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Power type lithium batteries, also known as power lithium batteries, are mainly characterized by supporting high rate charging and discharging, which can reach over 10C. The main consideration is the specific function (W/kg).
The main characteristic of a capacity type is its specific energy (Wh/kg).
For example:
If the capacity type is similar to a marathon runner, endurance is required, but high capacity is required and high current discharge performance is not required; So the power type is a sprinter who strives for burst power, but also needs endurance, otherwise if the capacity is too small, they won't be able to run far. Power energy type lithium batteries emerged with the emergence of plug-in hybrid vehicles. It requires the battery to store a high amount of energy, support pure electric driving for a distance, and also have good power characteristics to enter hybrid mode when the battery is low.
Capacity based batteries emphasize that batteries should have high capacity, and the charging and discharging current may not be large; Power type batteries emphasize the need for batteries to withstand high charging and discharging currents (i.e., high power). Because it is difficult to have both, there is such a classification.
Combination method: ICR18500-3S2P nominal voltage: 11.1V discharge voltage: 11.1V-12.6V conventional discharge current is 0-2A large capacity is 3-4A nominal capacity: in MahA units, there are multiple sizes standard continuous discharge current: 0.2C maximum continuous discharge current: 1C working temperature: charging: 0-45 ℃ discharge: -20~60 ℃ product size: MAX39 * 56.6 * 99mm finished product internal resistance: ≤ 280m Ω standard weight: protection board: IC-S8254AAJ+MOS-AO4409 lead model: JST-VHR-2P forward plug UL1007/24 # line, line length 100mm protection parameters: overcharge protection voltage/each string 4.35 ± 24 #. 0.025V over discharge protection voltage 2.4 ± 0.08V over current value: 10-25A12V lithium battery specification parameters: voltage: 12V battery capacity: There is no standard capacity, which is determined according to the specific requirements of the appliance or equipment. The general capacity is 2200ma/h, 5AH, 10Ah, etc, Some electric vehicles have a capacity of up to 20AH or 50AH. The more batteries are connected in parallel, the larger the capacity. According to the physics formula, in a parallel circuit, I total=I1+I2+I3 volume: The volume of a 12V lithium battery needs to be determined based on the capacity of the battery, and there is no unified specification. The larger the battery capacity, the larger the volume and weight: Nowadays, many devices require lithium batteries with larger capacity and lighter weight, such as electric vehicles. Previously, lead-acid batteries were used, but now many electric vehicles have become lithium batteries because lithium batteries have larger capacity, lighter weight, and smaller size. Charging and discharging current: The charging and discharging current of a lithium battery is determined based on the power of the device, and the electric power formula is P=UI. On the basis of a constant voltage, the greater the power of the device, the greater the required output current. 12V lithium battery applications: electric vehicles, power tools, laptops, mobile DVDs, UPS, GPS, medical equipment, etc
Battery capacity is one of the important performance indicators for measuring battery performance. It represents the amount of electricity released by the battery under certain conditions (discharge rate, temperature, termination voltage, etc.) (JS-150D can be used for discharge testing), which is the capacity of the battery. It is usually measured in ampere hours (abbreviated as A · H, 1A · h=3600C).
The battery capacity is divided into actual capacity, theoretical capacity, and rated capacity according to different conditions. The calculation formula for battery capacity C is C=Δ t0It1dt (integrating current I within t0 to t1 time), and the battery is divided into positive and negative poles.
The battery capacity is divided into actual capacity, theoretical capacity, and rated capacity according to different conditions.
The minimum capacity required to discharge at 25 ℃ to the termination voltage at a certain discharge rate is the specified capacity of the battery during design and production, which is called the rated capacity of a certain discharge rate RH.
Square lithium-ion battery
Square lithium-ion battery
The battery capacity is generally calculated in AH (ampere hours), and another method is to calculate in watts (W) per cell. (W/CELL)
1. Ah (ampere hour) calculation, discharge current (constant current) I x discharge time (hour) T. For example, if the continuous discharge current of a 7AH battery is 0.35A, the time can be continuous for 20 hours.
2. The charging time is based on 15 hours, and the charging current is 1/10 of the battery capacity. Fast charging will reduce the battery life.
Battery capacity refers to the amount of electricity stored by the battery. The unit of battery capacity is "mAh", and the Chinese name is milliampere hour (for convenience when measuring large capacity batteries such as lead-acid batteries, "Ah" is generally used, and the Chinese name is ampere hour, with 1Ah=1000mAh). If the rated capacity of the battery is 1300mAh, that is, a current of 130mA is used to discharge the battery, then the battery can operate continuously for 10 hours (1300mAh/130mA=10h); If the discharge current is 1300mA, the power supply time is only about 1 hour (the actual working time may vary due to individual differences in the actual capacity of the battery). This is an ideal analysis. The actual current of a digital device during operation cannot always be constant at a certain value (taking a digital camera as an example, the working current will undergo significant changes due to the opening or closing of components such as LCD screens and flash lights). Therefore, the power supply time that a battery can provide to a certain device can only be an approximate value, and this value can only be estimated through practical operating experience.
Usually, we talk about battery capacity in ampere hours, which is based on a specific battery that has already been determined.
For example, what is the battery capacity of this mobile phone; The capacity of this electric vehicle battery is determined by different batteries. The battery voltage has been determined without considering the actual voltage, and simply stating ampere hours can represent the capacity of this battery.
However, for batteries with different voltages, we cannot simply use ampere hours to represent capacity. For example, a 12V20AH battery, a 15V20AH battery, even if they are both 20AH, can supply the same power load, and the equipment can work normally, but the duration is different. Therefore, the standard capacity should be measured in power.
For example, if a device can support both 12V and 24V, and is powered by a 12V (20AH) battery for one hour, then using two pieces in series will result in 24V (20AH). The ampere hour does not increase, but the duration will double. Therefore, the capacity should be considered based on the power capacity of the battery, rather than just ampere hours.
W (work)=P (power) * T (time)=I (current) * U (voltage) * T (time)
Discussing battery capacity in this way has practical significance and must be truthful. Otherwise, there may be a claim that a mobile phone battery has a larger capacity than a car battery, which is obviously unscientific.
Charge a battery with constant current and voltage, and then discharge it with constant current. The amount of electricity released is the capacity of the battery, such as a nickel hydrogen battery, but not a lithium battery. It has a minimum discharge voltage of 2.75V, which is usually 3.0V as the lower limit protection voltage. For example, if the capacity of a lithium battery is 1000mAh, then the charging and discharging current is 1000mA. When the maximum voltage of the battery is 4.2V and it is placed at 3.0V, the released capacity is the most true capacity of the battery.
The capacity of a battery is an important indicator to measure its performance. It is generally expressed in ampere hours. The total term for discharge time (hours) and discharge current (amperes) is capacity=discharge time x discharge current. The actual capacity of a battery depends on the amount and utilization rate of active substances in the battery. The more active substances there are, the higher the utilization rate of active substances, and the larger the battery capacity. Conversely, the smaller the capacity, the many factors that affect the battery capacity, commonly including the following:
(1) The influence of discharge rate on battery capacity
The capacity of lead-acid batteries decreases with the increase of discharge rate, which means that the larger the discharge current, the smaller the calculated capacity of the battery. For example, a 10Ah battery can be discharged for 2 hours with 5A discharge, which is 5 × 2=10; So using 10A discharge can only release 47.4 minutes of electricity, equivalent to 0.79 hours. Its capacity is only 10 x 0.79=7.9 ampere hours. Therefore, for a given battery to discharge at different time rates, there will be different capacities. When talking about capacity, we must know the discharge rate or multiple. Simply put, it is how much current is used for discharge.
(2) The influence of temperature on battery capacity
The temperature has a significant impact on the capacity of lead-acid batteries. Generally, as the temperature decreases, the capacity decreases. The relationship between capacity and temperature is as follows:
Ct1=Ct2/1+k (t1-t2). t1t2 is the temperature of the electrolyte, k is the temperature coefficient of the capacity, Ct1 is the capacity at t1 (Ah), and Ct2 is the capacity at t2 (Ah). In battery production standards, a temperature is generally specified as the rated standard temperature. If t1 is the actual temperature and t2 is the standard temperature (usually 25 degrees Celsius), the negative electrode plate is more sensitive to low temperatures than the positive electrode plate. When the electrolyte temperature decreases, the viscosity of the electrolyte increases, ions are subject to greater resistance, diffusion ability decreases, and electrolyte resistance also increases, resulting in electrochemical resistance. Increase, some lead sulfate cannot be converted normally. The charging capacity decreases, resulting in a decrease in battery capacity
(3) The effect of termination voltage on battery capacity
When the battery is discharged to a certain voltage value, the voltage drops sharply, and in fact, the energy obtained is very small. If it is discharged deeply for a long time, the damage to the battery is considerable. Therefore, it is necessary to terminate the discharge at a certain voltage value, which is called the discharge termination voltage. Setting the discharge termination voltage is of great significance for extending the service life of the battery. Generally, the discharge termination voltage of the electric motorcycle battery we repair is 1.75 volts per cell, which means that a 12 volt battery is 6 cells, and its discharge termination voltage is 6 x 1.75=10.5 volts [2]
(4) The influence of the geometric dimensions of the electrode plate on the battery capacity
When the amount of active substance is constant, the geometric area of the electrode plate in direct contact with the electrolyte increases, leading to an increase in battery capacity. Therefore, the influence of the geometric size of the electrode plate on battery capacity cannot be ignored
① The influence of plate thickness on capacity
The amount of active substance is constant, and the battery capacity decreases with the increase of electrode thickness. The thicker the electrode, the smaller the contact surface between sulfuric acid and active substance, the lower the utilization rate of active substance, and the smaller the battery capacity
② The influence of electrode height on capacity
In batteries, there is a significant difference in the utilization efficiency of active substances between the upper and lower parts of the electrode plate. Experiments have shown that in the early stages of discharge, the current density in the upper part of the electrode plate is about 2 to 2.5 times higher than that in the lower part. This difference gradually decreases as discharge progresses, but the current density in the upper part is higher than that in the lower part
③ The influence of plate area on capacity
When the amount of active substance is constant, the larger the geometric area of the electrode plate, the higher the utilization rate of the active substance, and the larger the capacity of the battery. When the battery shell is the same and the quality of the active substance remains unchanged, using a thin electrode plate to increase the number of electrode plates increases the effective reaction area of the electrode plate, thereby improving the utilization rate of the active substance and increasing the capacity of the battery.
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