Introduction To the Components of Lithium-Ion Battery Power Pack

Future of mobility is Electric Vehicles. By switching to EVs, India will curb its CO2 emissions by one Giga tons by 2030. This feat will translate into less air pollution in metros and mini metros and will keep the present and future generations healthier.
Electric vehicles are the future! The manufacturing companies are putting more effort into moving from traditional vehicles to electric cars. There are plenty of benefits to owning an electric vehicle with the right amount of functionality and infrastructure.
While other internal combustion engines derive energy from burning fuel, electric vehicles receive their power directly from a large battery assortment. In EVs , The Lithium-Ion Battery Used & Compared with traditional battery technology, lithium-ion batteries charge faster, last longer and have a higher power density for more battery life in a lighter package.
It charges fast for convenience and slow for longevity. Lithium is beneficial to cells for three reasons. First, since it rapidly releases its outermost electron, it is reactive, making it simple to get power flow through a cell.
Secondly, lithium is considerably lighter than other elements utilized in cells, such as lead, necessary for small devices such as phones and cars with several batteries. Finally, since lithium ions and electrons quickly move back into negative electrodes, the lithium-ion batteries can get recharged.
When it comes to applications of lithium-ion batteries, They are very good electricity storages, The Li-ion battery (LIB-LFP) functions in the same way as other batteries. The electrodes, on the other hand, are not as highly influenced by chemical processes. While draining, Li-ions move from the negative anode to the positive cathode, and likewise when recharged.
An electric vehicle can now travel 360-450 kilometers on a single charge. The independence of a car will enhance as power density improves, making electric automobiles more feasible.
Formation of 6S2P (6 In Series & 2 In Parallel) Module Assembly for Generating 21.5 volts Battery Module, further to this, it will form 350 volts Battery Power Pack With 39.5 kWh Energy, which will be used for SUV 4W Cars.
Having Cell Capacity ≥ 56Ah & Nominal Voltage range Approx 3.65 V ~ 3.68 V, Also Operating Voltage Range 2.8 V ~ 4.25 V at constant & 2.5 V ~ 4.25 V at peak, this cell will get converted in to 21.5 V Capacity Module Formations.
This Module will get converted in to 350 V System with Battery Power Pack 96S2P (96 In Series & 2 In Parallel) With Nominal Pack Voltage 351.5 V & Maximum Voltage of 398.5 V & Minimum Voltage of 288.5 V
By Assembly Total 16 Nos of Modules of 21.5 V, This Battery Power Pack will form a Pack Capacity of 112 Ah at 1 C Rate of Charging Capacity & Which will generate the Total Energy of 39.5 kWh
This Entire Battery Power Pack Is Nothing but Lithium-Ion Cell Rechargeable Electrical Energy Storage System (RE-ESS) of 350 V @ 39.50 kWh
In order to take decisions on C-rates or power for battery pack in various modes, temperature for battery pack (T_Batt) needs to be defined.
The operating temperature limit of the battery in drive mode should be between -20°C to 55°C.The maximum discharge current and regeneration current are function of temperature and SoC also needs to define.
In drive mode, the battery can be charged with regenerative current. Since the magnitudes of these currents are expected to be high, these might affect the warranty life of battery. Hence, the C- rates of regeneration currents are limited. The operating temperature limit of the battery in drive mode should be between 0°C to 45°C.