Interactive scenarios offer hands-on learning experiences that equip users with essential skills for safely maintaining, assembling, and troubleshooting electric and hybrid vehicle systems. Through practical applications, each scenario guides users step-by-step, emphasizing safety measures and the correct use of tools and equipment. From mastering vehicle locking mechanisms and diagnosing complex electronics to learning battery charging procedures and assembling motors, these scenarios provide valuable insight into electric vehicle technology. Participants gain foundational expertise, allowing them to approach real-life maintenance and repair tasks confidently, fostering efficiency, and supporting a sustainable future in automotive technology.
Safety is crucial during high-voltage electrical maintenance. Vehicle locking scenario covers essential electrical safety steps and post-maintenance measures that must be followed when servicing hybrid and electric vehicles.
Vehicle locking scenario is designed to give users a comprehensive understanding of vehicle locking systems through practical applications. It provides detailed information to ensure a safe and efficient maintenance process, focusing on enhancing safety during electric vehicle maintenance.
Fuel cell and battery charging procedures aim to educate users in order to identify and repair malfunctions that may occur in the fuel cells and battery charging systems of hybrid and electric vehicles.
Users are expected to gain the ability to increase the efficiency and ensure the safety of the systems by learning charging processes and maintenance requirements. Provided content offers an effective learning experience by combining both theoretical knowledge and practical applications.
Electric vehicle conversion and retrofit technologies aim to provide users with information on converting conventional vehicles to electric vehicles.
Focus of the content is on planning, implementation and management of successful transformation projects. Users will be able to develop the skills necessary to tackle the complexity of electric vehicle conversion and ensure efficiency and sustainability in their projects.
Autonomous and advanced driver assistance systems scenario aims to provide information and practical experience on adjusting and optimizing camera sensors used in Autonomous and Advanced Driver Assistance Systems (ADAS) technologies.
Correct adjustment of these sensors is critical to improve driver safety and optimize system performance. This process will help users understand ADAS systems more effectively.
Vehicle communication technologies scenario aims to help users understand vehicle communication technologies. It was specifically designed to teach how to measure CAN Bus (Controller Area Network).
By performing these measurements, users will better understand the functioning of the system and gain the ability to effectively analyze data transmission between vehicles. Additionally, this information will play an important role in vehicle maintenance processes.
Scenario teaches users how to handle high-voltage risks and apply essential safety measures in automotive electronics. It focuses on recognizing potential hazards during maintenance and following the necessary precautions to ensure safety for both personnel and vehicle systems.
Practical examples and step-by-step guidance are provided to help users develop the skills required to safely perform maintenance tasks. Techniques learned aim to enhance both safety and efficiency when dealing with high-voltage systems, ensuring proper risk management and secure handling during troubleshooting and repair procedures.
Maintenance and troubleshooting scenario provides essential information on safety precautions and high-voltage risks in automotive electronics. Emphasis is placed on recognizing potential hazards during maintenance and learning the necessary steps to create a safe working environment.
Users will develop an understanding of the precautions required to reduce risks, allowing them to approach maintenance tasks more consciously and carefully. Knowledge gained ensures safer and more effective handling of automotive electronics during troubleshooting and repair processes.
Vehicle diagnostics and troubleshooting scenario covers the process of diagnosing malfunctions in electric and hybrid vehicles for users.
Scenario includes topics such as identifying the problem, observing it, measuring and testing procedures, determining the sources of the problems, understanding error codes. Practical examples and guidance are provided throughout the scenario to enhance understanding of the topic.
AC charging station disassembly scenario provides an immersive experience within a VR training module. It guides users through the systematic process of disassembling AC charging stations.
Participants will learn essential techniques while identifying potential hazards and ensuring safety protocols are followed. Hands-on approach enhances understanding of the components involved and reinforces proper maintenance practices, preparing users for real-world applications in electric vehicle infrastructure.
AC charging station assembly scenario serves as a VR training module, focusing on the detailed step-by-step process required to assemble AC charging stations. Users will gain hands-on experience, enhancing their skills in the assembly process.
Training emphasizes safety protocols and best practices, ensuring that participants understand the intricacies of assembly and maintenance. Immersive learning experience prepares users for real-world applications in electric vehicle infrastructure development.
Electric vehicle assembly scenario is designed to teach users the detailed, step-by-step process of assembling an electric vehicle. Users acquire practical knowledge of vehicle structure and assembly techniques by learning to position and integrate pre-prepared components accurately.
Emphasis is placed on accuracy and attention to detail at each stage of assembly, ensuring proper vehicle operation. By following the assembly process, users enhance their ability to assemble electric vehicles efficiently and precisely, furthering their understanding of electric vehicle systems.
Asynchronous motor disassembly scenario aims to teach users the disassembly process of asynchronous motors. Scenario also explains how to carefully remove engine components and the function of each part is.
Users will have the opportunity to improve their practical skills by getting to know the internal structure of the engine and learning the important points to be considered during the disassembly process.
Asynchronous motor assembly scenario aims to teach users the assembly process of asynchronous motors step by step. Scenario focuses on guiding users in the assembly of engine components.
By completing the scenario, users will develop basic skills in using and aligning parts, following assembly instructions correctly and addressing common problems that may arise during motor assembly, contributing to a comprehensive understanding of induction motor systems.
Scenario of DC charging station disassembly for VR training module is designed to teach users how to disassemble the DC charging station step by step.
Throughout the process, stages such as safety precautions and use of correct equipment are discussed in detail. Thanks to this module, users learn to assembly and disassembly processes of DC charging stations and also have the opportunity to improve their technical knowledge and skills.
DC charging station assembly scenario provides a guided experience in assembling components within a VR training module.
Training emphasizes the development of technical skills, focusing on precise component assembly, secure connections, and adherence to safety standards. By completing the scenario, users deepen their knowledge of DC charging station installation. Additionally, participants enhance their problem-solving skills to address any challenges that may arise during the installation process.
Hub motor disassembly scenario guides users through the step-by-step process of dismantling hub (wheel hub) motors. By familiarizing themselves with engine components, users learn to safely separate parts and understand the function of each component within the engine.
Participants develop skills to improve the efficiency of electric vehicle engines by strengthening their maintenance and troubleshooting abilities. By the end of the scenario, they build confidence in safely and effectively disassembling hub motors.
Scenario aims to teach users the step-by-step process of assembling hub motors (wheel hub motors). Training focuses on the assembly of parts and ensuring efficient motor operation.
Participants will learn the key points to consider during assembly and how to prevent potential errors, gaining a critical skill in electric vehicle maintenance. These skills are designed to improve motor performance and overall vehicle reliability. Additionally, users will gain hands-on experience that reinforces theoretical knowledge with practical application.
Scenario teaches safe procedures for removing and reactivating locks on hybrid and electric vehicles. Mechanical and electronic lock systems are explored, with an emphasis on essential safety precautions during the removal process.
Practical tips and step-by-step instructions guide the execution of lock removal, aiming to enhance both efficiency and safety. Techniques learned provide effective management of lock systems during maintenance, ensuring secure handling and reactivation throughout the process.
Scenario introduces users to the step-by-step process of disassembling permanent magnet (PM) motors. Users gain insights into PM motors, a key component in electric vehicles, exploring their internal structure and understanding how each part interacts.
Proper techniques and safety procedures are emphasized throughout the scenario to ensure each step is completed carefully and precisely. By applying the disassembly process, users strengthen their understanding of motor construction and develop essential technical skills for electric vehicle systems.
Scenario guides users through each step involved in assembling permanent magnet (PM) motors. Users acquire knowledge of how to align and combine motor parts accurately, focusing on points critical for achieving optimal motor performance.
Emphasis is placed on accuracy and attention to detail during assembly, which enhances both performance and reliability. By completing the assembly process, users refine practical motor assembly skills, contributing to effective and safe electric vehicle operation.
Scenario provides a detailed guide on the step-by-step disassembly process for synchronous motors. Users learn safe methods for removing each component, gaining a clear understanding of the motor's internal structure and operating principles. Knowledge of how each part contributes to the overall performance of synchronous motor systems is also developed.
Proper disassembly techniques and safety protocols are highlighted throughout, ensuring careful completion of each step. Applying these techniques, users enhance their technical skills in motor disassembly, which is essential for effective maintenance of electric vehicle systems.
Scenario teaches users the precise steps required for assembling synchronous motors. Detailed guidance is provided on aligning and combining motor components correctly, with an emphasis on the importance of attention and care at each stage of assembly.
By mastering these assembly techniques, users build practical skills in working with synchronous motors, which contribute to their technical expertise in electric vehicle maintenance and enable effective and safe motor assembly.
Theory test scenario helps users learn the correct selection of tools and equipment required for electric vehicle maintenance. Recognizing the characteristics of the tools used in electric vehicle servicing is crucial for safe and efficient work.
Throughout the scenario, users will develop their ability to choose the right tools for various maintenance tasks. This test helps them understand the importance of proper maintenance procedures for vehicle safety and long-term performance.