KR20200077238A - Battery life estimation method and battery pack - Google Patents

Abstract

The present invention relates to a battery life prediction method and a battery pack applied to the same. More specifically, provided are the method for predicting the life of a battery using a resistance change in a section frequently used after charging without fully discharging the battery pack and the battery pack applied to the same.

Description

Battery life estimation method and battery pack using the same

The present invention relates to a battery life prediction method and a battery pack using the same, and more particularly, to a method for predicting the battery life through the control of a smart charger without fully discharging the battery and a battery pack using the same.

Rechargeable secondary batteries (hereinafter referred to as'batteries'), which are used as energy sources in various fields, including electric vehicles, energy storage systems (ESS), as well as portable electronic devices such as smartphones, laptops, PDAs, etc. The longer the period of continuous use, and the more the charge/discharge is repeated, the shorter the life of the battery, and the capacity/performance of the battery gradually decreases. A decrease in capacity/performance of the battery due to these characteristics affects the stable operation of the system using the battery.

Therefore, predicting the life of the battery enables to grasp when the battery needs to be replaced, thereby minimizing the negative effects that may occur due to deterioration of the capacity/performance of the battery, so that the system using the battery can be operated stably. Make it possible.

On the other hand, in the related art, the initial battery capacity is measured by integrating the current while discharging the voltage of the initial battery, and then, when there is an opportunity to fully discharge the battery, the capacity of the battery is measured through full discharge and compared with the initial battery capacity. Battery life could be predicted. However, in order to predict the life of the battery, it is difficult to predict the life of the current battery by using it, since it is rare that an opportunity to fully discharge the voltage of the battery generally occurs.

(Patent Document 1) KR10-1211789 B1

The present invention is to solve the above problems, and to provide a method for predicting the life of the battery through the control of the smart charger without the need to fully discharge the voltage of the battery and a battery pack using the same.

The battery life prediction method according to the present invention includes: a communication connection step of connecting communication with a smart charger connected to the battery; A first charging step of controlling charging such that a battery is fully charged with the first charging voltage by setting a charging voltage of a smart charger connected to communication through the communication connection step to a first charging voltage that is preset; A first idle state maintaining step of maintaining the state for a predetermined time in a state in which charging of the battery is blocked as the battery is fully charged to the first charging voltage by the first charging step; A second charging step of controlling charging such that the battery is fully charged with the second charging voltage by setting the charging voltage of the communication connected smart charger to a preset second charging voltage after the first idle state maintaining step; A second dormant state maintaining the battery for a predetermined period of time in a state in which charging of the battery is blocked as the battery is charged to the second charging voltage by the second charging step; An open voltage (OCV) measurement step of measuring an open voltage (OCV) of the battery after the second idle state maintenance step; A resistance calculation step of calculating the resistance of the current battery state by using the open voltage (OCV) measured through the open voltage (OCV) measurement step, the preset second charging voltage and constant current (CC); A life prediction step of comparing a resistance value calculated through the resistance calculation step with previously prepared data, extracting a resistance section to which the calculated resistance value belongs, and detecting a corresponding life span to predict the life of the current battery; It is configured to include.

On the other hand, the first charging step, the first charging voltage setting step of setting the charging voltage of the smart charger connected to the communication through the communication connection step to a preset first charging voltage; A first full charge detection step of detecting whether a battery is fully charged with the first charge voltage while being charged by receiving a charging current from a smart charger whose charge voltage is set to the first charge voltage by the first charge voltage setting step; A first charging blocking step of blocking charging of the battery by outputting a charging blocking signal to a communication connected smart charger when the current battery is detected to be charged with the first charging voltage in the first charging detection step; Characterized in that it comprises a.

In addition, the second charging step, the second charging voltage setting step of setting the charging voltage of the smart charger connected to the communication through the communication connection step to a preset second charging voltage; A second full charge detection step of detecting whether a battery is full of the second charge voltage while being charged by receiving a charging current from a smart charger in which the charge voltage is set as the second charge voltage by the second charge voltage setting step; A second charge blocking step of blocking the charging of the battery by outputting a charge blocking signal to the communication connected smart charger 200 when the current battery is detected as being charged to the second charging voltage in the second full charge detection step; Characterized in that it comprises a.

On the other hand, calculating the resistance in the resistance calculation step, using the open voltage (OCV) measured through the open voltage (OCV) measurement step, the preset second charging voltage and constant current (CC) It is characterized by calculating by 1).

Equation (1): (second charging voltage-open voltage (OCV)) / constant current (CC)

Here, the first and second charging voltages are characterized by being voltage values included in a section in which the battery is repeatedly used.

A battery pack to which the method for predicting battery life according to the present invention is applied includes: one or more battery cells; Communication unit for connecting the communication with the smart charger; A voltage measuring unit measuring voltages of the battery cells at predetermined periodic intervals; A charging control unit controlling the smart charger connected to the communication unit through the communication unit to control the battery cells to be filled with a predetermined first and second charging voltage; A storage unit that stores data for predicting the life of the battery cells; A life prediction unit for predicting the lifespan of the current battery cells based on the open voltage (OCV) value measured through the idle state after being filled with the second charging voltage by the charging control unit and the data stored in the storage unit; It is configured to include.

Specifically, the charging control unit sequentially sets the charging voltage of the smart charger connected to the communication unit through the communication unit to a first charging voltage and a second charging voltage, so that the battery cells are charged with respective corresponding charging voltages. A charging voltage setting unit; While the charging voltage of the smart charger is set to the first or second charging voltage by the charging voltage setting unit, while the battery cells are being charged, the full-charge detection unit detects whether the battery cells are filled with the first or second charging voltage ; When it is sensed that the battery cells are fully charged with the first or second charging voltage by the full charge detection unit, a charge blocking signal is output to the smart charger to block charging of the battery cells full with the first or second charging voltage. Charge blocking unit; Characterized in that it comprises a.

Here, when the charging voltage setting unit communicates with the smart charger by the communication unit, the charging voltage of the smart charger is set to a preset first charging voltage to control charging so that the battery cells are filled with the first charging voltage. , The charge detection unit monitors the voltage of the battery cells measured by the voltage measurement unit, and outputs a first charge signal when it is detected that the battery cells are fully charged with the first charge voltage. When the first full charge signal is output from the full charge detector, the charging of the battery cells is blocked by outputting a first charge cut off signal to the smart charger.

In addition, when the first full-charge signal is output from the charging blocking unit, the charging voltage setting unit sets the charging voltage of the smart charger to a predetermined second charging voltage after a predetermined time from the output time, so that the battery cells are second Charging is controlled to be filled with a charging voltage, and the filling detection unit monitors the voltage of the battery cells measured by the voltage measuring unit and outputs a second filling signal when it is detected that the battery cells are filled with the second charging voltage. In this case, when the second full charge signal is output from the full charge detector, the charge blocking part outputs a second charge block signal to the smart charger to block charging of the battery cells.

On the other hand, the voltage measuring unit is characterized in that when the second charging blocking signal is output from the charging blocking unit, measuring the open voltage (OCV) of the battery cells after a predetermined time from the output point.

Meanwhile, the data stored in the storage unit is characterized by including the predetermined first and second charging voltage values, constant current (CC) values, and previously prepared data.

On the other hand, the life prediction unit, using the open voltage (OCV) value measured by the voltage measurement unit, the second charging voltage value and the constant current (CC) value stored in the storage unit, the resistance value by the following equation (1) Resistance calculation unit for calculating; It is characterized in that the resistance value calculated from the resistance calculation unit is compared with pre-prepared data stored in the storage unit, and the lifespan corresponding to the calculated resistance value is predicted as the current lifespan.

Equation (1): (second charging voltage-open voltage (OCV)) / constant current (CC)

Here, the first and second charging voltages are characterized in that they are voltage values included in a section in which battery cells are repeatedly used.

The battery pack according to the present invention may be included in a device such as a smart phone, a laptop, and wearable electronic devices.

The present invention can increase the chance of predicting the life of the current battery because the life is possible through the control of the smart charger connected to the battery without having to discharge the battery.

In addition, accuracy and efficiency can be improved by predicting the life of the battery by using the resistance of a frequently used section according to the usage of the battery.

1 is a block diagram schematically showing a method for predicting battery life according to the present invention.
2 is a block diagram schematically showing a battery pack to which a life prediction method according to the present invention is applied.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are attached to similar parts throughout the specification.

Terms including ordinal numbers such as first and second may be used to describe various components, but the components are not limited by the terms. The terms are used only for the purpose of distinguishing one component from other components. For example, the first component may be referred to as a second component without departing from the scope of the present invention, and similarly, the second component may be referred to as a first component. Terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Throughout the specification, when a part is “connected” to another part, this includes not only “directly connected” but also “electrically connected” with another element in between. . Also, when a part “includes” a certain component, this means that other components may be further included instead of excluding other components, unless otherwise stated. The terms “~(steps)” or “steps of” as used in the present specification do not mean “steps for”.

The terminology used in the present invention has been selected, while considering the functions in the present invention, general terms that are currently widely used have been selected, but this may vary according to the intention or precedent of a person skilled in the art or the appearance of new technologies. In addition, in certain cases, some terms are arbitrarily selected by the applicant, and in this case, their meanings will be described in detail in the description of the applicable invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the entire contents of the present invention, not a simple term name.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1. Outline

1.1. 1st, 2nd charging voltage

The first and second charging voltages used in the present specification mean respective voltage values partially set in a voltage region in which the battery pack is repeatedly used during discharge.

For example, in the case of a mobile phone, it is often used up to about 50% of the charging state due to the use of the mobile phone in a full state. Typically, users frequently use the mobile phone to charge up to 0%. Sometimes it can happen.

In the case of the electric bicycle, when the electric bicycle is used in a full state, it is often used up to about 40% of the charged state, and often it may be used up to 0% due to long distance travel.

In the case of an electric vehicle, it is often used up to about 30% in a fully charged state, and in the case of an electric vehicle, it is almost impossible to use it up to 0% because it is difficult to deal with the situation when the vehicle stops when there is no remaining battery power. I never do that.

As described above, there is a main use area that is generally expected for each use of the battery, and an expected interval that is repeated in the main use area is set and some voltages in the section are set as first and second charging voltages.

Since the present invention does not fully discharge the battery as in the prior art, and uses the resistance of the frequently used section of the battery to predict the life, the voltages corresponding to the section can be set to the first and second charging voltages, respectively. Therefore, since the usage pattern varies according to the battery model (purpose of use), the values of the first and second charging voltages may be changed accordingly.

1.2. Smart charger(200)(200)

In the present invention, a smart charger 200 other than a general charger can be used to predict the life of the battery. The smart charger 200 is a charger that can be controlled through a communication connection with a battery, and it is possible to set a charging voltage in a battery through a communication connection, unlike a general charger in which the charging voltage is fixed. In addition, it is possible to control the charging on/off of the smart charger 200 to control charging according to the state of the battery.

Therefore, the present invention may use the smart charger 200, and may predict the lifespan without discharging the battery through the method according to the embodiment of the present invention.

2. Method for predicting the life of the battery according to the present invention

1 is a block diagram schematically showing a method for predicting the life of a battery according to the present invention. Referring to FIG. 1, a method for predicting the life of a battery according to the present invention may be configured as follows.

2.1. Communication connection step (S100)

The communication connection step is a step of connecting communication with the smart charger 200 when the battery and the smart charger 200 are connected. By connecting the communication with the smart charger 200 through the communication connection step, the control of the smart charger 200 is possible, so that charging of the battery can be controlled.

Here, in the communication connection step, communication with the smart charger 200 may be connected using, for example, CAN communication.

The communication connection step (S100) may be performed by the communication unit 120 to be described later.

2.2. First charging step (S200)

The first charging step is a step of controlling charging so that the battery is fully charged with the corresponding first charging voltage by setting the charging voltage of the smart charger 200 connected through communication through the communication connecting step to a preset first charging voltage. The first charging step may include the following detailed steps.

end. First charging voltage setting step (S210)

When communication with the smart charger 200 is connected through the communication connection step (S100), the charging voltage of the smart charger 200 may be set to a first charging voltage value through this. Setting the charging voltage of the smart charger 200 to the first charging voltage value may be, for example, by providing the first charging voltage value information to the smart charger 200 through CAN communication. Accordingly, the smart charger 200 provided with the first charging voltage value information may output the voltage with the first charging voltage value to charge the battery.

The first charging voltage setting step may be performed by the charging voltage setting unit 142 of the charging control unit 140 described later.

I. The first full detection step (S220)

After the first charging voltage setting step (S210), while the charging voltage is supplied to the charging current from the smart charger 200 set to the first charging voltage value while charging, detecting whether the battery is fully charged with the first charging voltage It is a step. This may monitor whether the battery currently being charged by the smart charger 200 is fully charged with the first charging voltage by monitoring the voltage of the battery measured at a predetermined cycle interval. This is performed by the fullness detection unit 144 of the charging control unit 140 described later, and when detected as the first charging voltage, a first fullness signal indicating this may be output.

All. First charging blocking step (S230)

In the first full detection step (S220), if it is detected that the current battery is full, that is, when the first full signal is output, outputting a charge blocking signal to the communication connected smart charger 200 to cut off the supply of charging current. to be. The reason for blocking charging by outputting the charging cutoff signal to the smart charger 200 is, otherwise, the smart charger 200 continuously attempts to charge the battery until the charging current reaches 0. 1 If it is determined that the battery is full through the full-charge detection step (S220), the smart charger 200 may output the first charge-blocking signal to block charging. The smart charger 200 receiving the first charge blocking signal may block supply of a charging current to the battery, so that charging of the battery may be stopped. Such an operation may be performed by the charging blocking unit 146 of the charging control unit 140 described later.

2.3. Maintaining the first rest state (S300)

The first idle state maintaining step is a step of maintaining a state in which charging of the battery is stopped by the first charging blocking step (S230) for a predetermined time. Here, the predetermined time may mean a time required until a battery in which resistance, temperature, etc. is increased due to charging is stabilized.

As described above, when the battery is fully charged with the first charging voltage, stopping charging of the battery and maintaining the state may be to minimize the effect of temperature on battery life prediction. When charging, the longer the life of the battery, the higher the resistance of the cell or the like, and thereby the temperature of the battery increases. Accordingly, in order to minimize the influence of other factors such as the resistance and temperature of the battery in the second charging step (S400) described later, the first state is performed until the state of the battery whose resistance and temperature are raised due to charging is stabilized. It is possible to perform an idle state maintenance step.

2.4. Second charging step (S400)

In the second charging step, after the first idle state maintaining step (S300), the charging voltage of the smart charger 200 connected to the communication is set to a preset second charging voltage value, so that the battery is fully charged with the second charging voltage. It is a step to control. This may allow the battery to be charged to the second charging voltage in the same manner as the first charging step (S200).

end. Second charging voltage setting step (S410)

The charging voltage of the smart charger 200 connected to the communication through the communication connection step (S100) may be set to a preset second charging voltage value. Setting the charging voltage of the smart charger 200 to the second charging voltage may be, for example, by providing the second charging voltage value information to the smart charger 200 through CAN communication. Accordingly, the smart charger 200 receiving the second charging voltage value information may output the voltage with the second charging voltage value to charge the battery. This may be achieved by the charging voltage setting unit 142 of the charging control unit 140.

I. The second full detection step (S420)

After the second charging voltage setting step (S410), while the charging voltage is supplied to the charging current from the smart charger 200 set to the second charging voltage value and is charged, detecting whether the battery is fully charged with the first charging voltage It is a step. This monitors the voltage of the battery measured at a predetermined periodic interval, as in the first full charge detection step (S220), to detect whether the battery currently being charged by the smart charger 200 is full with the second charge voltage. Can. This may be performed by the charging blocking unit 146 of the charging control unit 140, and when the battery is detected to be charged with the second charging voltage, a second charging signal indicating this may be output.

All. Second charging blocking step (S430)

If it is detected that the current battery is full in the second full-charge detection step (S420), that is, when the second full-charge signal is output, a second charging cut-off signal is output to the communication connected smart charger 200 to block the supply of charging current. It is a step. The reason for blocking charging by outputting the second charge blocking signal to the smart charger 200 is to prevent the smart charger 200 from continuously attempting to charge the battery until the charging current reaches zero as described above. It can be sake. The smart charger 200 receiving the second charge blocking signal may block charging of the charging current to the battery to stop charging the battery.

2.5. Second resting state maintenance step (S500)

The second idle state maintaining step is a step of maintaining a state in which charging of the battery is stopped by the second charging blocking step (S430) for a predetermined time. Here, the predetermined time may be described as a time required until a battery in which resistance, temperature, and the like are increased due to charging is stabilized.

Thus, when the battery is fully charged with the second charging voltage, stopping charging of the battery and maintaining the state may be to minimize the influence of temperature on the life prediction. As described in the first idle state maintaining step (S300), the longer the life of the battery during charging, the higher the resistance and temperature. Accordingly, in order to minimize the influence of other factors such as resistance and temperature of the battery in performing the open-voltage (OCV) measurement step (S600) described later, when the state of the battery in which the resistance and temperature are raised due to charging is stabilized Until the second idle state can be performed. Through this, the influence of other factors is minimized in the open voltage (OCV) measurement step (S600) described below, so that the stable open voltage (OCV) measurement is possible, thereby improving its accuracy.

2.6. Open voltage (OCV) measurement step (S600)

The open-voltage (OCV) measurement step may be a step of measuring the open-circuit voltage (OCV) of the battery that is in the open-voltage (OCV) state by the second idle state maintaining step (S500). In the present invention, that the battery is in an open voltage (OCV) state, the state of the battery in which the resistance and temperature are increased due to charging, the second resting state maintaining step (S500) for accurate open voltage (OCV) measurement It refers to the stabilized state by maintaining the idle state for a predetermined time. Measuring the open voltage (OCV) of the battery is to measure the voltage applied to both ends of the battery in the no-load state, and measures the open voltage (OCV) in a stabilized state through the second idle state maintenance step (S500). By doing so, it is possible to measure a stable open voltage (OCV) value with minimal influence of resistance and temperature, and accordingly, an effect of improving the accuracy of life prediction using this can be exhibited.

The open voltage (OCV) measuring step may be performed by the voltage measuring unit 130 as a second charging blocking signal is output from the charging blocking unit 146 of the charging control unit 140.

2.7. Resistance calculation step (S700)

As a step of calculating the resistance value for the current state of the battery after the above steps, the open voltage (OCV) value measured through the open voltage (OCV) measurement step (S600), the second charging voltage value and the preset The resistance value of the current battery state may be calculated using the constant current (CC) value. The resistance value can be calculated by the following equation (1).

Equation (1): Resistance = (second charging voltage-OCV voltage) / constant current (CC)

Here, the OCV voltage is an open voltage (OCV) value measured in the open voltage (OCV) measurement step (S710) after the second idle state maintaining step (S500) in a state full of the second charging voltage as described above. Can.

2.8. Life expectancy stage (S800)

As a step of predicting the life of the current battery by comparing the resistance value calculated through the resistance calculation step (S700) with previously prepared data, it may be made by the life prediction unit 160 to be described later. Here, the pre-prepared data is the first and second charging voltages, which are voltages corresponding to a section in which the battery is frequently used under conditions of charge/discharge frequency, temperature, and current according to the life of the battery obtained in advance through experiments. It may be data including the resistance change value at.

Therefore, the lifespan corresponding to the resistance value can be predicted as the lifespan of the current battery by comparing the previously prepared data with the resistance value calculated in the resistance calculation step (S600).

Through these steps, the present invention predicts the life of the battery by using a resistance to a section in which the battery is frequently used without discharging the battery, so that the battery does not need to be fully discharged, thereby increasing the chance of life prediction. The current battery usage pattern is applied to predict the accuracy, so the accuracy can be improved.

3. Battery pack 100 using the life prediction method according to the present invention

Referring to FIG. 2, a battery pack 100 using a life prediction method according to the present invention will be described. 2, the battery pack 100 according to the present invention may be configured to include the following configuration.

3.1. Battery cell (110)

The battery pack 100 according to the present invention may include one or more battery cells connected in series or in parallel.

3.2. Communication unit 120

As a configuration for connecting communication with the smart charger 200 connected to the battery pack 100, the above-described communication connection step (S100) may be performed. The communication unit may connect communication with the smart charger 200 using, for example, CAN communication. By being communicatively connected to the smart charger 200 by the communication unit, the battery pack 100 can control the smart charger 200 to control charging of the battery cells 110.

3.3. Voltage measurement unit 130

The voltage measurement unit is a configuration that measures the voltage of the battery cells 110 at a predetermined periodic interval, and through this, the fullness detection unit 144, which will be described later, can detect whether the battery cells 110 being charged are full.

In addition, the voltage measurement unit, when the battery cell 110 is full of the second charging voltage from the charging blocking unit 146 to be described later is output a second charge blocking signal for blocking further charging, the time from the output time After flowing, the voltage can be measured. Here, measuring the voltage after the predetermined time has passed, the battery cells with increased resistance and temperature due to charging are stabilized, and the open voltage (OCV) is measured in a state where the influence of other factors such as resistance and temperature is minimized. This is for the following, which may be to perform the above-described open voltage (OCV) measurement step (S600). The open voltage (OCV) measured accordingly is a voltage applied to both ends of the battery in a state stabilized with the passage of a predetermined time, and is a stabilized voltage with minimal influence of other elements, which is a life prediction unit 160 to be described later. In can be used to predict the life of the battery pack 100. The accuracy of the open voltage (OCV) measured in the stabilized state can be improved by using it for life prediction.

3.4. Charging control unit 140

The charging control unit is configured to control the battery charger 110 to be fully charged with a predetermined charging voltage by controlling the smart charger 200 connected to the communication unit through the communication unit 120, and may include a detailed configuration as follows. have.

end. Charging voltage setting unit (142)

The charging voltage setting unit controls the battery cells 110 to be charged with the first charging voltage by setting the charging voltage of the smart charger 200 to a first charging voltage through a communication connection by the communication unit 120. Can. In this step, the first charging voltage setting step S210 of the above-described first charging step S200 may be performed.

In addition, through the communication connection by the communication unit 120, the charging voltage of the smart charger 200 may be set to a preset second charging voltage to control the battery cells 110 to be charged with the second charging voltage. Here, setting the charging voltage of the smart charger 200 to the second charging voltage, the battery cell 110 from the charging blocking unit 146, which will be described later, is full of the first charging voltage, which is a signal for blocking charging. 1 When the charge blocking signal is output, it can be performed after a predetermined time has passed since the output point. In this case, the predetermined time may be a time required until the battery having the resistance, temperature, etc. increased due to charging after the battery cells 110 are fully charged with the first charging voltage. . This may be that the second charging voltage setting step S410 of the second charging step S400 described above is performed.

Accordingly, the charging voltage setting unit controls the smart charger 200 to allow the battery cells 110 to be filled with the first charging voltage, and when it becomes an open voltage (OCV) state, the smart charger 200 is controlled to control the battery The cells 110 may be controlled to be filled with the second charging voltage.

I. Fullness detection unit (144)

The fullness detection unit may be configured to monitor whether the battery cells 110 are full of the first and second charging voltages by monitoring the voltage of the battery cells measured by the voltage measurement unit 130.

Specifically, while the charging voltage is supplied from the smart charger 200 whose charging voltage is set to the first charging voltage by the charging voltage setting unit 142 and being charged, the voltage measuring unit 130 performs battery charging at predetermined cycle intervals. The voltage of the cells 110 can be measured. Accordingly, the fullness detection unit may monitor the voltage of the battery cell 110 measured by the voltage measurement unit 130 to detect whether the fullness of the first charge voltage is satisfied. When it is sensed that the battery cells 110 are fully charged with a first charge voltage, a first full charge signal indicating this may be output. This may be the first full charge detection step S220 in the first charging step S200 described above.

Meanwhile, the battery cell 110 measured by the voltage measurement unit 130 while being charged by receiving the charging current from the smart charger 200 whose charging voltage is set to the second charging voltage by the charging voltage setting unit 142 It is possible to detect whether the second charging voltage is full by monitoring their voltage. When it is sensed that the battery cells 110 are fully charged with a second charging voltage, a second full signal indicating this may be output. This may be the second full charge detection step S420 of the second charge step S400.

All. Charging blocker (146)

As the battery cells 110 are detected as being filled with the first or second charging voltage by the full charge detection unit 144, the smart charger 200 is instructed to block charging to charge the battery cells 110. It is a stop configuration.

Specifically, first, when the first full charge signal indicating that the battery cells 110 are fully charged with the first charging voltage is output from the full charge detection unit 144, the charge blocking unit blocks the first charge with the smart charger 200. By outputting a signal, the charging current supply of the smart charger 200 may be blocked. Accordingly, the charging of the battery cells 110 may be stopped because the smart charger 200 no longer supplies a charging current in a state full of the first charging voltage. This is the first charging blocking step (S230) is performed, and accordingly, the first idle state maintaining step (S300) may be performed.

Thereafter, as the charging voltage of the smart charger 200 is set to the second charging voltage and charged by the charging voltage setting unit 142, the battery cells 110 from the full charge detection unit 144 are charged with the second charging voltage. As the second full charge signal indicating that the state is fully charged, the charge blocking unit may block the supply of the charging current of the smart charger 200 by outputting the second charge blocking signal to the smart charger 200. Accordingly, the charging of the battery cells 110 may be stopped because the smart charger 200 no longer supplies a charging current in a state full of the second charging voltage. This may be that the above-described second charging blocking step (S430) and the second idle state maintaining step (S500) are performed.

2.5. Storage unit (150)

The storage unit is configured to store data for predicting the life of the current battery pack 100 in the life prediction unit 160, which will be described later. The first and second charging voltage values, constant current (CC) values, previously prepared data, etc. This can be saved.

Here, the pre-prepared data is the first voltage, which is a voltage corresponding to a section in which the battery is frequently used under conditions of charge/discharge count, temperature, and current according to the life of the battery previously obtained through experiments as described above. , 2 It may be data including a resistance change value at the charging voltage.

Here, the constant current (CC) value may be set in advance during development.

2.6. Life Prediction Unit (160)

The life prediction unit is a configuration for predicting the life of the current battery pack 100, and may include a detailed configuration as follows.

end. Resistance calculator (162)

In the current battery pack state using the open voltage (OCV) measured after the battery cells 110 are fully charged with the second charging voltage, the second charging voltage and the constant current (CC) stored in the storage unit 150 As a configuration for calculating the resistance, it corresponds to the above-described resistance calculation step (S700). Calculating the resistance can be calculated by the following equation (1).

Equation (1): Resistance = (second charging voltage-OCV voltage) / constant current (CC)

Here, the OCV voltage, after the charging is stopped while the battery cells 110 are full of the second charging voltage by the charging blocking unit 146 as described above, the voltage measuring unit after a predetermined time ( It may be an open voltage (OCV) value measured through the open voltage (OCV) measurement step (S600) by 130.

I. Data comparison unit (164)

The data comparison unit compares the resistance value of the current battery pack calculated by the resistance calculation unit 162 with previously prepared data stored in the storage unit to predict the life of the current battery pack. The life prediction step S800 may be performed.

The first and second charging voltages, which are voltages corresponding to a section in which the battery is frequently used under conditions of charge/discharge count, temperature, and current according to the life of the battery previously obtained through the experiment stored in the storage unit 150 In the data including the resistance change value at, a section to which the resistance value calculated by the resistance calculation unit 162 belongs may be extracted, and a life corresponding thereto may be detected. Here, a life corresponding to the calculated resistance value may be predicted as a life state of the current battery pack 100.

Through such a configuration, the present invention has an effect of increasing the chance of life prediction because the battery does not need to be fully discharged because the life can be predicted by using the resistance to a section in which the battery is frequently used without discharging the battery. Exactly, the accuracy of the battery can be improved because current battery usage patterns are applied to predict life.

On the other hand, although the technical spirit of the present invention has been described in detail according to the above embodiment, it should be noted that the above embodiment is for the purpose of explanation and not for the limitation. In addition, those skilled in the art will appreciate that various embodiments are possible within the scope of the technical spirit of the present invention.

100: battery pack
110: battery cell
120: communication unit
130: voltage measurement unit
140: charging control
142: charging voltage setting unit
144: full detector
146: charging block
150: storage unit
160: life prediction unit
162: resistance calculator
164: data comparison unit

Claims (14)

In the battery life prediction method,
A communication connection step of connecting communication with a smart charger connected to the battery;
A first charging step of controlling charging such that a battery is fully charged with the first charging voltage by setting a charging voltage of a smart charger connected to communication through the communication connection step to a first charging voltage that is preset;
A first idle state maintaining step of maintaining the state for a predetermined time in a state in which charging of the battery is blocked as the battery is charged to the first charging voltage by the first charging step;
A second charging step of controlling charging so that the battery is fully charged with the second charging voltage by setting the charging voltage of the communication connected smart charger to a preset second charging voltage after the first idle state maintaining step;
A second dormant state maintaining the battery for a predetermined period of time in a state in which charging of the battery is blocked as the battery is charged to the second charging voltage by the second charging step;
An open voltage (OCV) measurement step of measuring an open voltage (OCV) of the battery after the second idle state maintenance step;
A resistance calculation step of calculating the resistance of the current battery state using the open voltage (OCV) measured through the open voltage (OCV) measurement step, the preset second charging voltage and constant current (CC);
A life prediction step of comparing a resistance value calculated through the resistance calculation step with previously prepared data, extracting a resistance section to which the calculated resistance value belongs, and detecting a corresponding life span to predict the life of the current battery;
Battery life prediction method comprising a. According to claim 1,
The first charging step,
A first charging voltage setting step of setting the charging voltage of the smart charger connected in communication through the communication connection step to a preset first charging voltage;
A first full charge detection step of detecting whether a battery is fully charged with the first charge voltage while being charged by receiving a charging current from a smart charger whose charge voltage is set to the first charge voltage by the first charge voltage setting step;
A first charging blocking step of blocking charging of the battery by outputting a charging blocking signal to a communication connected smart charger when the current battery is detected to be charged with the first charging voltage in the first charging detection step;
Battery life prediction method comprising a. According to claim 1,
The second charging step,
A second charging voltage setting step of setting the charging voltage of the smart charger connected to the communication to the preset second charging voltage through the communication connection step;
A second full charge detection step of detecting whether a battery is full of the second charge voltage while being charged by receiving a charging current from a smart charger in which the charge voltage is set as the second charge voltage by the second charge voltage setting step;
A second charge blocking step of blocking charging of the battery by outputting a charge blocking signal to a communication connected smart charger when the current battery is detected as being charged to the second charging voltage in the second full charge detection step;
Battery life prediction method comprising a. According to claim 1,
Calculating the resistance in the resistance calculation step,
Battery life prediction characterized in that it is calculated by the following equation (1) using the open voltage (OCV) measured through the open voltage (OCV) measurement step, the preset second charging voltage and constant current (CC) Way.
Equation (1): (second charging voltage-open voltage (OCV)) / constant current (CC) The method according to any one of claims 1 to 4,
The first and second charging voltage,
A method for predicting battery life, characterized in that it is a voltage value included in a section in which the battery is repeatedly used. One or more battery cells;
Communication unit for connecting the communication with the smart charger;
A voltage measuring unit measuring voltages of the battery cells at predetermined periodic intervals;
A charging control unit controlling the smart charger connected to the communication unit through the communication unit to control the battery cells to be filled with a predetermined first and second charging voltage;
A storage unit that stores data for predicting the life of the battery cells;
A life prediction unit for predicting the lifespan of the current battery cells based on the open voltage (OCV) value measured through the idle state after being filled with the second charging voltage by the charging control unit and the data stored in the storage unit;
Battery pack comprising a. The method of claim 6,
The charging control unit,
A charging voltage setting unit for sequentially setting the charging voltage of the smart charger connected to the communication unit through the communication unit to a preset first charging voltage and a second charging voltage, so that the battery cells are charged with respective corresponding charging voltages;
While the charging voltage of the smart charger is set to the first or second charging voltage by the charging voltage setting unit, while the battery cells are being charged, the full-charge detection unit detects whether the battery cells are filled with the first or second charging voltage ;
When it is sensed that the battery cells are fully charged with the first or second charging voltage by the full charge detection unit, a charge blocking signal is output to the smart charger to block charging of the battery cells full with the first or second charging voltage. Charge blocking unit;
Battery pack characterized in that it comprises a. The method of claim 7,
The charging voltage setting unit,
When communication with the smart charger is connected by the communication unit, the charging voltage of the smart charger is set to a preset first charging voltage to control charging so that the battery cells are filled with the first charging voltage,
The fullness detection unit,
Monitoring the voltage of the battery cells measured by the voltage measurement unit, and outputs a first full signal when it is detected that the first charge voltage of the battery cells is full,
The charge blocking unit,
When the first full-charge signal is output from the full-fledged sensing unit, the battery pack is characterized in that it blocks the charging of the battery cells by outputting a first charge-blocking signal to the smart charger. The method of claim 8,
The charging voltage setting unit,
When a first full charge signal is output from the charge blocking unit, after a predetermined time from the output time, the charging voltage of the smart charger is set to a preset second charge voltage to control charging so that the battery cells are full with the second charge voltage. And
The fullness detection unit,
Monitoring the voltage of the battery cells measured by the voltage measuring unit, and when it is detected that the battery cells are full of the second charging voltage, outputs a second full signal,
The charge blocking unit,
A battery pack characterized in that when the second full charge signal is output from the full charge detector, a second charge blocking signal is output to the smart charger to block charging of the battery cells. The method of claim 9,
The voltage measuring unit,
A battery pack characterized in that when a second charge blocking signal is output from the charge blocking unit, an open voltage (OCV) of the battery cells is measured after a predetermined time from the output point. The method of claim 10,
Data stored in the storage unit,
A battery pack comprising the predetermined first and second charging voltage values, constant current (CC) values, and pre-prepared data. The method of claim 11,
The life prediction unit,
A resistance calculating unit for calculating a resistance value by the following equation (1) using the open voltage (OCV) value measured by the voltage measuring unit, the second charging voltage value and the constant current (CC) value stored in the storage unit;
A battery pack comprising comparing a resistance value calculated from the resistance calculation unit with previously prepared data stored in the storage unit and predicting a lifespan corresponding to the calculated resistance value as a current lifespan.
Equation (1): (second charging voltage-open voltage (OCV)) / constant current (CC) The method of claim 11,
The first and second charging voltage,
The battery pack, characterized in that the voltage value included in the interval in which the battery cells are repeatedly used. A device comprising the battery pack according to claim 6.

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