The SOLIDWORKS Simulation Static course is an intensive training program that provides users with the skills and knowledge necessary to effectively use the SOLIDWORKS Simulation software. This course covers how to create and set up a static analysis or static analysis model, and how to interpret the analysis results. Students will learn to evaluate the effects of loads and boundary conditions, compare different analysis scenarios, and use advanced tools for optimization. Use the results to improve product designs by effectively applying the results to design decisions. At the end of the course, participants will have a thorough understanding of the fundamentals of SOLIDWORKS Simulation and be able to apply its tools to their own design projects.

Duration: 3 days (21h)

This training course will cover:

• An overview of the full simulation process
• Assembly testing and result analysis
• Mesh controls, options, and mixed meshing
• Stress concentrations and boundary conditions

SOLIDWORKS Motion is a comprehensive program designed to help engineers and designers create motion simulations in SOLIDWORKS. This course covers motion analysis, constraints, optimization, motion control, and visualization. It introduces participants to tools and techniques that enable them to create virtual prototypes, test designs, and analyze results. Participants will gain the knowledge and skills necessary to effectively design and simulate motion-based systems. By the end of this training course, students will have a thorough understanding of the principles and techniques behind motion analysis, as well as the confidence to apply them to real-world scenarios.

Duration: 2 days (14h)

This training course will cover:

• The basics of building, simulating and refining mechanical systems
• Building motion models and post-processing
• Contacts, springs, and dampers
• Exporting to FEA and direct solutions in SOLIDWORKS Motion

The SOLIDWORKS Simulation Professional course provides an in-depth look at the powerful Finite Element Analysis tools available in SOLIDWORKS. This course is designed to equip users of SOLIDWORKS Simulation Professional with the knowledge and skills to use the extension productively. It covers a range of advanced Finite Element Analysis topics, including heat transfer analysis, frequency analysis, fatigue, linear buckling stability analysis, 2D simulations (plane stress, strain, and axisymmetry), and pressure vessel modulus. Students will gain the skills necessary to simulate complex designs accurately and efficiently and use the results to validate designs and improve product performance.

Duration: 2 days (14h)

This training course will cover:

• Frequency analysis of parts and assemblies
• Topology studies and optimizing designs to reduce material cost
• Best practices for managing simulations and interpreting results
• Troubleshooting common simulation problems

This course is designed for SOLIDWORKS Simulation Premium users to advance their Finite Element Analysis (FEA) skills. It provides both the basics and advanced topics in non-linear stress analysis. Participants are introduced to the various material models available in SOLIDWORKS Simulation Premium and learn how to correctly execute a non-linear analysis. The second half of the course focuses on Dynamics, including time-dependent analysis, harmonic analysis, and random vibrations. Students learn to analyze the strength and design of products, optimize designs for cost and performance, and create accurate simulations of real-world environments.

Duration: 3 days (21h)

This training course will cover:

• Non-linear static finite element analysis
• Linear and non-linear dynamic finite element analysis
• Random vibration fatigue analysis

The SOLIDWORKS Simulation Premium Composite training course provides users with an introduction to composite materials and the simulation tools available in SOLIDWORKS to analyze and simulate their performance. Participants will learn how to use these tools to predict the behavior and performance of composite components and assemblies. Examples will be presented and discussed to demonstrate how composite materials are used in industries such as aerospace, automotive, and manufacturing. By the end of this course, users will understand the principles of composite materials and how to use SOLIDWORKS Simulation to analyze their performance in a variety of situations.

Duration: 1 day (7h)

This training course will cover:

• Linear static, buckling, and frequency analyses
• Composite material basics and properties
• Setting up and running simulations for composite materials
• Industry use cases

SOLIDWORKS Flow Simulation training introduces users to the powerful capabilities of the SOLIDWORKS Flow Simulation extension. Through this course, users will gain the skills necessary to analyze and optimize the performance of products and processes using computational fluid dynamics. The course will cover topics such as the fundamentals of fluid flow, creating and modifying geometry, setting up and running analyses, post-processing results, and troubleshooting. Students will also gain an understanding of how to identify and use the appropriate boundary conditions and parameters for different types of problems. By the end of the course, users will be able to confidently use SOLIDWORKS Flow Simulation to analyze and optimize their products and processes.

Duration: 2 days (14h)

This training course will cover:

• Creating a Flow Simulation project
• Meshing, modeling, and post-processing options
• Turbulent flow analysis basics
• Industry use cases

The SOLIDWORKS Flow Simulation: HVAC Module training course provides students with a comprehensive understanding of how to use SOLIDWORKS Flow Simulation to model, analyze, and optimize HVAC systems. Participants are given an overview of HVAC system types and their components, as well as an in-depth look at the advanced features of Flow Simulation. Topics covered include airflow and pressure, heat transfer, and fan and duct design. Upon completion, participants will be able to set up and run simulations, interpret results, and optimize designs for energy efficiency.

Duration: 1 day (7h)

This training course will cover:

• Introduction to HVAC and an overview of the Flow Simulation software
• Setting up HVAC models, managing data sets, and analyzing results
• Designing and optimizing systems
• Managing the simulation environment

SOLIDWORKS Flow Simulation: Electronic Cooling is an ideal training module for engineers and product designers who need to understand the principles of cooling electronic components and devices. The module covers the fundamentals of thermal management and provides a comprehensive overview of thermal analysis techniques to identify potential areas of concern. Participants will be able to use the software to simulate cooling flow within electronic components and devices and analyze the results. Participants will learn best practices and techniques to create robust designs that meet industry standards.

Duration: 1 day (7h)

This training course will cover:

• Setting up electronic cooling models
• Performing electronic cooling simulations and result analysis
• Heat transfer analysis
• Design optimization for electronic cooling system performance

The SOLIDWORKS Plastics course is designed to give students a comprehensive understanding of the product design, tooling, and molding processes involved in creating plastic parts. Students learn how to use SOLIDWORKS Plastics software to simulate the injection molding process, design and create plastic parts, and analyze the results. This course covers material selection, mold design, part design, simulation and analysis, and post-processing. Students will also learn about plastic part design principles, molding tools, and settings, and design best practices. With the knowledge and skills acquired from this course, students will be able to confidently design and produce plastic parts.

Duration: 1.5 days (10h), 2 days (14h), or 3 days (21h)

This training course will cover:

• Part design and material selection
•  Injection molding, mold filling, and packing analysis
• Simulation and verification
• Part design troubleshooting and optimization techniques