JP2012220448A - Voltage measuring device, balance correction device, power storage system and voltage measuring method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve such a problem that, when the voltages of a plurality of secondary batteries are measured, measurement errors vary depending on the positions of the secondary batteries in a battery module.SOLUTION: A voltage measuring device includes: a first voltage measuring part which measures a voltage of each of a plurality of power storage cells; a storage part in which identification information for identifying each of the plurality of the power storage cells, and correspondence information showing a correspondence relationship between a voltage value measured by the first voltage measuring part and a voltage value pre-measured by a second voltage measuring part different from the first voltage measuring part are stored; and a correction part which outputs the voltage value measured by the second voltage measuring part corresponding to the voltage value measured by the first voltage measuring part based on the identification information for identifying an object to be measured of the first voltage measuring part and the voltage value measured by the first voltage measuring part.

Description

  The present invention relates to a voltage measurement device, a balance correction device, a power storage system, and a voltage measurement method.

When charging a battery module in which a plurality of secondary batteries are connected in series, if the voltages of the secondary batteries vary, some of the batteries may be overcharged. Then, the balance correction apparatus and voltage measurement apparatus which measure the voltage of a battery and equalize a voltage are known (refer patent documents 1-3).
[Prior art documents]
[Patent Literature]
(Patent Document 1) JP-A-10-257682 (Patent Document 2) JP-A 2007-184135 (Patent Document 3) JP-A 2010-181168

  When each voltage of a plurality of secondary batteries is measured using a voltage measuring device, the measurement error varies depending on the position of the secondary battery in the battery module.

  In the first aspect of the present invention, there is provided a voltage measuring device for measuring voltages of a plurality of storage cells connected in series, and a first voltage measuring unit for measuring the voltages of the plurality of storage cells. And identification information for identifying each of the plurality of power storage cells, the value of the voltage measured by the first voltage measurement unit, and a second voltage measurement unit that is different from the first voltage measurement unit. A storage unit that stores correspondence information indicating a correspondence relationship with a voltage value, identification information of a measurement target of the first voltage measurement unit, a measurement value of the voltage by the first voltage measurement unit, using the correspondence information; Based on the above, a voltage measuring device is provided that includes a correction unit that outputs a voltage value obtained by the second voltage measuring unit corresponding to a voltage measured value obtained by the first voltage measuring unit.

  In the voltage measurement device, the measurement accuracy of the second voltage measurement unit may be higher than the measurement accuracy of the first voltage measurement unit. In the voltage measurement device, the storage unit measures, as correspondence information, identification information for identifying each of the plurality of power storage cells, a voltage measurement value by the first voltage measurement unit, and a second voltage measurement unit in advance. The voltage values thus obtained may be stored in association with each other. In the voltage measurement device, the storage unit may store statistical values of a plurality of measurement results obtained by the first voltage measurement unit as voltage measurement values obtained by the first voltage measurement unit. In the voltage measuring apparatus, the number of pieces of correspondence information in the predetermined first voltage range may be larger than the number of pieces of correspondence information in the second voltage range different from the first voltage range.

  In the voltage measurement apparatus, the first voltage measurement unit includes a first input terminal to which a reference potential is input, a second input terminal electrically connected to the positive electrode end of the measurement target, and a measurement target. You may have the 3rd input terminal electrically connected with a negative electrode end. In the voltage measuring apparatus, the voltage to be measured is obtained by subtracting the potential difference between the first input terminal and the third input terminal from the potential difference between the first input terminal and the second input terminal. May be measured. In the above voltage measurement device, the second voltage measurement unit may measure each voltage of the plurality of storage cells by being electrically connected to each positive electrode end and each negative electrode end of the plurality of storage cells. .

  In the second aspect of the present invention, the voltage of the plurality of storage cells is measured based on the voltage measurement device that measures the voltages of the plurality of storage cells connected in series and the voltage measured by the voltage measurement device. A balance correction apparatus including a voltage equalization unit for equalization is provided.

  In a third aspect of the present invention, an electricity storage system is provided that includes a plurality of electricity storage cells connected in series and the voltage measuring device that measures the voltages of the electricity storage cells. The power storage system may further include a voltage equalization unit that equalizes the voltages of the plurality of power storage cells based on the voltage measured by the voltage measurement device.

  In the fourth aspect of the present invention, the first voltage measurement unit measures the voltage of each of the plurality of storage cells connected in series, and identification information for identifying each of the plurality of storage cells, The correspondence information indicating the correspondence between the voltage value measured by the first voltage measurement unit and the voltage value measured in advance by a second voltage measurement unit different from the first voltage measurement unit is used. The second voltage corresponding to the voltage measurement value by the first voltage measurement unit based on the identification information for identifying the measurement object of the first voltage measurement unit and the voltage measurement value by the first voltage measurement unit There is provided a voltage measurement method including a correction step of outputting a voltage value by a measurement unit.

  It should be noted that the above summary of the invention does not enumerate all the necessary features of the present invention. In addition, a sub-combination of these feature groups can also be an invention.

An example of the electrical storage system 110 is shown schematically. An example of control measurement part 150 is shown roughly. An example of correction information database 168 is shown roughly. An example of a voltage measuring method is shown roughly. An example of the charging curve 502 of a lithium ion battery is shown roughly.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. Not all combinations of features described in the embodiments are essential for the solution of the invention. In addition, embodiments will be described with reference to the drawings, but in the description of the drawings, the same or similar parts may be denoted by the same reference numerals and redundant description may be omitted.

  FIG. 1 schematically shows an example of a power storage system 110. FIG. 1 shows a power storage system 110 together with a charging device 102 and a calibration measuring unit 104. FIG. 1 schematically shows an example of the state of charge of the power storage system 110. In the present embodiment, the power storage system 110 includes a terminal 112, a terminal 114, a power storage module 120, and a balance correction unit 130. The power storage module 120 includes a power storage cell 122, a power storage cell 124, a power storage cell 126, and a power storage cell 128.

  The balance correction unit 130 may include a voltage equalization unit 132 and a control unit 134. The voltage equalization unit 132 may include a switching element 142, a switching element 144, a switching element 146, and a switching element 148. The voltage equalizing unit 132 may include a resistor 143, a resistor 145, a resistor 147, and a resistor 149. The control unit 134 may include a control measurement unit 150, a storage unit 162, a correction unit 164, and a signal generation unit 166. The storage unit 162 may store the correction information database 168.

  The calibration measurement unit 104 may be an example of a second voltage measurement unit. The balance correction unit 130 may be an example of a balance correction device. The control unit 134 may be an example of a voltage measurement device. The control measurement unit 150 may be an example of a first voltage measurement unit. The power storage cell 122, the power storage cell 124, the power storage cell 126, and the power storage cell 128 may be an example of a plurality of power storage cells.

  In this embodiment, the case where the electrical storage module 120 has four electrical storage cells is demonstrated for the purpose of simplifying the description. However, the number of storage cells is not limited to four. The power storage module 120 may have a plurality of power storage cells connected in series.

  “Electrically connected” is not limited to a case where an element and another element are directly connected. A third element may be interposed between one element and another element. Moreover, it is not limited to when a certain element and another element are physically connected. For example, the input winding and output winding of the transformer are not physically connected, but are electrically connected. Further, not only when an element and another element are actually electrically connected, but also when an energy storage cell and a balance correction circuit are electrically connected, an element and another element are electrically connected. Including the case of connection. Further, “connected in series” indicates that an element and another element are electrically connected in series.

  Charging device 102 is electrically connected to power storage system 110 and charges power storage system 110. The calibration measurement unit 104 is used when the correction information database 168 is constructed. Calibration measurement unit 104 measures the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128. In the present embodiment, the calibration measurement unit 104 is a voltage measurement device physically different from the control measurement unit 150. Further, the measurement accuracy of the calibration measurement unit 104 is higher than the measurement accuracy of the control measurement unit 150.

  The calibration measurement unit 104 may include a terminal 105 and a terminal 107. When the voltage of each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 is measured, the terminal 105 is connected to the positive terminal of each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128. Electrically connected. When the voltage of each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 is measured, the terminal 107 is connected to the negative end of each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128. Electrically connected.

  The power storage system 110 is electrically connected to a power load such as a motor (not shown) and supplies power to the power load. Terminal 112 and terminal 114 electrically connect a device external to power storage system 110 to power storage system 110. The power load and charging device 102 described above may be an example of a device external to the power storage system 110. The power storage system 110 may be used as a power source for a transportation device such as an electric vehicle, a hybrid vehicle, an electric motorcycle, a railway vehicle, and an elevator. The power storage system 110 may be used as a power source for electric devices such as PCs and mobile phones. The power storage system 110 may be used in a power management system that manages power supply.

  One end of the power storage module 120 is electrically connected to the terminal 112. The other end of the power storage module is electrically connected to the terminal 114. Power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 are connected in series. Thereby, the power storage module 120 can output a predetermined current.

  Each of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 may include a plurality of power storage cells. For example, at least one of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 may include a plurality of storage cells connected in parallel. Thereby, the electrical storage module 120 can output a predetermined voltage. Further, at least one of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 may be formed by connecting a plurality of unit cells in series.

The power storage cell 122, the power storage cell 124, the power storage cell 126, and the power storage cell 128 may be secondary batteries or capacitors. Examples of secondary batteries include lithium ion batteries, lithium ion polymer batteries, and nickel metal hydride batteries. In particular, an iron phosphate lithium ion battery using LiFePO ₄ as a positive electrode material has a range of operating voltage as compared with a lithium ion battery or a lithium ion polymer battery using LiCoO ₂ , LiMn ₂ O ₄ or the like as a positive electrode material. narrow. Therefore, it is preferable to manage the voltage more strictly.

  The balance correction unit 130 equalizes the voltages of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 at least during the charging operation of the storage system 110. As a result, even when charging of the power storage module 120 is started in a state where the voltages among the power storage cells 122, the power storage cells 124, the power storage cells 126, and the power storage cells 128 vary, some of the power storage cells An overcharged state can be prevented.

  Based on at least one of the control signal φ42, the control signal φ44, the control signal φ46, and the control signal φ48 generated by the control unit 134, the voltage equalizing unit 132 is based on at least one of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell. The voltage of 128 is equalized. The control signal φ42, the control signal φ44, the control signal φ46, and the control signal φ48 are respectively at least one of an ON operation and an OFF operation of the switching element 142, the switching element 144, the switching element 146, and the switching element 148 (in the case of an on / off operation) There is control).

  Control unit 134 measures the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128. The control unit 134 calculates a correction value for the measured voltage based on the correction information acquired in advance. Control unit 134 generates at least one of control signal φ42, control signal φ44, control signal φ46, and control signal φ48 based on the corrected voltage. Control unit 134 generates charge completion signal φ20 when the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 reach predetermined voltages. Charging may be terminated when charging device 102 receives charging completion signal φ20.

  Part or all of the control unit 134 may be realized by hardware or may be realized by software. A part or all of the control unit 134 may be a system specialized for each application, or may be a general-purpose information processing apparatus such as a personal computer. The specialized system and information processing apparatus described above may be configured by a single computer or may be configured by a plurality of computers distributed on a network.

  A part or all of the control unit 134 may function as a part or all of the control unit 134 by executing a program. In an information processing apparatus having a general configuration including a data processing device having a CPU, ROM, RAM, communication interface, and the like, an input device, an output device, and a storage device, the operation of each unit of the control unit 134 is defined. A part or all of the control unit 134 may be realized by starting the software.

  One end of the switching element 142 is electrically connected to the negative electrode end of the storage cell 122 via the resistor 143. The other end of the switching element 142 is electrically connected to the positive end of the storage cell 122. When the switching element 142 is turned on during the charging operation of the power storage module 120, a part of the charging current flows through the switching element 142 bypassing the power storage cell 122. Thereby, the overcharge of the electrical storage cell 122 can be suppressed.

  The switching element 142 may be a transistor such as a bipolar transistor or a MOSFET. Switching element 142 may be an element that turns off when control signal φ42 is not received. The switching element 144, the switching element 146, and the switching element 148 may have the same configuration as the switching element 142.

  For example, one end of the resistor 143 is electrically connected to the negative end of the storage cell 122. The other end of the resistor 143 is electrically connected to the switching element 142. Accordingly, when the switching element 142 is turned on, the electric energy stored in the storage cell 122 can be released to the outside as heat energy. The resistor 145, the resistor 147, and the resistor 149 may have a configuration similar to that of the resistor 143.

  Control measurement unit 150 measures the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 at least during the charging operation of power storage system 110. Control measurement unit 150 may measure the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 during the discharging operation of power storage system 110. The control measurement unit 150 may notify the correction unit 164 of the measured voltage value in association with identification information for identifying the measured storage cell (sometimes referred to as a measurement target).

  When the potential at the negative electrode end of the storage cell 122 is set as a reference potential, the control measurement unit 150 subtracts the potential difference between the reference potential and the negative electrode end of the storage cell 122 from the potential difference between the reference potential and the positive end of the storage cell 122. Thus, the voltage of the storage cell 122 may be measured. The control measurement unit 150 may measure the voltage of the storage cell 124 by subtracting the potential difference between the reference potential and the positive end of the storage cell 122 from the potential difference between the reference potential and the positive end of the storage cell 124. Control measurement unit 150 may measure the voltages of power storage cell 126 and power storage cell 128 in the same manner as the voltage of power storage cell 124.

  In the present embodiment, the case where the reference potential of the control measurement unit 150 is the potential of the negative electrode end of the storage cell 122 has been described. However, the reference potential of the control measurement unit 150 is not limited to this. The reference potential of control measurement unit 150 may be the potential at the positive end of power storage cell 122. In this case, the control measurement unit 150 measures the voltage of the storage cell 124 by subtracting the potential difference between the reference potential and the negative electrode end of the storage cell 124 from the potential difference between the reference potential and the negative electrode end of the storage cell 126. It's okay. The reference potential of the control measurement unit 150 may be a potential at a connection point between the positive electrode end of the storage cell 124 and the storage cell negative electrode end.

  In this embodiment, the case where the control measurement unit 150 calculates the voltage of the storage cell based on the potential difference from the reference potential has been described. However, the control measurement unit 150 is not limited to this. The control measurement unit 150 may include a voltage measurement capacitor. The control measurement unit 150 charges the output of the capacitor while sequentially switching the storage cell to be measured using a switch, and measures the voltage across the capacitor with a differential amplifier, thereby measuring the storage cell to be measured. May be measured.

  The storage unit 162 has identification information for identifying each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128, the voltage value measured by the control measurement unit 150, and the calibration measurement unit 104 in advance. Stores correspondence information indicating a correspondence relationship with the measured voltage value. The storage unit 162 stores a correction information database 168. The correction information database 168 includes identification information for identifying each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128, the voltage value measured by the control measurement unit 150, and the calibration measurement unit 104. It may be a database that correlates values of voltages measured in advance. The information stored in the correction information database 168 may be an example of correspondence information.

  In the present embodiment, the case where the correspondence information is provided as the correction information database 168 has been described. However, the correspondence information is not limited to this. The correspondence information may be provided as a function of outputting the voltage value measured in advance by the calibration measuring unit 104 when the voltage value measured by the control measuring unit 150 is input. The function is, for example, a function that plots the voltage value measured by the control measurement unit 150 and the voltage value measured in advance by the calibration measurement unit 104 and represents an approximate curve by the least square method or the like. It is obtained by calculating.

  The storage unit 162 may store statistical values of a plurality of measurement results obtained by the control measurement unit 150 as voltage measurement values obtained by the control measurement unit 150. When the terminals 105 and 107 of the calibration measurement unit 104 are electrically connected to the positive electrode end and the negative electrode end of the storage cell that is the measurement target of the control measurement unit 150 for the purpose of acquiring correspondence information, the calibration measurement is performed. As the unit 104 is connected, noise may be observed in the measurement result of the control measurement unit 150. By storing statistical values of a plurality of measurement results by the control measurement unit 150 as voltage measurement values by the control measurement unit 150, more accurate values can be stored as correspondence information. The statistical value may be an average value.

  Correction unit 164 receives the value of the voltage measured by control measurement unit 150 for each of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128. The correction unit 164 receives, from the control measurement unit 150, information in which the identification information for identifying each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 is associated with each voltage value. .

  The correction unit 164 corrects the voltage value received from the control measurement unit 150. The correction unit 164 uses the correspondence information to correspond to the voltage measurement value by the control measurement unit 150 based on the identification information of the measurement target of the control measurement unit 150 and the voltage measurement value by the control measurement unit 150. The voltage value by the calibration measuring unit 104 is output.

  In the present embodiment, the correction unit 164 includes the measurement target identification information received from the control measurement unit 150 and the measurement value of the measurement target voltage, the measurement target identification information stored in the correction information database 168, and the measurement target. Compare the measured voltage value. The correction unit 164 is a calibration measurement corresponding to the identification information of the measurement target and the voltage measurement value, among the voltage values stored in the correction information database 168 and measured in advance by the calibration measurement unit 104. The value of the voltage measured in advance by the unit 104 is extracted.

  The correction unit 164 notifies the signal generation unit 166 of the extracted voltage value as the voltage to be measured. The correction unit 164 may notify the signal generation unit 166 of the extracted voltage value in association with identification information for identifying each of the storage cell 124, the storage cell 126, and the storage cell 128.

  For example, when the control measurement unit 150 calculates the voltage values of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 based on the potential difference from the reference potential, the potential difference from the reference potential is As it increases, the voltage measurement accuracy decreases. On the other hand, the calibration measurement unit 104 directly measures the voltage between the terminals of the storage cell to be measured.

  Therefore, by correcting the voltage value measured by the control measurement unit 150 using the voltage value measured in advance by the calibration measurement unit 104, the power storage cell 124, the power storage cell can be obtained using the control measurement unit 150. Even when the voltage values of 126 and the storage cell 128 are measured, the voltage can be measured with high accuracy. In addition, by using a voltage measuring instrument with higher measurement accuracy than the control measuring section 150 as the calibration measuring section 104, an inexpensive voltage measuring instrument with low accuracy is used as the control measuring section 150. The voltage can be measured with high accuracy. Thereby, even if the tolerance of the control measurement unit 150 is relatively large, the voltage of the storage cell can be accurately measured.

  The signal generation unit 166 receives the corrected voltage value for each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128 from the correction unit 164. The signal generator 166 generates at least one of the control signal φ42, the control signal φ44, the control signal φ46, and the control signal φ48 based on the corrected voltage value received from the correction unit 164.

  For example, when the voltage of the storage cell 122 received from the correction unit 164 is greater than a predetermined value, the signal generation unit 166 generates a control signal φ42 that turns on the switching element 142. The signal generation unit 166 may generate the control signal φ42 that makes the switching element 142 conductive and decreases the resistance as the difference between the voltage of the storage cell 122 and a predetermined value increases. As a result, the storage cell 122 is bypassed, and the current flowing through the switching element 142 increases. As a result, overcharging of the storage cell 122 can be suppressed.

  Thereafter, when the voltage of the storage cell 122 received from the correction unit 164 becomes smaller than a predetermined value, the signal generation unit 166 generates a control signal φ42 for turning off the switching element 142. When the switching element 142 is an element that performs an off operation when the control signal φ42 is not received, the signal generation unit 166 has the voltage of the storage cell 122 received from the correction unit 164 smaller than a predetermined value. Then, the generation of the control signal φ42 may be stopped.

  FIG. 2 schematically shows an example of the control measurement unit 150. FIG. 2 shows the control measurement unit 150 together with the terminal 112, the terminal 114, the power storage module 120, and the correction unit 164. In the present embodiment, the control measurement unit 150 includes an A / D converter 252 and a voltage dividing circuit 254. The voltage dividing circuit 254 includes a terminal 271, a terminal 273, a terminal 275, a terminal 277, a terminal 279, a resistor 283, a resistor 285, a resistor 287, a resistor 289, a resistor 293, a resistor 295, A resistor 297 and a resistor 299 are provided.

  The A / D converter 252 may be an example of a first voltage measurement unit. The terminal 271 may be an example of a first terminal. The terminal 271, the terminal 273, the terminal 275, and the terminal 277 may be an example of a first input terminal. The terminal 273, the terminal 275, the terminal 277, and the terminal 279 may be an example of a second input terminal.

  The A / D converter 252 has a plurality of input ports ch0 to ch4. In this embodiment, the input port ch0 is grounded, and a reference potential is input. The input port ch0 is electrically connected to the negative electrode end of the storage cell 122. Input port ch <b> 1 is electrically connected to a connection point between the positive end of power storage cell 122 and the negative end of power storage cell 124. Input port ch <b> 2 is electrically connected to a connection point between the positive end of power storage cell 124 and the negative end of power storage cell 126. Input port ch3 is electrically connected to a connection point between the positive end of power storage cell 126 and the negative end of power storage cell 128. Input port ch4 is electrically connected to the positive end of power storage cell 128.

  The A / D converter 252 performs an operation based on the potential read from the input ports ch0 to ch4, and measures each voltage value of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128. A / D converter 252 outputs each voltage value of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128 to correction unit 164. The A / D converter 252 may output the measured voltage value to the correction unit 164 in association with identification information for identifying the measurement target.

  For example, the A / D converter 252 calculates the potential at the terminal 273 by dividing the potential value read from the input port ch1 by the voltage dividing ratio of the resistor 283 and the resistor 293. The voltage dividing ratio between the resistor 283 and the resistor 293 can be calculated by dividing the resistance value of the resistor 283 by the total value of the resistance value of the resistor 283 and the resistance value of the resistor 293. The A / D converter 252 calculates the potential at the terminal 275 by dividing the potential value read from the input port ch2 by the voltage dividing ratio of the resistor 285 and the resistor 295. The voltage dividing ratio between the resistor 285 and the resistor 295 can be calculated by dividing the resistance value of the resistor 285 by the total value of the resistance value of the resistor 285 and the resistance value of the resistor 295.

  Next, the A / D converter 252 measures the voltage of the storage cell 124 by subtracting the potential difference between the terminal 271 and the terminal 273 from the potential difference between the terminal 271 and the terminal 275. In the present embodiment, since the terminal 271 is grounded, the A / D converter 252 calculates the voltage of the storage cell 124 by subtracting the potential at the terminal 273 from the potential at the terminal 275. Similarly, A / D converter 252 measures the voltage values of power storage cell 122, power storage cell 126, and power storage cell 128.

  The voltage dividing circuit 254 divides the voltages input to the terminal 273, the terminal 275, the terminal 277, and the terminal 279 so that the magnitude of the voltage input to the input ports ch0 to ch4 of the A / D converter 252 is A / D. Adjustment is made so that the input voltage rating of the D converter 252 is below the rated value. Terminal 271 is electrically connected to the negative electrode end of power storage cell 122. Terminal 271 is electrically connected to input port ch0 of A / D converter 252. In the present embodiment, the terminal 271 is grounded and receives a reference potential.

  Terminal 273 is electrically connected to a connection point between the positive electrode end of power storage cell 122 and the negative electrode end of power storage cell 124. Terminal 273 is electrically connected to input port ch 1 of A / D converter 252 via resistor 293. The terminal 273 is electrically connected to the terminal 271 through the resistor 283. Terminal 275 is electrically connected to a connection point between the positive electrode end of power storage cell 124 and the negative electrode end of power storage cell 126. Terminal 275 is electrically connected to input port ch2 of A / D converter 252 via resistor 295. The terminal 275 is electrically connected to the terminal 271 through the resistor 285.

  Terminal 277 is electrically connected to a connection point between the positive end of power storage cell 126 and the negative end of power storage cell 128. Terminal 277 is electrically connected to input port ch 3 of A / D converter 252 via resistor 297. The terminal 277 is electrically connected to the terminal 271 through the resistor 287. Terminal 279 is electrically connected to the positive end of power storage cell 128. Terminal 279 is electrically connected to input port ch 4 of A / D converter 252 via resistor 299. The terminal 279 is electrically connected to the terminal 271 through the resistor 289.

  One end of the resistor 283 is electrically connected to the terminal 273 via the resistor 293. The other end of the resistor 283 is electrically connected to the terminal 271. One end of the resistor 285 is electrically connected to the terminal 275 via the resistor 295. The other end of the resistor 285 is electrically connected to the terminal 271. One end of the resistor 287 is electrically connected to the terminal 277 via the resistor 297. The other end of the resistor 287 is electrically connected to the terminal 271. One end of the resistor 289 is electrically connected to the terminal 279 via the resistor 293. The other end of the resistor 289 is electrically connected to the terminal 271.

  One end of the resistor 293 is electrically connected to the terminal 273. The other end of the resistor 293 is electrically connected to the input port ch1 of the A / D converter 252. One end of the resistor 295 is electrically connected to the terminal 275. The other end of the resistor 295 is electrically connected to the input port ch2 of the A / D converter 252. One end of the resistor 297 is electrically connected to the terminal 277. The other end of the resistor 297 is electrically connected to the input port ch3 of the A / D converter 252. One end of the resistor 299 is electrically connected to the terminal 273. The other end of the resistor 299 is electrically connected to the input port ch4 of the A / D converter 252.

  FIG. 3 schematically shows an example of the correction information database 168. The correction information database 168 includes the voltage value measured by the control measurement unit 150 and the voltage measured in advance by the calibration measurement unit 104 for each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128. Stores the correspondence with the value of. The correction information database 168 stores the storage cell name 302, the measured voltage value 304, and the voltage correction value 306 in association with each other.

  The name 302 of the storage cell may be an example of identification information for identifying each of the storage cell 122, the storage cell 124, the storage cell 126, and the storage cell 128. The actual voltage value 304 stores the voltage value measured by the control measurement unit 150. The actual voltage measurement value 304 may be an example of a voltage measurement value obtained by the first voltage measurement unit. The voltage correction value 306 stores the voltage value measured by the calibration measuring unit 104. The voltage correction value 306 may be an example of a voltage value obtained by the second voltage measurement unit.

  The correspondence relationship between the voltage value measured by the control measurement unit 150 and the voltage value measured in advance by the calibration measurement unit 104 can be acquired as follows, for example. First, the terminals 105 and 107 of the calibration measuring unit 104 are electrically connected to the positive electrode end and the negative electrode end of the storage cell 122. Next, the voltage of the storage cell 122 is measured by the control measurement unit 150 and the calibration measurement unit 104 while changing the voltage of the storage cell 122.

  As a result, the voltage value measured by the calibration measuring unit 104 corresponding to the voltage value measured by the control measuring unit 150 can be acquired. Similarly, for the storage cell 124, the storage cell 126, and the storage cell 128, the voltage value measured by the calibration measurement unit 104 corresponding to the voltage value measured by the control measurement unit 150 is acquired. Can do.

  In the present embodiment, when the measured voltage value 304 is in the voltage range 312, the correspondence between the measured voltage value 304 and the corrected voltage value 306 is acquired every 0.1V. On the other hand, when the measured voltage value 304 is in the voltage range 314, it is acquired every 0.025V. That is, the number of pieces of correspondence information in the voltage range 314 is larger than the number of pieces of correspondence information in the voltage range 312. Similarly, when the measured voltage value 304 is in the voltage range 316, the correspondence between the measured voltage value 304 and the correction value 306 of the voltage is acquired every 0.1V. When the voltage measured value 304 is in the voltage range 318, it is acquired every 0.025V.

  This improves the measurement accuracy when the actual voltage measurement value 304 is in the voltage range 314 or the voltage range 318 as compared to the case where the actual voltage measurement value 304 is in the voltage range 312 or the voltage range 316. it can. The voltage range 314 may include a lower limit value of voltage management. The voltage range 318 may include an upper limit value for voltage management. The voltage range 312 and the voltage range 316 may be an example of a second voltage range. The voltage range 314 and the voltage range 318 may be an example of a first voltage range.

  The format of the correction information database 168 is not particularly limited, but the correction information database 168 stores the value of the voltage correction value 306 when the value of the actual measurement value 304 of the voltage is a predetermined value. It's okay. The correction information database 168 may store the value of the actually measured voltage 304 when the value of the voltage correction value 306 is a predetermined value. The correction information database 168 may store correspondence information over the entire range of the upper limit value and the lower limit value of the voltage management value. The correction information database 168 may store correspondence information for a partial range between the upper limit value and the lower limit value of the voltage management value.

  The correction information database 168 stores correspondence information for a predetermined first range including the upper limit value of the voltage management value and a predetermined second range including the lower limit value of the voltage management value, Correspondence information does not have to be stored for the third range between the first range and the second range. In this case, when the voltage value received from the control measurement unit 150 is in the third range, the voltage value received from the control measurement unit 150 may be output to the signal generation unit 166.

  FIG. 4 schematically shows an example of a voltage measurement method. In this embodiment, correspondence information is acquired in S402. For example, the terminal 105 and the terminal 107 of the calibration measurement unit 104 are electrically connected to the positive electrode end and the negative electrode end of the storage cell 122. Next, the voltage of the storage cell 122 is measured by the control measurement unit 150 and the calibration measurement unit 104 while changing the voltage of the storage cell 122. As a result, the voltage value measured by the calibration measurement unit 104 corresponding to the voltage value measured by the control measurement unit 150 is acquired for the storage cell 122.

  The same operation is performed on the storage cell 124, the storage cell 126, and the storage cell 128 to create the correction information database 168. Thereafter, the correction information database 168 is stored in the storage unit 162. The correction information database 168 may be acquired via a communication line such as the Internet and stored in the storage unit 162.

  In S <b> 404, during measurement of power storage system 110, control measurement unit 150 measures the voltages of power storage cell 122, power storage cell 124, power storage cell 126, and power storage cell 128. The control measurement unit 150 notifies the correction unit 164 of the measured voltage value in association with the identification information for identifying the measured power storage cell.

  In step S <b> 406, the correction unit 164 corrects the voltage value received from the control measurement unit 150 using the correction information database 168. The correction unit 164 matches the measurement value of the measurement target voltage received from the control measurement unit 150 with the measurement object identification information received from the control measurement unit 150 and the measurement value of the voltage of the measurement target as search keys. The actual measurement value 304 of the voltage is searched. The correction unit 164 outputs the value stored in the voltage correction value 306 corresponding to the found actual measured value 304 to the signal generation unit 166 as a corrected voltage.

  Thereby, the measurement accuracy of the voltage in the control part 134 can be improved. When there is no actual voltage measurement value 304 that matches the measurement value of the voltage to be measured received from the control measurement unit 150, the correction unit 164 stores the data of the actual voltage measurement value 304 and the voltage correction value 306. The corrected voltage value may be calculated by interpolation.

  The storage unit 162 and the correction unit 164 may be realized by software. The storage unit 162 and the correction unit 164 cause the computer to identify information for identifying each of the plurality of storage cells, the voltage value measured by the first voltage measurement unit, and the first voltage measurement unit different from the first voltage measurement unit. Identification information for identifying a measurement target of the first voltage measurement unit using the correspondence information indicating the correspondence relationship with the voltage value measured in advance by the two voltage measurement units, and the voltage of the first voltage measurement unit Based on the measured value, the program may be implemented by a program that executes a correction step of outputting the voltage value by the second voltage measuring unit corresponding to the voltage measured value by the first voltage measuring unit.

FIG. 5 schematically shows an example of a charging curve 502 of a lithium ion battery. In FIG. 5, the horizontal axis indicates the capacity, and the vertical axis indicates the voltage. When the lithium ion battery is overcharged, the thermal stability of the battery is lowered due to heat generation or destabilization of the active material due to participation decomposition of the electrolyte. On the other hand, if the lithium ion battery is overdischarged, it will not function as a secondary battery. Therefore, the battery voltage is controlled to be between the lower limit value V ₁ and the upper limit value V _2.

Recently, due to improvement of positive electrode material, the slope of the charge curve 502 between the upper capacitor Q ₂ to which corresponds to the lower limit capacity Q _1, the upper limit value V ₂ corresponding to the lower limit value V ₁ is being developed a small lithium ion battery Yes. For example, a lithium iron phosphate battery using lithium iron phosphate as a positive electrode material has attracted attention as a battery excellent in safety and economy.

On the other hand, it is preferable to measure the lower limit value V ₁ and the upper limit value V ₂ more accurately as the slope of the charging curve 502 between the lower limit capacity Q ₁ and the upper limit capacity Q ₂ becomes smaller. According to the present embodiment, the control unit 134 uses the correction information database 168 and based on the measurement target identification information of the control measurement unit 150 and the measured voltage value of the control measurement unit 150. The voltage value by the calibration measuring unit 104 corresponding to the voltage measurement value by 150 is output.

Thereby, the control part 134 can measure a voltage accurately. As a result, as the lithium iron phosphate ion battery, a small difference battery with the lower limit value V ₁ and the upper limit value V ₂ of the battery voltage, even when used as a storage cell, the overcharge and overdischarge least One can be prevented.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  The order of execution of each process such as operations, procedures, steps, and stages in the apparatus, system, program, and method shown in the claims, the description, and the drawings is particularly “before” or “prior to”. It should be noted that the output can be realized in any order unless the output of the previous process is used in the subsequent process. Regarding the operation flow in the claims, the description, and the drawings, even if it is described using “first”, “next”, etc. for convenience, it means that it is essential to carry out in this order. It is not a thing.

  DESCRIPTION OF SYMBOLS 102 Charging apparatus 104 Measurement unit for calibration 105 terminal 107 terminal 110 power storage system 112 terminal 114 terminal 120 power storage module 122 power storage cell 124 power storage cell 126 power storage cell 128 power storage cell 130 balance correction unit 132, voltage equalization unit, 134 control unit, 142 switching element, 143 resistance, 144 switching element, 145 resistance, 146 switching element, 147 resistance, 148 switching element, 149 resistance, 150 control measurement unit, 162 storage unit, 164 Correction unit, 166 signal generation unit, 168 correction information database, 252 A / D converter, 254 voltage dividing circuit, 271 terminal, 273 terminal, 275 terminal, 277 terminal, 279 terminal, 283 resistance, 285 resistance, 287 resistance, 289 Resistance, 293 Resistance, 295 Resistance, 297 Resistance, 299 Resistance, 302 Name, 304 Measured Value, 306 Correction Value, 312 Voltage Range, 314 Voltage Range, 316 Voltage Range, 318 Voltage Range, 502 Charging Curve

Claims (10)

A voltage measuring device that measures the voltage of each of a plurality of storage cells connected in series,
A first voltage measuring unit for measuring a voltage of each of the plurality of power storage cells;
Identification information for identifying each of the plurality of power storage cells, a voltage value measured by the first voltage measurement unit, and a second voltage measurement unit different from the first voltage measurement unit are measured in advance. A storage unit for storing correspondence information indicating a correspondence relationship with the voltage value;
Using the correspondence information, based on the identification information of the measurement target of the first voltage measurement unit and the measured value of the voltage by the first voltage measurement unit, the voltage measurement by the first voltage measurement unit A correction unit that outputs a voltage value by the second voltage measurement unit corresponding to the value;
Comprising
Voltage measuring device. The measurement accuracy of the second voltage measurement unit is higher than the measurement accuracy of the first voltage measurement unit,
The voltage measuring device according to claim 1. The storage unit is preliminarily measured by the second voltage measurement unit, as the correspondence information, identification information for identifying each of the plurality of power storage cells, a voltage measurement value by the first voltage measurement unit, and the second voltage measurement unit Store the voltage value in association with each other.
The voltage measuring device according to claim 1 or 2. The storage unit stores statistical values of a plurality of measurement results by the first voltage measurement unit as voltage measurement values by the first voltage measurement unit.
The voltage measuring device according to claim 3. The number of correspondence information in a predetermined first voltage range is greater than the number of correspondence information in a second voltage range different from the first voltage range.
The voltage measuring device according to claim 3 or 4. The first voltage measurement unit includes:
A first input terminal to which a reference potential is input;
A second input terminal electrically connected to the positive electrode end of the measurement object;
A third input terminal electrically connected to the negative electrode end of the measurement object;
Have
The voltage to be measured is measured by subtracting the potential difference between the first input terminal and the third input terminal from the potential difference between the first input terminal and the second input terminal. ,
The second voltage measurement unit includes:
By electrically connecting the positive electrode end and the negative electrode end of each of the plurality of power storage cells, each voltage of the plurality of power storage cells is measured.
The voltage measuring device according to any one of claims 1 to 5. The voltage measuring device according to any one of claims 1 to 6, which measures each voltage of a plurality of power storage cells connected in series,
Based on the voltage measured by the voltage measuring device, a voltage equalizing unit that equalizes the voltages of the plurality of storage cells,
A balance correction device. A plurality of storage cells connected in series;
The voltage measuring device according to any one of claims 1 to 6, which measures each voltage of the plurality of power storage cells;
Comprising
Power storage system. Based on the voltage measured by the voltage measuring device, further comprising a voltage equalization unit for equalizing the voltage of the plurality of storage cells,
The power storage system according to claim 8. A measurement step of measuring each voltage of the plurality of power storage cells connected in series by the first voltage measurement unit;
Identification information for identifying each of the plurality of power storage cells, a voltage value measured by the first voltage measurement unit, and a second voltage measurement unit different from the first voltage measurement unit are measured in advance. Based on the identification information for identifying the measurement object of the first voltage measurement unit, and the measurement value of the voltage by the first voltage measurement unit, using the correspondence information indicating the correspondence relationship with the value of the measured voltage, A correction step of outputting a voltage value by the second voltage measurement unit corresponding to a voltage measurement value by the first voltage measurement unit;
Having
Voltage measurement method.

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