|| SolidWork Certification Course

A SolidWorks Training Course provides comprehensive training in utilizing SolidWorks, a prominent CAD software extensively used in engineering and manufacturing sectors. Participants in these courses acquire essential skills to create 3D models, simulate designs, and generate detailed engineering drawings. The curriculum typically covers fundamental concepts of parametric modeling, enabling users to efficiently manipulate dimensions and relationships to control design geometry and ensure design intent. Advanced topics often include assembly design, where participants learn to construct and manage complex assemblies using mates and constraints.

One of the most well-liked and potent 3D CAD applications available today is Solidworks. It is used by millions of individuals to design a wide range of products, from fully functional mechanical vehicles to toys that are 3D printed. You may now become a part of the Solidworks community and learn how to make your own models entirely from scratch!


The SolidWorks Professional course is designed to equip individuals with advanced skills in using SolidWorks, a leading CAD (Computer-Aided Design) software widely used in various engineering and design industries. This course covers comprehensive modules that delve into the core functionalities of SolidWorks, including parametric design, advanced part modeling, complex assembly creation, and detailed drafting. Participants learn to work with surface modeling, sheet metal design, and weldments, as well as gain proficiency in creating and managing configurations, design tables, and parametric equations. Additionally, the course includes training on simulation and analysis tools within SolidWorks to validate design performance under real-world conditions. A combination of lectures, practical projects, and hands-on exercises will make up the course. In order to reinforce learning objectives, participants will receive step-by-step tutorial guidance and access to SolidWorks software. In addition, industry experts and guest lecturers might be asked to provide their perspectives and practical implementations. This Solidworks course is made with a beginner in mind and it will help you learn everything about Solidworks right from scratch.


Please contact the nearest BIT training institute or send an email to inquiry@bitbaroda.com with any additional questions you may have regarding our Solidworks training course. We offer a free demo by calling us at +91-9328994901. We offer top-notch Solidworks classes in Vadodara-Sayajigunj, Vadodara - Waghodia Road, Vadodara - Manjalpur, Ahmedabad, Anand, and Nadiad.

|| Choose SolidWork Course From BIT

SolidWorks course features in india , Features of bit , features of bit coaching classes ,Experienced instructors ,comprehensive curriculum ,certification and accreditation

Certificate

|| What will I learn?

  • Develop proficiency in using SolidWorks software, including understanding its interface, tools, and functionalities for creating 2D drafts and 3D models.
  • Master parametric modeling techniques, including creating and editing 3D parts using features such as extrusions, revolves, sweeps, blends, and advanced surfacing.
  • Gain expertise in assembly design, including creating and managing assemblies of parts, defining assembly constraints, and simulating assembly motion for testing.
  • Learn how to create detailed 2D drawings with annotations, dimensions, and geometric tolerances, ensuring accurate documentation of designs for manufacturing.
  • Understand how to perform simulations and analyses within SolidWorks to evaluate the structural integrity, kinematics, and performance of your designs under various conditions.
  • Acquire skills in sheet metal design, including creating sheet metal parts, bends, flanges, and forming tools, and unfolding sheet metal components for manufacturing.
  • Explore advanced surface modeling techniques for creating complex surface geometries, such as freeform surfaces and Class-A surfaces, for aesthetic and functional purposes.
  • Learn direct modeling techniques for making quick design changes and edits to 3D models without being constrained by parametric history, enabling faster iteration and design exploration.

|| What will I learn?

  • Develop proficiency in using SolidWorks software, including understanding its interface, tools, and functionalities for creating 2D drafts and 3D models.
  • Master parametric modeling techniques, including creating and editing 3D parts using features such as extrusions, revolves, sweeps, blends, and advanced surfacing.
  • Gain expertise in assembly design, including creating and managing assemblies of parts, defining assembly constraints, and simulating assembly motion for testing.
  • Learn how to create detailed 2D drawings with annotations, dimensions, and geometric tolerances, ensuring accurate documentation of designs for manufacturing.
  • Understand how to perform simulations and analyses within SolidWorks to evaluate the structural integrity, kinematics, and performance of your designs under various conditions.
  • Acquire skills in sheet metal design, including creating sheet metal parts, bends, flanges, and forming tools, and unfolding sheet metal components for manufacturing.
  • Explore advanced surface modeling techniques for creating complex surface geometries, such as freeform surfaces and Class-A surfaces, for aesthetic and functional purposes.
  • Learn direct modeling techniques for making quick design changes and edits to 3D models without being constrained by parametric history, enabling faster iteration and design exploration.

|| Requirements

  • Basic knowledge of engineering principles
  • Familiarity with computer operations is recommended

|| Requirements

  • Basic knowledge of engineering principles
  • Familiarity with computer operations is recommended

    A comprehensive SolidWorks course covers essential topics including the software interface, 2D sketching, and 3D modeling techniques such as extrudes, revolves, lofts, and sweeps. Students learn assembly modeling, combining multiple parts and managing complex projects, as well as creating professional engineering drawings with views, sections, and annotations. Advanced sections cover surface modeling, sheet metal design, and weldments. The course also introduces simulation tools for basic stress analysis, motion studies, and thermal analysis. Emphasis is on best practices and real-world applications, ensuring students can create detailed, accurate 3D models and assemblies, produce high-quality technical drawings, and perform basic simulations.


    The benefits of completing the SolidWorks Professional course are manifold. Firstly, it enhances participants' technical capabilities, enabling them to produce highly detailed and accurate 3D models and technical drawings. This proficiency is crucial for roles in product design, mechanical engineering, and manufacturing, where precision and innovation are key. Secondly, the course improves job prospects by providing a widely recognized certification that attests to the individual's expertise in SolidWorks, making them attractive candidates for engineering and design firms. Lastly, by mastering advanced SolidWorks tools, professionals can streamline their design processes, reduce development time, and enhance collaboration within design teams, ultimately contributing to more efficient and innovative product development cycles.

    • Introduction to SolidWorks
    • Overview of SolidWorks software and its capabilities
    • Understanding the parametric 3D modeling approach
    • Introduction to the SolidWorks user interface and navigation


    • Sketching Fundamentals
    • Understanding sketching principles and best practices
    • Creating and editing 2D sketches using sketch entities (lines, circles, rectangles, etc.)
    • Applying sketch constraints and dimensions to control geometry


    • Part Modeling Basics
    • Introduction to part modeling workflows
    • Creating basic 3D features by extruding and revolving sketches
    • Understanding the concept of features, sketches, and design intent


    • Intermediate Part Modeling
    • Exploring more advanced modeling techniques such as fillets, chamfers, and shells
    • Working with multi-body parts and configurations
    • Utilizing advanced features like sweeps, lofts, and ribs


    • Advanced Part Modeling
    • Mastering complex modeling tasks with surface modeling tools
    • Creating sheet metal parts and utilizing specialized sheet metal features
    • Exploring the SolidWorks Toolbox for standard parts and components


    • Assembly Modeling
    • Introduction to assembly modeling and its components
    • Inserting and positioning components within assemblies
    • Applying assembly constraints and relationships to define motion


    • Advanced Assembly Techniques
    • Working with advanced assembly features like mate references and smart components
    • Creating exploded views and animations for assembly instructions
    • Performing interference detection and collision checking


    • Drawing and Detailing
    • Creating and annotating drawing views (orthographic, isometric, auxiliary)
    • Adding dimensions, annotations, and GD&T symbols to drawings
    • Generating bill of materials (BOM) and parts lists
    • Choose Any One Specialisation


    • Sheet Metal Design
    • Understanding sheet metal design principles and terminology
    • Creating sheet metal parts with bends, flanges, and forming tools
    • Unfolding and flattening sheet metal parts for manufacturing


    • Weldments
    • Creating structural frames and weldment structures
    • Adding weld beads, cuts, and end treatments to weldments
    • Detailing weldment drawings with weld symbols and annotations


    • Surface Modeling
    • Exploring advanced surface modeling techniques for complex shapes
    • Creating and editing surfaces using loft, sweep, and boundary features
    • Converting solid models to surfaces and vice versa


    • Mold Design
    • Introduction to mold design principles and terminology
    • Creating parting surfaces, shut-off surfaces, and split lines for molds
    • Generating mold cavities and cores using core/cavity tools


    • Motion Study and Simulation
    • Performing motion studies to simulate mechanical motion and animations
    • Introduction to finite element analysis (FEA) for structural simulations
    • Analyzing stress, displacement, and factor of safety in parts and assemblies


    • Design Automation and Customization
    • Introduction to macros and automation in SolidWorks using Visual Basic for Applications (VBA)
    • Customizing the SolidWorks environment with templates, libraries, and design standards
    • Integrating SolidWorks with other CAD/CAM software and systems


    • Collaboration and Data Management
    • Working with Product Data Management (PDM) systems for data organization and collaboration
    • Collaborating with team members and stakeholders through shared projects and design reviews
    • Managing design revisions and version control for projects


    • Project Work and Case Studies
    • Applying learned skills and techniques to real-world design projects and examples
    • Hands-on exercises and project-based learning to reinforce concepts
    • Presentations and discussions on project outcomes and best practices

    • Introduction to Sheet Metal Design
    • Overview of sheet metal design principles and terminology
    • Understanding the advantages and applications of sheet metal parts
    • Introduction to SolidWorks Sheet Metal tools and features


    • Basic Sheet Metal Features
    • Creating base and edge flanges
    • Adding bends, hems, and miters to sheet metal parts
    • Understanding the Flatten feature and unfolding sheet metal geometry


    • Advanced Sheet Metal Features
    • Exploring lofted bends and swept flanges
    • Creating closed corners and junctions
    • Adding rips and cross breaks to strengthen sheet metal parts


    • Sheet Metal Design Guidelines
    • Understanding design considerations for manufacturability
    • Designing for minimum bend radius and material thickness
    • Avoiding interference and collision issues in sheet metal parts


    • Sheet Metal Modification Tools
    • Using the Convert to Sheet Metal tool to convert solid models to sheet metal
    • Editing and modifying existing sheet metal features
    • Employing techniques for adding cuts, extrusions, and fillets to sheet metal parts


    • Designing Sheet Metal Assemblies
    • Creating assemblies with sheet metal components
    • Inserting and positioning sheet metal parts within assemblies
    • Applying assembly constraints and relationships to define motion


    • Flat Pattern Development
    • Understanding the flat pattern representation of sheet metal parts
    • Creating and editing flat patterns
    • Exporting flat patterns for manufacturing and fabrication


    • Sheet Metal Documentation
    • Creating detailed drawings for sheet metal parts
    • Adding dimensions, annotations, and GD&T symbols to sheet metal drawings
    • Generating bill of materials (BOM) and parts lists for sheet metal assemblies


    • Designing Sheet Metal Enclosures
    • Design considerations for sheet metal enclosures
    • Creating complex sheet metal shapes and forms
    • Incorporating ventilation, access panels, and fastening features into enclosures


    • Sheet Metal Simulation and Analysis
    • Introduction to sheet metal simulation tools in SolidWorks
    • Analyzing and validating sheet metal designs for manufacturability and performance
    • Optimizing designs for material usage, cost, and efficiency


    • Sheet Metal Design Automation
    • Utilizing SolidWorks configurations and design tables for automating sheet metal design
    • Creating custom sheet metal libraries and standard components
    • Implementing macros and automation scripts for repetitive tasks


    • Case Studies and Real-World Applications
    • Analyzing real-world sheet metal design examples and case studies
    • Hands-on exercises and projects to reinforce concepts
    • Presentations and discussions on best practices and industry trends

    • Introduction to Weldments
    • Overview of weldments in SolidWorks
    • Understanding the advantages and applications of weldments
    • Introduction to the SolidWorks Weldments environment


    • Basic Weldment Profiles
    • Exploring standard weldment profiles
    • Creating custom weldment profiles
    • Adding and managing weldment profiles in SolidWorks


    • Structural Members
    • Inserting and positioning structural members
    • Applying standard profiles to create structural frames
    • Defining properties and parameters for structural members


    • Weldment Tools
    • Utilizing weldment tools for creating welds and weld features
    • Adding weld beads, fillet welds, and groove welds
    • Editing and modifying weldment features


    • Coping and Mitering
    • Understanding coping and mitering in weldments
    • Creating coped and mitered connections between structural members
    • Editing and adjusting coping and mitering settings


    • Gussets and End Caps
    • Adding gussets and end caps to strengthen and finish weldments
    • Exploring different types of gussets and end caps
    • Customizing gusset and end cap properties


    • Weldment Cut Lists and BOMs
    • Generating cut lists and bills of materials (BOMs) for weldments
    • Customizing cut list templates and formats
    • Managing and updating cut list data


    • Weldment Drawings and Detailing
    • Creating detailed drawings for weldments
    • Adding dimensions, annotations, and weld symbols to drawings
    • Generating section views and detail views for weldment drawings


    • Weldment Simulation and Analysis
    • Introduction to weldment simulation tools in SolidWorks Simulation
    • Analyzing and validating weldments for strength, stability, and performance
    • Optimizing weldment designs for material usage and cost efficiency


    • Weldment Documentation
    • Creating fabrication drawings and assembly instructions for weldments
    • Adding welding symbols, notes, and specifications to drawings
    • Generating weldment cut lists and shop drawings


    • Case Studies and Real-World Applications
    • Analyzing real-world weldment design examples and case studies
    • Hands-on exercises and projects to reinforce concepts
    • Presentations and discussions on best practices and industry standards

    • Introduction to Surface Modeling
    • Overview of surface modeling in SolidWorks
    • Understanding the advantages and applications of surface modeling
    • Introduction to the SolidWorks Surface Modeling environment


    • Basic Surface Creation
    • Creating surface geometry using sketch entities
    • Utilizing surface features like extrude, revolve, and sweep
    • Editing and manipulating surface geometry


    • Advanced Surface Features
    • Exploring lofted and swept surface features
    • Understanding the use of guide curves in surface modeling
    • Creating complex surface shapes and forms


    • Surface Editing and Modification
    • Editing surface geometry using direct and parametric methods
    • Employing surface trimming and extending tools
    • Applying fillets, chamfers, and other surface modifications


    • Surface Repair and Analysis
    • Identifying and repairing gaps, overlaps, and other surface errors
    • Analyzing surface curvature and continuity
    • Optimizing surface quality and smoothness


    • Surface Modeling Techniques
    • Exploring advanced surface modeling techniques
    • Creating surface blends, offsets, and lofts
    • Using surface knitting and stitching tools


    • Surface Sweeping and Lofting
    • Utilizing advanced surface sweep and loft features
    • Creating complex surface shapes with multiple guide curves
    • Understanding lofted surface profiles and paths


    • Complex Surface Modeling
    • Creating organic and freeform surface shapes
    • Using spline-based surface modeling techniques
    • Applying curvature control and continuity constraints


    • Surface Modeling for Mold Design
    • Design considerations for moldable surface geometry
    • Creating draft angles and split lines for mold design
    • Generating core and cavity surfaces for molds


    • Surface Modeling for Aesthetic Design
    • Creating stylish and ergonomic surface designs
    • Incorporating surface textures, patterns, and logos
    • Understanding surface finish requirements and specifications


    • Surface Modeling Simulation and Analysis
    • Analyzing surface models for manufacturability and performance
    • Performing curvature analysis and surface continuity checks
    • Optimizing surface designs for aesthetics and functionality


    • Surface Modeling Documentation
    • Creating technical drawings and documentation for surface models
    • Adding dimensions, annotations, and GD&T symbols to surface drawings
    • Generating 3D PDFs and other interactive documentation


    • Case Studies and Real-World Applications
    • Analyzing real-world surface modeling examples and case studies
    • Hands-on exercises and projects to reinforce concepts
    • Presentations and discussions on best practices and industry standards

    Introduction to Mold Design

    • Overview of mold design principles and terminology
    • Understanding the advantages and applications of molds
    • Introduction to the SolidWorks Mold Design environment


    • Parting Surfaces and Split Lines
    • Creating parting surfaces to define mold cavities and cores
    • Generating split lines to separate mold components
    • Applying draft angles and shutoffs for mold release


    • Core and Cavity Creation
    • Generating mold cavities and cores using parting surfaces
    • Understanding the difference between solid and surface-based molds
    • Utilizing tools and features to create complex mold geometry
    • Mold Inserts and Lifters
    • Designing mold inserts and lifters for complex features
    • Adding sliders, side cores, and other movable mold components
    • Incorporating draft analysis and undercut detection tools


    • Cooling and Ventilation Systems
    • Designing cooling channels and venting systems for mold efficiency
    • Placing cooling components and optimizing flow paths
    • Analyzing mold temperature and thermal management


    • Mold Components and Standard Parts
    • Utilizing standard mold components and libraries
    • Designing custom mold components and features
    • Incorporating ejector pins, sprues, and runners


    • Mold Assemblies and Interference Checking
    • Creating mold assemblies and inserting mold components
    • Applying assembly constraints and relationships
    • Performing interference checking and collision detection


    • Mold Analysis and Simulation
    • Introduction to mold flow analysis and simulation
    • Analyzing filling, packing, and cooling phases of the molding process
    • Optimizing mold designs for part quality and cycle time


    • Mold Documentation and Drawings
    • Creating detailed drawings and documentation for molds
    • Adding dimensions, annotations, and GD&T symbols to mold drawings
    • Generating bill of materials (BOM) and parts lists for molds


    • Mold Manufacturing Considerations
    • Understanding mold manufacturing processes and techniques
    • Designing molds for injection molding, blow molding, and other processes
    • Incorporating design for manufacturability (DFM) principles


    • Mold Maintenance and Repair
    • Designing molds for easy maintenance and repair
    • Adding features for mold disassembly and cleaning
    • Addressing common mold maintenance issues and concerns


    • Case Studies and Real-World Applications
    • Analyzing real-world mold design examples and case studies
    • Hands-on exercises and projects to reinforce concepts
    • Presentations and discussions on best practices and industry standards

Get in touch

|| SolidWorks Projects

SolidWorks Course Projects  ,projects for SolidWorks Course , V-twin engine diagram ,Motorcycle engine illustration , internal combustion engine components , pistons and crankshaft schematic ,engineering drawing of engine

Certificate

|| Scope of SolidWorks in India

The scope of a SolidWorks course in India is vast and promising, given the country's rapidly growing manufacturing and engineering sectors. Here are some key points highlighting the scope:


  • Manufacturing Industry: SolidWorks is widely used in India's manufacturing industry for product design and development. A SolidWorks course can lead to opportunities in automotive, aerospace, consumer goods, and heavy machinery companies.
  • Engineering Services: Many engineering service providers in India use SolidWorks for creating detailed design solutions for clients globally. Proficiency in SolidWorks can open doors to jobs in these firms.
  • Research and Development: R&D centers in India, both private and government, require skilled SolidWorks users to develop innovative products and solutions.
  • Startups and SMEs: The rise of startups and small to medium enterprises in India has increased the demand for versatile CAD designers who can handle end-to-end product development using SolidWorks.
  • Educational Institutions: Technical universities and colleges in India are incorporating SolidWorks into their curriculum. Skilled professionals can find opportunities as educators or trainers in these institutions.
  • Freelancing and Consulting: With a SolidWorks certification, individuals can offer freelance services or consultancy, catering to various design and development projects.
  • Global Opportunities: Indian professionals skilled in SolidWorks are in demand globally, providing opportunities for international careers.


In summary, a SolidWorks course can significantly enhance career prospects in various engineering and manufacturing domains in India, offering roles in design, product development, simulation, and analysis across multiple industries.

 

placement report placement report

|| SolidWorks Career Option and Job Opportunities

A SolidWorks course can open up numerous career options and job opportunities across various industries. Here are some potential career paths and job roles:


  • Mechanical Design Engineer: Design and develop mechanical components and systems using SolidWorks, creating detailed 3D models and technical drawings.
  • Product Designer: Conceptualize and design new products, considering aesthetics, functionality, and manufacturability, often using SolidWorks for modeling and prototyping.
  • CAD Engineer: Create detailed CAD models and drawings for manufacturing, ensuring precision and adherence to industry standards.
  • R&D Engineer: Work in research and development teams to innovate and improve products, using SolidWorks for design and simulation to test new ideas.
  • Manufacturing Engineer: Collaborate with design and production teams to optimize designs for manufacturability and streamline production processes.
  • Simulation Engineer: Use SolidWorks Simulation tools to perform stress analysis, thermal analysis, and motion studies, ensuring product reliability and performance.
  • Tool and Die Designer: Design molds, dies, and fixtures for manufacturing processes, utilizing SolidWorks for creating precise and functional tools.
  • Sheet Metal Designer: Specialize in designing sheet metal parts and assemblies, using SolidWorks to create accurate flat patterns and bend allowances.
  • Freelance CAD Designer: Offer design services to various clients as an independent contractor, working on diverse projects across different industries.
  • Trainer/Instructor: Teach SolidWorks at educational institutions or training centers, helping others to gain proficiency in the software.
  • Technical Support Engineer: Provide support and troubleshooting for SolidWorks users, helping to resolve issues and optimize their use of the software.
  • Project Engineer/Manager: Oversee design projects, ensuring timely delivery and quality of CAD models and technical drawings, often coordinating between design, production, and quality teams.
  • Automotive Engineer: Design and develop automotive components and systems, leveraging SolidWorks for precision modeling and simulations.
  • Aerospace Engineer: Design and analyze aircraft components, utilizing SolidWorks for complex geometries and simulations to ensure safety and performance.
  • Industrial Designer: Create and develop concepts for industrial products, focusing on usability, aesthetics, and function, with SolidWorks as a key design tool.


These career options highlight the versatility and demand for SolidWorks skills in the job market, spanning multiple industries and roles. Proficiency in SolidWorks can significantly enhance employability and career growth opportunities.

 

|| SolidWorks Holds a Prominent Position in Indian Job Market

A SolidWorks course can significantly enhance placement opportunities in India, given the high demand for skilled CAD professionals in various industries. Graduates of a SolidWorks course can find employment in top companies across sectors such as automotive, aerospace, manufacturing, consumer goods, and industrial machinery. Leading companies like Tata Motors, Mahindra & Mahindra, Larsen & Toubro, Godrej, Bajaj Auto, Ashok Leyland, and Honeywell India regularly seek professionals proficient in SolidWorks for roles such as design engineer, product designer, CAD drafter, and simulation engineer. Many engineering service providers and R&D centers also value SolidWorks skills for their design and development projects. Additionally, the rise of startups and small to medium enterprises in India has further increased the demand for versatile CAD designers. Institutes offering SolidWorks courses often have strong industry connections and dedicated placement cells, providing students with opportunities for internships and job placements. The comprehensive skill set acquired through a SolidWorks course ensures that graduates are well-prepared to meet the technical demands of these roles, making them attractive candidates for a wide range of employers.

 

|| Empowering Your Career Transition From Learning To Leading

User Image
Roshni Adatiya

Roshni Adatiya, excelling as a Revit Architect at Stemmons Business Services Pvt. Ltd. showcases proficiency in essential tools such as Autodesk Revit, AutoCAD, and Navisworks. Her adept use of these critical software contributes to effective architectural design.

User Image
Pratik Shah

Best institute for Mechanical engineering seriously just see today's condition of mechanical engineers they have to work in industry as a labour but here they bring you and offer you a bright future Platform, and here they will not only give you placement but they will make u skill person in software and Technically strong. Thank you BIT!

User Image
Sanket Vaidya

Taking admission in BIT Institute was one of the best decision that I have taken in my career. After working for 2.5 year in different department and now working for one of the top company in the world in design field. This happened only because BIT. My course instructor explained the topics with many examples and hands-on experience. His in-depth knowledge, along with his technique of explaining things thoroughly, Thanks to the support team for quickly resolving our queries. Thanks, BIT!" Best SolidWorks training given by BIT.

User Image
Dhiraj Gandhi

According to my view, BIT is the best institute where anyone can learn to develop their own design from beginning. The professors over here are likely our friend and also tough in the same manner . Here one can easily experience the live working environment ( the level of project is very much good ). If you were looking forward for designing please do prefer this institute. Thank you for great support and great knowledge. My Skills are – AutoCAD, SolidWorks, Fusion 360, Autodesk HSM, Vault etc

|| Average salary of SolidWork in India

The average salary of professionals with SolidWorks skills in India varies depending on their level of experience, education, and the industry they work in. Here’s a general overview of the salary ranges at different career stages:

  • Entry-Level (0-2 years of experience): ₹2.5 - ₹4.5 lakhs per annum. At this level, professionals typically perform basic design tasks, create detailed 2D and 3D models, and assist senior engineers with projects.
  • Mid-Level (2-5 years of experience): ₹4.5 - ₹8 lakhs per annum. Mid-level professionals take on more complex design responsibilities, manage parts of projects independently, and may begin to specialize in areas such as simulation or sheet metal design.
  • Senior-Level (5-10 years of experience): ₹8 - ₹15 lakhs per annum. Senior-level professionals lead design projects, oversee junior engineers, and work closely with manufacturing and other departments to ensure the feasibility and quality of designs.
  • Managerial Level (10+ years of experience): ₹15 - ₹25 lakhs per annum. Managers are responsible for overseeing entire design teams, managing multiple projects, coordinating with other departments, and ensuring that all design work aligns with company goals and standards.
  • Specialized Roles: ₹10 - ₹20 lakhs per annum. These roles often require advanced expertise in specific areas of SolidWorks, such as simulation, analysis, or advanced surface modeling, and professionals in these positions are highly valued for their specialized skills.


These figures are approximate and can vary based on factors such as the specific industry, company size, location, and individual qualifications. For instance, professionals in metropolitan areas like Bangalore, Mumbai, or Delhi may command higher salaries due to the higher cost of living and demand for skilled engineers in these regions. Additionally, certifications, advanced degrees, and specialized training can also impact salary levels.

 

|| Job Roles and Salary 

SolidWorks course job roles,SolidWorks Course job roles ,design engineer ,product designer ,cad drafter ,R&D Engineer

Certificate

|| Some Prominent Companies in India that used SolidWorks

Several companies across various industries in India use SolidWorks for their design and engineering needs. These companies range from large multinational corporations to medium and small enterprises. Here are some notable examples:


  • Tata Motors: A major player in the automotive industry, Tata Motors uses SolidWorks for vehicle design and development.
  • Mahindra & Mahindra: Another automotive giant, Mahindra & Mahindra, utilizes SolidWorks for designing their range of vehicles and components.
  • Larsen & Toubro (L&T): A prominent engineering and construction company, L&T uses SolidWorks for various engineering and infrastructure projects.
  • Godrej Group: Known for its diverse product range, Godrej uses SolidWorks in their consumer goods and industrial products divisions.
  • Bajaj Auto: One of India's leading motorcycle manufacturers, Bajaj Auto employs SolidWorks for designing motorcycles and automotive components.
  • Ashok Leyland: A major manufacturer of commercial vehicles, Ashok Leyland uses SolidWorks for designing trucks and buses.
  • Tata Technologies: This engineering and design services provider uses SolidWorks to offer solutions to clients in automotive, aerospace, and other sectors.
  • Honeywell India: A technology and manufacturing company, Honeywell uses SolidWorks for product development in their aerospace and automation divisions.
  • Bosch India: A global leader in engineering and electronics, Bosch uses SolidWorks for designing automotive components and industrial products.
  • Siemens India: Known for its engineering solutions, Siemens uses SolidWorks for various design and manufacturing applications.
  • GE India: General Electric uses SolidWorks in their healthcare, energy, and aviation divisions for product design and development.
  • Kirloskar Group: This engineering conglomerate uses SolidWorks for designing pumps, engines, and other industrial products.
  • TVS Motor Company: One of the leading two-wheeler manufacturers in India, TVS Motor Company uses SolidWorks for motorcycle design.
  • Wipro Infrastructure Engineering: This division of Wipro uses SolidWorks for hydraulic cylinders and other industrial products.
  • Blue Star: A leading air conditioning and commercial refrigeration company, Blue Star employs SolidWorks for product design and development.

These companies illustrate the widespread adoption of SolidWorks in India across various sectors, including automotive, aerospace, consumer goods, industrial products, and engineering services. Proficiency in SolidWorks can lead to career opportunities in these and many other organizations.

 

|| Top Hiring Companies

Hiring Companies ,Top Companies ,Job Placement ,L&T ,TATA ,MAHINDRA,HAVELS ,SUZUKI ,HYUNDAI,ONGC ,Top Hiring Companies at BIT ,Top Placement Opportunities at BIT

Certificate

|| Get SolidWorks Certification Training

Three easy steps will unlock your SolidWorks Certification:

 

  • Finish the online / offline course of SolidWorks Course and the Assignment
  • Take on and successfully complete a number of industry-based Projects
  • Pass the SolidWorks certification exam

 

The certificate for this SolidWorks Course will be sent to you through our learning management system, where you can also download it. Add  a link to your certificate to your CV or LinkedIn profile.

 

 

Certificate

|| Frequently asked question

SolidWorks is a computer-aided design (CAD) software used extensively in engineering, product design, and manufacturing. It allows users to create, simulate, and manage complex 3D models and technical drawings.

A SolidWorks course is ideal for mechanical engineers, product designers, manufacturing engineers, CAD technicians, and anyone involved in the design and development of physical products.

Yes, SolidWorks offers several certification exams, such as the Certified SolidWorks Associate (CSWA) and Certified SolidWorks Professional (CSWP), which validate your skills and knowledge in using the software.

Benefits include: Enhanced design and modeling skills Improved job prospects and career advancement Ability to create detailed and accurate 3D models Proficiency in using advanced simulation tools to test and validate designs Streamlined design processes and improved efficiency in project workflows

Yes, many training providers offer online SolidWorks courses, which can be self-paced or instructor-led, providing flexibility for learners to study from anywhere.

Projects typically include creating 3D models of mechanical parts, developing complex assemblies, generating detailed technical drawings, and performing simulations to test design performance.
-->