Hybrid vehicle technology scenario in the informative scenarios covers the basic components and functions of different hybrid vehicle systems. Participants will gain a solid foundation in understanding how these systems work and how they are integrated in hybrid vehicles. It also highlights the key differences between various hybrid architectures, helping participants better grasp their real-world applications. By the end, they will be able to identify the critical components and their roles in ensuring efficient vehicle operation.
Informative Scenarios >
Scenario provides fundamental information about the operating principles, types, and functions of high-voltage and battery systems in hybrid vehicles. Participants will learn about the components of three different types of hybrid vehicles: complex hybrid, series hybrid, and plug-in hybrid. Through this, they will gain insights into the unique technologies of each type and how they differ in terms of energy efficiency, performance, and design.
Participants will learn about key components of series hybrid, parallel hybrid, and complex hybrid vehicles. These components include electric motors, battery systems, power transmission mechanisms, and energy management systems. Knowledge gained will provide a strong foundation for understanding various hybrid technologies.
Participants will understand the role of each component used in hybrid vehicles. Insights into how battery systems, inverters, motors, and energy storage units function will help grasp the impact of components on vehicle performance.
Participants will learn about variations in design and operation across different types of hybrid vehicles, including SHEV (Series Hybrid Electric Vehicle), where the engine only generates electricity to power the motor; PHEV (Plug-in Hybrid Electric Vehicle), which can be recharged by plugging into an external power source; and CHEV (Combined Hybrid Electric Vehicle), which uses both series and parallel configurations for optimal efficiency.
Participants will learn how critical components like the electric motor, battery, and inverter work together to ensure vehicle movement and energy efficiency. Understanding these interactions will be crucial for addressing maintenance and repair tasks with a system-based approach.