for professionals who want to design, prototype, test, and manufacture products within a single integrated platform.

Fusion 360 is widely used by startups, product companies, and manufacturing teams to accelerate product development cycles. This program focuses on how to take an idea from concept to production-ready design efficiently.

Program Overview

Modern product development demands speed, flexibility, and integration.

This program trains participants to:

• Create 3D product designs and assemblies
• Simulate performance and validate concepts
• Generate CAM toolpaths for manufacturing
• Prototype and iterate designs quickly
• Collaborate across design and production teams

Participants gain the ability to deliver end-to-end product development solutions using a single platform.

What Makes This Training Different

Most design courses stop at modeling.
This program covers the complete product development lifecycle.

Key differentiators:

• Concept-to-manufacturing workflow
• Integration of CAD + CAM + simulation
• Focus on rapid prototyping and iteration
• Real product-based project learning
• Emphasis on design thinking and innovation

Core Learning Outcomes

By the end of the program, participants will be able to:

• Create parametric 3D product models
• Develop assemblies and functional designs
• Perform basic simulations and design validation
• Generate toolpaths for manufacturing
• Prepare designs for prototyping and production
• Improve product design efficiency and innovation

Program Curriculum

Module 1: Fusion 360 Fundamentals

• Interface and workspace overview
• Sketching and parametric modeling
• Design workflow basics

Module 2: 3D Modeling & Product Design

• Solid modeling techniques
• Feature creation and modification
• Design intent and parametric control

Module 3: Assembly Design

• Component-based design
• Joints and motion
• Functional assembly validation

Module 4: Simulation & Validation

• Basic stress and motion analysis
• Load conditions and performance checks
• Design improvement based on simulation

Module 5: CAM & Manufacturing

• Toolpath generation
• CNC machining basics
• Manufacturing strategies

Module 6: Prototyping & Iteration

• Design for prototyping (3D printing, machining)
• Rapid iteration techniques
• Version control and collaboration

Module 7: Product Development Project

• End-to-end product design project
• Design validation and optimization
• Final presentation and review

Training Methodology

• Instructor-led sessions by product design experts
• Hands-on modeling, simulation, and CAM exercises
• Real-world product development case studies
• Project-based learning with design reviews

Who This Program is For

• Product Design Engineers
• Mechanical Engineers and Designers
• Startup Founders and Innovators
• Manufacturing Engineers
• CAD/CAM Professionals
• Students and Fresh Graduates

Prerequisites

• Basic understanding of engineering or design concepts
• No prior Fusion 360 experience required

Post-Training Impact

For Professionals

• Ability to handle complete product development lifecycle
• Strong capability in integrated CAD/CAM workflows
• Improved design innovation and speed
• Enhanced career opportunities in product design

For Organizations

• Faster product development cycles
• Improved collaboration between design and manufacturing
• Reduced prototyping costs and rework
• Increased innovation and product quality

Certification

Participants receive a Professional Certification from Pertecnica Engineering, validating their expertise in Fusion 360 for Product Development.

Why Corporates Choose Pertecnica

• Focus on end-to-end product development, not just tools
• Trainers with real product design and manufacturing experience
• Programs aligned with modern product development practices
• Proven impact on innovation and efficiency

Industries Where This Training is Critical

• Product Design & Development
• Manufacturing & Industrial Design
• Automotive & Consumer Products
• Startups & Innovation Labs
• Engineering & R&D Centers

Call to Action

If your product development process is slow and fragmented, you are losing competitive advantage.
Adopt integrated design and manufacturing with Fusion 360.

Partner with Pertecnica Engineering to build a fast, innovative, and product-driven engineering team.

Mastercam Training for Machining

Program Positioning

This is not just a CAM software course.
Pertecnica Engineering’s Mastercam Training for Machining is designed for professionals who need to convert designs into efficient, error-free machining operations.

Mastercam is widely used across manufacturing industries for CNC programming and toolpath generation. This program focuses on real machining workflows—how parts are actually produced on the shop floor.

Program Overview

Modern machining demands precision, speed, and cost efficiency.

This program trains participants to:

• Generate optimized toolpaths using Mastercam
• Convert CAD models into machining-ready programs
• Improve cycle time and machining efficiency
• Reduce tool wear and material waste
• Validate machining processes before execution

Participants gain the ability to deliver production-ready CAM solutions aligned with real manufacturing needs.

What Makes This Training Different

Most CAM courses focus only on software navigation.
This program focuses on machining logic + toolpath strategy + production efficiency.

Key differentiators:

• Strong focus on real machining practices
• Integration of design-to-manufacturing workflow
• Emphasis on cycle time reduction and optimization
• Exposure to industrial machining challenges
• Project-based learning aligned with production scenarios

Core Learning Outcomes

By the end of the program, participants will be able to:

• Create efficient CNC toolpaths using Mastercam
• Select appropriate machining strategies and tools
• Optimize cutting parameters for productivity
• Simulate and validate machining operations
• Reduce errors and improve machining accuracy
• Translate CAD designs into manufacturable components

Program Curriculum

Module 1: Mastercam Fundamentals

• Interface and workflow overview
• Importing CAD models
• Basic machining concepts

Module 2: 2D Machining

• Contouring, facing, and drilling
• Toolpath creation and editing
• Entry/exit strategies

Module 3: 3D Machining

• Surface machining techniques
• Roughing and finishing strategies
• High-speed machining concepts

Module 4: Tooling & Cutting Parameters

• Tool selection and tool libraries
• Speeds, feeds, and cutting conditions
• Material-based optimization

Module 5: Toolpath Optimization

• Reducing cycle time
• Improving surface finish
• Minimizing tool wear

Module 6: Simulation & Verification

• Toolpath simulation
• Collision detection
• Process validation

Module 7: Post Processing & CNC Output

• Generating G-code
• Post processors and machine compatibility
• Program verification

Training Methodology

• Instructor-led sessions by CAM and manufacturing experts
• Hands-on toolpath creation and simulation exercises
• Real-world machining case studies
• Practical optimization and troubleshooting sessions

Who This Program is For

• CNC Programmers and Machine Operators
• CAM Engineers
• Manufacturing and Production Engineers
• Tool & Die Engineers
• Mechanical Engineers involved in machining
• Fresh Graduates entering manufacturing careers

Prerequisites

• Basic understanding of machining or manufacturing concepts
• Prior CAD knowledge is beneficial but not mandatory

Post-Training Impact

For Professionals

• Strong capability in CAM programming using Mastercam
• Ability to optimize machining processes
• Increased efficiency and technical confidence
• Career growth in CNC and manufacturing roles

For Organizations

• Reduced machining time and operational costs
• Improved production quality and consistency
• Lower tool wear and material wastage
• Skilled workforce ready for advanced machining

Certification

Participants receive a Professional Certification from Pertecnica Engineering, validating their expertise in Mastercam for Machining.

Why Corporates Choose Pertecnica

• Focus on real machining performance, not just software
• Trainers with actual CNC and production experience
• Programs aligned with industrial manufacturing requirements
• Proven impact on productivity and efficiency

Industries Where This Training is Critical

• Automotive & Component Manufacturing
• Aerospace & Precision Engineering
• Tool & Die Industry
• Industrial Equipment Manufacturing
• CNC Production Units

Call to Action

If your machining process is not optimized, you are losing time, cost, and quality.
Upgrade your manufacturing capability with Mastercam expertise.

Partner with Pertecnica Engineering to build a high-efficiency, production-ready workforce.

CNC Programming & CAM Training

This is not just a programming course.
Pertecnica Engineering’s CNC Programming & CAM Training is designed for professionals who want to bridge the gap between design and manufacturing execution.

The program focuses on how CNC machining actually works on the shop floor—covering G-code programming, CAM-based toolpath generation, and machining optimization for real industrial applications.

Program Overview

Modern manufacturing requires precision, efficiency, and minimal error.

This program trains participants to:

• Program CNC machines using G-code and M-code
• Generate toolpaths using CAM software
• Optimize machining operations for productivity
• Reduce cycle time and material waste
• Translate engineering designs into manufacturable components

Participants gain the ability to deliver accurate, production-ready machining instructions.

What Makes This Training Different

Most CNC courses are either theory-heavy or software-only.
This program combines programming + machining logic + industrial practice.

Key differentiators:

• Hands-on CNC programming approach
• Integration of manual coding + CAM software
• Focus on real machining strategies
• Exposure to production challenges and solutions
• Industry-oriented project-based learning

Core Learning Outcomes

By the end of the program, participants will be able to:

• Write and interpret CNC programs (G-code & M-code)
• Develop toolpaths using CAM software
• Select cutting tools and machining parameters
• Optimize machining cycles and reduce errors
• Understand CNC machine operations and setup
• Troubleshoot machining and programming issues

Program Curriculum

Module 1: Fundamentals of CNC Machining

• Basics of CNC machines and operations
• Types of machines (lathe, milling, multi-axis)
• Coordinate systems and axes

Module 2: CNC Programming (G-Code & M-Code)

• Structure of CNC programs
• Tool movement commands
• Drilling, turning, and milling cycles

Module 3: Tooling & Machining Parameters

• Cutting tools and materials
• Speeds, feeds, and depth of cut
• Tool selection and optimization

Module 4: CAM Software Introduction

• CAM interface and workflow
• Toolpath generation
• Simulation and verification

Module 5: Advanced Machining Techniques

• Multi-axis machining basics
• Complex contour machining
• Toolpath optimization

Module 6: Machine Setup & Operation

• Workpiece setup and fixturing
• Tool offsets and calibration
• Dry run and safety checks

Module 7: Troubleshooting & Optimization

• Common machining errors
• Program debugging
• Cycle time reduction strategies

Training Methodology

• Instructor-led sessions by manufacturing experts
• Hands-on CNC programming exercises
• CAM simulation and validation
• Real-world machining case studies
• Practical problem-solving sessions

Who This Program is For

• Manufacturing and Production Engineers
• CNC Programmers and Machine Operators
• Mechanical and Design Engineers
• Tool & Die Engineers
• CAM Engineers
• Fresh Graduates entering manufacturing careers

Prerequisites

• Basic understanding of mechanical or manufacturing concepts
• No prior CNC programming experience required (beginner to advanced track available)

Post-Training Impact

For Professionals

• Ability to create and optimize CNC programs
• Strong understanding of machining processes
• Increased productivity and technical confidence
• Career growth in manufacturing and production roles

For Organizations

• Reduced machining errors and rework
• Improved production efficiency
• Lower cycle time and operational costs
• Skilled workforce ready for advanced manufacturing

Certification

Participants receive a Professional Certification from Pertecnica Engineering, validating their expertise in CNC Programming & CAM.

Why Corporates Choose Pertecnica

• Focus on practical machining and production needs
• Trainers with real shop-floor and manufacturing experience
• Programs aligned with modern CNC and CAM technologies
• Proven impact on productivity and workforce capability

Industries Where This Training is Critical

• Automotive & Component Manufacturing
• Aerospace & Precision Engineering
• Tool & Die Industry
• Industrial Equipment Manufacturing
• CNC Production Units

Call to Action

If your manufacturing depends on precision, your workforce must master CNC programming.
Upgrade your production capability with industry-ready training.

Siemens NX for Integrated CAD/CAM Training

Program Positioning

This is not just a CAD or CAM course.
Pertecnica Engineering’s Siemens NX for Integrated CAD/CAM Training is built for engineers who need to design, simulate, and manufacture within a single digital environment.

Siemens NX is widely used in high-end manufacturing sectors where precision, integration, and efficiency are critical. This program focuses on how leading industries use NX to connect design with production seamlessly.

Program Overview

Modern engineering demands a unified workflow—from concept to manufacturing.

This program trains participants to:

• Design complex 3D models
• Develop toolpaths for manufacturing
• Integrate CAD with CAM processes
• Optimize production efficiency
• Reduce design-to-manufacturing cycle time

Participants learn how to deliver production-ready designs with minimal iteration and maximum accuracy.

What Makes This Training Different

Most CAD/CAM programs teach tools separately.
This program teaches integration.

Key differentiators:

• CAD + CAM in a single workflow
• Focus on manufacturing-ready design
• Exposure to real industrial machining processes
• Emphasis on efficiency, accuracy, and cost optimization
• Project-based learning aligned with industry needs

Core Learning Outcomes

By the end of the program, participants will be able to:

• Create advanced 3D models using Siemens NX
• Generate CNC toolpaths for manufacturing
• Integrate design with machining processes
• Optimize machining strategies and reduce cycle time
• Improve product quality and production efficiency
• Handle end-to-end digital manufacturing workflows

Program Curriculum

Module 1: Siemens NX Fundamentals

• Interface and navigation
• Sketching and basic modeling
• Parametric design concepts

Module 2: Advanced 3D Modeling

• Feature-based modeling
• Surface and solid modeling techniques
• Complex geometry creation

Module 3: Assembly Design

• Assembly modeling and constraints
• Large assembly management
• Interference and fit analysis

Module 4: CAM Fundamentals

• Introduction to CNC machining
• Toolpath generation basics
• Machining operations (milling, drilling)

Module 5: Advanced CAM Techniques

• Multi-axis machining concepts
• Toolpath optimization
• Cutting strategies and efficiency improvement

Module 6: CAD-CAM Integration

• Design for manufacturability (DFM)
• Workflow from design to production
• Simulation of machining processes

Module 7: Industrial Project Application

• End-to-end product development project
• CAD design + CAM programming
• Validation and optimization

Training Methodology

• Industry-driven instructor sessions
• Hands-on CAD/CAM exercises
• Real-world manufacturing case studies
• Project-based learning with simulation and validation

Who This Program is For

• Mechanical and Manufacturing Engineers
• CAD/CAM Engineers
• CNC Programmers and Machinists
• Product Design Engineers
• Tooling and Production Engineers
• Fresh Graduates targeting manufacturing careers

Prerequisites

• Basic understanding of mechanical or manufacturing concepts
• Prior CAD knowledge (preferred but not mandatory)

Post-Training Impact

For Professionals

• Ability to handle complete CAD to CAM workflow
• Strong capability in CNC programming and toolpath optimization
• Increased value in manufacturing and production roles
• Transition from design-only roles to integrated engineering roles

For Organizations

• Reduced design-to-production cycle time
• Improved manufacturing accuracy and efficiency
• Lower production costs and material waste
• Enhanced digital manufacturing capability

Certification

Participants receive a Professional Certification from Pertecnica Engineering, validating their expertise in Siemens NX for Integrated CAD/CAM.

Why Corporates Choose Pertecnica

• Focus on real manufacturing workflows, not isolated tools
• Trainers with industrial CAD/CAM and CNC experience
• Programs aligned with Industry 4.0 and digital manufacturing
• Proven impact on workforce productivity

Industries Where This Training is Critical

• Automotive & Heavy Engineering
• Aerospace & Precision Manufacturing
• Tool & Die Manufacturing
• Industrial Equipment Production
• Advanced Manufacturing & CNC Operations

Call to Action

If your design and manufacturing teams are working in silos, you are losing time and efficiency.
Integrate your engineering workflow with Siemens NX.

CATIA for Aerospace & Automotive Design Training

This is not a generic CAD course.
Pertecnica Engineering’s CATIA for Aerospace & Automotive Design Training is built for engineers who want to work on high-precision, safety-critical, and performance-driven products.

CATIA is the backbone of design in leading aerospace and automotive organizations. This program focuses on how industry actually uses CATIA—for complex surfaces, assemblies, and large-scale product development.

Program Overview

Modern product design in aerospace and automotive industries requires:

• High precision
• Complex surface modeling
• Large assembly management
• Design validation before manufacturing

This program trains participants to design, analyze, and optimize components and assemblies used in real-world vehicles and aircraft systems.

What Makes This Training Different

Most CATIA programs teach tools.
This program teaches industrial design thinking.

Key differentiators:

• Focus on aerospace & automotive applications
• Emphasis on surface modeling and complex geometry
• Exposure to OEM-level design workflows
• Integration of design + assembly + validation
• Real project-based learning approach

Core Learning Outcomes

By the end of the program, participants will be able to:

• Create complex 3D models and advanced surfaces
• Design automotive and aerospace components
• Develop and manage large assemblies
• Apply GD&T and industry design standards
• Optimize designs for manufacturability and performance
• Work with real-world product development workflows

Program Curriculum

Module 1: CATIA Fundamentals & Interface

• CATIA workbench overview
• Sketcher and Part Design basics
• Parametric modeling concepts

Module 2: Advanced Part Design

• Feature-based modeling
• Design intent and parametric control
• Complex geometry creation

Module 3: Surface Modeling (Critical Module)

• Wireframe and surface design
• Generative shape design
• Class-A surface basics

Module 4: Assembly Design

• Product structure management
• Constraints and assembly techniques
• Large assembly handling

Module 5: Automotive & Aerospace Components

• Automotive body components
• Aerospace structural parts
• Sheet metal and structural design

Module 6: Drafting & GD&T

• 2D drawing generation
• Dimensioning and tolerancing (GD&T)
• Industry drafting standards

Module 7: Product Design Workflow

• Design lifecycle in OEM environments
• Collaboration and data management basics
• Design review and validation practices

Training Methodology

• Industry-driven instructor sessions
• Hands-on modeling and surface design exercises
• Real-world automotive and aerospace case studies
• Project-based learning with design reviews

Who This Program is For

• Mechanical and Design Engineers
• Automotive and Aerospace Engineers
• Product Development Engineers
• CAD Designers upgrading to CATIA
• Fresh Graduates aiming for OEM roles

Prerequisites

• Basic understanding of mechanical design concepts
• Prior CAD knowledge (preferred but not mandatory)

Post-Training Impact

For Professionals

• Ability to work on OEM-level design projects
• Strong capability in surface and assembly modeling
• Enhanced employability in automotive and aerospace sectors
• Transition from basic CAD user to design specialist

For Organizations

• Improved design accuracy and quality
• Faster product development cycles
• Reduced design errors and rework
• Skilled workforce aligned with global standards

Certification

Participants receive a Professional Certification from Pertecnica Engineering, validating their expertise in CATIA for Aerospace & Automotive Design.

Why Corporates Choose Pertecnica

• Focus on industry application, not just software
• Trainers with real automotive and aerospace experience
• Programs aligned with OEM and Tier-1 supplier requirements
• Proven impact on engineering workforce capability

Industries Where This Training is Critical

• Automotive OEMs & Tier-1 Suppliers
• Aerospace & Defense
• Industrial Equipment Manufacturing
• Engineering Design & R&D Centers
• EPC & Advanced Engineering Projects

Call to Action

If your team is designing without advanced surface and assembly capability, you are limiting innovation.
Upgrade your engineering strength with CATIA expertise.

Partner with Pertecnica Engineering to build engineers ready for global automotive and aerospace challenges.

Advanced SolidWorks Training – Simulation & Assembly Engineering

This is not a basic CAD course.
Pertecnica Engineering’s Advanced SolidWorks – Simulation & Assembly Training is designed for engineers who want to move beyond modeling and start engineering performance, reliability, and real-world functionality into their designs.

Built on 15+ years of industry training expertise, this program focuses on how assemblies behave under real conditions—loads, motion, stress, and constraints—making it highly relevant for manufacturing, product development, and EPC environments.

Program Overview

Modern engineering demands more than drawing—it demands validation before manufacturing.

This program trains professionals to:

• Build complex, multi-component assemblies
• Simulate real-world operating conditions
• Identify design failures before production
• Optimize performance, weight, and cost

Participants learn how to convert designs into validated, production-ready engineering solutions.

What Makes This Training Different

Unlike conventional SolidWorks courses, this program focuses on:

• Engineering thinking, not just software usage
• Simulation-driven design decisions
• Assembly-level problem solving
• Failure prediction and prevention
• Industrial project-based learning

Core Learning Outcomes

By the end of the program, participants will be able to:

• Design and manage complex assemblies with real-world constraints
• Perform structural and motion simulations
• Analyze stress, deformation, and failure points
• Optimize designs for performance and manufacturability
• Validate designs before fabrication
• Reduce rework, material waste, and design errors

Program Curriculum

Module 1: Advanced Assembly Engineering

• Large assembly management
• Top-down vs bottom-up design
• Advanced mates and constraints
• Configuration-driven assemblies

Module 2: Assembly Performance Analysis

• Interference detection and clearance analysis
• Tolerance stack-up concepts
• Fit and functional validation

Module 3: Motion Simulation

• Motion studies (basic to advanced)
• Kinematics and dynamics
• Force, velocity, and displacement analysis

Module 4: Structural Simulation (FEA Basics)

• Stress and strain analysis
• Load and boundary conditions
• Factor of safety evaluation

Module 5: Design Optimization

• Weight reduction strategies
• Material selection insights
• Performance vs cost optimization

Module 6: Failure Analysis & Troubleshooting

• Identifying weak points in assemblies
• Design correction techniques
• Preventive design strategies

Module 7: Industrial Project Application

• Real-world assembly design case study
• Simulation-based validation
• Final design review and improvement

How the Training is Delivered

• Scenario-based engineering sessions
• Hands-on simulation exercises
• Industrial case studies
• Design validation workshops

This ensures participants don’t just learn tools—they learn how engineers actually solve problems in industry.

Who This Program is For

• Mechanical Design Engineers
• Product Development Engineers
• R&D Engineers
• Manufacturing Engineers
• CAD Professionals upgrading to simulation
• EPC Design Engineers

Prerequisites

• Working knowledge of SolidWorks (basic modeling & assemblies)
• Understanding of mechanical fundamentals

Post-Training Impact

For Professionals

• Move from “designer” to design engineer
• Ability to validate designs before production
• Strong capability in simulation-driven decision making
• Increased value in product development roles

For Organizations

• Reduced design failures and rework
• Faster product development cycles
• Improved product reliability
• Lower material and manufacturing costs

Certification

Participants receive a Professional Certification from Pertecnica Engineering, recognizing their capability in advanced assembly design and simulation using SolidWorks.

Why Corporates Choose Pertecnica

• Focus on practical engineering application, not just software
• Trainers with real project and product design experience
• Programs aligned with manufacturing and EPC requirements
• Proven impact on workforce performance

Industries Where This Matters Most

• Manufacturing & Product Development
• Automotive & Heavy Engineering
• Aerospace & Precision Engineering
• Industrial Equipment Design
• EPC & Engineering Consultancy

Call to Action

If your team is still designing without validating, you are accepting risk.
Upgrade your engineering capability with simulation-driven design expertise.

SolidWorks for Mechanical Design Training

Course Overview

Pertecnica Engineering offers a specialized SolidWorks for Mechanical Design Training program tailored for manufacturing, product design, and EPC project environments. With over 15 years of expertise, this program equips professionals with practical skills to create accurate 3D models, assemblies, and engineering drawings using SolidWorks.

The training emphasizes real-world industrial applications, enabling participants to design components, simulate assemblies, and generate production-ready documentation aligned with industry standards.

Course Description

This comprehensive course focuses on using SolidWorks for mechanical design, modeling, and product development. Participants will learn to create parametric 3D models, develop assemblies, and generate detailed engineering drawings for manufacturing and project execution.

Participants will gain expertise in:

• 3D part modeling and feature creation
• Assembly design and motion analysis
• 2D drawing generation from 3D models
• Design validation and basic simulation
• Product design documentation and standards

The program ensures participants can confidently handle end-to-end mechanical design workflows using SolidWorks.

Key Learning Objectives

By the end of this training, participants will be able to:

• Understand SolidWorks interface and modeling workflow
• Create parametric 3D models of mechanical components
• Develop assemblies with proper constraints and relationships
• Generate detailed 2D drawings from 3D designs
• Apply design standards and best practices
• Perform basic simulation and design validation

Curriculum

Module 1: Introduction to SolidWorks

• Interface and navigation
• Sketching fundamentals
• Feature-based modeling concepts

Module 2: Part Modeling

• Extrude, revolve, sweep, and loft features
• Fillets, chamfers, and shell operations
• Parametric design techniques

Module 3: Assembly Design

• Creating and managing assemblies
• Mates and constraints
• Interference detection and motion basics

Module 4: Drawing & Documentation

• Generating 2D drawings from 3D models
• Dimensioning and annotations
• Bill of Materials (BOM)

Module 5: Advanced Features

• Configurations and design tables
• Sheet metal and weldments basics
• Surface modeling fundamentals

Module 6: Simulation & Analysis

• Basic stress analysis
• Load and boundary conditions
• Design validation concepts

Module 7: Project-Based Learning

• Real-world component and assembly design
• Documentation and review
• Best practices for industrial projects

Training Methodology

• Instructor-led sessions by design experts
• Hands-on modeling and design exercises
• Real-world mechanical design projects
• Interactive feedback and design reviews

Who Should Attend

This training program is ideal for:

• Mechanical Engineers and Design Engineers
• Product Design Engineers
• Manufacturing Engineers
• CAD Professionals and Drafting Engineers
• EPC Project Engineers
• Students and Fresh Engineering Graduates

Prerequisites

• Basic understanding of mechanical engineering concepts
• No prior SolidWorks experience required (for beginners track)

After Completion of the Course

Participants Will Gain

• Strong proficiency in 3D modeling and mechanical design
• Ability to create assemblies and production drawings
• Improved design accuracy and productivity
• Enhanced employability and project readiness

Organizational Benefits

• Faster product design and development cycles
• Improved design accuracy and reduced errors
• Better collaboration between design and production teams
• Enhanced innovation and product quality

Certification

Participants will receive a Professional Certification from Pertecnica Engineering, validating their expertise in SolidWorks for Mechanical Design.

Why Choose Pertecnica Engineering

• 15+ years of technical training excellence
• Practical, industry-oriented design training
• Trainers with real-world product design experience
• Customized training for corporate teams
• Proven track record in engineering skill development

Industries Covered

• Manufacturing & Product Design
• Automotive & Heavy Engineering
• Aerospace & Defense
• Oil & Gas / Industrial Equipment
• EPC and Industrial Projects

Call to Action

Enhance your mechanical design capabilities with advanced 3D modeling and product development skills.