Design of Electric Vehicle Batteries

Course Overview

What does this course tell?
(Please note that the following overview content is from the original platform)
For centuries, humankind has relied on fossil fuel to power their machines, from tools to vehicles. The internal combustion engine, for example, revolutionised the automotive industry. But now, fossil fuel deposits are depleting, the price of petrol and diesel is rising and the excess of vehicles in big cities is contributing to pollution. For this reason, big manufacturing countries, such as China and the United States, are pushing automakers to produce more electric vehicles. As a result, there is a need for engineers with a background in electric vehicle technology. This course will help you understand how to build the power-core of electric vehicles: the battery pack. This knowledge will be useful not only in designing batteries for electric vehicles but any other type of electric-powered machines.
The first thing you will learn in this course is how to measure essential battery parameters. You will also understand the role of charge and discharge rates. Next, you will study the chemical composition of batteries. Special attention will be given to the lithium-ion battery, the battery of choice for electric vehicles, and why this battery's chemical properties separate it from other batteries. You will then learn about battery cells and how there are three different types of cells that form what we know as a ‘battery pack’ when assembled. You will understand how to compute the amount of energy, known as ‘battery capacity’, stored in an assembled battery pack, estimate the amount of charge and discharge cycles that a battery pack has left and determine battery health.
Finally, you will learn how to assemble a safe and reliable battery pack, following an excellent mechanical, thermal and electrical design. When you study a battery pack’s mechanical design, you will review stress-strain theory to understand the forces that act on a battery pack, such as tension force. Selecting materials based on their properties to build a battery pack container using a material index is critical. When you study the thermal design of a battery pack, you will learn how to design a good thermal management system, calculate the amount of energy a battery loses due to heat and calculate different materials' thermal resistance. If your interests are in automotive technology, mechanical or electrical engineering, this course is for you. Why wait? Start this ‘Design of Electric Vehicle Batteries’ course today and equip yourself with the knowledge needed to design and build electric vehicles batteries.


We considered the value of this course from many aspects, and finally summarized it for you from two aspects: skills and knowledge, and the people who benefit from it:
(Please note that our content is optimized through artificial intelligence tools and carefully reviewed by our editorial staff.)
What skills and knowledge will you acquire during this course?
During this course, learners will acquire the following skills and knowledge:
1. Measurement of essential battery parameters: Learners will understand how to measure important battery parameters, such as voltage, current, and resistance.
2. Charge and discharge rates: Learners will comprehend the role of charge and discharge rates in battery performance and efficiency.
3. Chemical composition of batteries: Special focus will be given to the lithium-ion battery, including its unique chemical properties that differentiate it from other battery types.
4. Battery cells: Learners will study the three different types of cells that make up a battery pack and understand their assembly process.
5. Battery capacity estimation: Learners will learn how to compute the amount of energy stored in a battery pack, known as battery capacity, and estimate the remaining charge and discharge cycles.
6. Battery health assessment: Learners will be able to determine the health of a battery pack and assess its remaining lifespan.
7. Mechanical design of battery packs: Learners will review stress-strain theory and understand the forces acting on a battery pack, such as tension force. They will also learn how to select materials based on their properties to build a safe and reliable battery pack container.
8. Thermal design of battery packs: Learners will learn how to design an effective thermal management system for a battery pack, calculate energy losses due to heat, and evaluate different materials' thermal resistance.
By completing this course, learners will be equipped with the necessary knowledge and skills to design and build electric vehicle batteries, as well as batteries for other electric-powered machines. This course is particularly beneficial for those interested in automotive technology, mechanical engineering, or electrical engineering.
Who will benefit from this course?
This course will benefit engineers and professionals in the fields of automotive technology, mechanical engineering, and electrical engineering. Specifically, individuals who are interested in electric vehicle technology will find this course valuable. It will provide them with the knowledge and skills necessary to design and build electric vehicle batteries. Additionally, professionals involved in the manufacturing and production of electric vehicles will benefit from this course as it will enhance their understanding of battery technology and enable them to contribute to the development of more efficient and reliable electric vehicles.