JP7217681B2 - Measuring apparatus and measuring method for power storage device - Google Patents

Description

The present invention relates to a measuring apparatus and measuring method for measuring an electricity storage device.

Patent Literature 1 discloses an inspection method for determining the quality of a secondary battery based on the amount of voltage drop in the secondary battery during aging. In this inspection method, the secondary battery is stored for several days to several weeks with the positive electrode and the negative electrode left open, and the voltage is measured after the voltage drops due to self-discharge, thereby determining the quality of the secondary battery. .

JP 2015-072148 A

In the inspection method of Patent Document 1, parameters related to self-discharge, such as the self-discharge current of the secondary battery or the discharge resistance of the secondary battery through which the self-discharge current flows, are obtained based on the amount of voltage drop in the secondary battery during the aging time. is also possible. However, in order to obtain such parameters, it is necessary to store the secondary battery for several days to several weeks as an aging time until the voltage drops due to self-discharge.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object of the present invention is to obtain parameters relating to self-discharge of an electricity storage device in a short period of time.

According to one aspect of the present invention, an electricity storage device measuring apparatus includes: constant current supply means for supplying a constant current to the electricity storage device; voltage measurement means for measuring voltage of the electricity storage device; a control means for calculating a self-discharge current of the electric storage device or a discharge resistance of the electric storage device through which the self-discharge current flows, based on a voltage change.

According to another aspect of the present invention, a method for measuring an electricity storage device includes: supplying a constant current to the electricity storage device; measuring voltage of the electricity storage device; or the discharge resistance of the electrical storage device through which the self-discharge current flows.

According to this aspect, by supplying a constant current to the electricity storage device, the voltage change of the electricity storage device increases in a short time. Since the manner of this voltage change changes according to the magnitude of the discharge resistance of the electricity storage device, by detecting the voltage change of the electricity storage device, it is possible to obtain a parameter related to the self-discharge of the electricity storage device. Therefore, since it is not necessary to wait until the voltage of the electricity storage device drops due to self-discharge, it takes less time to obtain the parameters related to the self-discharge of the electricity storage device. Therefore, it is possible to obtain parameters related to self-discharge of the electricity storage device in a short period of time.

FIG. 1 is a diagram showing the configuration of an electric storage device inspection apparatus according to a first embodiment of the present invention. FIG. 2 is a flowchart of an inspection method using an inspection apparatus for power storage devices. FIG. 3 is a diagram showing an example of voltage change with respect to charging time of an electricity storage device. FIG. 4 is a block diagram showing the functional configuration of a controller according to the second embodiment. FIG. 5 is a flow chart of an inspection method according to the second embodiment. FIG. 6 is a diagram showing an example of voltage change with respect to charging time when the magnitude of the constant current charged to the power storage device is switched. FIG. 7 is a flow chart of an inspection method according to the third embodiment. FIG. 8 is a diagram showing an example of voltage change with respect to supply time when the direction of the constant current supplied to the electricity storage device is switched.

(First embodiment)
Hereinafter, an inspection apparatus (hereinafter simply referred to as "inspection apparatus") 1 for an electric storage device 10 according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG.

First, the configuration of the power storage device 10 and the configuration of the inspection apparatus 1 will be described with reference to FIG. 1 . FIG. 1 is a diagram showing the configuration of an inspection apparatus 1. As shown in FIG.

The power storage device 10 is, for example, a single power storage cell of a lithium ion secondary battery. The electric storage device 10 is not limited to a secondary battery (chemical battery), and may be an electric double layer capacitor, for example. Alternatively, the power storage device 10 may be a power storage module in which a plurality of power storage cells are connected in series.

The power storage device 10 is represented by an equivalent circuit model as shown in FIG. According to the equivalent circuit model, the electricity storage device 10 has a positive electrode 11 , a negative electrode 12 , an electricity storage section 13 , an internal resistance 14 and a parallel resistance 15 .

When a voltage higher than the cell voltage of the power storage device 10 is applied, the power storage unit 13 is charged by accumulating charges. In the storage unit 13, when the current flowing during charging is relatively small and the applied voltage is lower than the overvoltage, an electric double layer reaction occurs. a reaction occurs. The overvoltage of the electricity storage device 10 referred to here is the difference between the theoretical potential (equilibrium electrode potential) of the reaction thermodynamically required in the electrochemical reaction and the potential of the positive electrode 11 when the reaction actually progresses. be. Here, the capacitance of power storage unit 13 is Cst[F], and the current flowing through power storage unit 13 is Ist[A].

Internal resistance 14 is a series resistance connected in series to power storage unit 13 between positive electrode 11 and negative electrode 12 . Here, the resistance value of the internal resistor 14 is Rir [mΩ], and the current flowing through the internal resistor 14 is Iir [A].

Parallel resistor 15 is a discharge resistor connected in parallel to power storage unit 13 . A self-discharge current, a so-called leakage current, flows through the parallel resistor 15 . Here, the resistance value of the parallel resistor 15 is Rpr [kΩ], and the current flowing through the parallel resistor 15 is Ipr [A].

The inspection apparatus 1 is an apparatus for inspecting self-discharge in the electricity storage device 10 to check whether the electricity storage device 10 is normal. The inspection apparatus 1 includes a constant current source 2 as constant current supply means, a voltage sensor 3 as voltage measurement means, a controller 4 as control means, and a display section 5 .

The constant current source 2 is a DC power supply that supplies a constant current for detecting a self-discharge current to the electricity storage device 10 to charge the electricity storage device 10 . The constant current source 2 maintains the current of the power supply flowing through the electricity storage device 10 at a predetermined magnitude. The constant current source 2 charges the power storage device 10 by supplying a constant current that is smaller than the overvoltage in the power storage device 10 and that causes mainly an electric double layer reaction. At this time, the constant current supplied from the constant current source 2 is, for example, 10 [μA].

Here, when a constant voltage is applied to the electricity storage device 10 to charge the electricity storage device 10, the constant voltage that is smaller than the overvoltage in the electricity storage device 10 and that mainly causes the electric double layer reaction is stabilized. It is difficult to apply On the other hand, it is easy to supply a relatively small current using the constant current source 2 . Therefore, in the inspection apparatus 1, by using the constant current source 2, a constant current that is smaller than the overvoltage in the electric storage device 10 and that mainly causes an electric double layer reaction can be stably supplied.

The voltage sensor 3 measures the voltage of the electricity storage device 10 . The voltage sensor 3 measures the voltage of the electric storage device 10 twice or more including the state in which the constant current is supplied from the constant current source 2 . Voltage sensor 3 outputs an electrical signal corresponding to the detected voltage value of power storage device 10 to controller 4 .

The controller 4 is composed of a microcomputer having a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), and an input/output interface (I/O interface). The controller 4 controls various operations of the inspection apparatus 1 by reading programs stored in the ROM by the CPU. The controller 4 can also be composed of a plurality of microcomputers.

A controller 4 controls power supply from the constant current source 2 . An electrical signal from the voltage sensor 3 is input to the controller 4 . The controller 4 detects a voltage change of the electricity storage device 10 based on the measured voltage of the electricity storage device 10 . The controller 4 determines that the electricity storage device 10 is normal when the voltage change of the electricity storage device 10 is within the normal range, and determines that the electricity storage device 10 is abnormal when the voltage change of the electricity storage device 10 is not within the normal range. Determine that there is. In this way, the controller 4 determines whether the power storage device 10 is good or bad.

The display unit 5 displays information such as inspection results by the controller 4 and notifies the user. The display unit 5 is, for example, a touch screen, and is configured so that the user can visually recognize information and can operate the display unit 5 .

Next, with reference to FIGS. 2 and 3, an inspection method of the electricity storage device 10 for inspecting self-discharge in the electricity storage device 10 using the inspection apparatus 1 will be described. FIG. 2 is a flow chart of an inspection method using the inspection apparatus 1. As shown in FIG. FIG. 3 is a diagram showing an example of voltage change with respect to the charging time of the electricity storage device 10. As shown in FIG.

The inspection apparatus 1 performs inspection in an environment in which the temperature change of the power storage device 10 is suppressed, for example, by housing the power storage device 10 in a constant temperature bath capable of maintaining a constant ambient temperature.

In step S<b>1 , the inspection apparatus 1 is connected to the power storage device 10 , constant current is supplied from the constant current source 2 to start charging, and inspection of the power storage device 10 is started.

In step S<b>2 , the controller 4 causes the voltage sensor 3 to measure the voltage (initial voltage) of the electricity storage device 10 . An electric signal corresponding to the voltage value of the electric storage device 10 detected by the voltage sensor 3 is input to the controller 4 .

In step S3, the controller 4 determines whether or not the charging time, which is the elapsed time from the start of charging, has exceeded a predetermined time. The predetermined time is set in advance to such a length that a difference appears in the voltage change between when the power storage device 10 is normal and when it is abnormal. When it is determined in step S3 that the charging time has exceeded the predetermined time, the process proceeds to step S4. On the other hand, if it is determined in step S3 that the charging time has not exceeded the predetermined time, the process returns to step S2 to measure the voltage of power storage device 10 again.

In this way, by executing steps S2 and S3, the voltage sensor 3 detects the initial voltage when the constant current supply is started (when charging is started) and the charging voltage when the constant current is supplied from the constant current source 2. Measure the voltage and That is, the voltage sensor 3 measures the voltage of the electricity storage device 10 twice or more including the state in which the constant current is supplied from the constant current source 2 .

In step S<b>4 , the controller 4 detects voltage change of the electricity storage device 10 based on the voltage of the electricity storage device 10 measured by the voltage sensor 3 . Specifically, the controller 4 obtains an approximate straight line of the voltage change of the power storage device 10 based on the initial voltage at the start of charging and the charging voltage when the constant current is supplied from the constant current source 2 . More specifically, the controller 4 obtains an approximate straight line of voltage change by, for example, the least-squares method based on the voltage value of the electricity storage device 10 measured in each control cycle.

Alternatively, the controller 4 may detect the voltage change from the difference between the initial voltage at the start of charging and the charging voltage when the constant current is supplied from the constant current source 2 . In this case, since the voltage of the electric storage device 10 is measured twice by the voltage sensor 3, it is also possible to switch the voltage measurement using a multiplexer, for example. Therefore, the inspection device 1 can be simplified.

In step S5, it is determined whether or not the slope of the approximate straight line is within a predetermined range. If it is determined in step S5 that the slope of the approximate straight line is within the predetermined range between the upper limit value and the lower limit value, the power storage device 10 is in a normal state, so the process proceeds to step S6. On the other hand, if it is determined in step S5 that the slope of the approximate straight line is not within the predetermined range, that is, is greater than the upper limit value of the predetermined range or less than the lower limit value of the predetermined range, the power storage device 10 Since it is in an abnormal state, it transfers to step S7.

Here, the processing of steps S4 and S5 will be described with reference to the specific example of FIG. The horizontal axis of FIG. 3 is the charging time [s], which is the elapsed time from the start of charging of the power storage device 10, and the vertical axis is the difference between the voltage detected by the voltage sensor 3 and the initial voltage [μV]. is.

The data of the solid line shown in FIG. 3 is the voltage change when the power storage device 10 is in a normal state, and the straight line of the solid line is the approximate straight line Ln of the voltage change obtained by the process of step S4. On the other hand, the dotted line data shown in FIG. 3 is the voltage change when the power storage device 10 is in an abnormal state, and the broken straight line is the approximate straight line La of the voltage change obtained by the processing in step S4. Let Rn be the slope of the approximate straight line Ln, and Ra be the slope of the approximate straight line La.

In addition, the two dashed-dotted lines shown in FIG. 3 respectively indicate the upper limit Rmax and the lower limit Rmin of the slope of the approximate straight line. 10 is the slope in the normal state. The upper limit value Rmax and the lower limit value Rmin of the slope of the approximation straight line are set to, for example, ±10% of the approximation straight line obtained by actual measurement in advance using the power storage device 10 in a normal state.

Referring to FIG. 3, the approximate straight line Ln (slope Rn) of the voltage change of the power storage device 10 indicated by the solid line is between the upper limit value Rmax and the lower limit value Rmin of the slope of the approximate straight line. Therefore, the controller 4 determines that the power storage device 10 is in a normal state. On the other hand, the approximate straight line La (slope Ra) of the voltage change of the power storage device 10 indicated by the dotted line is not between the upper limit Rmax and the lower limit Rmin of the slope of the approximate straight line. Therefore, the controller 4 determines that the power storage device 10 is in an abnormal state.

Thus, the controller 4 determines whether the power storage device 10 is in a normal state or an abnormal state based on whether the slope of the approximate straight line is between the upper limit value Rmax and the lower limit value Rmin. determine whether That is, the controller 4 detects a voltage change of the electricity storage device 10 based on the measured voltage of the electricity storage device 10, and determines that the electricity storage device 10 is normal when the voltage change is within a normal range.

In the example shown in FIG. 3, it takes 600 [s] to determine whether the power storage device 10 is good or bad. The difference in slope from the approximate straight line La of change can be clearly confirmed after about 200 [s]. In this manner, the inspection apparatus 1 can determine whether the power storage device 10 is good or bad in a short time of about several minutes.

As described above, the power storage device 10 is charged with the constant current supplied from the constant current source 2, and the voltage change of the power storage device 10 detected by measuring the voltage two or more times including the state in which the constant current is supplied is normal. If it is within the range, it is determined that the power storage device 10 is normal. Therefore, it is not necessary to wait until the voltage of the electricity storage device 10 drops due to self-discharge, so the time required to determine the quality of the electricity storage device 10 is short. Therefore, it is possible to determine the quality of the electricity storage device 10 in a short time.

At this time, the constant current source 2 charges the storage device 10 by supplying a constant current that is smaller than the overvoltage in the storage device 10 and that mainly causes an electric double layer reaction.

Therefore, since the magnitude of the constant current is small, the ratio of the current Ist [A] flowing through power storage unit 13 to the current Iir [A] flowing through internal resistance 14 is large. Therefore, the difference in the slope of the charging curve depending on the presence or absence of the parallel resistor 15 becomes large, so it is easy to detect whether the power storage device 10 is normal.

In step S6, the controller 4 determines that the power storage device 10 is in a normal state, and notifies the user by displaying that effect on the display unit 5. FIG. On the other hand, in step S7, the controller 4 determines that the power storage device 10 is in an abnormal state, and notifies the user by displaying that effect on the display unit 5. FIG.

By executing the above processing, the quality determination of the electricity storage device 10 is completed.

Next, functions and effects of the first embodiment will be described.

An inspection apparatus 1 for an electricity storage device 10 for inspecting self-discharge in an electricity storage device 10 includes a constant current source 2 that supplies a constant current to the electricity storage device 10, and a constant current source 2 that supplies a constant current to the electricity storage device 10. A voltage sensor 3 that measures two or more times including a state in which power is supplied, detects a voltage change of the electricity storage device 10 based on the measured voltage of the electricity storage device 10, and detects a voltage change in the electricity storage device 10 when the voltage change is within a normal range. and a controller 4 that determines that is normal.

In addition, a method for inspecting the electricity storage device 10 for inspecting self-discharge in the electricity storage device 10 is to supply a constant current to the electricity storage device 10, adjust the voltage of the electricity storage device 10, and adjust the voltage of the electricity storage device 10 to Measurement is performed twice or more including the state, voltage change of the electricity storage device 10 is detected based on the measured voltage of the electricity storage device 10, and the electricity storage device 10 is determined to be normal when the voltage change is within a normal range.

According to these configurations, a constant current is supplied from the constant current source 2 to the electricity storage device 10, and the voltage change of the electricity storage device 10 detected by measuring the voltage two or more times including the state in which the constant current is supplied is within the normal range. If it is within the range, it is determined that the power storage device 10 is normal. Therefore, it is not necessary to wait until the voltage of the electricity storage device 10 drops due to self-discharge, so the time required to determine the quality of the electricity storage device 10 is short. Therefore, it is possible to determine the quality of the electricity storage device 10 in a short time.

In addition, it is easier to supply a relatively small current using the constant current source 2 compared to supplying a relatively low constant voltage to the power storage device 10 . Therefore, in the inspection apparatus 1, by using the constant current source 2, a constant current that is smaller than the overvoltage in the electric storage device 10 and that mainly causes an electric double layer reaction can be stably supplied.

In addition, the constant current source 2 supplies a constant current that is smaller than the overvoltage in the electricity storage device 10 and that mainly causes an electric double layer reaction to charge the electricity storage device 10 .

According to this configuration, since the magnitude of the constant current is small, the ratio of the current Ist [A] flowing through power storage unit 13 to the current Iir [A] flowing through internal resistance 14 increases. Therefore, the difference in the slope of the charging curve depending on the presence or absence of the parallel resistor 15 becomes large, so it is easy to detect whether the power storage device 10 is normal.

Further, the voltage sensor 3 measures the initial voltage when the constant current supply is started and the charging voltage when the constant current is supplied from the constant current source 2, and the controller 4 measures the initial voltage and the charging voltage. Based on this, the voltage change of the electricity storage device 10 is detected.

According to this configuration, the controller 4 detects the voltage change from the difference between the initial voltage when the constant current supply is started and the charging voltage when the constant current is supplied from the constant current source 2 . In this case, since the voltage of the electric storage device 10 is measured twice by the voltage sensor 3, it is also possible to switch the voltage measurement using a multiplexer, for example. Therefore, the inspection device 1 can be simplified.

In the above embodiment, the voltage sensor 3 measures the voltage of the power storage device 10 as the initial voltage after charging of the power storage device 10 is started. 3 may measure the voltage of the electrical storage device 10 as the initial voltage. Even in this case, since the voltage of the electricity storage device 10 can be measured two or more times including the state in which the constant current is supplied, an approximate straight line of voltage change can be obtained.

(Second embodiment)
Next, an inspection apparatus 1 according to a second embodiment will be described. FIG. 4 is a block diagram showing the functional configuration of the controller 4 according to the second embodiment.

The controller 4 of this embodiment includes a constant current source 2 that sequentially supplies constant currents with different current values to the electricity storage device 10, and a voltage sensor 3 that measures the voltage of the electricity storage device 10 for each constant current supplied to the electricity storage device 10. , and a process of inspecting the power storage device 10 is executed.

Specifically, the controller 4 calculates the discharge resistance Rpr through which the self-discharge current Ipr of the storage device 10 flows or the self-discharge current Ipr based on the voltage change of the storage device 10 measured by the voltage sensor 3 for each constant current. .

In this way, the inspection device 1 including the controller 4 of this embodiment constitutes a measurement device that measures the self-discharge current Ipr or the discharge resistance Rpr of the power storage device 10 . At least one of the self-discharge current Ipr and the discharge resistance Rpr is hereinafter also referred to as "a parameter relating to self-discharge".

The controller 4 includes an operation reception unit 41 , a current switching unit 42 , a current command unit 43 , a voltage acquisition unit 44 , a storage unit 45 , a calculation unit 46 and a device determination unit 47 . The storage unit 45 includes a constant current value storage unit 451 that stores at least two current values, and a voltage change storage unit 452 that stores changes in the voltage of the electricity storage device 10 measured by the voltage sensor 3 .

The operation reception unit 41 receives operation information generated by a user's input operation to an input device such as a keyboard and a mouse. Upon receiving operation information instructing execution of inspection processing of power storage device 10 , operation accepting unit 41 outputs a control signal for supplying a constant current to power storage device 10 to current switching unit 42 .

The current switching unit 42 constitutes switching means for switching the constant current supplied to the electricity storage device 10 . Upon receiving the control signal from the operation receiving unit 41, the current switching unit 42 of the present embodiment acquires the first current value for detecting the self-discharge current Ipr of the power storage device 10 from the constant current value storage unit 451. and outputs the acquired first current value to the current command unit 43 .

The first current value is smaller than the overvoltage in the electricity storage device 10 when the electricity storage device 10 is charged by supplying a constant current to the electricity storage device 10 as in the first embodiment, and is mainly the electric double layer. It is set to the magnitude at which the reaction occurs. Specifically, the first current value is set to be one or several times the reference value of the self-discharge current Ipr of the power storage device 10 . For example, the first current value is set to 10 [μA] which is one times the reference value of the self-discharge current Ipr.

The reference value of the self-discharge current Ipr is known information, for example, statistical data summarizing the self-discharge currents Ipr of a large number of power storage devices 10, or the self-discharge current of a specific power storage device 10 with normal electrical characteristics. It is determined in advance using the Ipr test result or the like.

After outputting the first current value to the current command unit 43, the current switching unit 42 determines whether or not a predetermined switching condition is satisfied for switching the constant current supplied from the constant current source 2 to the power storage device 10. do.

For example, as in the first embodiment, the current switching unit 42 sets the charging time, which is the elapsed time after the constant current having the first current value is supplied from the constant current source 2 to the power storage device 10, for a predetermined time. is exceeded, it is determined that the switching condition is satisfied. Alternatively, the current switching unit 42 may determine that the switching condition is satisfied when a control signal for switching the constant current is received from the operation receiving unit 41 by the user's input operation.

When determining that the predetermined switching condition is satisfied, the current switching unit 42 acquires a second current value larger than the first current value from the constant current value storage unit 451, and the acquired second current value is output to the current command unit 43 . Thus, the current switching unit 42 switches the constant current supplied to the power storage device 10 between the constant current indicating the first current value and the constant current indicating the second current value. Hereinafter, the constant current indicating the first current value is also simply referred to as "first constant current", and the constant current indicating the second current value is also simply referred to as "second constant current".

The second current value is set several tens of times or more the reference value of the self-discharge current Ipr of the electricity storage device 10 . For example, the second current value is set to fifty times the reference value of the self-discharge current Ipr. This second current value is acquired by the current switching unit 42 and output to the current command unit 43 .

When the current command unit 43 acquires the first or second current value from the current switching unit 42, the current command unit 43 transmits to the constant current source 2 a command signal for instructing supply of constant current indicating the acquired current value. Thereby, the constant current source 2 supplies the electric storage device 10 with a constant current indicating the current value instructed by the command signal.

In the present embodiment, the constant current source 2 switches the constant current supplied to the power storage device 10 to the second current value after maintaining the constant current at the first current value for a predetermined time. That is, the constant current source 2 supplies a first constant current to the electricity storage device 10 for a predetermined period of time, and then supplies a second constant current to the electricity storage device 10 for a specific period of time. The specified period of time may be the same duration as the predetermined period of time or may be shorter than the predetermined period of time.

The voltage acquisition unit 44 acquires a detection signal from the voltage sensor 3 that measures the voltage of the power storage device 10 for each constant current switched by the current switching unit 42 . For example, the voltage acquisition unit 44 obtains an electric signal corresponding to the voltage value of the power storage device 10 from the voltage sensor 3 from the start of the supply of the first constant current until the end of the supply of the second constant current. receive. The voltage acquisition unit 44 records the received electrical signals in the voltage change storage unit 452 in chronological order.

The constant current value storage unit 451 stores at least the first and second current values described above. For example, the first and second current values may be stored in the constant current value storage unit 451 in advance, or may be recorded in the constant current value storage unit 451 by the operation reception unit 41 in accordance with the user's input operation. may

In the voltage change storage unit 452 , the voltage change measured for each constant current supplied to the electricity storage device 10 is recorded by the voltage acquisition unit 44 . The data indicating the voltage change of the electricity storage device 10 recorded in the voltage change storage unit 452 is processed by the calculation unit 46 .

The calculation unit 46 constitutes control means for calculating the self-discharge current Ipr and the discharge resistance Rpr of the storage device 10 based on the voltage change of the storage device 10 measured by the voltage sensor 3 for each constant current having a different current value. The calculation unit 46 of this embodiment includes a leakage current calculation unit 461 and a discharge resistance calculation unit 462 .

Leakage current calculator 461 obtains the slope of the voltage change of power storage device 10 for each constant current supplied to power storage device 10 . Then, the leakage current calculation unit 461 is a current calculation means for calculating the self-discharge current Ipr of the electricity storage device 10 using each slope of the voltage change of the electricity storage device 10 and each current value of the first and second constant currents obtained. configure.

Leakage current calculation unit 461 refers to voltage change storage unit 452 and detects voltage change of power storage device 10 for each constant current supplied to power storage device 10 . Specifically, as shown in FIG. 3, the leakage current calculation unit 461 is based on the initial voltage at the start of constant current supply and the charging voltage when the constant current is supplied from the constant current source 2. A slope of voltage change of the electric storage device 10 is obtained.

Instead, the leakage current calculation unit 461 refers to the voltage change storage unit 452, obtains the approximate straight line Ln of the voltage change of the power storage device 10 for each constant current supplied to the power storage device 10, and calculates the approximate straight line Ln. may be used as the slope of the voltage change.

Leakage current calculation unit 461 calculates self-discharge current Ipr of power storage device 10 using a formula for obtaining electrostatic capacitance Cst of power storage unit 13 , which is a capacitive component of power storage device 10 . A method of calculating the self-discharge current Ipr of the power storage device 10 will be described below.

The formula for obtaining the capacitance Cst of the power storage unit 13 is obtained by combining the self-discharge current Ipr of the power storage device 10 and the slope A1 of the voltage change when the power storage device 10 is charged with a constant current indicating the first current value I1. can be expressed as in the following equation (1).

Furthermore, the formula for obtaining the capacitance Cst of the power storage unit 13 is obtained by combining the second current value I2 and the slope A2 of the voltage change when the power storage device 10 is charged with the constant current indicating the second current value I2. can be expressed as in the following equation (2).

With respect to formula (2), the amount of charge per unit time accumulated in the capacitance Cst of the power storage unit 13 , that is, the current Ist [A] charged in the capacitance Cst is the current Ist [A] supplied to the power storage device 10 . It corresponds to a value (I2-Ipr) obtained by subtracting the self-discharge current Ipr from the current value I2 of the second constant current. However, the current value I2 of the second constant current, which is the current flowing through the internal resistor 14 shown in FIG. ) can be approximated as

Therefore, in the above formula (2), the current value I2 of the second constant current is used instead of the current value (I2−Ipr) obtained by subtracting the self-discharge current Ipr from the current value I2 of the second constant current. ing.

Next, by solving equations (1) and (2) for the self-discharge current Ipr, the following equation (4) is derived.

In this way, by substituting the slopes A1 and A2 of the voltage change detected for each constant current and the current values I1 and I2 of the constant current into the formula for obtaining the capacitance Cst of the power storage unit 13, the self A discharge current Ipr can be calculated.

Therefore, the leakage current calculator 461 obtains the slope A1 of the voltage change corresponding to the first constant current and the slope A2 of the voltage change corresponding to the second constant current. , to obtain the current value I1 of the first constant current and the current value I2 of the second constant current.

Leakage current calculator 461 then substitutes these parameters into equation (4) to calculate self-discharge current Ipr. Leakage current calculator 461 outputs the calculated self-discharge current Ipr of power storage device 10 to discharge resistance calculator 462 .

The discharge resistance calculation unit 462 constitutes resistance calculation means for calculating the discharge resistance Rpr of the electricity storage device 10 based on the self-discharge current Ipr output from the leakage current calculation unit 461 . In the present embodiment, the discharge resistance calculator 462 calculates the discharge resistance Rpr of the electricity storage device 10 by dividing the open circuit voltage (VOC) of the electricity storage device 10 by the self-discharge current Ipr of the electricity storage device 10 .

The open-circuit voltage (VOC) of the electricity storage device 10 may be the voltage value of the electricity storage device 10 measured by the voltage sensor 3 before starting to supply the constant current, or the test results of the electricity storage device 10 may be used. A predetermined voltage value may be used.

Note that instead of the calculation method described above, the discharge resistance calculation unit 462 pre-stores in the storage unit 45 a correspondence table or function representing the relationship between the self-discharge current Ipr of the electric storage device 10 and the discharge resistance Rpr. A table or function may be used to calculate the discharge resistance Rpr.

The discharge resistance calculation unit 462 outputs the calculated discharge resistance Rpr of the electricity storage device 10 to the device determination unit 47 .

The device determination unit 47 constitutes determination means for determining that the electricity storage device 10 is normal based on the self-discharge current Ipr or the discharge resistance Rpr calculated by the calculation unit 46 .

In the present embodiment, the device determination unit 47 determines whether the power storage device 10 is normal based on the discharge resistance Rpr of the power storage device 10 output from the discharge resistance calculation unit 462 . For example, the device determination unit 47 determines whether or not the calculated value of the discharge resistance Rpr of the electricity storage device 10 is within a predetermined resistance range. The upper and lower limits of the predetermined resistance range are determined in advance using statistical data obtained by aggregating the discharge resistances Rpr of a large number of power storage devices 10, test results of a specific power storage device 10 with normal electrical characteristics, or the like. . This resistance range is stored in the storage unit 45, for example.

When determining that the calculated value of the discharge resistance Rpr is within the predetermined resistance range, the device determination unit 47 determines that the electricity storage device 10 is in a normal state, and determines that the calculated value of the discharge resistance Rpr is within the predetermined range. If it is determined that the power storage device 10 does not exist, it is determined that the power storage device 10 is abnormal.

Further, the device determination unit 47 acquires the self-discharge current Ipr of the power storage device 10 instead of the discharge resistance Rpr of the power storage device 10, and determines whether the power storage device 10 is in a normal state based on the self-discharge current Ipr. You may make it judge.

In this case, the device determination unit 47 determines whether or not the calculated value of the self-discharge current Ipr is within the predetermined current range. , the power storage device 10 is determined to be in a normal state. The predetermined current range is determined in advance using statistical data or test results of the self-discharge current Ipr, and is stored in the storage unit 45, for example, in the same manner as the resistance range.

The device determination unit 47 outputs to the display unit 5 determination results indicating whether the power storage device 10 is in a normal state or an abnormal state. As a result, the determination result of the power storage device 10 by the device determination unit 47 is displayed on the screen of the display unit 5 .

In the above embodiment, the current switching unit 42 switches the constant current supplied to the power storage device 10 from the first current value I1 to the second current value I2, but it is not limited to this. For example, the current switching unit 42 first causes the power storage device 10 to supply a constant current having the second current value I2, and then changes the constant current to be supplied to the power storage device 10 from the second current value I2 to the first current value. It may switch to the value I1. Even in this case, the controller 4 can calculate the self-discharge current Ipr and the discharge resistance Rpr of the power storage device 10 .

Further, in the above embodiment, the current switching unit 42 controls the operation of the constant current source 2 so as to sequentially supply constant currents of different current values to the power storage device 10. However, the capacitance Cst of the power storage unit 13 is known. If so, only a constant current having the first current value I1 may be supplied.

In this case, the capacitance Cst of the power storage unit 13 is stored in advance in the storage unit 45, and the leakage current calculation unit 461 acquires the capacitance Cst of the power storage unit 13 from the storage unit 45 and calculates the first current value I1. and the slope A1 of the voltage change corresponding to the first current value I1. Current calculator 461 then substitutes these parameters into equation (1) to calculate self-discharge current Ipr of power storage device 10 .

The capacitance Cst of the power storage unit 13 stored in the storage unit 45 is statistical data obtained by aggregating the capacitances Cst of the power storage units 13 in a large number of power storage devices 10, or a specific power storage device 10 having normal electrical characteristics. is determined in advance using the test results of Regarding the capacitance Cst of the power storage unit 13, the power storage device 10 is charged with a constant current that indicates the second current value I2, and the slope A2 of the voltage change at that time and the second current value I2 are expressed by the formula ( 2) to obtain the capacitance Cst of the storage unit 13 .

Next, a method for inspecting the power storage device 10 including a method for measuring parameters relating to self-discharge of the power storage device 10 using the inspection apparatus 1 according to the present embodiment will be described with reference to FIGS. 5 and 6. FIG. FIG. 5 is a flow chart of an inspection method using the inspection apparatus 1. As shown in FIG. FIG. 6 is a diagram showing an example of voltage change with respect to the charging time of the electricity storage device 10. As shown in FIG.

The inspection method according to the present embodiment includes steps S41 to S43 and step S50 instead of steps S5 to S7 in the procedure of the inspection method shown in FIG. Here, the processing of steps S41 to S43 and the processing of step S50 will be described in detail.

In step S1, the inspection apparatus 1 is connected to the power storage device 10, the constant current source 2 supplies a constant current having the first current value I1 to start charging, and the power storage device 10 is started to be inspected.

In step S<b>2 , the controller 4 causes the voltage sensor 3 to measure the voltage (initial voltage) of the electricity storage device 10 . An electric signal corresponding to the voltage value of the electric storage device 10 detected by the voltage sensor 3 is input to the controller 4 .

In step S3, the controller 4 determines whether or not the charging time, which is the elapsed time from the start of charging, has exceeded a predetermined time. The predetermined time is set in advance to such a length that a difference appears in the voltage change between when the power storage device 10 is normal and when it is abnormal. When it is determined in step S3 that the charging time has exceeded the predetermined time, the process proceeds to step S4. On the other hand, if it is determined in step S3 that the charging time has not exceeded the predetermined time, the process returns to step S2 to measure the voltage of power storage device 10 again.

In step S<b>4 , the controller 4 detects voltage change of the electricity storage device 10 based on the voltage of the electricity storage device 10 measured by the voltage sensor 3 . Specifically, the controller 4 obtains an approximate straight line of the voltage change of the power storage device 10 based on the initial voltage at the start of charging and the charging voltage when the constant current is supplied from the constant current source 2 . More specifically, the controller 4 obtains an approximate straight line of voltage change by, for example, the least-squares method based on the voltage value of the electricity storage device 10 measured in each control cycle.

In step S41, the controller 4 determines whether or not the number of times of measurement, which is the number of times the approximate straight line of the measured voltage change is obtained, is less than two times. If it is determined in step S41 that the number of times of measurement is less than two, it is necessary to switch the constant current supplied to the electricity storage device 10, so the process proceeds to step S42.

In step S<b>42 , the controller 4 switches the magnitude of the constant current supplied to the electricity storage device 10 . In this embodiment, the controller 4 switches the constant current supplied to the power storage device 10 from the first constant current to the constant current having the second current value I2 larger than the first current value I1.

After that, the controller 4 returns to step S1 to start charging by supplying a second constant current from the constant current source 2, and measures the voltage of the power storage device 10 for a predetermined period of time in steps S2 and S3. Then, in step S4, the controller 4 obtains an approximate straight line of voltage change corresponding to the second constant current.

If it is determined in step S41 that the number of times of measurement has reached two, the parameters necessary for calculating the self-discharge current Ipr of power storage device 10 are obtained, so the process proceeds to step S43.

In step S43, the controller 4 calculates the self-discharge current Ipr of the electricity storage device 10 based on the slope of the voltage change of the electricity storage device 10 obtained for each constant current. In this embodiment, the controller 4 uses, as the parameters, the first current value I1, the slope A1 of the approximate straight line corresponding to the first constant current, the second current value I2, and the second constant current The self-discharge current Ipr of the electric storage device 10 is calculated using the slope A2 of the corresponding approximate straight line. Specifically, the controller 4 calculates the self-discharge current Ipr of the electricity storage device 10 by substituting the above parameters into the above equation (4).

In step S<b>50 , controller 4 determines whether power storage device 10 is normal based on self-discharge current Ipr of power storage device 10 .

For example, the controller 4 divides the open-circuit voltage of the storage device 10 by the self-discharge current Ipr of the storage device 10 to obtain the discharge resistance Rpr of the storage device 10, and determines whether the discharge resistance Rpr is within a predetermined resistance range. judge. When it is determined that discharge resistance Rpr is within the predetermined resistance range between the upper limit and the lower limit, controller 4 determines that power storage device 10 is in a normal state. On the other hand, if it is determined that the discharge resistance Rpr is not within the predetermined resistance range, that is, is larger than the upper limit of the resistance range or smaller than the lower limit of the resistance range, the controller 4 controls the power storage device 10 is determined to be in an abnormal state.

Alternatively, controller 4 may determine whether power storage device 10 is in a normal state by determining whether self-discharge current Ipr of power storage device 10 is within a predetermined current range. Alternatively, the controller 4 may store in advance a diagnostic table indicating normality or abnormality of the power storage device 10 for each current value of the self-discharge current Ipr. In this case, after calculating the self-discharge current Ipr of the electric storage device 10, the controller 4 refers to the diagnosis table and identifies the state of the electric storage device 10 associated with the calculated self-discharge current Ipr.

By executing the above processing, the quality determination of the electricity storage device 10 is completed.

Note that in the example of FIG. 5, the controller 4 switches the magnitude of the constant current supplied to the electricity storage device 10 only once, and obtains the slope of the voltage change of the electricity storage device 10 twice, thereby causing self-discharge of the electricity storage device 10. A current Ipr was calculated. Instead of this, a plurality of self-discharge currents Ipr are calculated by switching the magnitude of the constant current a plurality of times and sequentially obtaining the slope of the approximate straight line of the voltage change, and statistical values such as the average value or median value of these are calculated. You may use it as a final result.

Next, the processing of step S43 will be described with reference to the specific example of FIG. The horizontal axis of FIG. 6 is the charging time [s], which is the elapsed time from the start of charging of the power storage device 10, and the vertical axis is the difference between the voltage detected by the voltage sensor 3 and the initial voltage [μV]. is.

The predetermined time T1 is a period during which the power storage device 10 is charged with a constant current indicating the first current value I1, and the predetermined time T2 is a period during which the power storage device 10 is charged with a constant current indicating the second current value I2 after switching. is the period during which the battery is charged to The first current value I1 is 10 [μA] and the second current value I2 is 100 [μA].

The solid line data shown in FIG. 6 is the voltage change when the power storage device 10 is in a normal state, and the solid straight lines are the approximate line Ln1 of the voltage change corresponding to the first constant current and It is an approximate straight line Ln2 of the voltage change corresponding to the constant current. Both the approximation straight line Ln1 and the approximation straight line Ln2 are straight lines obtained by the process of step S4.

On the other hand, the dotted line data shown in FIG. 6 is the voltage change when the power storage device 10 is in an abnormal state, and the dashed straight line is the approximate straight line La1 of the voltage change corresponding to the first constant current and the second constant current. It is an approximate straight line La2 of voltage change corresponding to two constant currents. Both the approximate straight line La1 and the approximate straight line La2 are straight lines obtained by the process of step S4.

Referring to FIG. 6, the slopes of the approximate straight lines Ln1 and Ln2 for the power storage device 10 in the normal state are greater than the slopes of the approximate straight lines La1 and La2 for the power storage device 10 in the abnormal state. Recognize.

This is because the electricity storage device 10 in a normal state has a larger discharge resistance Rpr and a smaller self-discharge current Ipr than the electricity storage device 10 in an abnormal state. This is because electric charges are likely to be accumulated in the capacitance Cst of . Thus, when a constant current is supplied to the electricity storage device 10, the voltage change of the electricity storage device 10 increases as the discharge resistance Rpr of the electricity storage device 10 increases.

For example, when calculating the self-discharge current Ipr of the electricity storage device 10 in the normal state, the controller 4 of the present embodiment uses the first current value I1, the slope of the approximate straight line Ln1, and the second current value I2. , and the slope of the approximation straight line Ln2 are obtained and substituted into the above equation (4). In this way, by supplying constant currents with different current values to the electricity storage device 10 and obtaining the slope of the voltage change for each constant current, the self-discharge current Ipr of the electricity storage device 10 can be obtained.

After obtaining the self-discharge current Ipr of the electricity storage device 10, the controller 4 determines the quality of the electricity storage device 10 based on the self-discharge current Ipr. Note that the controller 4 determines whether the slope of the approximate straight line is between the upper limit and the lower limit for each constant current, as shown in FIG. is in a normal state or in an abnormal state.

In this embodiment, the controller 4 switches the magnitude of the constant current supplied from the constant current source 2 to the positive electrode 11 of the electricity storage device 10 to calculate the self-discharge current Ipr of the electricity storage device 10, but the present invention is limited to this. not a thing For example, the connection relationship between the constant current source 2 and the electricity storage device 10 is reversed, and a constant current is supplied from the constant current source 2 to the negative electrode 12 of the electricity storage device 10 to discharge the electricity storage device 10. In this state, the electricity storage device 10 is discharged. You may switch the magnitude|size of the constant current supplied to. Even in this case, it is possible to calculate the self-discharge current Ipr of the electricity storage device 10 as in the above embodiment.

Next, functions and effects of the second embodiment will be described.

An inspection device 1 that constitutes a measurement device for the power storage device 10 includes a constant current source 2 that supplies a constant current to the power storage device 10 and a voltage sensor 3 that measures the voltage of the power storage device 10 . The inspection apparatus 1 further includes a controller 4 that calculates the self-discharge current Ipr of the storage device 10 or the discharge resistance Rpr of the storage device 10 through which the self-discharge current Ipr flows based on the measured voltage change of the storage device 10 .

In addition, the measurement method included in the inspection method of the electricity storage device 10 is to supply a constant current to the electricity storage device 10, switch the constant current supplied to the electricity storage device 10, measure the voltage of the electricity storage device for each constant current, A self-discharge current of the storage device 10 or a discharge resistance of the storage device 10 through which the self-discharge current flows is calculated based on the measured voltage change of the storage device.

According to these configurations, the voltage change of the electricity storage device 10 is increased by supplying the constant current from the constant current source 2 to the electricity storage device 10, so that the voltage change of the electricity storage device 10 can be accurately detected in a short time. can. Therefore, parameters relating to self-discharge, such as self-discharge current Ipr or discharge resistance Rpr of power storage device 10 can be obtained in a short time.

For example, as a method of calculating the self-discharge current Ipr, if the capacitance Cst of the power storage unit 13 is known in the above equation (1), the slope A1 of the approximate straight line of the voltage change of the power storage device 10 is detected. The self-discharge current Ipr of the electricity storage device 10 can be calculated. Alternatively, by substituting the measured values or predicted values actually measured in advance for the capacitance Cst and the first current value I1 of the power storage unit 13 in the above equation (1), the slope A1 of the approximate straight line and the self-discharge current Ipr may be generated and stored in the controller 4. In this case, when the controller 4 obtains the slope A1 of the approximate straight line of the voltage change of the electric storage device 10, the controller 4 refers to the calculation table and calculates the self-discharge current Ipr related to the slope A1 of the approximate straight line thus obtained.

Further, the discharge resistance Rpr is calculated by dividing the open-circuit voltage of the electricity storage device 10 by the self-discharge current Ipr. A calculation table showing the relationship may be generated and stored in the controller 4 . In this case, when the controller 4 obtains the slope A1 of the approximate straight line of the voltage change of the electric storage device 10, the controller 4 refers to the calculation table and calculates the discharge resistance Rpr associated with the slope A1 of the approximate straight line thus obtained.

In this way, the controller 4 can obtain the self-discharge current Ipr or the discharge resistance Rpr of the electricity storage device 10 by using the voltage change of the electricity storage device 10 detected in a short time. can be asked for.

In addition, the controller 4 in the inspection apparatus 1 of the present embodiment includes a current switching unit 42 that switches the constant current supplied to the electricity storage device 10 , and the calculation unit 46 of the controller 4 switches each constant current supplied to the electricity storage device 10 First, the self-discharge current Ipr or discharge resistance Rpr of the storage device 10 is calculated based on the voltage change of the storage device 10 measured by the voltage sensor 3 .

According to this configuration, by switching the magnitude of the constant current supplied to the electricity storage device 10, the voltage change of the electricity storage device 10 is detected for each constant current. A discharge current Ipr can be calculated. In this way, since the parameters related to self-discharge can be obtained using the measured values of the power storage device 10, which is the object of measurement, errors in the parameters related to self-discharge can be suppressed compared to the case of using the above-described calculation table. can be done.

Further, the current switching unit 42 in the inspection apparatus 1 of the present embodiment selects the constant current supplied to the power storage device 10 as the first constant current for detecting the self-discharge current Ipr of the power storage device 10, the first constant current Switch between a second constant current that is greater than the constant current.

According to this configuration, the current switching unit 42 causes the constant current source 2 to supply the second constant current, which is larger than the first constant current, to the power storage device 10, thereby increasing the voltage change of the power storage device 10. Therefore, the slope of the voltage change can be determined in a short time with high accuracy. Furthermore, since the signal-to-noise ratio (S/N ratio) of the voltage signal detected by the voltage sensor 3 is increased, the accuracy of calculating the slope of the voltage change can be increased.

In particular, the second constant current supplied to the electricity storage device 10 is preferably set to several tens of times or more the reference value of the self-discharge current Ipr of the electricity storage device 10 . By setting in this way, it is possible to reduce the error in the calculation result caused by omitting the self-discharge current Ipr in the above equation (2).

Moreover, in the present embodiment, the first constant current supplied to the electricity storage device 10 is preferably set to be one or several times the reference value of the self-discharge current Ipr of the electricity storage device 10 . By setting in this way, it is possible to ensure the estimation accuracy of the self-discharge current Ipr of the electricity storage device 10 calculated using the above equation (4). In addition, since the allowable range of the first constant current is relatively wide, it is possible to suppress deterioration in estimation accuracy of the self-discharge current Ipr due to setting errors of the first constant current.

Further, the calculation unit 46 in the present embodiment calculates the current value I1 of the constant current supplied to the power storage device 10, the slope A1 of the voltage change of the power storage device 10, the voltage change of the power storage unit 13, and the The self-discharge current Ipr of the electric storage device 10 may be calculated based on the capacitance Cst.

As a result, the self-discharge current Ipr can be obtained without switching the constant current, so the parameters related to the self-discharge of the electricity storage device 10 can be obtained in a shorter time. Note that the capacitance Cst of the power storage unit 13 may be calculated in advance using the above formula (2), or may be obtained from the statistical data of the power storage device 10 .

At this time, the constant current supplied from the constant current source 2 to the electricity storage device 10 is set to a magnitude that is lower than the overvoltage in the electricity storage device 10 and mainly causes an electric double layer reaction. As a result, the self-discharge current Ipr can be obtained with high accuracy, and the power consumption of the constant current source 2 can be reduced.

Further, the calculation unit 46 in the present embodiment obtains the slope of the voltage change of the power storage device 10 for each constant current, and uses the slopes A1 and A2 of the voltage change and the current values I1 and I2 of the constant current to calculate the voltage of the power storage device. 10, a leakage current calculator 461 for calculating the self-discharge current Ipr. Further, calculation unit 46 includes discharge resistance calculation unit 462 that calculates discharge resistance Rpr of power storage device 10 based on self-discharge current Ipr calculated by leakage current calculation unit 461 .

According to this configuration, the discharge resistance Rpr of the electric storage device 10 can be calculated by using the slopes A1 and A2 of the voltage change obtained for each constant current and the current values I1 and I2 of the constant current.

Moreover, the controller 4 of the present embodiment further includes a device determination section 47 that determines that the power storage device 10 is normal based on the self-discharge current Ipr or the discharge resistance Rpr calculated by the calculation section 46 . According to this configuration, it is possible to determine whether the power storage device 10 is in a normal state or an abnormal state by using the parameters related to self-discharge calculated by the calculation unit 46 .

(Third Embodiment)
Next, an inspection apparatus 1 according to a third embodiment will be described. The configuration of the inspection apparatus 1 according to this embodiment is the same as the configuration shown in FIG. 1, and the functional configuration of the controller 4 constituting the inspection apparatus 1 is also basically the same as the functional configuration shown in FIG. .

The inspection apparatus 1 of this embodiment is different from the second embodiment in which the magnitude of the constant current is switched in that the direction of the constant current supplied from the constant current source 2 to the power storage device 10 is switched.

As in the second embodiment, the constant current value storage unit 451 of the controller 4 stores the first current value I1 and the second current value I2. flows in the opposite direction to the first constant current.

For example, the first current value I1 is set to a positive value so that the power storage device 10 is charged with a constant current, and the second current value I2 is set to a negative value so that the power storage device 10 is discharged with a constant current. is set to At least one of the absolute values of the first current value I1 and the second current value I2 may be set to be one or several times the reference value of the self-discharge current Ipr. may be the same value or different values.

In this embodiment, the first current value I1 is set to be one or several times the reference value of the self-discharge current Ipr. That is, the first current value I1 is set to a current value for detecting the self-discharge current Ipr of the power storage device 10. FIG. For example, the first current value I1 is set to 10 [μA] that is one times the reference value of the self-discharge current Ipr, and the second current value I2 is the first current value I1 multiplied by “−1”. is set to -10 [μA].

After acquiring the first current value I1 from the constant current value storage unit 451, the current switching unit 42, when acquiring the second current value I2, changes the magnitude of the first constant current through the current command unit 43. and directs the constant current source 2 to supply a second constant current flowing in the opposite direction to the electricity storage device 10 . As a result, the constant current source 2 supplies the first constant current to the positive electrode 11 of the power storage device 10 to charge the power storage device 10, and then supplies the negative electrode 12 of the power storage device 10 with the second constant current. A constant current is supplied to discharge the electricity storage device 10 .

In this way, the current switching unit 42 selects the constant current supplied to the power storage device 10 as the first constant current for detecting the self-discharge current Ipr and the second constant current flowing in the opposite direction to the first constant current. A switching means for switching between the two constant currents is configured.

In this embodiment, the controller 4 controls the operation of the constant current source 2 so as to switch the direction of the current, but it is not limited to this. For example, a switch is connected between the constant current source 2 and the storage device 10 as switching means, and the controller 4 issues a switching command to this connector, whereby the connection relationship between the constant current source 2 and the storage device 10 is changed. may be reversed.

Next, a method for calculating the self-discharge current Ipr of the electricity storage device 10 according to this embodiment will be described.

The formula for obtaining the capacitance Cst of the power storage unit 13 is obtained by combining the self-discharge current Ipr of the power storage device 10 and the slope Ac of the voltage change when the power storage device 10 is charged with a constant current indicating the first current value I1. can be expressed as in the following equation (5).

Furthermore, the formula for obtaining the capacitance Cst of the electricity storage unit 13 is based on the self-discharge current Ipr of the electricity storage device 10 and the slope Ad of the voltage change when the electricity storage device 10 is discharged by the constant current indicating the second current value I2. , can be expressed as in the following equation (6).

Solving the above equations (5) and (6) for the self-discharge current Ipr yields the following equation (7).

Therefore, the self-discharge current Ipr of the electricity storage device 10 can be calculated by substituting the above parameters into the equation (7).

For this reason, the leakage current calculator 461 of the present embodiment calculates the gradient Ac of the voltage change during charging corresponding to the first constant current and the gradient Ad of the voltage change during discharging corresponding to the second constant current. At the same time, the first current value I1 and the second current value I2 are acquired from the constant current value storage unit 451 . Leakage current calculator 461 substitutes these parameters into the above equation (7) to calculate self-discharge current Ipr. Leakage current calculator 461 outputs the calculated self-discharge current Ipr of power storage device 10 to discharge resistance calculator 462 .

Next, an inspection method including a measurement method for the electricity storage device 10 according to the third embodiment will be described with reference to FIGS. 7 and 8. FIG. FIG. 7 is a flow chart of an inspection method using the inspection apparatus 1. FIG. FIG. 8 is a diagram showing an example of voltage change with respect to elapsed time after a constant current is supplied to the electricity storage device 10. As shown in FIG.

The inspection method of this embodiment includes steps S42a and S43a instead of steps S42 and S43 in the processing procedure shown in FIG.

In step S1, the inspection apparatus 1 is connected to the power storage device 10, the constant current source 2 supplies a constant current having the first current value I1 to start charging, and the power storage device 10 is started to be inspected.

In step S<b>2 , the controller 4 causes the voltage sensor 3 to measure the voltage (initial voltage) of the electricity storage device 10 . An electric signal corresponding to the voltage value of the electric storage device 10 detected by the voltage sensor 3 is input to the controller 4 .

In step S3a, the controller 4 determines whether or not the elapsed time after starting the supply of the constant current has exceeded a predetermined time. The predetermined time is set in advance to such a length that a difference appears in the voltage change between when the power storage device 10 is normal and when it is abnormal. When it is determined in step S3 that the elapsed time has exceeded the predetermined time, the process proceeds to step S4. On the other hand, if it is determined in step S3 that the elapsed time has not exceeded the predetermined time, the process returns to step S2 to measure the voltage of power storage device 10 again.

In step S<b>4 , the controller 4 detects voltage change of the electricity storage device 10 based on the voltage of the electricity storage device 10 measured by the voltage sensor 3 . Specifically, based on the initial voltage at the start of charging and the charging voltage when a constant current is supplied from the constant current source 2, the controller 4 draws an approximate straight line of the voltage change during charging of the power storage device 10. demand. More specifically, the controller 4 obtains an approximate straight line of voltage change by, for example, the least-squares method based on the voltage value of the electricity storage device 10 measured in each control cycle.

In step S41, the controller 4 determines whether or not the number of times of measurement, which is the number of times the approximate straight line of the measured voltage change is obtained, is less than two times. If it is determined in step S41 that the number of times of measurement is less than two, it is necessary to switch the constant current supplied to the electricity storage device 10, so the process proceeds to step S42.

In step S<b>42 a , the controller 4 switches the direction of the constant current supplied to the electricity storage device 10 . In the present embodiment, the controller 4 switches the constant current supplied to the power storage device 10 to a second constant current that is the same in magnitude as the first constant current and flows in the opposite direction.

In step S42b, the controller 4 supplies a constant current having the second current value I2 from the constant current source 2 to start discharging. After that, the controller 4 returns to step S2 to measure the discharge voltage, which is the voltage of the electric storage device 10, for a predetermined period of time, and obtains an approximate straight line of discharge voltage change corresponding to the second constant current in step S4.

If it is determined in step S41 that the number of measurements has reached two, the parameters necessary for calculating the self-discharge current Ipr of the electricity storage device 10 have been obtained, so the process proceeds to step S43.

In step S<b>43 a , the controller 4 calculates the self-discharge current Ipr of the electricity storage device 10 based on the slope of the voltage change of the electricity storage device 10 obtained for each constant current supplied to the electricity storage device 10 . In the present embodiment, the controller 4 uses, as the parameters, the first current value I1, the slope Ac of the approximate straight line of the charge voltage change, the second current value I2, and the slope Ad of the approximate straight line of the discharge voltage change. , to calculate the self-discharge current Ipr of the electricity storage device 10 .

In step S50, the controller 4 determines whether the power storage device 10 is in a normal state based on the self-discharge current Ipr of the power storage device 10, as described in the second embodiment.

By executing the above processing, the quality determination of the electricity storage device 10 is completed.

Note that in the example of FIG. 7, the controller 4 switches the direction of the constant current supplied to the electricity storage device 10 only once, and obtains the slope of the voltage change of the electricity storage device 10 twice, thereby reducing the self-discharge current of the electricity storage device 10. Ipr was calculated. Alternatively, a plurality of self-discharge currents Ipr are calculated by switching the direction of the constant current a plurality of times and sequentially obtaining the slope of the approximate straight line of the voltage change, and the statistical value such as the average value or median value of these is finally obtained. You may use it as a result.

Next, the processing of step S43 will be described with reference to the specific example of FIG. The horizontal axis of FIG. 8 is the elapsed time [s] after charging of the power storage device 10 is started, and the vertical axis is the difference [μV] between the voltage detected by the voltage sensor 3 and the initial voltage.

The predetermined charging time T1a is a period during which the power storage device 10 is charged with a constant current indicating the first current value I1, and the predetermined discharging time T2a is a period during which the constant current indicating the second current value I2 is stored after switching. It is the period during which the device 10 is charged. The first current value I1 is 10 [μA] and the second current value I2 is -10 [μA].

The solid line data shown in FIG. 8 is the voltage change when the power storage device 10 is in a normal state, and the solid straight lines are the approximate straight line Ln1 of the voltage change corresponding to the first constant current and the second straight line. It is an approximate straight line Ln2 of the voltage change corresponding to the constant current. Both the approximation straight line Ln1 and the approximation straight line Ln2 are straight lines obtained by the process of step S4.

On the other hand, the dotted line data shown in FIG. 8 is the voltage change when the power storage device 10 is in an abnormal state, and the dashed straight line is the approximate line La1 of the voltage change corresponding to the first constant current and the second constant current. It is an approximate straight line La2 of voltage change corresponding to two constant currents. Both the approximate straight line La1 and the approximate straight line La2 are straight lines obtained by the process of step S4.

Referring to FIG. 8, similar to FIG. 6, the absolute values of the slopes of the approximate straight lines Ln1 and Ln2 of the power storage device 10 in the normal state are the absolute values of the slopes of the approximate straight lines La1 and La2 of the power storage device 10 in the abnormal state. It can be seen that it is larger than the value.

For example, when calculating the self-discharge current Ipr of the power storage device 10 in the normal state, the controller 4 of the present embodiment uses the first current value I1, the slope of the approximate straight line Ln1, the second current value I2, The absolute value of the slope of the approximate straight line Ln2 is obtained and substituted into the above equation (7). Thus, the self-discharge current Ipr of the electricity storage device 10 can be obtained by supplying constant currents in different directions to the electricity storage device 10 and obtaining the slope of the voltage change for each constant current.

After obtaining the self-discharge current Ipr of the electricity storage device 10, the controller 4 determines the quality of the electricity storage device 10 based on the obtained self-discharge current Ipr. Note that the controller 4 determines whether the slope of the approximate straight line is between the upper limit and the lower limit for each constant current, as shown in FIG. is in a normal state or in an abnormal state.

Next, functions and effects of the third embodiment will be described.

The current switching unit 42 according to the present embodiment allows the constant current supplied to the power storage device 10 to flow in the first constant current for detecting the self-discharge current Ipr and in the opposite direction to the first constant current. Second, switch between constant current and .

According to this configuration, by switching the direction of the constant current supplied to the electricity storage device 10, the voltage change of the electricity storage device 10 is detected for each constant current. , the self-discharge current Ipr of the electricity storage device 10 can be calculated.

In this way, the parameters related to self-discharge can be obtained using the actual measurement values of the power storage device 10 to be measured, so there is no need to use the assumed value of the capacitance Cst of the power storage unit 13 in the power storage device 10 . Therefore, the controller 4 can suppress the estimation error of the parameters related to the self-discharge of the power storage device 10 .

Further, the constant current source 2 of the present embodiment supplies a first constant current to the positive electrode 11 of the electricity storage device 10, and supplies a first constant current to the negative electrode 12 of the electricity storage device 10 as a second constant current. do. According to this configuration, it is only necessary to reverse the connection between the power storage device 10 and the constant current source 2 without changing the magnitude of the constant current, so the power storage device 10 can be easily inspected.

Although the embodiments of the present invention have been described above, the above embodiments merely show a part of application examples of the present invention, and the technical scope of the present invention is not limited to the specific configurations of the above embodiments. do not have.

For example, the controller 4 may switch the direction of the constant current after switching the magnitude of the constant current supplied to the power storage device 10 , or switch the direction of the constant current supplied to the power storage device 10 before switching the direction of the constant current. You can change the size. In this case, since a plurality of self-discharge currents Ipr are obtained, their average value may be used as the final result.

1 inspection device 2 constant current source (constant current supply means)
3 voltage sensor (voltage measuring means)
4 controller (control means)
10 power storage device 13 power storage unit 14 internal resistance 15 parallel resistor 42 current switching unit (switching means)
46 calculation unit (control means)
47 device determination unit (determination means)

Claims (12)

A power storage device measuring device,
constant current supply means for supplying a constant current to the electricity storage device;
voltage measuring means for measuring the voltage of the electricity storage device;
control means for calculating a self-discharge current of the electricity storage device or a discharge resistance of the electricity storage device through which the self-discharge current flows, based on the measured voltage change of the electricity storage device;
A power storage device measuring apparatus comprising: The power storage device measuring device according to claim 1,
A switching means for switching a constant current supplied to the electricity storage device,
The control means calculates the self-discharge current or the discharge resistance based on the voltage change of the electricity storage device measured by the voltage measurement means for each constant current supplied to the electricity storage device.
Measurement equipment for power storage devices. The power storage device measuring apparatus according to claim 2,
The switching means switches the constant current supplied to the power storage device between a first constant current for detecting the self-discharge current and a second constant current larger than the first constant current. switch with
Measurement equipment for power storage devices. The power storage device measuring device according to claim 3,
The second constant current is set to be several tens of times or more the reference value of the self-discharge current,
Measurement equipment for power storage devices. The power storage device measuring apparatus according to claim 2,
The switching means selects the constant current supplied to the power storage device from a first constant current for detecting the self-discharge current and a second constant current flowing in the opposite direction to the first constant current. and switch between
Measurement equipment for power storage devices. The power storage device measuring apparatus according to claim 5,
The constant current supply means supplies the first constant current to the positive electrode of the electricity storage device, and supplies the first constant current to the negative electrode of the electricity storage device as the second constant current.
Measurement equipment for power storage devices. The power storage device measuring apparatus according to any one of claims 3 to 6,
The first constant current is set to one or several times the reference value of the self-discharge current,
Measurement equipment for power storage devices. The power storage device measuring device according to claim 1,
The control means calculates a self-discharge current of the electricity storage device based on a current value of a constant current supplied to the electricity storage device, a slope of voltage change of the electricity storage device, and a capacitive component of the electricity storage device.
Measurement equipment for power storage devices. The power storage device measuring apparatus according to claim 1 or claim 8,
The constant voltage supplied to the electricity storage device is lower than the overvoltage in the electricity storage device, and is set to a magnitude at which an electric double layer reaction mainly occurs.
Measurement equipment for power storage devices. The power storage device measuring apparatus according to any one of claims 2 to 7,
The control means is
A current for calculating the slope of the voltage change of the power storage device for each constant current supplied to the power storage device, and using each slope of the voltage change and each current value of the constant current to calculate the self-discharge current of the power storage device. computing means;
resistance calculation means for calculating the discharge resistance of the electricity storage device based on the self-discharge current calculated by the current calculation means;
Measurement equipment for power storage devices. The power storage device measuring apparatus according to any one of claims 1 to 10,
The control means comprises determination means for determining that the electricity storage device is normal based on the calculated self-discharge current or the discharge resistance.
Measurement equipment for power storage devices. A method for measuring an electricity storage device,
supplying a constant current to the electricity storage device;
measuring the voltage of the electrical storage device;
calculating a self-discharge current of the power storage device or a discharge resistance of the power storage device through which the self-discharge current flows, based on the measured voltage change of the power storage device;
A measurement method for power storage devices.

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