JP2024059344A - Impedance measurement system and impedance measurement method - Google Patents

Abstract

[Problem] To provide an impedance measurement system and an impedance measurement method that can improve safety during measurement. [Solution] The impedance measurement system 1 has an impedance measurement device 5 that includes a measurement signal source 11, a current detection section 13, and a voltage detection section 15 and measures the impedance of electronic components 21, 22 under measurement. A switch 30 is provided for connecting a current measurement line 54 between the measurement signal source 11 and the electronic component 22 under measurement, and a current measurement line 46 between one of the output terminals of the current detection section 13 and the electronic component 21 under measurement. [Selected Figure] Figure 1

Description

The present invention relates to an impedance measurement system and an impedance measurement method.

The four-terminal method is known as one of the methods for measuring the impedance of a conductor pattern, battery, element, etc. (hereinafter, these are referred to as "sample under test (DUT)") present on a circuit board. An impedance measuring device using the four-terminal method is configured using current measurement lines 410, 420 for connecting a pair of output terminals (high side terminal and low side terminal: not shown) of a measurement signal source to one terminal 400a, 500a of each of the battery cells 400, 500, and voltage measurement lines 510, 520 for connecting a pair of output terminals (not shown) of a voltmeter to both side terminals 500a, 500b of the battery cell 500 (see FIG. 4). The other terminals 400b, 500b of each of the battery cells 400, 500 are connected in series.

The configuration of the impedance measuring device described above will be described in detail with reference to FIG. 5. The impedance measuring system 600 includes an impedance measuring device 615 connected to the battery cells 710, 720 via a current measurement line (current cable) and a voltage measurement line (voltage cable), and a scanner 613. The impedance measuring device 615 includes a measurement signal source 621 that generates a measurement signal, a voltmeter 625 as a voltage detection means, and an ammeter (not shown) as a current detection means.

Specifically, as shown in FIG. 5, when the switches 810, 820, 830, and 880 are turned on, a measurement current is passed from the measurement signal source 621 to the high-side terminals of the battery cells 710 and 720 as the measurement targets via the current measurement line, the voltage between the two terminals of the battery cell 710 is measured by the voltmeter 625, and the current value of the measurement current is measured by an ammeter (not shown) connected to the measurement signal source 621. The impedance of the battery cell 710 is calculated based on the current value and voltage value of the measurement current. Next, the switches 820 and 830 are turned off, and the switches 860 and 870 are turned on, the voltage between the two terminals of the battery cell 720 is measured by the voltmeter 625, and the current value of the measurement current is measured by an ammeter (not shown) connected to the measurement signal source 621. The impedance of the battery cell 720 is calculated based on the current value and voltage value of the measurement current.

With this impedance measuring device using the four-terminal method, the forward and return paths of the measurement current are overlapped within the measurement current path, so the effects of magnetic flux (electromagnetic induction) caused by the measurement current can be reduced. Therefore, the effects of electromagnetic induction caused by magnetic flux leakage that occurs in part of the current measurement line near the terminal of the battery cell can be suppressed, and the effects on the internal impedance measurement of the battery cell caused by magnetic flux leakage loops can be suppressed.

JP 2011-257340 A

However, in a battery cell production line, multiple battery cells are not connected to each other, so when performing the impedance measurement described above, one side of each battery cell must all be short-circuited (connected in series), which can pose a safety problem.

Therefore, the objective of the present invention is to provide an impedance measurement system and an impedance measurement method that can improve safety during measurement.

One aspect of the impedance measurement system according to the present invention is an impedance measurement system having an impedance measurement device including a measurement signal generating source that supplies a measurement signal of a predetermined frequency to at least one set of electronic components under test, a current detection unit that is disposed between one output terminal of the measurement signal generating source and the other output terminal of the measurement signal generating source and detects a current flowing through the electronic components under test, and at least one voltage detection unit that measures a voltage generated between both terminals of each of the set of electronic components under test, and measuring the impedance of each of the electronic components under test,
The device is characterized by having a connection means for connecting a first current measurement line between one of a pair of output terminals of the measurement signal generating source and one of the set of electronic components to be measured, and a second current measurement line between one of the pair of output terminals of the current detection unit and the other of the set of electronic components to be measured.

Another aspect of the impedance measurement system of the present invention is characterized in that when measuring the voltage generated between both terminals of one of a pair of electronic components to be measured, the first current measurement line and the second current measurement line are connected via a connection means.

Another aspect of the impedance measurement system according to the present invention is characterized in that, when a plurality of sets of electronic components to be measured are arranged, the system includes a signal selection unit having a plurality of switches, the plurality of switches being composed of at least a first switch group connected to a measurement signal source, a second switch group connected to a current detection unit, and a third switch group connected to a voltage detection unit, and at least when the current measurement line connected to the measurement signal source by the first switch group is connected to the high-side terminal of one or the other of the set of electronic components to be measured, the current measurement line connected to the current detection unit by the second switch group is connected to the low-side terminal of one or the other of the electronic components to be measured, and when the voltage measurement line connected to one terminal of the voltage detection unit is connected to the high-side terminal of one or the other of the set of electronic components to be measured by the third switch group, and the voltage measurement line connected to the other terminal of the voltage detection unit is connected to the low-side terminal of the one or the other of the electronic components to be measured, the voltage detection unit detects the voltage between both terminals of one or the other of the set of electronic components to be measured.

Another aspect of the impedance measurement system according to the present invention is that when multiple sets of electronic components to be measured are arranged, the voltage detection unit is connected to each set of electronic components to be measured for each measurement of the electronic components to be measured.

One aspect of the impedance measurement method of the present invention is an impedance measurement method in which a current detection unit detects a current flowing through a measurement target electronic component having at least a pair of terminals, the measurement target electronic component being arranged between one and the other of a pair of output terminals of a measurement signal generation source that supplies a measurement signal of a predetermined frequency to at least one set of measurement target electronic components, at least one voltage detection unit measures a voltage generated between each of the two terminals of the set of measurement target electronic components, and measures the impedance of each measurement target electronic component based on the current value of the detected current and the voltage value of the measured voltage, characterized in that a first current measurement line is connected between one of the pair of output terminals of the measurement signal generation source and one of the set of measurement target electronic components, and a second current measurement line is connected between the other of the pair of output terminals of the current detection unit and the other of the set of measurement target electronic components.

Another aspect of the impedance measurement method of the present invention is characterized in that when measuring the voltage generated between both terminals of one of a pair of electronic components to be measured, the first current measurement line and the second current measurement line are connected via a connection means.

Another aspect of the impedance measurement method of the present invention is characterized in that, when a set of electronic components to be measured is arranged in a plurality of sets, a signal selection unit having a plurality of switches is provided, and the plurality of switches are composed of at least a first switch group connected to a measurement signal generating source, a second switch group connected to a current detection unit, and a third switch group connected to a voltage detection unit, and at least a current measurement line connected to the measurement signal generating source via the first switch group is connected to a high-side terminal of one or the other of the set of electronic components to be measured, a current measurement line connected to the current detection unit is connected to a low-side terminal of one or the other of the electronic components to be measured via the second switch group, a voltage measurement line connected to one terminal of the voltage detection unit is connected to a high-side terminal of one or the other of the set of electronic components to be measured via the third switch group, and a voltage measurement line connected to the other terminal of the voltage detection unit is connected to a low-side terminal of the one or the other of the electronic components to be measured, and the voltage detection unit detects a voltage between both terminals of one or the other of the set of electronic components to be measured.

It is possible to provide an impedance measurement system and an impedance measurement method that can improve safety during measurement.

1 is a diagram showing a configuration of an impedance measurement system according to a first embodiment of the present invention, illustrating a first connection configuration mode. FIG. 11 shows a configuration of an impedance measurement system according to a second embodiment of the present invention, illustrating a second connection configuration mode. FIG. 13 shows a configuration of an impedance measurement system according to a third embodiment of the present invention, illustrating a third connection configuration mode. FIG. 1 is a diagram showing a configuration of a conventional impedance measurement system. FIG. 1 is a diagram showing a more detailed configuration of a conventional impedance measurement system.

First Embodiment
A first embodiment of an impedance measuring system according to the present invention will be described below with reference to FIG. 1. The electronic components to be measured by the impedance measuring system (hereinafter referred to as "measurement objects") are battery cells and elements constituting an electric circuit, and the impedance is measured as an important electric parameter for evaluating the characteristics of the battery cells and elements. In this embodiment, a battery cell is taken as an example of the measurement object. The present invention is characterized by the connection between the impedance measuring device constituting the impedance measuring system and the battery cells, and in this connection, at least two battery cells are required and are arranged overlapping each other at a close distance. In this first embodiment, a pair of battery cells that are arranged overlapping each other at a close distance will be described as an example of the measurement object, but other elements constituting an electric circuit, for example, can also be applied.

[Configuration of impedance measurement system]
The impedance measurement system 1 includes a scanner (signal selection unit) 3 connected to battery cells 21 and 22 via current measurement lines 45, 46, 54, and 56 and voltage measurement lines 47, 48, 57, and 58, and an impedance measurement device 5 connected to the scanner 3 via current measurement lines 25 and 26 and voltage measurement lines 27 and 28. The current measurement lines 25, 45, and 54 are Hi-side current measurement lines (SOURCE Hi), and the current measurement lines 26, 46, and 56 are Lo-side current measurement lines (SOURCE Lo). The voltage measurement lines 27, 47, and 57 are Hi-side voltage measurement lines (SENSE Hi), and the voltage measurement lines 28, 48, and 58 are Lo-side voltage measurement lines (SENSE Lo).

Here, unlike the above-mentioned embodiment, the current measurement lines 25, 45, 54 may be Lo side current measurement lines, the current measurement lines 26, 46, 56 may be Hi side current measurement lines, the voltage measurement lines 27, 47, 57 may be Lo side voltage measurement lines, and the voltage measurement lines 28, 48, 58 may be Hi side voltage measurement lines, and the Lo side and the Hi side may be interchanged. In that case, the tab terminal 21a of the battery 21 of CH1 becomes the Lo side terminal, the tab terminal 21b becomes the Hi side terminal, and the tab terminal 22a of the battery 22 of CH2 becomes the Lo side terminal, and the tab terminal 22b becomes the Hi side terminal. This interchange of the Hi side terminal and the Lo side terminal is also possible in the second and third embodiments described later, but for convenience, the above description will be omitted. The scanner 3 corresponds to the signal selection unit of claim 3.

The impedance measuring device 5 includes a measurement signal source 11 that generates a measurement signal, an ammeter 13 as a current detection unit, and a voltmeter 15 as a voltage detection unit. The measurement signal source 11 corresponds to the measurement signal generating source in claim 1.

As shown in FIG. 1, the scanner 3 has switches 30 to 38 as signal selection units, and switches 30 to 38 are turned on and off (switched).

[Connection between the measuring device 5 and the battery cells 21, 22]
The following describes the connection of the voltage measurement lines and the current measurement lines among the impedance measuring device 5, the scanner 3, and the measurement target battery cells 21, 22. When the impedance measuring device 5 measures the internal impedance of each of the measurement target battery cells 21, 22, the measurement signal source 11, the ammeter 13, and the voltmeter 15 are connected to the battery cells 21, 22 via the scanner 3.

<Connection of Voltage Measurement Line of Battery Cell 21 of CH1>
By turning on each of the switches 31 and 32 of the scanner 3, the voltage measurement lines 27 and 28 are connected to the voltage measurement lines 47 and 48, respectively, and the voltmeter 15 is connected to the battery cell 21. One of a pair of output terminals (not shown) of the voltmeter 15 is connected to the tab terminal 21a of the battery cell 21 via the voltage measurement lines 27 and 47, and the other of the pair of output terminals of the voltmeter 15 is connected to the tab terminal 21b of the battery cell 21 via the voltage measurement lines 28 and 48. This connection mode is a mode for measuring the internal impedance of the battery cell 21. The measurement method will be described later.

<Connection of Voltage Measurement Line of Battery Cell 22 of CH2>
By turning on each of the switches 37 and 38 of the scanner 3, the voltage measurement lines 27 and 28 are connected to the voltage measurement lines 57 and 58, respectively, and the voltmeter 15 is connected to the battery cell 22. One of a pair of output terminals (not shown) of the voltmeter 15 is connected to the tab terminal 22a of the battery cell 22 via the voltage measurement lines 27 and 57, and the other of the pair of output terminals of the voltmeter 15 is connected to the tab terminal 22b of the battery cell 22 via the voltage measurement lines 28 and 58. This connection mode is a mode for measuring the internal impedance of the battery cell 22. The measurement method will be described later.

<Current measurement line connection mode>
By turning on switch 33 of scanner 3, current measurement line 25 and current measurement line 45 are connected, by turning on switch 34, current measurement line 26 and current measurement line 46 are connected, by turning on switch 35, current measurement line 25 and current measurement line 54 are connected, and by turning on switch 36, current measurement line 26 and current measurement line 56 are connected.

When measuring the impedance of the battery cells 21 and 22, the switches 33 and 36 of the scanner 3 are turned on, and one of the pair of output terminals (not shown) of the measurement signal source 11 is connected to the tab terminal 21a of the battery cell 21 via the current measurement lines 25 and 45, and the other of the pair of output terminals of the measurement signal source 11 is connected to the tab terminal 22b of the battery cell 22 via the ammeter 13 and the current measurement lines 26 and 56.

Here, the tab terminal 21b of the battery cell 21 is connected to the tab terminal 22a of the battery cell 22 via the switch 30. By turning on the switch 30 of the scanner 3, a measurement current loop is formed in the current measurement lines 25, 45, 46, 54, and 56. As a result, the direction of the measurement current flowing through the battery cell 21 and the direction of the measurement current flowing through the battery cell 22 are opposite to each other. The switch 30 corresponds to the connection means of claim 1.

The voltmeter 15 is disposed between the end of the voltage measurement line 27 and the end of the voltage measurement line 28, and measures the voltage generated between the end of the voltage measurement line 47 and the end of the voltage measurement line 48 due to the measurement current flowing in the measurement current loop, and the measured voltage is output to an arithmetic processing unit (not shown). This voltage measurement is performed according to the connection state of the voltage measurement lines described above when measuring the impedance of the battery cells 21 and 22 after connecting the current measurement lines described above.

[Measuring method]
Regarding the impedance measurement of the battery cell 21 (corresponding to the first connection mode), the internal impedance of the battery cell 21 is calculated in the arithmetic processing unit based on the current value of the measured current (current flowing through the battery cell 21) measured by the ammeter 13 and the voltage value of the voltage generated across the battery cell 21. As a prerequisite, the switches 30, 31, 32, 33, and 36 of the scanner 3 need to be turned on.

For impedance measurement of the battery cell 22 (corresponding to the second connection mode), the internal impedance of the battery cell 22 is calculated in the calculation processing unit based on the current value of the measured current (current flowing through the battery cell 22) measured by the ammeter 13 and the voltage value of the voltage generated across the battery cell 22. As a prerequisite, the switches 30, 33, 36, 37, and 38 of the scanner 3 must be turned on.

Figure 1 has been explained using one set of battery cells as an example, but even in the case of multiple sets of battery cells, impedance can be measured sequentially by switching using a switch as described above each time the battery cell to be measured is changed. More specifically, this will be explained in the second embodiment described later.

[effect]
According to the impedance measurement system of the first embodiment described above, a switch 30 is provided in the scanner 3, and a set of battery cells (one pair of battery cells) is used through connection processing within the scanner 3, so that the direction of the current flowing through each of the pair of battery cells is made different. Therefore, when measuring the impedance of each battery cell that constitutes a battery, the internal impedance of each battery cell can be safely measured without shorting the battery cells on the battery side.

When measuring the internal impedance, the loop length of the measurement current loop that flows from the measurement signal source 11 that applies the measurement current through the battery cells 21 and 22 is the same as the loop length of the conventional measurement current loop (see FIG. 5), so the internal impedance of the battery cells 21 and 22 can be safely measured while suppressing the magnetic flux leakage loop by minimizing the loop length. Note that the same effect can be obtained with cylindrical and rectangular cells other than laminated battery cells, and with measurement objects other than batteries.

Second Embodiment
A second embodiment of the impedance measurement system according to the present invention will be described below with reference to FIG. 2. This embodiment is different from the first embodiment in that two pairs of battery cells (total of 4 CH) are arranged and the number of switches (19) constituting the scanner corresponding thereto. The second embodiment has an increased number of connection modes compared to the impedance measurement system according to the first embodiment, but the basic idea is the same. That is, the basic idea is to provide switches 90, 109, and 119 (switch 30 in the first embodiment) for shorting one and the other of a pair of battery cells, to short one Hi side current measurement line (SOURCE Hi) of a pair of battery cells (battery cells CH1 and CH2 in the first embodiment) and the other Lo side current measurement line (SOURCE Lo) of a pair of battery cells (battery cells CH1 and CH2 in the first embodiment) during measurement, and to connect the Hi side voltage measurement line (SENSE Hi) and the Lo side voltage measurement line (SENSE Lo) of the battery cell to be measured to a voltmeter to perform impedance measurement. The switches 93, 95, 101 and 103 correspond to the first switch group of claim 3, the switches 94, 96, 102 and 104 correspond to the second switch group of claim 3, and the switches 91, 92, 97, 98, 99, 100, 105 and 106 correspond to the third switch group of claim 3.

Therefore, in this second embodiment, there are three combinations (three sets) of pairs of battery cells: battery cell 221 of CH1 and battery cell 222 of CH2, battery cell 222 of CH2 and battery cell 223 of CH3, and battery cell 223 of CH3 and battery cell 224 of CH4. In impedance measurement of battery cells 221 to 224, a voltmeter is connected to the battery cell being measured at each measurement to measure the voltage across each of the four battery cells being measured, so there are four connection modes of the voltage measurement line. Specifically, when the combination of battery cells 221 and 222 is the measurement target, two connections are required to measure the voltage across each of battery cells 221 and 222.

In addition, if the measurement target is the combination of battery cells 222 and 223, a connection (one mode) is required during measurement to measure the voltage across battery cell 223 (because the measurement of the voltage across battery cell 222 has already been performed and is therefore not necessary). In addition, if the measurement target is the combination of battery cells 223 and 224, a connection (one mode) is required during measurement to measure the voltage across battery cell 224 (because the measurement of the voltage across battery cell 223 has already been performed and is therefore not necessary). In the end, there are four modes of voltage measurement, the number of channels, for the impedance measurement of battery cells 221 to 224.

The following explanation will be given with the above points in mind. Note that battery cells 221, 222 and battery cells 223, 224 are actually arranged close to each other, but in Figure 2 they are shown separated by a certain distance for drawing purposes.

[Configuration of impedance measurement system]
The impedance measurement system 60 includes a scanner (signal selection unit) 63 connected to the battery cells 221 to 224 via current measurement lines 115, 116, 125, 126, 135, 136, 145, 146 and voltage measurement lines 117, 118, 127, 128, 137, 138, 147, 148, and an impedance measurement device 55 connected to the scanner 63 via current measurement lines 85, 86 and voltage measurement lines 87, 88. The current measurement lines 85, 115, 125, 135, 145 are Hi-side current measurement lines (SOURCE Hi), and the current measurement lines 86, 116, 126, 136, 146 are Lo-side current measurement lines (SOURCE Lo). Voltage measurement lines 87, 117, 127, 137, and 147 are voltage measurement lines on the Hi side (SENSE Hi), and voltage measurement lines 88, 118, 128, 138, and 148 are voltage measurement lines on the Lo side (SENSE Lo). The scanner 63 corresponds to a signal selection unit in claim 3.

The impedance measuring device 55 includes a measurement signal source 71 that generates a measurement signal, an ammeter 73 as a current detection unit, and a voltmeter 75 as a voltage detection unit. The measurement signal source 71 corresponds to the measurement signal generating source in claim 1.

As shown in FIG. 2, the scanner 63 has switches 90 to 106, 109, and 119 as signal selection units, and switches 90 to 106, 109, and 119 on and off (switching).

[Connection between the measuring device 55 and the battery cells 221 to 224]
The following describes the connection of the voltage measurement lines and the current measurement lines in the connection between the impedance measuring device 55, the scanner 63, and the battery cells 221 to 224 to be measured. When the impedance measuring device 55 measures the internal impedance of each of the battery cells 221 to 224 to be measured, the measurement signal source 71, the ammeter 73, the voltmeter 75, and the battery cells 221 to 224 are connected via the scanner 63.

<Connection of Voltage Measurement Line of Battery Cell 221 of CH1>
By turning on the switches 91 and 92 of the scanner 63, the voltage measurement lines 87 and 88 are connected to the voltage measurement lines 117 and 118, respectively, and the voltmeter 75 is connected to the battery cell 221. One of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 221a of the battery cell 221 via the voltage measurement lines 87 and 117, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 221b of the battery cell 221 via the voltage measurement lines 88 and 118. This first connection mode is a mode for measuring the internal impedance of the battery cell 221. The measurement method is the same as that of the first embodiment described above, so a description thereof will be omitted. Similarly, a description of the measurement method will be omitted for the following voltage measurement line connection modes.

<Connection of Voltage Measurement Line of Battery Cell 222 of CH2>
By turning on each of the switches 96 and 97, the voltage measurement lines 87 and 88 are connected to the voltage measurement lines 127 and 128, respectively, and the voltmeter 75 is connected to the battery cell 222. One of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 222a of the battery cell 222 via the voltage measurement lines 87 and 127, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 222b of the battery cell 222 via the voltage measurement lines 88 and 128. This connection mode is a mode for measuring the internal impedance of the battery cell 222.

<Connection of Voltage Measurement Line of Battery Cell 223 of CH3>
By turning on each of the switches 99, 100, the voltage measurement lines 87, 88 and the voltage measurement lines 137, 138 are connected, respectively, and the voltmeter 75 is connected to the battery cell 223. One of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 223a of the battery cell 223 via the voltage measurement lines 87, 137, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 223b of the battery cell 223 via the voltage measurement lines 88, 138. This connection mode is for measuring the internal impedance of the battery cell 223.

<Connection of Voltage Measurement Line of Battery Cell 224 of CH4>
By turning on each of the switches 105 and 106, the voltage measurement lines 87 and 88 are connected to the voltage measurement lines 147 and 148, respectively, and the voltmeter 75 is connected to the battery cell 224. One of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 224a of the battery cell 224 via the voltage measurement lines 87 and 147, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 224b of the battery cell 224 via the voltage measurement lines 88 and 148. This connection mode is for measuring the internal impedance of the battery cell 224.

<Current measurement line connection mode>
By turning on switch 93 of scanner 63, current measurement line 85 and current measurement line 115 are connected, and by turning on switch 94, current measurement line 86 and current measurement line 116 are connected. By turning on switch 95, current measurement line 85 and current measurement line 125 are connected, and by turning on switch 96, current measurement line 86 and current measurement line 126 are connected. By turning on switch 101, current measurement line 85 and current measurement line 135 are connected, and by turning on switch 102, current measurement line 86 and current measurement line 136 are connected. By turning on switch 103, current measurement line 85 and current measurement line 145 are connected, and by turning on switch 104, current measurement line 86 and current measurement line 146 are connected.

[Impedance Measurement of Battery Cells 221, 222]
When measuring the impedance of the battery cell 221, the switches 90, 93, and 96 of the scanner 63 are turned on, one of a pair of output terminals (not shown) of the measurement signal source 71 is connected to the tab terminal 221a of the battery cell 221 via the current measurement lines 85 and 115, and the other of the pair of output terminals of the measurement signal source 71 is connected to the tab terminal 222b of the battery cell 222 via the ammeter 73 and the current measurement lines 86 and 126. Then, the switches 91 and 92 of the scanner 63 are turned on, one of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 221a of the battery cell 221, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 221b of the battery cell 221, and the impedance measurement of the battery cell 221 is performed. Note that when measuring the impedance of the battery cell 221, the switches other than the switches 90, 91, 92, 93, and 96 of the scanner 63 are turned off.

When measuring the impedance of the battery cell 222, the switches 90, 93, and 96 of the scanner 63 are turned on to connect one of the pair of output terminals (not shown) of the measurement signal source 71 to the tab terminal 221a of the battery cell 221, and the other of the pair of output terminals of the measurement signal source 71 to the tab terminal 222b of the battery cell 222. Next, the switches 97 and 98 of the scanner 63 are turned on to connect one of the pair of output terminals (not shown) of the voltmeter 75 to the tab terminal 222a of the battery cell 222, and the other of the pair of output terminals of the voltmeter 75 to the tab terminal 222b of the battery cell 222, thereby measuring the impedance of the battery cell 222. When measuring the impedance of the battery cell 222, all switches other than the switches 90, 93, 96, 97, and 98 of the scanner 63 are turned off.

Here, the tab terminal 221b of the battery cell 221 is connected to the tab terminal 222a of the battery cell 222 via the switch 90. By turning on the switch 90 of the scanner 63, a measurement current loop is formed in the current measurement lines 115, 116, 125, and 126. As a result, the direction of the measurement current flowing through the battery cell 221 and the direction of the measurement current flowing through the battery cell 222 are opposite to each other.

[Impedance Measurement of Battery Cells 223, 224]
When measuring the impedance of the battery cell 223, the switches 101, 104, and 119 of the scanner 63 are turned on, one of a pair of output terminals (not shown) of the measurement signal source 71 is connected to the tab terminal 223a of the battery cell 223 via the current measurement lines 85 and 135, and the other of the pair of output terminals of the measurement signal source 71 is connected to the tab terminal 224b of the battery cell 224 via the ammeter 73 and the current measurement lines 86 and 146. Then, the switches 99 and 100 of the scanner 63 are turned on, one of a pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 223a of the battery cell 223, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 223b of the battery cell 223, thereby performing impedance measurement of the battery cell 223. Note that when measuring the impedance of the battery cell 223, the switches other than the switches 99, 100, 101, 104, and 119 of the scanner 63 are turned off.

When measuring the impedance of the battery cell 224, the switches 101, 104, and 119 of the scanner 63 are turned on, one of the pair of output terminals (not shown) of the measurement signal source 71 is connected to the tab terminal 223a of the battery cell 223 via the current measurement lines 85 and 135, and the other of the pair of output terminals of the measurement signal source 71 is connected to the tab terminal 224b of the battery cell 224 via the ammeter 73 and the current measurement lines 86 and 146. Next, the switches 105 and 106 of the scanner 63 are turned on, one of the pair of output terminals (not shown) of the voltmeter 75 is connected to the tab terminal 224a of the battery cell 224, and the other of the pair of output terminals of the voltmeter 75 is connected to the tab terminal 224b of the battery cell 224, and the impedance measurement of the battery cell 224 is performed. When measuring the impedance of the battery cell 224, the switches other than the switches 101, 104, 105, 106, and 119 of the scanner 63 are turned off.

Here, the tab terminal 223b of the battery cell 223 is connected to the tab terminal 224a of the battery cell 224 via the switch 119. By turning on the switch 119 of the scanner 63, a measurement current loop is formed in the current measurement lines 135, 136, 145, and 146. As a result, the direction of the measurement current flowing through the battery cell 223 and the direction of the measurement current flowing through the battery cell 224 are opposite to each other.

The voltmeter 75 is disposed between the end of the voltage measurement line 87 and the end of the voltage measurement line 88, and measures the voltage generated between the end of the voltage measurement line 117 and the end of the voltage measurement line 118 due to the measurement current flowing in the measurement current loop, and the measured voltage is output to an arithmetic processing unit (not shown). This voltage measurement is performed according to the connection state of the corresponding voltage measurement line described above after connecting the corresponding current measurement line described above when the measurement target of the impedance measurement is battery cells 221, 222 and when it is battery cells 223, 224.

Note that the measurement targets may be the battery cells 222 and 223 of CH2 and CH3. In this case, the voltage measurement line connection and current measurement line connection are performed by turning on the switch 109, forming a measurement current loop including the current measurement line 125 on the Hi side of the battery cell 222 of CH2, the current measurement line 136 on the Lo side of the battery cell 223 of CH3, and the switch 109, and measuring the voltage for each battery cell to be measured, and calculating the impedance.

[effect]
According to the impedance measurement system of the second embodiment described above, a scanner is provided with multiple switches 90, 109, 119, and two sets of battery cells (two pairs of battery cells) are used so that the direction of current flowing through each pair of battery cells in each set is made different. Therefore, even when measuring the impedance of each battery cell that constitutes a battery consisting of multiple sets of large capacity batteries, the internal impedance of the battery cells can be measured safely without shorting out the individual battery cells.

Third Embodiment
A third embodiment of the impedance measuring system according to the present invention will be described below with reference to FIG. 3. In the third embodiment, the current measurement line 116 on the Lo side of the battery cell 221 of CH1 and the current measurement line 125 on the Hi side of the battery cell 222 of CH2 are always connected via a connection line 150, the current measurement line 126 on the Lo side of the battery cell 222 of CH2 and the current measurement line 135 on the Hi side of the battery cell 223 of CH3 are always connected via a connection line 151, and the current measurement line 136 on the Lo side of the battery cell 223 of CH3 and the current measurement line 145 on the Hi side of the battery cell 224 of CH4 are always connected via a connection line 152. The third embodiment is the same as the second embodiment described above except that the switches 90, 109, and 119 are not provided and the configuration is as described above. Therefore, the same parts as those in the second embodiment will be described using the same reference numerals.

Even in the above configuration, if the Hi side current measurement line (SOURCE Hi) of one battery cell pair (the CH1 and CH2 battery cells in the first embodiment) and the Lo side current measurement line (SOURCE Lo) of the other battery cell pair are shorted during measurement, and the Hi side voltage measurement line (SENSE Hi) and the Lo side voltage measurement line (SENSE Lo) of the battery cell to be measured are connected to a voltmeter, the same effect as in the second embodiment described above can be obtained.

It goes without saying that if the number of switches constituting the scanner in the above embodiment is further increased, the number of sets of battery cells to be measured can be increased. Also, the voltage measurement wires connected to the voltmeters 15 and 75 may be shielded wires instead of twisted cables.

[effect]
As described above, according to the third embodiment, in addition to the effects obtained by the impedance measurement system of the first embodiment described above, impedance measurement can be performed with a simple configuration, thereby reducing manufacturing costs.

Although specific embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention. For example, the high side terminal and the low side terminal can be interchanged.

1, 60, 160 Impedance measurement system 3, 63 Scanner 5, 55 Impedance measurement device 11, 71 Measurement signal source 13, 73 Ammeter 15, 75 Voltmeter 21, 22, 221, 222, 223, 224 Battery cell 21a, 22a, 121a, 122a, 221a, 222a 223a, 224a, 21b, 22b, 121b, 122b, 221b, 222b, 223b, 224b, 225b Tab terminal 25, 26, 45, 46, 54, 56 Current measurement line 27, 28, 47, 48, 57, 58 Voltage measurement lines 31, 32, 33, 34, 35, 36, 37, 38, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 109, 119 Switches 110, 111, 150, 151, 152 Short-circuit lines (connection lines)

Claims (7)

a measurement signal source for supplying a measurement signal of a predetermined frequency to at least one pair of the electronic device under test having at least one pair of terminals;
a current detection unit disposed between a pair of output terminals of the measurement signal generating source and detecting a current flowing through the electronic device under test;
At least one voltage detection unit for measuring a voltage generated between both terminals of each of the set of electronic components to be measured,
An impedance measurement system having an impedance measurement device for measuring the impedance of each of the test target electronic components,
a connection means for connecting a first current measurement line between one of a pair of output terminals of the measurement signal generating source and one of the set of electronic components to be measured, and a second current measurement line between one of a pair of output terminals of the current detection unit and the other of the set of electronic components to be measured;
1. An impedance measurement system comprising: when measuring a voltage generated between both terminals of one of the pair of electronic components to be measured, the first current measurement line and the second current measurement line are connected via the connection means.
2. The impedance measurement system according to claim 1 . a signal selection unit having a plurality of switches when the set of electronic components to be measured is provided, the plurality of switches including at least a first switch group connected to the measurement signal generating source, a second switch group connected to the current detection unit, and a third switch group connected to the voltage detection unit;
At least in a state where a current measurement line connected to the measurement signal generating source by the first switch group is connected to a high-side terminal of one or the other of the set of target electronic components, and a current measurement line connected to the current detection unit by the second switch group is connected to a low-side terminal of the one or the other of the target electronic components, and in a state where a voltage measurement line connected to one terminal of the voltage detection unit is connected to a high-side terminal of one or the other of the set of target electronic components and a voltage measurement line connected to the other terminal of the voltage detection unit is connected to a low-side terminal of the one or the other of the set of target electronic components by the third switch group, the voltage detection unit detects a voltage between both terminals of the one or the other of the target electronic components.
3. The impedance measuring system according to claim 1, wherein the impedance measuring device is a casing. When the set of electronic components to be measured is provided in a plurality of sets, the voltage detection unit is connected to each set of electronic components to be measured for each set of electronic components to be measured.
4. The impedance measuring system according to claim 3. An impedance measurement method comprising the steps of: detecting a current flowing through an electronic component under test having at least a pair of terminals, the electronic component being disposed between one of a pair of output terminals of a measurement signal generating source which supplies a measurement signal of a predetermined frequency to at least one set of the electronic components under test; detecting a current flowing through the electronic component under test, the step of measuring a voltage generated between both terminals of each of the set of electronic components under test by at least one voltage detecting unit; and measuring an impedance of each of the electronic components under test based on a current value of the detected current and a voltage value of a measured voltage,
a first current measurement line between one of the pair of output terminals of the measurement signal generating source and one of the set of electronic components to be measured, and a second current measurement line between the other of the pair of output terminals of the current detection unit and the other of the set of electronic components to be measured;
13. An impedance measuring method comprising: when measuring a voltage generated between both terminals of one of the pair of electronic components to be measured, the first current measurement line and the second current measurement line are connected via a connection means;
6. The impedance measuring method according to claim 5. a signal selection unit having a plurality of switches when the set of electronic components to be measured is provided, the plurality of switches including at least a first switch group connected to the measurement signal generating source, a second switch group connected to the current detection unit, and a third switch group connected to the voltage detection unit;
At least a current measurement line connected to the measurement signal generating source via the first switch group is connected to a high-side terminal of the one or the other of the set of measurement target electronic components;
a current measurement line connected to the current detection unit via the second switch group is connected to a low-side terminal of the one or the other of the electronic components to be measured;
via the third switch group, a voltage measurement line connected to one terminal of the voltage detection unit is connected to a high-side terminal of one or the other of the set of measurement target electronic components;
a voltage measurement line connected to the other terminal of the voltage detection unit is connected to a low-side terminal of the one or the other of the electronic components to be measured;
The voltage detection unit detects a voltage between both terminals of one or the other of the pair of electronic components to be measured.
7. The impedance measuring method according to claim 5 or 6.

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