KR102185010B1 - Lithium-ion Battery Charging Method for Correcting and Compensating Voltage - Google Patents

Abstract

The present invention relates to a method of charging a lithium-ion battery for correcting and compensating voltage, and when the voltage of the battery reaches the upper limit voltage U during charging, the charging current is switched to constant voltage charging so that the charging current is 5% of the charging current before the constant voltage. Charging is terminated when the charging current reaches 50% to 99.99% of the charging current before the constant voltage, and charging is terminated when the charging current reaches 50% to 99.99%, and the charging upper limit voltage between the positive electrodes of the battery is U=3Uo-Us. -Uso, of which Uso is the standard stable voltage of the voltage drop of the battery after charging to Uo with a constant current constant voltage, Us is the stable voltage of the voltage drop of the battery after charging to Uo with a constant current, and Uo is the standard charging cutoff voltage to be. The charging method of the present invention rapidly charges an amount of electricity close to a fully charged state; Discharge by standard or user method to have longer cycle life or equal number of cycles; The output capacity is greater during discharge; It is possible to use a constant voltage charging method, which is more suitable for the user charging habits of lithium-ion batteries and more suitable for the selection of charging ICs; Since it is charged up to a predetermined current value in a constant voltage method, it has advantages that are more easily realized.

Description

Lithium-ion Battery Charging Method for Correcting and Compensating Voltage}

The present invention relates to a battery charging method, and more particularly, to a lithium ion battery and a lithium ion polymer battery charging method.

Chinese patent CN101388477B discloses a fast charging method, which is a charging method for a lithium-ion battery that compensates for the voltage drop inside the battery by increasing the upper limit voltage. When charging a lithium-ion battery or a lithium-ion polymer battery, the voltage is the upper limit voltage of charging. When the battery reaches Uo, charging is terminated. The upper limit voltage of battery charging between the positive electrodes of the battery is U=2Uo-Us, of which Us is the stable voltage of the battery voltage drop after charging to Uo with a constant current; Uo is a standard charge cut-off voltage, which is a charge cut-off voltage used in a low-rate constant current-constant voltage charging method commonly used in the industry; The selection of the stable voltage Us measures the time after the constant current charging is terminated and the stationary is started, and the battery starts from a certain time period, and if the voltage drop of the open-circuit voltage within a certain time period is lower than a predetermined value, the voltage of the battery is stable. As reached, the voltage corresponding to the first point in this time period was determined as the stable voltage Us of the battery.

When the above method is applied to a lithium iron anate battery, Uo is a charging cutoff voltage of 3.60V used in a low rate constant current-constant voltage charging method commonly used in the industry, and the battery is charged to the upper limit voltage U = 2Uo-Us. Since the battery cannot be fully charged and reaches only 88% of the full charging voltage, the efficiency of the battery has not been sufficiently increased. The charging cutoff voltage Uo used in the low-rate constant current-constant voltage charging method commonly used in the technology field to which the lithium iron anate battery belongs is 3.50V, 3.65V, and 3.7V. When charging to the upper limit voltage U=2Uo-Us All of them did not fully charge the battery and did not sufficiently increase the efficiency of the battery.

When the above method is applied to a lithium cobalt oxide battery, Uo is a charging cutoff voltage of 4.20V used in a low rate constant current-constant voltage charging method commonly used in the industry, and the battery is charged to the upper limit voltage U = 2Uo-Us. Since the battery cannot be fully charged and reaches only 97% of the full charging voltage, the efficiency of the battery has not been sufficiently increased.

Thus, in order to increase the efficiency of the battery, a certain correction is required for the charging upper limit voltage of the battery.

An object of the present invention is to sufficiently increase the efficiency of the battery by providing a method of charging a lithium ion battery for voltage correction and compensation.

Justice

The ideal charging is to charge the lithium-ion battery in a constant voltage constant current method, cut off the charging circuit, and then open the lithium-ion battery so that the stable voltage reaches the constant voltage charging voltage. Theoretically, charging for a lithium-ion battery of a constant voltage and constant current method is to charge the lithium ion battery with a constant voltage until the current reaches an infinite limit, and after the charging circuit is cut off, the stable voltage of the lithium ion battery can reach the constant voltage charging voltage. will be. In practice, when charging a lithium ion battery of a constant voltage and constant current method, if a constant voltage is charged to the consumption current of the lithium ion battery, the charging current of the lithium ion battery maintains a dynamic balance with the consumption current. After the opening of the lithium battery, the stable voltage may be very close to the constant voltage charging voltage. Standard stable voltage: After charging with a constant current up to Uo with the current specified by the standard or manufacturer, charging with a constant voltage up to the standard or the blocking current specified by the manufacturer, and charging ends: Constant current of the battery When the constant voltage charging is terminated and stationary stationary is started. When the voltage drop of the open-circuit voltage within a certain time period is lower than a predetermined value, the battery has reached a stable state, and the voltage corresponding to the first time in this time period is determined. It is determined by the stable voltage Uso of the battery.

The degree of freedom of lithium ions is the degree to which lithium ions freely act on the anode. During the charging process of the lithium ion battery, lithium ions are desorbed from the positive electrode and inserted into the negative electrode through the electrolyte. Lithium ions are freely distributed in the anode lattice and go to an appropriate position. During the desorption process, lithium ions with a close distance and high degree of freedom are first desorbed, while lithium ions with a long distance and low degree of freedom are later desorbed and the intermittent of the anode is greatly reduced. Receiving lithium ions has a low degree of freedom, making it difficult to desorb, or it requires greater charging energy to desorb.

principle

The charging method suggested by CN101388477B compensates for the voltage drop (Uo-Us) inside the battery by charging and terminating U=2Uo-Us=Uo+ (Uo-Us). The voltage drop (Uo-Us) is It occurred while still after charging to Uo with constant current I; It compensates only the voltage drop of the ohm corresponding to the current I, the concentration difference polarization voltage drop, the electrochemical polarization voltage drop, and other resistance voltage drops, and does not take into account the failure to fully charge Uo with the constant current I. The compensated pressure drop is not an ideal state of charge because it cannot charge the battery to 100% full charge because it does not consider tally. The charging method proposed in CN101388477B does not take into account the effects of errors in equipment and measurements. 100% full charge means charging with a constant current up to Uo with a current specified by the standard or manufacturer, charging with a constant voltage up to the standard or the blocking current specified by the manufacturer, charging with a constant voltage, and then charging with a standard or a current specified by the manufacturer. When discharging to the cut-off current specified by the manufacturer, if the output capacity is 100%, the state of charge before discharging is said to be 100% fully charged. The degree of freedom to charge U=Uo+(Uo-Us)+(Uo-Uso)=3Uo-Us-Uso with current I by adding (Uo-Uso) to U=2Uo-Us=Uo+（Uo-Us） Considering the very low desorption of lithium ions, the battery can be charged adjacent to a 100% full charge state, and the most ideal state of charge can be realized by reducing the effect of errors generated in equipment and measurement.

Solution to the task

If the battery is charged to full charge by the standard constant current constant voltage charging method and then left open, the standard stable voltage of the lithium iron anate battery is significantly different from the charge cutoff voltage, and the standard stable voltage of the lithium cobalt oxide battery is different from the standard charge cutoff voltage. It can be found that is small, which is directly correlated with the low level of full charge of the lithium iron anate battery and the high level of full charge of the lithium cobalt oxide battery.

In order to increase the efficiency and fully charge the battery, a correction value (Uo-Uso) is added to the existing U=Uo+(Uo-Us), and the correction and compensation voltage are:

U=Uo+(Uo-Us)+(Uo-Uso)=3Uo-Us-Uso.

Based on this, the battery can be charged up to 100% through the correction and compensation voltage when charging the lithium iron anate battery and the lithium cobalt oxide battery.

In the same way, experiments were conducted on a ternary lithium ion battery, a lithium manganese oxide battery, and a lithium titanium oxide battery, all of which had the same effect.

In the charging method of a lithium-ion battery for voltage correction and compensation, when the voltage reaches the charging upper limit voltage U during battery charging, the charging current is switched to constant voltage charging and the charging current is reduced to 5% to 99.99% of the charging current before the constant voltage. When the battery is completed, charging is terminated. The upper limit voltage of the battery is U=3Uo-Us-Uso.

In the charging method of a lithium-ion battery for voltage correction and compensation, when the battery is charged, when the voltage reaches the upper limit voltage U of the battery, it is switched to constant voltage charging, and the charging current is 50% to 99.99% of the charging current before the constant voltage. Charging is terminated when it decreases to, and the upper limit voltage between the positive electrodes of the battery is U=3Uo-Us-Uso.

Uso is the standard stable voltage of the voltage drop of the battery after charging to Uo with a constant current constant voltage;

It is the stable voltage of the voltage drop of the battery after charging to Uo with the Us current;

Uo is the standard charge cutoff voltage.

Uso is the standard stable voltage of the voltage drop of the battery after charging to Uo with a constant current constant voltage. The selection of that value is measured from the time after charging is terminated and stationary is started with a constant current constant voltage, and the battery starts from a certain time period T _Uso. , any time if the T-circuit voltage drop of the voltage in the _Uso is below the predetermined value the voltage of the battery is to have reached a steady state, establishes a voltage corresponding to the first time point of the time T _Uso with standard stable voltage Uso of the battery.

More specifically, after charging with a constant current to Uo with the current specified by the standard or manufacturer, charging with a constant voltage up to the standard or the blocking current specified by the manufacturer, and charging is terminated: When the constant current constant voltage charging of the battery is terminated and stationary stationary is started. from the measured time, the battery is that, starting from any time T _Uso, any time if the T-circuit voltage drop of the voltage in the _Uso is below the predetermined value the voltage of the battery has reached a steady state, the first of the time T _Uso The voltage corresponding to the time point is determined as the standard stable voltage Uso of the battery.

Us is the stable voltage after charging at a constant current until Uo battery voltage drops, the choice of the values measured hours after the start of the constant-current charging is terminated politics, batteries, starting any time T _Us, which times T _Us If the open-circuit voltage drop of the voltage is below the predetermined value of the battery voltage is within to have reached a steady state, establishes a voltage corresponding to the first time point of the time T _Us voltage Us to the stabilization of the battery.

Uo is the standard charge cut-off voltage, which is the charge cut-off voltage used in the low-rate constant current-constant voltage charging method commonly used in the industry.

As an improvement plan, in the charging method of a lithium ion battery for voltage correction and compensation according to the present invention, the battery can be charged up to U=3Uo-Us-Uso and terminated in a constant current method of current.

As another improvement plan, in the charging method of a lithium ion battery for voltage correction and compensation of the present invention, the battery is charged to U=3Uo-Us-Uso in a multi-stage constant current method and then converted to a constant voltage, so that the charging current is transferred to a constant voltage. It terminates when it decreases from 5% to 99.99% of the current of, and Us is determined by measuring the current in the last stage before the termination of charging.

As another improvement measure, in the charging method of a lithium ion battery for voltage correction and compensation of the present invention, the battery is charged to U=3Uo-Us-Uso in a non-constant current method and then converted to a constant voltage, so that the charging current is converted to a constant voltage. It terminates when it decreases from 50% to 99.99% of the previous current, and Us is determined by measuring the current in the last stage before termination of charging.

As the measurement method of Uso, in the charging method of a lithium-ion battery for voltage correction and compensation, the time is measured after the constant current constant voltage charging is terminated and stationary is started, and 5 minutes is set in one time zone, and the battery is in a certain time zone. Starting from T ₅ , if the voltage drop of the open-route voltage within the 5-minute time zone T ₅ is less than 2 mV, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point in the time zone T ₅ is the standard stable voltage of the battery. It is decided as Uso.

As another measurement method of Uso, in the charging method of a lithium-ion battery for voltage correction and compensation, the time is measured after the constant current constant voltage charging is terminated and stationary is started, 10 minutes is set as one time zone, and the battery is Starting from a certain time zone T ₁₀ , if the voltage drop of the open-route voltage within a 10-minute time zone T ₁₀ is lower than 1 mV, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point in the time zone T ₁₀ It is determined by constant voltage Uso.

In yet a different measurement methods, the selection of the Us value of Us, the constant current charging is terminated and measures the time after value is started, the _battery, starting from, freezing time T _Us' which times T _Us open-circuit voltage voltage in the If the drop is lower than the predetermined value, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point of this time period T _Us' is determined as the stable voltage Us of the battery.

Uo is the charge-off voltage used in the low-rate constant current-constant voltage charging method commonly used in the industry.

If the battery is a lithium cobalt oxide battery and the value of Uo is 4.2V, it is Uo ≒ Uso, and is terminated after charging to Uo+(Uo-Us).

It should be clarified that the standard stable voltage Uso correlates with the standard charge cut-off voltage Uo and the standard charge cut-off current, and has little or no relation to the charge factor.

As is widely known, in the lithium iron anate battery, the standard charge cutoff voltage Uo may be 3.5V, 3.6V, 3.65V, 3.7V, and different Uo can obtain different standard capacity C ₀ . The standard capacity is charged with a constant current up to Uo with the current specified by the standard or manufacturer, charged with a constant voltage to the standard or the blocking current specified by the manufacturer, and charging is terminated, and the current specified by the standard or manufacturer is blocked by the standard or manufacturer. It discharges to current, and at this time, the output capacity is the standard capacity C ₀ . The standard charge cutoff voltage Uo of the lithium iron anate battery can be selected from a widely known value, and the value of the correction and compensation voltage is U=Uo+(Uo-Us)+ in order to charge an electric quantity close to the standard capacity C ₀ in case of rapid charging. The charging method of (Uo-Uso)=3Uo-Us-Uso is applied.

As is widely known, the most common standard cutoff voltage Uo of lithium cobalt oxide batteries is 4.2V, and high voltage lithium cobalt oxide batteries of 4.3V and 4.35V are currently developed, and 4.4V and 4.5V high voltage lithium cobalt oxide batteries are developed. In the meantime, the corresponding standard charge cutoff voltage Uo is 4.3V, 4.35V, 4.4V, 4.5V, respectively, and different standard capacity C ₀ can be obtained for each Uo. Voltage is different here lithium-cobalt oxide may be selected a well-known standard charge cut-off voltage Uo corresponding cell, rapidly if the charging standard capacity C ₀ value of the compensation and the compensation voltage to rapidly charge the nearest electricity quantity in the U = Uo + ( The charging method of Uo-Us)+(Uo-Uso)=3Uo-Us-Uso is applied.

As is widely known, the typical standard cut-off voltage Uo of a ternary lithium-ion battery (lithium nickel cobalt manganese oxide battery) is 4.2V, and a high-voltage ternary lithium-ion battery of 4.3V and 4.35V is currently being developed, and the corresponding standard The charging cutoff voltage Uo is 4.3V and 4.35V, respectively, and a different standard capacity C ₀ can be obtained for each Uo. Voltage can be selected for known standard charge cut-off voltage Uo corresponding to the other three won a lithium ion battery, rapidly if the charging standard capacity C ₀ value of the compensation and the compensation voltage to rapidly charge the nearest electricity quantity in the U = Uo + ( The charging method of Uo-Us)+(Uo-Uso)=3Uo-Us-Uso is applied.

In particular, if the Uo value of the lithium cobalt oxide battery is 4.2V (see Fig. 2), even after charging to Uo≒Uso, U≒Uo+(Uo-Us), it is almost the same as charging to 4.2V with a constant current constant voltage even after charging. You can get the effect. That is, when the Uo value of the lithium cobalt oxide battery is 4.2V, the correction value Uo-Uso may not be considered. However, as for the other standard charging cutoff voltage Uo, as in the case of Uo=4.35V shown in Fig. 3, the difference between Uo and Uso is large, so charging is possible to a 100% full charge state only when the correction value (Uo-Uso) is considered. .

Compared with the conventional charging method, the effects of the present invention are as follows.

1. Lithium-ion battery can be quickly charged to near full charge;

2. The charging method of the present invention can be applied to various lithium-ion batteries, charges almost 100%, and can increase the efficiency of the battery.

3. The charging method of the lithium ion battery of the present invention has a longer cycle life or the same number of cycles as compared to the constant current constant voltage charging of the same magnification current, and the charging method of the present invention provides a larger capacity during discharge. Can be printed.

4. A charger can be manufactured by designing a charging circuit with the charging method of the present invention.

5. An electronic device can be fabricated by the method of the present invention and assembled with a cell.

1 is a view showing a curve of a stable voltage Us after charging a lithium iron anate battery to Uo at a constant current and constant voltage and charging to Uo at a standard cutoff voltage Uso and a constant current constant voltage.
2 is a diagram showing a curve of a standard cut-off voltage Uso after charging a lithium cobalt oxide battery to Uo at a constant current constant voltage and a curve of a stable voltage Us after charging to Uo at a constant current constant voltage.
3 is a view showing a curve of a stable voltage Us after charging a 4.35V high voltage lithium cobalt oxide battery to Uo at a constant current and constant voltage, and then charging to Uo at a standard cutoff voltage Uso and a constant current constant voltage.

Hereinafter, the present invention will be described in detail with reference to comparative examples and examples to present specific implementation methods and advantages of the present invention.

Comparative Example 1.1 : Lithium iron anate battery, standard charging method

402045Fe15C is a high-rate 3.2V190mAh lithium iron anate battery, a LiFePO4/C-based unit battery (Uo=3.6V), its rated capacity is Cr=190mAh, and refer to GB/T18287-2013 standard charging method,

1. Charge until it reaches 3.6V with a constant current of 38mA (0.2C), converts to a constant voltage of 3.6V, charges until the current decreases to 3.8mA (0.02C) and terminates, charging time Tc and charging capacity Cc Record;

2. Discharge to 2.0V with a constant current of 38mA (0.2C), and record the discharge capacity Cd; (This step is to measure the output capacity after charging and is not an essential step in the charging method.)

3. Circulation:

3.1. After charging until it reaches 3.6V with a constant current of 1140mA, it converts to a constant voltage of 3.6V and charges until the current decreases to 3.8mA.

3.2. 5min stand still.

3.3. Discharge until it reaches 2.0V with a constant current of 1140mA.

3.4. 5min stand still.

3.5. Steps 3.1 to 3.4 are cycled 1000 times.

3.6. To close.

Comparative Example 1.2 : Lithium iron anate battery, CN101388477B charging method

Like the battery of Comparative Example 1.1, charging is completed within t=10min, and based on the rapid charging method disclosed in CN101388477B, the required constant current charging current is I=Cr/t*60=190/10*60=1140mA (6C magnification).

1. Stable voltage measurement: After charging until it reaches 3.6V with a constant current of 1140mA, it is terminated, and the open-circuit voltage is tested to measure the stable voltage Us. The curve of the stable voltage Us is shown in Fig. 1; The time is measured after the constant current charging is completed and stationary is started, and 10 minutes is set in one time zone, and the voltage of the battery is stable when the voltage drop of the open-ro voltage within the 10 minute time zone is lower than 1 mV starting from a certain time zone. When the state has been reached, the voltage corresponding to the first point in the time period is determined as the stable voltage Us of the battery;

Discharge until it reaches 2.0V with a constant current of 38mA (0.2C). (This step is to output the capacity charged in the previous step to put the battery into a charging standby state, and is not an essential step in the charging method);

3. Charge it with a constant current of 1140mA until it reaches 2Uo-Us and then terminate it and record the charging time Tc and the charging capacity Cc;

4. Discharge with a constant current of 38mA (0.2C) until 2.0V is reached, and record the discharge capacity Cd (this step is to measure the output capacity after charging, and is not an essential step of the charging method);

5. Circulation:

5.1. Charge it with constant current of 1140mA until it reaches 2Uo-Us.

5.2. 5min stand still.

5.3. Discharge until it reaches 2.0V with a constant current of 1140mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 1000 times.

5.6. To close.

Example 1 : Lithium iron anate battery, the method of the present invention,

Similar to the battery of Comparative Example 1.1, the stable voltage Us measured in Comparative Example 1.2 was used;

1. Measurement of standard stable voltage: Charge until 3.6V is reached with a constant current of 38mA (0.2C), convert to a constant voltage of 3.6V, charge until the current decreases to 3.8mA (0.02C), then terminate and open. By testing the voltage, the standard stable voltage Uso is measured, and the curve of the standard stable voltage Uso is shown in Fig. 1; Constant current Constant voltage The time is measured from the end of charge and stationary start, and 10 minutes is set in one time zone.If the voltage drop of the open-ro voltage within the 10 minute time zone is lower than 1 mV, the battery voltage is lower than 1 mV. As the stable state has been reached, the voltage corresponding to the first time point of the time period is determined as the standard stable voltage Uso of the battery;

2. Discharge until it reaches 2.0V with a constant current of 38mA (0.2C); (This step is to output the capacity charged in the previous step to put the battery into a charging standby state, and is not an essential step in the charging method);

3. When charging is completed within 10 minutes, in the charging method of a lithium ion battery for voltage correction and compensation of the present invention, the required constant current charging current is 1140mA (6C magnification), and U=3Uo-Us-Uso When is reached, it switches to constant voltage charging, and ends when the charging current decreases to 95% of the charging current before the constant voltage, and records the charging time Tc and the charging capacity Cc.

4. Discharge with a constant current of 38mA (0.2C) until 2.0V is reached, and record the discharge capacity Cd (this step is to measure the output capacity after charging, and is not an essential step of the charging method);

5. Circulation:

5.1. After charging to 3Uo-Us-Uso with a constant current of 1140mA, it converts to constant voltage charging, and ends when the charging current decreases to 1083mA (95% of the charging current before the constant voltage).

5.2. 5min stand still.

5.3. Discharge until it reaches 2.0V with a constant current of 1140mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 1000 times.

5.6. To close.

The test results of Comparative Example 1.1, Comparative Example 1.2, and Example 1 are shown in Table 1.

Comparative Example 1.1, Comparative Example 1.2, Example 1 test results Comparative Example 1.1 Comparative Example 1.2 Example 1 Uo(V) 3.6 3.6 3.6 Us(V) ―― 3.312 3.312 Uso(V) ―― ―― 3.340 Charging current (mA) 38 1140 1140 Charging cut-off current (mA) 3.8 1140 1083 Charging upper limit voltage (V) 3.6 3.888 4.148 Charging time Tc(min) 338 9.2 10.6 Charging capacity Cc(mAh) 198 175 200 Discharge capacity Cd(mAh) 197 174 199 Full charge level 100% 88.3% 101.0% Capacity retention rate after 1000 cycles 85.2% 88.4% 88.2%

Full charge level: Charged by the standard charging method, discharged by the standard discharge method, and the output capacity is set to 100%; Charged by a non-standard charging method, and the ratio of the output capacity compared with the standard discharge capacity by discharging by the standard discharge method is the level of full charge.

Comparative Example 2.1 : Lithium cobalt oxide battery, standard charging method

703048H10C is a high-rate 3.7V800mAh lithium-ion polymer battery, LiCoO ₂ /C unit battery (Uo=4.2V), rated capacity is Cr=800mAh, refer to GB/T18287-2013 standard charging method,

1. Charge the constant current 160mA (0.2C) until it reaches 4.2V, convert it to the constant voltage 4.2V and charge it until the current decreases to 16mA (0.02C), and record the charging time Tc and the charging capacity Cc;

2. Discharge with a constant current of 160mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd (this step is to measure the output capacity after charging, it is not an essential step of the charging method);

3. Circulation:

3.1. After charging it with a constant current of 4800mA until it reaches 4.2V, it converts to a constant voltage of 4.2V and charges it until the current decreases to 16mA.

3.2. 5min stand still.

3.3. Discharge until it reaches 3.0V with a constant current of 4800mA.

3.4. 5min stand still.

3.5. Steps 3.1 to 3.4 are cycled 500 times.

3.6. To close.

Comparative Example 2.2 : Lithium cobalt oxide battery, CN101388477B charging method

Similar to the battery of Comparative Example 2.1, charging was completed within t=10min, and based on the rapid charging method disclosed in CN101388477B, the required constant current charging current was I=Cr/t*60=800/10*60= It is 4800mA (6C magnification).

1. Stable voltage measurement: After charging until it reaches 4.2V with a constant current of 4800mA, it is terminated, and the open-circuit voltage is tested to measure the stable voltage Us. The curve of the stable voltage Us is shown in Fig. 2; The time is measured after the constant current charging is completed and stationary is started, and 10 minutes is set in one time zone, and the voltage of the battery is stable when the voltage drop of the open-ro voltage within the 10 minute time zone is lower than 1 mV starting from a certain time zone. When the state has been reached, the voltage corresponding to the first point in the time period is determined as the stable voltage Us of the battery;

2. Discharge until 3.0V is reached with a constant current of 160mA (0.2C); (This step is to output the capacity charged in the previous step to put the battery into a charging standby state, and is not an essential step in the charging method);

3. Charge it with a constant current of 4800mA until it reaches 2Uo-Us, then terminate it, and record the charging time Tc and charging capacity Cc;

4. Discharge with a constant current of 160mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd (this step is to measure the output capacity after charging, it is not an essential step of the charging method);

5. Circulation:

5.1. Charge it with a constant current of 4800mA until it reaches 2Uo-Us.

5.2. 5min stand still.

5.3. Discharge until it reaches 3.0V with a constant current of 4800mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 500 times.

5.6. To close.

Example 2 : Lithium cobalt oxide battery, the method of the present invention,

In the same way as the battery of Comparative Example 2.1, the stable voltage Us measured in Comparative Example 2.2 was used;

1. Measurement of standard stable voltage: Charged with a constant current of 160mA (0.2C) until it reaches 4.2V, converts to a constant voltage of 4.2V and charges until the current decreases to 16mA (0.02C), then terminates, and the open voltage By testing, the standard stable voltage Uso is measured, and the curve of the standard stable voltage Uso is shown in Fig. 2; Constant current Constant voltage The time is measured from the end of charge and stationary start, and 10 minutes is set in one time zone.If the voltage drop of the open-ro voltage within the 10 minute time zone is lower than 1 mV, the battery voltage is lower than 1 mV. As the stable state has been reached, the voltage corresponding to the first time point of the time period is determined as the standard stable voltage Uso of the battery;

2. Discharge until 3.0V is reached with a constant current of 160mA (0.2C); (This step is to output the capacity charged in the previous step to put the battery into a charging standby state, and is not an essential step in the charging method);

3. When charging is completed within 10 minutes, in the charging method of a lithium ion battery for voltage correction and compensation of the present invention, the required constant current charging current is 4800mA (6C magnification), and U=3Uo-Us-Uso Is reached, it switches to constant voltage charging, terminates when the charging current decreases to 95% of the charging current before the constant voltage, and records the charging time Tc and the charging capacity Cc;

4. Discharge with a constant current of 160mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd (this step is to measure the output capacity after charging, it is not an essential step of the charging method);

5. Circulation.

5.1. After charging with a constant current of 4800mA until it reaches 3Uo-Us-Uso, it switches to constant voltage charging, and ends when the charging current decreases to 4560mA (95% of the charging current before the constant voltage).

5.2. 5min stand still.

5.3. Discharge until it reaches 3.0V with a constant current of 4800mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 500 times.

5.6. To close.

The test results of Comparative Example 2.1, Comparative Example 2.2, and Example 2 are shown in Table 2.

Comparative Example 2.1, Comparative Example 2.2, Example 2 Test Results Comparative Example 2.1 Comparative Example 2.2 Comparative Example 2 Uo(V) 4.2 4.2 4.2 Us(V) ―― 4.016 4.016 Uso(V) ―― ―― 4.196 Charging current (mA) 160 4800 4800 Charging cut-off current (mA) 16 4800 4560 Charging upper limit voltage (V) 4.2 4.384 4.388 Charging time Tc(min) 344 10.0 10.4 Charging capacity Cc(mAh) 826 802 830 Discharge capacity Cd(mAh) 825 801 828 Full charge level 100% 97.1% 100.5% Capacity retention rate after 500 cycles 81.3% 85.2% 85.1%

Comparative Example 3.1 : 4.35V high voltage lithium cobalt oxide battery, standard charging method

601250HV10C is a 4.35V high voltage type 235mAh lithium-ion polymer battery, LiCoO ₂ /C unit battery (Uo=4.35V), rated capacity is Cr=800mAh, refer to GB/T18287-2013 standard charging method,

1. Charge it with a constant current of 47mA (0.2C) until it reaches 4.35V, convert it to a constant voltage of 4.2V and charge it until the current decreases to 4.7mA (0.02C), and record the charging time Tc and the charging capacity Cc. ;

2. Discharge with a constant current of 47mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd (this step is to measure the output capacity after charging, not an essential step of the charging method);

3. Circulation:

3.1. After charging until it reaches 4.35V with a constant current of 470mA, it converts to a constant voltage of 4.35V, and charges until the current decreases to 4.7mA.

3.2. 5min stand still.

3.3. Discharge until it reaches 3.0V with a constant current of 470mA.

3.4. 5min stand still.

3.5. Steps 3.1 to 3.4 are cycled 500 times.

3.6. To close.

Comparative Example 3.2 : 4.35V high voltage lithium cobalt oxide battery, CN101388477B charging method

Like the battery of Comparative Example 3.1, charging was completed within t=30min, and based on the rapid charging method disclosed by CN101388477B, the required constant current charging current was I=Cr/t*60=235/30*60=470mA (2C magnification),

1. Stable voltage measurement: After charging until it reaches 4.35V with a constant current of 470mA, it is terminated, and the open-circuit voltage is tested to measure the stable voltage Us. The curve of the stable voltage Us is shown in Fig. 3; The time is measured after the constant current charging is completed and stationary is started, and 5 minutes is set in one time zone, and the voltage of the battery is stable when the voltage drop of the open-ro voltage within the 5 minute time zone is lower than 2 mV starting from a certain time zone. When the state has been reached, the voltage corresponding to the first point in the time period is determined as the stable voltage Us of the battery.

2. Discharge until it reaches 3.0V with a constant current of 47mA (0.2C); (This step is to output the capacity charged in the previous step to put the battery in a charging standby state, and is not an essential step in the charging method)

3. Charge it with a constant current of 470mA until it reaches 2Uo-Us, then terminate it, and record the charging time Tc and the charging capacity Cc;

4. Discharge with a constant current of 47mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd (this step is to measure the outputable capacity after charging and is not an essential step of the charging method);

5. Circulation

5.1. Charge it with a constant current of 470mA until it reaches 2Uo-Us.

5.2. 5min stand still.

5.3. Discharge until it reaches 3.0V with a constant current of 470mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 500 times.

5.6. To close.

Example 3: 4.35V high voltage lithium cobalt oxide battery, the method of the present invention,

Similar to the battery of Comparative Example 3.1, the stable voltage Us measured in Comparative Example 3.2 was used;

1. Measurement of standard stable voltage: Charge it with a constant current of 47mA (0.2C) until it reaches 4.35V, convert it to a constant voltage of 4.35V and charge it until the current decreases to 4.7mA (0.02C), then terminate it and open it. By testing the voltage, the standard stable voltage Uso is measured, and the curve of the standard stable voltage Uso is shown in Fig. 3; Constant current The time is measured from the end of constant voltage charging and stationary start, and 5 minutes is set in one time zone.If the voltage drop of the open-ro voltage within the 5 minute time zone is less than 2 mV, the battery voltage is lower than 2 mV. As the stable state has been reached, the voltage corresponding to the first time point of the time period is determined as the standard stable voltage Uso of the battery;

2. Discharge until it reaches 3.0V with a constant current of 47mA (0.2C); (This step is to output the capacity charged in the previous step to put the battery in a charging standby state, and is not an essential step in the charging method)

3. When charging is completed within 30 minutes, in the charging method of a lithium ion battery for voltage correction and compensation of the present invention, the required constant current charging current is 470mA (2C magnification), and U=3Uo-Us-Uso When is reached, it switches to constant voltage charging, and ends when the charging current decreases to 95% of the charging current before the constant voltage, and the charging time Tc and the charging capacity Cc are recorded.

4. Discharge with a constant current of 47mA (0.2C) until it reaches 3.0V, and record the discharge capacity Cd; (This step is to measure the output capacity after charging, not an essential step in the charging method)

5. Circulation

5.1. After charging with a constant current of 470mA until it reaches 3Uo-Us-Uso, it switches to constant voltage charging, and ends when the charging current decreases to 446.5mA (95% of the charging current before the constant voltage).

5.2. 5min stand still.

5.3. Discharge until it reaches 3.0V with a constant current of 470mA.

5.4. 5min stand still.

5.5. Steps 5.1 to 5.4 are cycled 500 times.

5.6. To close.

The test results of Comparative Example 3.1, 3.2, and Example 3 are shown in Table 3.

Comparative Example 3.1, Comparative Example 3.2, Example 3 Test Results Comparative Example 3.1 Comparative Example 3.2 Example 3 Uo(V) 4.35 4.35 4.35 Us(V) ―― 4.216 4.216 Uso(V) ―― ―― 4.333 Charging current (mA) 47 470 470 Charging cut-off current (mA) 4.7 470 446.5 Charging upper limit voltage (V) 4.2 4.484 4.501 Charging time Tc(min) 341 30.8 31.6 Charging capacity Cc(mAh) 245 239 247 Discharge capacity Cd(mAh) 244 238 246 Full charge level 100% 97.5% 100.8% Capacity retention rate after 500 cycles 75.4% 78.2% 77.8%

In a specific implementation process, optionally, 1. Us, Uso can be measured before each charge of each cell, and can be charged by the method of the present invention (or CN101388477B), which is very cumbersome; 2. Us, Uso can be measured before charging each battery and charged by the method of the present invention (or CN101388477B), which is also very cumbersome; 3, Us and Uso are measured before charging for each battery model, and each battery of the corresponding model can be charged by the method of the present invention (or CN101388477B), which is very simple. There are slight differences for each battery depending on the model of the battery or the number of times the battery is charged, but it does not affect the implementation of the present invention; The present invention can be charged close to 100%, but does not guarantee that each battery reaches 100% full charge every time.

In a specific implementation process, the battery can be completely discharged and then charged by the method of the present invention, even in a half or more charged state; When fully charged, there is no need to charge any more.

Through the contents presented in the above specification, a person of ordinary skill in the art to which the present invention pertains can implement the above-described embodiment of the present invention in various forms, for example, a lithium ion battery, a pack, a charging circuit, It can be used for products such as chargers and charging control devices. Therefore, the present invention is not limited to the specific implementation method described above, but it is possible to implement various modifications within the scope of the claims, the detailed description of the invention, and the accompanying drawings, and it is natural that this also falls within the scope of the present invention. Do.

Claims (12)

During battery charging, when the voltage reaches the charging upper limit voltage U, it switches to constant voltage charging, and when the charging current decreases from 5% to 99.99% of the charging current before the constant voltage, charging is terminated.The charging upper limit voltage of the battery is U=3Uo -Us-Uso,
Here, Uso is the standard stable voltage of the voltage drop of the battery after charging to Uo with a constant current constant voltage, the stable voltage of the voltage drop of the battery after charging to Uo with the Us current, and Uo is a voltage characterized in that it is the standard charging cutoff voltage. Li-ion battery charging method for calibration and compensation. The method of claim 1, wherein when the voltage reaches the charging upper limit voltage U, it is switched to constant voltage charging, and charging is terminated when the charging current is reduced to 50% to 99.99% of the charging current before the constant voltage, and the charging upper limit voltage of the battery is U =3Uo-Us-Uso, characterized in that the charging method of a lithium-ion battery for voltage correction and compensation. According to claim 1 or 2, wherein the selection of a stable voltage Us is by measuring the time after the start of the constant-current charging is terminated value, the cell starting from one time zone T _Us, which time T the open-circuit voltage drop of the voltage in the _Us the voltage of the low, the battery than the predetermined value are to have reached a steady state, the time T _Us lithium ion for correction and compensation of the voltage to a voltage corresponding to the first point, wherein the determining a stable voltage Us of the battery How to charge the battery. The method of claim 1 or 2, wherein the lithium ion battery is charged to the upper limit voltage U in a constant current method. The voltage correction and compensation according to claim 1 or 2, wherein the battery is charged up to the upper limit voltage U of the battery in a multi-stage constant current method, and Us is determined by measuring the current of the last stage before charging is terminated. Charging method of a lithium ion battery for. The voltage correction according to claim 1 or 2, wherein the battery is charged up to the upper limit voltage U of the battery in a non-constant current method, and Us is determined by measuring the current in the last stage before charging is terminated. Charging method of lithium-ion battery for compensation. The battery according to claim 1 or 2, wherein Uso is a standard stable voltage of the voltage drop of the battery after charging to Uo with a constant current and constant voltage, and the selection of the standard stable voltage Uso measures the time after charging is terminated and stationary is started. Is starting from a certain time zone T _Uso, and when the voltage drop of the open-circuit voltage within a certain time zone T _Uso is lower than a predetermined value, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point of the time zone T _Uso A method of charging a lithium-ion battery for voltage correction and compensation, characterized in that the standard stable voltage Uso is determined. The method according to claim 7, wherein the time is measured after charging is terminated and stationary is started with a constant current constant voltage, and 5 minutes are set in one time zone, and the battery starts from a time zone T ₅ of a certain 5 minutes, and within a time zone T ₅ of 5 minutes. When the voltage drop of the open-circuit voltage is less than 2mV, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point of the time period T ₅ is determined as the standard stable voltage Uso of the battery. Charging method of a lithium ion battery for. The method of claim 7, wherein the time is measured after charging is terminated and stationary is started with a constant current constant voltage, 10 minutes is set in one time zone, and the battery starts from a time zone T ₁₀ of a certain 10 minutes, and within a time zone T ₁₀ of 10 minutes. If the voltage drop of the open-circuit voltage is less than 1mV, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point of the time period T ₁₀ is determined as the standard stable voltage Uso of the battery. Charging method of a lithium ion battery for. The method of claim 7, wherein the selection of the Us value of the constant current charging is terminated and after value is started to measure the time, the battery which times T _{Us 'starts} to, which time T _Us from _the' open-circuit voltage drop of the voltage within a predetermined If it is lower than the value, the voltage of the battery has reached a stable state, and the voltage corresponding to the first time point of the time period T _Us' is determined as the stable voltage Us of the battery. Way. delete delete

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