Certification Course in 2W Electric Vehicle Design & Modeling with SOLIDWORKS
The “Certification Program in Electric Vehicle Modeling and Design with SOLIDWORKS” offers a comprehensive guide to designing a two-wheeler using SolidWorks. You’ll start by mastering the basics of 3D modeling and gradually move on to designing key components like the frame, suspension, swing arm, wheels, motor controller casing, and steering system. The course emphasizes integration and assembly, ensuring all parts fit and function cohesively. By the end, you’ll have a fully designed, production-ready two-wheeler, equipped with the skills to create complex models in SolidWorks.
At a glance
- Launching Soon! Stay Tuned!!
- 7 Modules
- 36 Lectures
- 10 Hours of video content.
- Quiz with Solutions
- Project Assignment
- Certification of Completion.
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LevelIntermediate
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Duration25 hours
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Enrollment validityEnrollment validity: Lifetime
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CertificateCertificate of completion
Course Curriculum
Welcome to the Course!
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Sign up on ev.care to access free learning materials & Q&A support!
00:00
Module 1: Introduction and Basics
This module introduces the fundamentals of SolidWorks and the initial steps in designing a two-wheeler (2W). You will learn about the SolidWorks user interface, essential tools, and basic design principles. The module covers basic 3D modeling techniques, including sketching, creating basic shapes, and assembling simple parts to form the foundation of a 2W model.
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15:52
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Lecture 2: Starting with 2W Modeling using SOLIDWORKS
16:26
Module 2: Chassis/Frame and Suspension Design
In this module, you will focus on designing the main structural components of the two-wheeler, specifically the frame and suspension system. You will learn how to create a robust and optimized frame, followed by detailed instructions on designing and assembling the suspension components to ensure proper vehicle dynamics and stability.
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Lecture 3: Designing Chassis/Frame with SOLIDWORKS
16:09 -
Lecture 4: Designing Suspension with SOLIDWORKS Part 1
16:32 -
Lecture 5: Designing Suspension with SOLIDWORKS Part 2
17:16 -
Lecture 6: Designing Suspension with SOLIDWORKS Part 3
08:18
Module 3: Swing Arm Design
This module delves into the design of the swing arm, a critical component for the rear wheel suspension of the 2W. You will explore the intricacies of swing arm design, including structural considerations, material selection, and integration with the rest of the suspension system to ensure durability and performance.
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Lecture 7: Designing Swing Arm with SOLIDWORKS Part 1
19:44 -
Lecture 8: Designing Swing Arm with SOLIDWORKS Part 2
12:18 -
Lecture 9: Designing Swing Arm with SOLIDWORKS Part 3
10:12
Module 4: Wheel Design
Wheel design is the focus of this module, where you will learn to create alloy wheels for the two-wheeler. The lectures cover the basics of wheel geometry, material considerations, and advanced design features. You will also ensure that the wheels are both aesthetically pleasing and functional within the overall 2W model.
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Lecture 10: Designing Allow Wheels with SOLIDWORKS Part 1
15:14 -
Lecture 11: Designing Allow Wheels with SOLIDWORKS Part 2
16:54 -
Lecture 12: Designing Allow Wheels with SOLIDWORKS Part 3
20:28
Module 5: Motor Controller Casing and Steering
This module covers the design of the motor controller casing and the steering mechanism. You will learn how to create a protective and efficient casing for the motor controller, considering aspects like cooling and ease of assembly. The steering design part focuses on ensuring control, maneuverability, and user comfort.
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Lecture 13: Designing Motor Controller Casing with SOLIDWORKS Part 1
19:23 -
Lecture 14: Designing Motor Controller Casing with SOLIDWORKS Part 2
15:24 -
Lecture 15: Designing Motor Controller Casing with SOLIDWORKS Part 3
15:56 -
Lecture 16: Designing 2W Steering with SOLIDWORKS Part 1
10:28 -
Lecture 17: Designing 2W Steering with SOLIDWORKS Part 2
20:14
Module 6: Integration and Assembly
Integration and assembly of various components designed in previous modules are the primary focus here. You will learn to integrate wheels, steering components, battery casing, and the 2W seat into the overall design. This module emphasizes ensuring that all parts fit together correctly and function as intended, leading to a cohesive and functional 2W system.
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Lecture 18: Integrating 2W Components in SOLIDWORKS
19:20 -
Lecture 19: Assembling 2W Components in SOLIDWORKS
16:24 -
Lecture 20: Integrating Wheels and Steering Components in SOLIDWORKS
21:48 -
Lecture 21: Integrating Battery Casing Components in SOLIDWORKS
14:50 -
Lecture 22: Modeling 2W Seat in SOLIDWORKS Part 1
19:45 -
Lecture 23: Modeling 2W Seat in SOLIDWORKS Part 2
19:45 -
Lecture 24: Integrating 2W Seat in SOLIDWORKS
17:47
Module 7: Final Assembly and Details
The final module covers the assembly of dynamic components and the finishing touches on the two-wheeler design. You will focus on assembling primary components, designing and integrating the front and back panels, headlight, and wheel support. The module concludes with a comprehensive review and final adjustments to ensure the model is production-ready, ensuring all components work together seamlessly and meet design specifications.
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Lecture 25: 2W Dynamics Assembly Part 1
11:09 -
Lecture 26: 2W Dynamics Assembly Part 2
16:04 -
Lecture 27: Assembling Primary Components with 2W System
18:45 -
Lecture 28: Assembling Foot Rest in SOLIDWORKS
17:16 -
Lecture 29: Designing Front Panel with SOLIDWORKS Part 1
17:27 -
Lecture 30: Designing Front Panel with SOLIDWORKS Part 2
16:51 -
Lecture 31: Designing Front Panel with SOLIDWORKS Part 3
14:16 -
Lecture 32: Designing Headlight with SOLIDWORKS
16:40 -
Lecture 33: Designing Wheel Support in SOLIDWORKS
19:57 -
Lecture 34: Designing Back Panel in SOLIDWORKS Part 1
16:16 -
Lecture 35: Designing Back Panel in SOLIDWORKS Part 2
16:12 -
Lecture 36: Finalizing 2W Design in SOLIDWORKS
23:55
DIY Projects:
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Project 1: Comprehensive Design and Analysis of an EV Bike Chassis and Suspension System.
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Project 2: Design and Integration of Swingarm, Alloy Wheels, and Motor Controller for an EV Bike.
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Congratulations on Successfully Completing the Course!
00:00
Earn a certificate
Add this certificate to your resume to demonstrate your skills & increase your chances of getting noticed.
Hardware & Software Required
Hardware: A computer with a robust processor (preferably Intel i5 or AMD Ryzen 5 and above), at least 8 GB RAM for smooth operation of SOLIDWORKS.
Software: SOLIDWORKS (preferably the latest version), compatible operating system (Windows 10 or later).
DIY Projects Included
Project 1: Comprehensive Design and Analysis of an EV Bike Chassis and Suspension System
The project will involve designing and analyzing the chassis and suspension system for an EV bike, including component selection, system modeling, and performance analysis using SOLIDWORKS. Students will present their projects, demonstrating their ability to apply theoretical knowledge to practical scenarios and showcasing their problem-solving and design skills.
Project 2: Design and Integration of Swingarm, Alloy Wheels, and Motor Controller for an EV Bike
The project will involve designing and integrating the swingarm, alloy wheels, and motor controller for an EV bike, including component selection, system modeling, and assembly using SOLIDWORKS. Students will present their projects, demonstrating their ability to apply theoretical knowledge to practical scenarios and showcasing their problem-solving and design skills.
Course Benefits
For Professionals:
- Enhance expertise in EV bike design and modeling using SOLIDWORKS.
- Broaden career prospects with specialized knowledge in chassis, suspension, and component design.
- Stay updated with the latest design and simulation tools in the EV industry.
For Freshers:
- Acquire in-demand skills for a career in EV bike design and modeling.
- Build a strong foundation in SOLIDWORKS for designing key EV components.
- Increase employability with hands-on project experience and industry-relevant knowledge.
Technical expertise you will gain
Technical Expertise: Develop a comprehensive understanding of EV modeling using SOLIDWORKS, focusing on key components and assembly.
Chassis and Suspension Design: Master the parameters, key components, and design process of chassis and suspension systems for EV bikes.
Swingarm and Alloy Wheel Design: Gain expertise in designing swingarm and alloy wheels, utilizing 2D drawing features in SOLIDWORKS.
Tire and Motor Controller Design: Learn to design and assemble tires, swingarms, motor controllers, and DC to DC converters for EV bikes.
Handlebar and Final Assembly: Develop skills in designing handlebars, assembling parts, and integrating components into a final EV bike assembly.
Simulation and Analysis: Perform comprehensive design and analysis of EV bike components and systems using SOLIDWORKS.
Industry Readiness: Be prepared for various roles in the EV industry with a comprehensive skill set in SOLIDWORKS modeling and design.
Career Readiness: Be prepared for various roles in engineering and technology with a comprehensive understanding of EV bike design and modeling.
- EV Bike Chassis Design
- Suspension System Design
- Swingarm and Alloy Wheel Design
- Tire and Motor Controller Design
- Handlebar and Final Assembly Design
- EV Component Modeling and Simulation
- EV Bike Chassis Designer
- Suspension System Engineer
- Swingarm and Alloy Wheel Designer
- Tire and Motor Controller Engineer
- Handlebar and Final Assembly Engineer
- SOLIDWORKS Modeler and Simulation Specialist
- Proficiency in SOLIDWORKS for EV bike modeling and design.
- Expertise in chassis and suspension system design.
- Ability to design swingarms and alloy wheels.
- Skills in tire fitting and motor controller design.
- Competence in final assembly and aesthetic integration of EV bikes.
- Knowledge of simulation and analysis using SOLIDWORKS.
- Hero MotoCorp
- Bajaj Auto
- TVS Motor Company
- Ather Energy
- Ola Electric
- Ultraviolette Automotive
- Revolt Motors
- Tork Motors
- Lohia Auto
- Ampere Vehicles
Who can take this course?
The Learners should have an optional fundamental understanding of engineering design principles and mechanical systems.
- Freshers
- Professionals
Personalized Trainer Support Portal:
- 24/7 Access to a personalized trainer support portal.
- One-on-One Mentorship for queries and project guidance.
- Access to diverse resources, including recorded lectures, reading materials, and practical guides.
- Dedicated forums for content discussion, insights, and project collaboration.
- Regular Feedback from trainers for comprehensive understanding and improvement.
At a glance
- Launching Soon! Stay Tuned!!
- 7 Modules
- 36 Lectures
- 10 Hours of video content.
- Quiz with Solutions
- Project Assignment
- Certification of Completion.
-
LevelIntermediate
-
Duration25 hours
-
Enrollment validityEnrollment validity: Lifetime
-
CertificateCertificate of completion
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