JP7407136B2 - Battery charging/discharging test equipment and battery testing equipment - Google Patents

Description

The present invention relates to a battery charge/discharge test device and a battery test device.

A battery charge/discharge test device is known as a test device for evaluating the performance and reliability of batteries (particularly secondary batteries). The battery charge/discharge test device according to the background art is equipped with a plurality of power supply units for charging and discharging batteries, and improves test efficiency by simultaneously performing charge/discharge tests on multiple batteries in parallel. Improvements are being made. Each power supply unit has multiple charging/discharging circuits with different current ranges (for example, a small current charging/discharging circuit and a large current charging/discharging circuit), and the optimum current range is selected according to the required charge/discharge current. By switching to a charging/discharging circuit, output response speed and accuracy are ensured.

The battery charging/discharging test device disclosed in Patent Document 1 below includes a plurality of small current charging/discharging circuits, and the small current charging/discharging circuits are individually connected to a plurality of batteries. A charge/discharge test is performed, and a large current charge/discharge test is performed by connecting a plurality of small current charge/discharge circuits in parallel to one battery.

Patent No. 5841042

The charge/discharge circuit must be designed with a current capacity that corresponds to the maximum value of the current range. Therefore, the large current charging/discharging circuit has larger external dimensions, weight, and manufacturing cost than the small current charging/discharging circuit.

On the other hand, in a battery charging/discharging test, the charging/discharging period using a large current is often shorter than the charging/discharging period using a small current in order to match the conditions when the battery is actually used. Therefore, the operating rate of a large current range generally tends to be lower than that of a small current range.

According to the battery charging/discharging test device according to the background art described above, each of the plurality of power supply units has a large current charging/discharging circuit. Therefore, as a result of mounting a large current charging/discharging circuit with a low operating rate in each power supply unit, the external dimensions, weight, and manufacturing cost of the test apparatus as a whole increase.

The present invention has been made in view of the above circumstances, and an object of the present invention is to obtain a battery charge/discharge test device and a battery test device that can reduce external dimensions, weight, and manufacturing costs.

A battery charge/discharge test device according to one aspect of the present invention is a battery charge/discharge test device that can perform a charge/discharge test on a plurality of batteries in parallel using a plurality of channels, wherein each of the plurality of channels and at least one second power supply unit provided in common to at least two or more channels among the plurality of channels, the first power supply unit comprising: , the second power supply unit has a first charging/discharging circuit capable of charging and discharging the battery with a first current whose maximum current value is a first current value, and the second power supply unit has a maximum current value larger than the first current value. Selecting a second charging/discharging circuit capable of charging/discharging the battery with a second current having a second current value and one channel to which the second charging/discharging circuit is connected from among the at least two or more channels. and a first selection circuit, and when charging or discharging a battery connected to a certain channel to a value equal to or less than the first current value, the first charging/discharging circuit of that channel selects the first current value. When the battery connected to a certain channel is to be charged or discharged with a current exceeding the first current value, the first selection circuit selects the channel and the second charging/discharging circuit selects the channel. A discharge circuit performs the charging and discharging using the second current.

According to this aspect, at least one second power supply unit having a second charging/discharging circuit whose maximum current value is larger than that of the first charging/discharging circuit is provided in common to at least two or more channels. When charging or discharging a battery connected to a certain channel to a value exceeding the first current value, the first selection circuit selects the channel, and the second charging/discharging circuit uses the second current to charge or discharge the battery. Perform discharge. In this way, by providing at least one second power supply unit in common to at least two or more channels, the entire battery charging/discharging test apparatus is As a result, it is possible to reduce external dimensions, weight, and manufacturing costs.

In the above aspect, the second power supply unit selects an additional circuit that adds a fluctuation component to the charging/discharging current of the battery, and one channel to which the additional circuit is connected from among the at least two or more channels. and a second selection circuit, and when performing charging/discharging of a battery connected to a certain channel at a current value equal to or less than the first current value including a fluctuation component, the second selection circuit is selected, and the charging/discharging is performed using the first current obtained by adding the fluctuation component to the charging/discharging current by the first charging/discharging circuit of the channel, and the fluctuation is applied to the battery connected to a certain channel. When performing charging/discharging exceeding the first current value including a component, the first selection circuit and the second selection circuit select the channel, and the charge/discharge current by the second charging/discharging circuit changes as described above. The charging and discharging is performed by the second current to which the component is added.

According to this aspect, since the second power supply unit includes the additional circuit, the additional circuit is provided in common to at least two or more channels. Therefore, compared to the case where an additional circuit is provided corresponding to each channel, it is possible to reduce the external dimensions, weight, and manufacturing cost of the battery charging/discharging test apparatus as a whole.

A battery testing device according to one aspect of the present invention includes a battery charging/discharging testing device according to the above aspect, a chamber in which the plurality of batteries to be tested are accommodated, and an environment control device that controls the environment in the chamber. , is provided.

According to this aspect, it is possible to perform a battery charge/discharge test using a plurality of batteries as test targets while controlling the environment within a chamber in which a plurality of batteries are housed using the environment control device.

According to the present invention, it is possible to reduce the external dimensions, weight, and manufacturing cost of a battery charge/discharge test device.

1 is a diagram showing a simplified configuration of a battery testing device according to an embodiment of the present invention. FIG. 2 is a diagram showing the configuration of a charge/discharge control device. It is a flowchart which shows the flow of the process performed by the control part with which a small current power supply unit is provided. It is a flowchart which shows the flow of the process performed by the control part with which a large current power supply unit is provided. It is a figure showing the composition of the charge and discharge control device concerning a modification.

Hereinafter, embodiments of the present invention will be described in detail using the drawings. Note that elements given the same reference numerals in different drawings indicate the same or corresponding elements.

FIG. 1 is a diagram showing a simplified configuration of a battery testing device 1 according to an embodiment of the present invention. As shown in FIG. 1, the battery testing device 1 includes a main controller 21, a charge/discharge controller 22, an environment controller 23, and a chamber 11. Note that the battery testing device 1 may be configured as a battery testing device without an environment adjustment function by omitting the environment control device 23, the chamber 11, and the like.

A plurality of batteries 100 (two batteries 100A and 100B in the example of FIG. 1) to be tested are connected to predetermined locations on the holder 14. The battery 100 is a rechargeable and dischargeable secondary battery such as a lithium ion battery.

The chamber 11 has a heat insulating inner wall 12 and a door 13. A socket 15 is arranged at a predetermined location on the inner wall 12. The battery 100 is housed in the chamber 11 by connecting the holder 14 to which the battery 100 is connected to the socket 15 . Further, the charge/discharge control device 22 and the battery 100 are electrically connected by wiring formed in the socket 15 and on the holder 14 .

The charge/discharge control device 22 includes a data processing device such as a CPU, and a data storage device such as a RAM and a ROM. The charge/discharge control device 22 has a plurality of channels CH as connection paths with the battery 100. The number of channels CH is, for example, 72 channels. One battery 100 can be connected to each channel CH, and a charge/discharge test of the battery 100 can be performed under individual conditions for each channel CH. Thereby, the charge/discharge control device 22 can simultaneously perform a charge/discharge test on a plurality of batteries 100 in parallel using a plurality of channels CH.

The battery testing device 1 also includes an air conditioner 31, a blower fan 32, and a temperature sensor 33. The air conditioner 31 includes a heater for heating and a cooler for cooling. The blower fan 32 and the temperature sensor 33 are arranged at predetermined locations within the chamber 11 . The blower fan 32 sends conditioned air generated by the air conditioner 31 into the chamber 11 . The temperature sensor 33 detects the temperature inside the chamber 11 and outputs temperature data indicating the detected temperature.

The environment control device 23 includes a data processing device such as a CPU, and a data storage device such as a RAM and a ROM. The environment control device 23 controls the driving of the air conditioner 31 and the ventilation fan 32 based on temperature data input from the temperature sensor 33. Thereby, the temperature inside the chamber 11 is adjusted to the target temperature. Note that the environment inside the chamber 11 is not limited to temperature, and humidity may be adjusted. Further, a plurality of chambers 11 whose environmental conditions can be individually adjusted may be provided.

The main control device 21 includes a data processing device such as a CPU, and a data storage device such as a RAM and a ROM. The main control device 21 can communicate with a personal computer 2 or the like placed outside the battery testing device 1 by wire or wirelessly.

The operator uses the personal computer 2 to input test conditions and the like. The main control device 21 receives a test file in which test conditions are described from the personal computer 2, and centrally controls the charge/discharge control device 22 and the environment control device 23 based on the test conditions. As a result, a charging/discharging test and an environmental test are performed on the battery 100 housed in the chamber 11.

FIG. 2 is a diagram showing the configuration of the charge/discharge control device 22. As shown in FIG. In the example of FIG. 2, to simplify the explanation, only the configurations of two channels CH1 and CH2 among the plurality of channels CH included in the charge/discharge control device 22 are shown. A battery 100A is connected to channel CH1, and a battery 100B is connected to channel CH2.

As shown in FIG. 2, the charge/discharge control device 22 includes a small current power supply unit 60 (two small current power supply units 60A and 60B in the example of FIG. 2) provided corresponding to each of the plurality of channels CH, A large current power supply unit 40 is provided in common to a plurality of channels CH.

The maximum current value of the charging/discharging current of the battery 100 by the small current power supply unit 60 is several amperes, and in the following example, it is assumed to be 5A. The maximum current value of the charging/discharging current of the battery 100 by the large current power supply unit 40 is several tens of amperes or more, and is set to 50 A in the following example.

The small current power supply unit 60A includes a control section 71A, a small current charging/discharging circuit 72A, a switch 73A, a storage section 74A, and a detection section 75A. The control unit 71A is configured using a data processing device such as a CPU. The small current charging/discharging circuit 72A is configured using a power source or the like. The switch 73A is configured using a relay, a semiconductor, or the like. The storage unit 74A is configured using RAM, ROM, and the like. The detection unit 75A includes a voltage sensor that detects the voltage value of the voltage between the terminals of the battery 100A, and a current sensor that detects the current value of the charging and discharging current of the battery 100A.

When the control unit 71A turns on the switch 73A, the small current charging/discharging circuit 72A and the battery 100A are connected to each other. When the control unit 71A turns off the switch 73A, the connection between the small current charging/discharging circuit 72A and the battery 100A is released.

Similar to the small current power supply unit 60A, the small current power supply unit 60B includes a control section 71B, a small current charging/discharging circuit 72B, a switch 73B, a storage section 74B, and a detection section 75B. Note that the configurations of the other small current power supply units 60 are also similar to the configurations of the small current power supply units 60A and 60B.

The large current power supply unit 40 includes a control section 51, a large current charging/discharging circuit 52, and a switch 53 (switches 53A and 53B in the example of FIG. 2).

The control unit 51 is configured using a data processing device such as a CPU. The control section 51 can communicate with the control sections 71A and 71B. The large current charging/discharging circuit 52 is configured using a power source or the like. The switches 53A and 53B are configured using relays, semiconductors, or the like.

The switch 53 is a selection circuit that selects one channel CH from among a plurality of channels CH. In the example of FIG. 2, the switch 53 includes a switch 53A corresponding to channel CH1 and a switch 53B corresponding to channel CH2.

When the control section 51 turns on the switch 53A, the large current charge/discharge circuit 52 and the battery 100A are connected to each other, and when the control section 51 turns off the switch 53A, the large current charge/discharge circuit 52 and the battery 100A are connected to each other. The connection will be terminated. Further, when the control unit 51 turns on the switch 53B, the large current charging/discharging circuit 52 and the battery 100B are connected to each other, and when the control unit 51 turns off the switch 53B, the large current charging/discharging circuit 52 and the battery 100B are connected to each other. The connection will be terminated.

FIG. 3 is a flowchart showing the flow of processing executed by the control section 71A included in the small current power supply unit 60A. The content of the processing executed by the control unit 71B is similar to that of the control unit 71A.

First, in step S101, the control unit 71A reads from the main control device 21 a test file related to channel CH1 that the main control device 21 received from the personal computer 2, and stores the test file in the storage unit 74A. In the test file, the current value of the charging current or discharging current and the charging time or discharging time are set for each of the plurality of test steps that constitute the sequence of the charging/discharging test for the battery 100A. .

Next, in step S102, the control unit 71A sets the contents of the test step to be executed this time (current value and time for charging and discharging) by updating the test step in the test file.

Next, in step S103, the control unit 71A determines whether the current value of the test step to be executed this time is a small current (5 A or less in this example).

If it is determined that the current value of the test step to be executed this time is a small current (step S103: YES), then in step S104, the control unit 71A turns on the switch 73A to perform small current charging/discharging. The circuit 72A and the battery 100A are connected to each other. The control unit 71A charges or discharges the battery 100A according to the contents (current value and time) set in the test file. Note that step S104 is executed after the temperature adjustment in the chamber 11 by the environment control device 23 is completed.

Next, in step S105, the control unit 71A determines whether the current test step is completed based on whether the time set in the test file has elapsed since the start of execution of the current test step. Determine.

If the current test step has not been completed (step S105: NO), the control unit 71A repeatedly executes the processes of steps S104 and S105.

If the current test step is completed (step S105: YES), then in step S106, the control unit 71A transmits the voltage and current values of the battery 100A detected by the detection unit 75A regarding the current test step. It is stored in the storage unit 74A as result data.

Next, in step S107, the control unit 71A determines whether all test steps constituting the charging/discharging test sequence for the battery 100A have been completed.

If all test steps have not been completed (step S107: NO), the control unit 71A executes the processes from step S102 onwards.

If all the test steps have been completed (step S107: YES), then in step S108, the control unit 71A reads the result data regarding all the test steps from the storage unit 74A, and stores the result data in the main controller 21. Send to.

If it is determined in step S103 that the current value of the test step to be executed this time is a large current (step S103: NO), then in step S109, the control unit 71A turns off the switch 73A and A request signal including the contents (current value and time) set in the file is transmitted to the control unit 51. As a modification, by turning on the switch 73A and transmitting a request signal, the large current charging/discharging by the large current charging/discharging circuit 52 and the small current charging/discharging by the small current charging/discharging circuit 72A can be combined. You may execute it. This makes it possible to perform a large current charging/discharging test using a large current that exceeds the maximum current value of the large current charging/discharging circuit 52.

Next, in step S110, the control unit 71A determines whether a completion notification signal for the transmitted request signal has been received from the control unit 51.

If the completion notification signal has not been received (step S110: NO), the control unit 71A waits until it receives a completion notification signal from the control unit 51.

If the completion notification signal is received from the control unit 51 (step S110: YES), the control unit 71A executes the processes from step S106 onwards.

FIG. 4 is a flowchart showing the flow of processing executed by the control section 51 included in the large current power supply unit 40.

First, in step S201, the control unit 51 determines whether a request signal has been received from the control units 71A and 71B.

If the request signal has not been received (step S201: NO), the control unit 51 repeatedly executes the process of step S201.

If the request signal is received from the control unit 71A of the channel CH1 (step S201: YES), then in step S202, the control unit 51 transmits the request signal to the other channel CH2, which is different from the channel CH1 that is the source of the request signal. Determine whether a large current charge/discharge test is currently being executed.

If a large current charge/discharge test regarding another channel CH2 is being executed (step S202: YES), the control unit 51 stores the request signal received in step S201 in a FIFO buffer (not shown), and in step S202. By repeating the process, it waits until the currently executed large current charge/discharge test is completed.

If the large current charging/discharging test regarding another channel CH2 is not being executed (step S202: NO), then in step S203, the control unit 51 connects the large current charging/discharging circuit 52 by turning on the switch 53A. Connect the battery 100A to each other. The control unit 51 performs a large current charge/discharge test on the battery 100A by charging or discharging the battery 100A with the contents (current value and time) set in the request signal. Note that step S203 is executed after the temperature adjustment in the chamber 11 by the environment control device 23 is completed.

When the high current charge/discharge test for the battery 100A is completed, next in step S204, the control unit 51 sends a completion notification signal to the source of the request signal indicating that the requested high current charge/discharge test has been completed. It is transmitted to the control unit 71A of a certain channel CH1. After that, the control unit 51 executes the processing from step S201 onwards.

In the above description, only one large current power supply unit 40 is provided, but a plurality of large current power supply units 40 less than the total number of channels CH may be provided. Thereby, it becomes possible to simultaneously perform large current charge/discharge tests regarding a plurality of channels CH using a plurality of large current power supply units 40. The plurality of large current power supply units 40 include at least a first large current power supply unit 40 and a second large current power supply unit 40.

As a first example, the first large current power supply unit 40 is provided for one specific channel CH, and is used when performing a large current charge/discharge test on the one channel CH. Further, the second large current power supply unit 40 is provided for the remaining plurality of channels CH, and is used when selecting any one of the plurality of channels CH to perform a large current charge/discharge test.

As a second example, the first large current power supply unit 40 is provided for a plurality of channels CH of a certain first group, and selects one of the plurality of channels CH of the first group to generate a large current. Used when performing current charge/discharge tests. Further, the second large current power supply unit 40 is provided for a plurality of channels CH of another second group, and performs a large current charging/discharging test by selecting any one of the plurality of channels CH of the second group. Used when executing.

<Summary>
According to the battery testing device 1 (battery charging/discharging testing device) according to the present embodiment, the small current power supply units 60A, 60B (first power supply unit ) are provided corresponding to each of the plurality of channels CH1 and CH2. On the other hand, a large current power supply unit 40 (second power supply unit) having a large current charge/discharge circuit 52 (second charge/discharge circuit) having a larger maximum current value than the small current charge/discharge circuits 72A, 72B has multiple channels CH1, It is provided in common to CH2. Then, for a battery 100A connected to a certain channel CH1, a current value exceeding the maximum current value (first current value) of the small current charging/discharging circuit 72A and below the maximum current value (second current value) of the large current charging/discharging circuit 52 is determined. When executing a large current charge/discharge test, the switch 53 (first selection circuit) selects the channel CH1, and the large current charge/discharge circuit 52 executes the large current charge/discharge test using a large current (second current). do. In this way, by providing the large current power supply unit 40 in common to the plurality of channels CH1 and CH2, the battery testing apparatus 1. Overall, it is possible to reduce external dimensions, weight, and manufacturing costs.

Further, the battery testing device 1 according to the present embodiment includes a charging and discharging control device 22 (charging and discharging testing device) that performs a charging and discharging test, a chamber 11 that accommodates a plurality of batteries 100 to be tested, and a chamber 11 that accommodates a plurality of batteries 100 to be tested. and an environment control device 23 that controls the environment within the environment. Therefore, while controlling the environment in the chamber 11 in which the plurality of batteries 100 are housed by the environment control device 23, it is possible to perform a charge/discharge test using the plurality of batteries 100 as test targets.

<Modified example>
FIG. 5 is a diagram showing the configuration of a charge/discharge control device 22 according to a modification. In addition to the configuration shown in FIG. 2, the large current power supply unit 40 further includes a ripple adding circuit 54 and a switch 55 (switches 55A and 55B in the example of FIG. 5). The ripple addition circuit 54 is configured using a power source or the like. The ripple addition circuit 54 generates a ripple component (sine wave , triangular wave, or square wave). Note that the additional circuit that adds a fluctuation component to the charging/discharging current may add not only a ripple component that has periodicity but also any fluctuation component such as spike noise that does not have periodicity to the charging/discharging current.

The switch 55 is a selection circuit that selects one channel CH from among a plurality of channels CH. In the example of FIG. 5, the switch 55 includes a switch 55A corresponding to channel CH1 and a switch 55B corresponding to channel CH2.

When the control section 51 turns on the switch 55A, the ripple addition circuit 54 and the battery 100A are connected to each other, and when the control section 51 turns off the switch 55A, the connection between the ripple addition circuit 54 and the battery 100A is released. Ru. Further, when the control section 51 turns on the switch 55B, the ripple addition circuit 54 and the battery 100B are connected to each other, and when the control section 51 turns off the switch 55B, the connection between the ripple addition circuit 54 and the battery 100B is established. It will be canceled.

For example, when performing a small current charge/discharge test including a ripple component on a battery of 100A, the control unit 71A turns on the switch 73A, the control unit 51 turns off the switch 53A, and turns on the switch 55A. . Further, the control unit 51 controls the ripple addition circuit 54 to generate a ripple component with a fluctuation width and a fluctuation period specified by the request signal received from the control unit 71A. Thereby, the desired ripple component generated by the ripple adding circuit 54 is superimposed on the charging/discharging current by the small current charging/discharging circuit 72A.

For example, when performing a large current charge/discharge test including a ripple component on the battery 100A, the control section 71A turns off the switch 73A, and the control section 51 turns on the switches 53A and 55A. Further, the control unit 51 controls the ripple adding circuit 54 to generate a ripple component having a fluctuation width and a fluctuation period specified by the request signal received from the control unit 71A. As a result, the desired ripple component generated by the ripple adding circuit 54 is superimposed on the charging/discharging current by the large current charging/discharging circuit 52 .

Moreover, when superimposition of a ripple component on the charging/discharging current is unnecessary, the control unit 51 turns off the switches 55A and 55B.

According to this modification, since the large current power supply unit 40 includes the ripple addition circuit 54, the ripple addition circuit 54 is provided in common to the plurality of channels CH1 and CH2. Therefore, compared to the case where the ripple adding circuit 54 is provided corresponding to each channel CH1, CH2, it is possible to reduce the external dimensions, weight, and manufacturing cost of the battery testing apparatus 1 as a whole.

1 Battery test device 11 Chamber 22 Charge/discharge control device 23 Environment control device 40 Large current power supply unit 52 Large current charge/discharge circuit 53, 53A, 53B Switch 54 Ripple addition circuit 55, 55A, 55B Ripple addition circuit 60A, 60B Small current power supply Unit 72A, 72B Small current charge/discharge circuit 100A, 100B Battery CH1, CH2 Channel

Claims (3)

A battery charge/discharge test device that can perform charge/discharge tests on multiple batteries in parallel using multiple channels,
a first power supply unit provided corresponding to each of the plurality of channels;
at least one second power supply unit provided in common to at least two or more channels among the plurality of channels;
Equipped with
The first power supply unit includes:
It has a first charging/discharging circuit capable of charging and discharging the battery with a first current whose maximum current value is a first current value,
The second power supply unit includes:
a second charging/discharging circuit capable of charging and discharging the battery with a second current whose maximum current value is a second current value larger than the first current value;
a first selection circuit that selects one channel to which the second charging/discharging circuit is connected from among the at least two or more channels;
has
When charging or discharging a battery connected to a certain channel to a value equal to or less than the first current value, the first charging/discharging circuit of that channel performs the charging/discharging using the first current,
When charging or discharging a battery connected to a certain channel to a value exceeding the first current value, the first selection circuit selects the channel, and the second charging/discharging circuit selects the channel using the second current value. A battery charging/discharging test device that performs the charging/discharging. The second power supply unit includes:
an additional circuit that adds a fluctuation component to the charging/discharging current of the battery;
a second selection circuit that selects one channel to which the additional circuit is connected from among the at least two or more channels;
It further has
When charging or discharging a battery connected to a certain channel at a current value equal to or less than the first current value including a fluctuation component, the second selection circuit selects the channel and performs the first charging or discharging of the battery connected to the channel. Performing the charging and discharging using the first current in which the fluctuation component is added to the charging and discharging current by the discharging circuit,
When charging or discharging a battery connected to a certain channel at a current value exceeding the first current value including a fluctuating component, the first selection circuit and the second selection circuit select the channel; The battery charging/discharging test device according to claim 1, wherein the charging/discharging is performed using the second current obtained by adding the fluctuation component to the charging/discharging current of a second charging/discharging circuit. A battery charge/discharge test device according to claim 1 or 2,
a chamber in which the plurality of batteries to be tested are housed;
an environment control device that controls the environment within the chamber;
A battery testing device comprising:

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