JP2020155274A - Predictor, secondary cell, prediction method and program - Google Patents

Abstract

To solve such a problem that when changing connection configuration between cell rows connected in parallel, an in-rush current flows between the cell rows for eliminating voltage difference between the cell rows, and an accumulator battery may be destroyed.SOLUTION: A predictor includes a first calculation part for acquiring information of total voltage value and total resistance value of multiple cell rows, assumed to be connected in parallel after replacement, and calculating finite difference of the total voltage value and finite difference of the total resistance value between the assumed multiple cell rows, respectively, and a prediction part for predicting the magnitude of an in-rush current expected to flow between the assumed multiple cell rows, by replacing at least any one of the multiple cells with a cell for replacement, on the basis of the finite difference of the total voltage value and the finite difference of the total resistance value.SELECTED DRAWING: Figure 2

Description

The present invention relates to predictors, secondary batteries, predictors and programs.

When the cell row in the storage battery contains deteriorated cells that need to be replaced, the connection configuration between the cell rows is changed so that the deteriorated cells are included in other parallel connected cell rows while the storage battery is running. By doing so, a storage battery system that enables an overall extension of life is known (see, for example, Patent Document 1).
[Prior art literature]
[Patent Document]
[Patent Document 1] Japanese Unexamined Patent Publication No. 2013-240155

In the above storage battery system, when the connection configuration is changed between the cell rows connected in parallel, an inrush current flows between the cell rows in order to eliminate the voltage difference between the cell rows. If the magnitude of the inrush current exceeds the permissible current value of each cell, the storage battery may be damaged.

In one aspect of the invention, a predictor is provided. Assuming that at least one of the plurality of serially connected cells contained in each of the plurality of cells connected in parallel in the secondary battery is replaced with a replacement cell, the predictor is in parallel after the replacement. Obtains information on the total voltage value and total resistance value of each of the plurality of cell rows that are assumed to be connected, and the difference in total voltage value and the difference in total resistance value between the assumed multiple cell rows. A first calculation unit for calculating each of the above may be provided. The predictor is expected to flow between the hypothesized cell rows by replacing at least one of the cells with a replacement cell based on the difference in total voltage and the difference in total resistance. A prediction unit for predicting the magnitude of the inrush current may be provided.

The predictor may further include a determination unit for determining whether or not the predicted inrush current magnitude is equal to or less than the permissible current values of the plurality of cells included in each of the plurality of cell rows after replacement. ..

When the predictor determines that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells, the predicted magnitude of the inrush current is equal to or less than the permissible current values of the plurality of cells. In addition, a first selection unit for selecting at least one of the voltage magnitude for the replacement cell and the cell having the voltage magnitude may be further provided.

When the predictor determines that the magnitude of the predicted inrush current is larger than the allowable current values of a plurality of cells, it is added to the replacement cell to increase the predicted magnitude of the inrush current. A second selection unit for selecting at least one of a resistance element having a resistance magnitude that is equal to or less than the allowable current value of the plurality of cells and a resistance element having the resistance magnitude may be further provided.

The prediction device may further include a display unit that displays the information selected by the selection unit to the user.

The prediction device may further include an acquisition unit that acquires information on the voltage value and resistance value of each of the plurality of cells that are assumed to be connected in series, which are included in each of the plurality of assumed cell rows. Good. The predictor may further include a second calculation unit that calculates the total voltage value and total resistance value of each of the hypothesized cell rows based on the voltage value and resistance value information.

In one aspect of the present invention, a secondary battery including the above prediction device is provided.

In one aspect of the invention, a prediction method is provided. The prediction method is based on the assumption that at least one of the plurality of cells connected in series contained in each of the plurality of cells connected in parallel in the secondary battery is replaced with a replacement cell, and the prediction method is parallel after the replacement. Obtains information on the total voltage value and total resistance value of each of the plurality of cell rows that are assumed to be connected, and the difference in total voltage value and the difference in total resistance value between the assumed multiple cell rows. May be provided with a calculation stage for calculating each of the above. The prediction method is expected to flow between a plurality of assumed cell rows by exchanging at least one of a plurality of cells with a replacement cell based on the difference in the total voltage value and the difference in the total resistance value. A prediction step for predicting the magnitude of the inrush current may be provided.

In one aspect of the invention, a program is provided for causing a computer to perform the above prediction method.

The outline of the above invention does not list all the necessary features of the present invention. Subcombinations of these feature groups can also be inventions.

To explain that the prediction device 100 according to the present embodiment predicts the inrush current flowing in the secondary battery 10 when it is assumed that the cell 13 included in the secondary battery 10 is replaced with the replacement cell 14. It is a figure of. It is a block diagram of the prediction device 100 which acquires various information from a secondary battery 10 and a replacement cell 14 according to this embodiment. It is a flow chart of the prediction method by this embodiment. It is a figure which shows the example of the computer 1200 which can embody a plurality of aspects of this invention in whole or part.

Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the inventions claimed in the claims. Also, not all combinations of features described in the embodiments are essential to the means of solving the invention. In the drawings, the same or similar parts may be given the same reference number to omit duplicate explanations.

FIG. 1 shows that the prediction device 100 according to the present embodiment predicts the inrush current flowing in the secondary battery 10 assuming that the cell 13 included in the secondary battery 10 is replaced with the replacement cell 14. It is a figure for demonstrating. The secondary battery 10 is, for example, an all-solid-state battery, a lithium-ion battery, or the like, and is a stationary storage battery for a power buffer used in a grid for power transmission or the like. The secondary battery 10 may be used at a grid operating voltage which is a high voltage of about 6600 V, or may be stored at a voltage equal to or lower than the grid operating voltage and boosted once when power is transmitted to the grid. The secondary battery 10 that can be used in such an application has a configuration in which a plurality of cell rows including a plurality of cells connected in series are connected in parallel in order to ensure high voltage use and required output.

The plurality of cells 13 included in the secondary battery 10 have different deterioration rates, and when one cell 13 reaches the deterioration life, it is necessary to replace the cell 13 with a new replacement cell 14. Further, when it becomes necessary to reuse any one or a plurality of cells 13 among the plurality of cells 13 connected in series for another purpose, the one or a plurality of cells 13 are used as new replacement cells 14. Need to be replaced with. When the secondary battery 10 is used as a stationary storage battery for a power buffer, it is required to continuously operate while the cell 13 in the secondary battery 10 is replaced with the replacement cell 14. ..

As an example, the secondary battery 10 according to the present embodiment has a cell row 11 and a cell row 12 including n cells (n is a natural number) connected in series, respectively. The cell row 11 and the cell row 12 are connected in parallel to each other. However, in the secondary battery 10 shown in FIG. 1, it becomes necessary to replace one cell 13 included in the cell row 12, and the cell 13 is extracted from the cell row 12 and at the extracted portion shown by the broken line. The replacement cell 14 is about to be inserted.

As shown in FIG. 1, each of the n cells 13 in the cell row 11, the n-1 cells 13 in the cell row 12, and one replacement cell 14 inserted in the cell row 12 , The measuring instrument 15 is attached. The measuring instrument 15 includes a voltmeter and a resistance meter that measure the voltage and resistance of each cell.

As shown in FIG. 1, the voltage and resistance of n cells 13 in the cell row 11 are represented by V _1n and r _1n , respectively. Similarly, the voltages and resistances of n-1 (n is a natural number) cell 13 and one replacement cell 14 of cell row 12 are represented by V _2n and r _2n , respectively. However, the voltage and resistance of the replacement cell 14 are V ₂₂ and r ₂₂ , respectively.

The prediction device 100 predicts the inrush current flowing in the secondary battery 10 assuming that at least one cell 13 out of the plurality of cells 13 included in the secondary battery 10 is replaced with a replacement cell 14. .. In order to acquire information on the voltage value of each cell and the resistance value of the internal resistance measured by each measuring instrument 15, the prediction device 100, as an example, has the secondary battery 10 and the measuring instrument 15 of the replacement cell 14. Wired connection with. The prediction device 100 may be wirelessly connected to the secondary battery 10 and the replacement cell 14 for the same purpose.

The above inrush current inserts a replacement cell 14 into at least one of a plurality of cell rows 11 and 12 connected in parallel in the secondary battery 10 while the secondary battery 10 is operating. In some cases, at the timing when the replacement cell 14 is inserted, and when the replacement cell 14 is inserted while the operation of the secondary battery 10 is stopped, at the timing when the replacement cell 14 is restarted, a plurality of cell rows This is the current flowing in the closed circuit between 11 and 12. The inrush current is caused by, for example, the voltage difference between a plurality of cell rows 11 and 12 connected in parallel, which is generated based on the voltage difference between the deteriorated cell 13 to be replaced and the replacement cell 14, as described above. Then, it flows from the cell row having a high voltage to the cell row having a low voltage. The inrush current ends when the voltage difference between the plurality of cell rows 11 and 12 connected in parallel disappears, for example, when the average voltage of each other is reached.

The prediction device 100 can predict the magnitude of the inrush current without stopping the operation of the secondary battery 10. Therefore, as described above, the secondary battery 10 is used as a stationary storage battery for the power buffer, and operates continuously while the cell 13 in the secondary battery 10 is replaced with the replacement cell 14. It is suitable when it is required to be present.

FIG. 2 is a block diagram of a prediction device 100 that acquires various information from the secondary battery 10 and the replacement cell 14 according to the present embodiment. The prediction device 100 includes a control unit 101, a storage unit 103, and a display unit 105. The control unit 101 includes an acquisition unit 110, a calculation unit 113, a prediction unit 116, a determination unit 119, and a selection unit 122.

Assuming that at least one of the plurality of cells 13 connected in series in the secondary battery 10 is replaced with the replacement cell 14, the acquisition unit 110 is assumed to replace each of the assumed plurality of cell rows 11 and 12, respectively. Information on the voltage value and the resistance value of the internal resistance of each of the plurality of cells 13 and 14 included in the cell 13 and 14 which are assumed to be connected in series is acquired. As an example, the acquisition unit 110 of the present embodiment may acquire the information from the secondary battery 10 and the measuring instrument 15 of the replacement cell 14 in response to the user input to the prediction device 100. The acquisition unit 110 outputs various acquired information to the calculation unit 113.

In the above assumption, the calculation unit 113 acquires information on the total voltage value and the total resistance value of each of the plurality of cell rows 11 and 12 that are assumed to be connected in parallel after the exchange, and the assumed plurality of cell rows 113. The difference in the total voltage value and the difference in the total resistance value between the cell rows 11 and 12, respectively, are calculated. As an example, the calculation unit 113 of the present embodiment is hypothesized by itself based on the information of the voltage values of the plurality of cells 13 and 14 and the resistance value of the internal resistance input from the acquisition unit 110. The total voltage value and the total resistance value of each of the plurality of cell rows 11 and 12 are calculated. Further, as an example, the calculation unit 113 of the present embodiment may perform an operation for calculating the total voltage value and the total resistance value in response to the above information being input from the acquisition unit 110. The calculation unit 113 outputs information indicating the difference in the total voltage value and the difference in the total resistance value between the calculated plurality of cell rows 11 and 12 to the prediction unit 116.

The calculation unit 113 may acquire information on the total voltage value and the total resistance value of each of the plurality of assumed cell rows 11 and 12 from the outside of the prediction device 100. In this case, the calculation unit 113 may acquire the information, for example, via the acquisition unit 110, in response to the user input to the prediction device 100. Further, in this case, the acquisition unit 110 does not have to acquire information on the voltage values and the resistance values of the internal resistances of the plurality of cells 13 and 14 in the above assumption. The calculation unit 113 is an example of the first calculation unit and the second calculation unit.

The prediction unit 116 of the plurality of cells 13 is based on the difference in the total voltage value and the difference in the total resistance value between the plurality of cell rows 11 and 12 in the above assumption shown in the information input from the calculation unit 113. By replacing at least one with the replacement cell 14, the magnitude of the inrush current expected to flow between the assumed plurality of cell rows 11 and 12 is predicted. The prediction unit 116 outputs information indicating the magnitude of the predicted inrush current to the determination unit 119.

The determination unit 119 has a plurality of cells 13 in which the magnitude of the predicted inrush current indicated in the information input from the prediction unit 116 is included in each of the plurality of cell rows 11 and 12 after the exchange in the above assumption. It is judged whether or not it is equal to or less than the allowable current value of. As an example, the information indicating the allowable current values of the plurality of cells 13 may be stored in the storage unit 103 together with the identification information of the secondary battery 10 and the plurality of cells 13. As an example, the determination unit 119 outputs information indicating a determination result to the selection unit 122.

When the determination unit 119 determines that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells 13, the selection unit 122 has the predicted magnitude of the inrush current of the plurality of cells 13. Select at least one of the voltage magnitudes for the replacement cell 14 and the cells having the voltage magnitudes such that the current value is equal to or less than the allowable current value of. When it is determined that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells 13, the selection unit 122 outputs the selected information to the display unit 105. The selection unit 122 of the present embodiment is further input from the determination unit 119 when the determination unit 119 determines that the magnitude of the predicted inrush current is equal to or less than the allowable current values of the plurality of cells 13. , Information indicating that the replacement cell 14 may be inserted may be output to the display unit 105. The voltage of the replacement cell 14 can be adjusted. The selection unit 122 is an example of the first selection unit.

The storage unit 103 stores a sequence, a program, or the like for controlling each configuration of the prediction device 100. The storage unit 103 is referred to by the control unit 101.

The display unit 105 displays to the user the information input by the selection unit 122 and selected by the selection unit 122. The display unit 105 may also display to the user information input by the selection unit 122 indicating that the replacement cell 14 may be inserted. As an example, the display unit 105 of the present embodiment may be a combination of a touch panel display or a push button and a monitor. In this case, the display unit 105 not only displays the above-mentioned various information but also the above-mentioned prediction device 100. User input may be accepted.

FIG. 3 is a flow chart of the prediction method according to the present embodiment. As an example, the flow is started by a user input to the prediction device 100.

Assuming that at least one of the plurality of cells 13 connected in series in the secondary battery 10 is replaced with the replacement cell 14, the predictor 100 has the assumed plurality of cell rows 11 and 12, respectively. Information on the voltage values and the resistance values of the internal resistances of the plurality of cells 13 and 14 included in the above, which are assumed to be connected in series, is acquired (step S101).

As a specific example, it is assumed that the acquisition unit 110 of the present embodiment has replaced one of the plurality of cells 13 connected in series in the secondary battery 10 with the replacement cell 14, and the secondary battery 10 and From the replacement cell 14, the voltage values of the 2n cells 13 and 14 contained in the assumed cell row 11 and the cell row 12 and the resistance values of the internal resistances of V _1n , r _1n , V _2n and r _2n Receive information.

The prediction device 100 calculates the total voltage value and the total resistance value of each of the assumed plurality of cell rows based on the information of the respective voltage values and the resistance values of the internal resistances of the plurality of cells 13 and 14 described above. , The difference in the total voltage value and the difference in the total resistance value between the assumed plurality of cell rows 11 and 12, respectively, are calculated (step S103).

As a specific example, the calculation unit 113 of the present embodiment acquires the information of the above V _1n , r _1n , V _2n and r _2n from the acquisition unit 110, and the total voltage of the above assumed cell row 11 The value and the total resistance value may be calculated by the following equations 1 and 2, respectively, and the total voltage value and the total resistance value of the assumed cell row 12 may be calculated by the following equations 3 and 4, respectively.

As a specific example, the calculation unit 113 of the present embodiment further calculates the difference ΔV between the total voltage value of the assumed cell row 11 and the total voltage value of the cell row 12 by the following equation 5. The difference Δr between the assumed total resistance value of the cell row 11 and the total resistance value of the cell row 12 may be calculated by the following equation 6.

The prediction device 100 replaces at least one of the plurality of cells 13 with the replacement cell 14 based on the difference in the total voltage value and the difference in the total resistance value between the plurality of cell rows 11 and 12 in the above assumption. This predicts the magnitude of the inrush current that is expected to flow between the assumed plurality of cell rows 11 and 12 (step S105).

As a specific example, as described above, the inrush current ends when the voltage difference between the plurality of cell rows 11 and 12 connected in parallel disappears, for example, when the average voltage _{Vave of} each other is reached. The average voltage _Vave is calculated by the following equation 7 when the total voltage value and the total resistance value of the assumed cell row 11 represented by the above equations 1 and 2 are used, where the magnitude of the inrush current is i. It is calculated. The average voltage _Vave also uses the total voltage value and total resistance value of the above-mentioned assumed cell row 12 represented by the above-mentioned equations 3 and 4 with the magnitude of the inrush current as i, and the following equation 8 It is calculated by. Since the plurality of cell rows 11 and 12 connected in parallel are connected by one path, the same inrush current i itself flows in each of the plurality of cell rows 11 and 12.

By combining the above equations 7 and 8, the following equation 9 for calculating the magnitude i of the inrush current is derived.

As an example, the prediction unit 116 of the present embodiment uses the equation 9 based on the ΔV and Δr represented by the equations 5 and 6, and flows between the plurality of assumed cell rows 11 and 12. You may predict the magnitude i of the inrush current that is expected to be. Even when the number of cell rows connected in parallel in the secondary battery 10 is three or more, the prediction unit 116 can predict the magnitude i of the inrush current in the same manner as described above.

The prediction device 100 determines whether or not the magnitude of the predicted inrush current is equal to or less than the permissible current value of the plurality of cells 13 included in each of the plurality of cell rows 11 and 12 after replacement in the above assumption. (Step S107).

As a specific example, the determination unit 119 of the present embodiment selects the lowest permissible current value among the permissible current values of the plurality of cells 13 included in the secondary battery 10, and predicts the inrush current. It may be determined whether or not the magnitude of i is equal to or less than the lowest allowable current value. In this case, the information referred to by the determination unit 119 may be only the identification information of the secondary battery 10 and the information indicating the lowest allowable current value, and even if these information are stored in the storage unit 103, for example. Good.

When the prediction device 100 determines that the magnitude of the predicted inrush current is equal to or less than the allowable current values of the plurality of cells 13 (step S107: YES), the prediction device 100 indicates that the replacement cell 14 may be inserted. The information is displayed to the user (step S109), and the flow ends.

When the prediction device 100 determines that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells 13 (step S107: NO), the predicted magnitude of the inrush current of the plurality of cells 13 The magnitude of the voltage for the replacement cell 14 is selected so that it is equal to or less than the allowable current value (step S111).

As a specific example, the magnitude of the voltage for the replacement cell 14 selected by the selection unit 122 of the present embodiment is, as an example, the magnitude of the inrush current that is equal to or less than the allowable current value of the plurality of cells 13. It may be the upper limit of the magnitude of the voltage for the replacement cell 14 corresponding to the upper limit of.

The selection unit 122 itself calculates an upper limit value of the magnitude of the inrush current that is equal to or less than the allowable current value of the plurality of cells 13, and the upper limit value of the magnitude of the voltage for the replacement cell 14 corresponding to the upper limit value. May be calculated. Instead of this, for example, the storage unit 103 corresponds to information on a plurality of allowable current values, an upper limit value of the magnitude of the inrush current corresponding to each allowable current value, which is equal to or less than the allowable current value, and the upper limit value. A table containing information on the upper limit of the voltage magnitude for the replacement cell 14 to be used is stored, and the selection unit 122 can set the allowable current value of the plurality of cells 13 by referring to the table. Information on the upper limit of the magnitude of the voltage for the corresponding replacement cell 14 may be obtained.

In step S111, when the selection unit 122 selects a cell having the voltage magnitude instead of or in addition to selecting the voltage magnitude for the replacement cell 14 described above. For example, the storage unit 103 stores a table containing the voltages and identification information of the plurality of candidate cells that are candidates for the replacement cell 14, and the selection unit 122 refers to the table to display the plurality of cells. A candidate cell having a voltage equal to or less than the upper limit of the voltage magnitude for the replacement cell 14 corresponding to the permissible current value of 13 may be selected, and the identification information of the candidate cell may be acquired.

Further, the magnitude of the voltage for the replacement cell 14 selected by the selection unit 122 does not generate an inrush current, that is, the total voltage difference between the above assumed cell row 11 and cell row 12 as an example. May be the magnitude of the voltage for the replacement cell 14 such that The selection unit 122 may calculate by itself the magnitude of the voltage for the replacement cell 14 such that the total voltage difference between the assumed cell row 11 and the cell row 12 is 0.

The prediction device 100 displays the selected information to the user (step S113), and the flow ends.

As described above, the prediction device 100 of the present embodiment replaces at least one of the plurality of cells 13 connected in series included in each of the plurality of cell rows 11 and 12 connected in parallel in the secondary battery 10. In the case of assuming that the cell 14 was replaced with the cell 14, information on the total voltage value and the total resistance value of each of the plurality of cell rows 11 and 12 that were assumed to be connected in parallel after the replacement was acquired and assumed. The difference in the total voltage value and the difference in the total resistance value between the plurality of cell rows 11 and 12, respectively, are calculated. Further, the prediction device 100 of the present embodiment replaces at least one of the plurality of cells 13 with the replacement cell 14 based on the difference in the total voltage value and the difference in the total resistance value, so that the plurality of assumed cells Predict the magnitude of the inrush current that is expected to flow between rows 11 and 12.

According to such a prediction device 100, the user replaces at least one of the plurality of series-connected cells 13 included in each of the plurality of cell rows 11 and 12 connected in parallel in the secondary battery 10. The prediction result of the prediction device 100 can be obtained before actually exchanging with the cell 14 of the cell 14, whereby the magnitude of the inrush current expected to flow between the plurality of cell rows 11 and 12 can be grasped. Can be done.

Further, in the prediction device 100 of the present embodiment, the magnitude of the predicted inrush current is equal to or less than the permissible current value of the plurality of cells 13 included in each of the plurality of cell rows 11 and 12 after replacement in the above assumption. Judge whether or not. The predictor 100 also displays to the user information indicating that the replacement cell 14 may be inserted if the predicted inrush current magnitude is less than or equal to the permissible current values of the plurality of cells 13. To do. According to such a prediction device 100, the user can further acquire the determination result and the information of the prediction device 100 before the actual replacement described above, and the inside of the secondary battery 10 does not take any measures. It is possible to grasp whether or not the deteriorated cell 13 may be replaced with the replacement cell 14, and the replacement work can be performed with peace of mind. Further, according to the prediction device 100, the user can further reduce the labor and cost as compared with the case where the resistance element is always added to and replaced with the replacement cell 14, for example. This is because it is difficult to add a resistance element in the secondary battery 10 due to space restrictions of the equipment, and it is costly to add a resistance every time the cell 13 in the secondary battery 10 is replaced. is there.

Further, when the prediction device 100 of the present embodiment determines that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells 13, the predicted magnitude of the inrush current is permissible for the plurality of cells 13. At least one of the voltage magnitude for the replacement cell 14 and the cell having the voltage magnitude such that the current value is equal to or less than the current value is selected, and the selected information is displayed to the user. According to such a prediction device 100, the user can further acquire information on either one of the above from the prediction device 100 before the actual exchange described above, and the magnitude of the predicted inrush current is the above. If it is larger than the permissible current value of, the voltage of the replacement cell 14 is adjusted so as to have the voltage magnitude selected by the predictor 100, or the cell having the selected voltage magnitude is replaced. It can be selected as the cell 14, and it is possible to prevent the secondary battery 10 from being damaged due to an inrush current exceeding the allowable current value flowing between the plurality of cell rows 11 and 12 in the secondary battery 10.

In the above embodiment, when the selection unit 122 of the prediction device 100 additionally or alternatively determines that the magnitude of the predicted inrush current is larger than the permissible current values of the plurality of cells 13. A resistance element having a resistance magnitude that makes the predicted inrush current magnitude equal to or less than the permissible current values of the plurality of cells 13 by being added to the replacement cell 14, and a resistance magnitude of the resistance. At least one of the above may be selected. The selection unit 122 in this case is an example of the second selection unit.

As a specific example, the magnitude of the resistance to be added to the replacement cell 14 selected by the selection unit 122 in this case is, as an example, the magnitude of the inrush current that is equal to or less than the allowable current value of the plurality of cells 13. It may be the lower limit of the magnitude of the resistance to be added to the replacement cell 14 corresponding to the upper limit of the current.

The selection unit 122 itself calculates an upper limit value of the magnitude of the inrush current that is equal to or less than the allowable current value of the plurality of cells 13, and corresponds to the upper limit of the magnitude of the resistance to be added to the replacement cell 14. The lower limit may be calculated. Instead of this, for example, the storage unit 103 corresponds to information on a plurality of allowable current values, an upper limit value of the magnitude of the inrush current corresponding to each allowable current value, which is equal to or less than the allowable current value, and the upper limit value. A table containing information on the lower limit of the magnitude of the resistor to be added to the replacement cell 14 is stored, and the selection unit 122 refers to the table and allows the allowable currents of the plurality of cells 13 to be stored. Information on the lower limit of the magnitude of the resistor to be added to the replacement cell 14 corresponding to the value may be acquired.

When the selection unit 122 selects, for example, a resistance element having the magnitude of the resistance instead of or in addition to selecting the magnitude of the resistance to be added to the replacement cell 14. The storage unit 103 stores a table including the resistance magnitudes and identification information of the plurality of candidate resistance elements that are candidates for the resistance element, and the selection unit 122 refers to the table to display the plurality of cells 13. Select a candidate resistance element having a resistance magnitude equal to or greater than the lower limit of the resistance magnitude to be added to the replacement cell 14 corresponding to the permissible current value of, and acquire the identification information of the candidate resistance element. May be good.

Further, the magnitude of the resistance to be added to the replacement cell 14 selected by the selection unit 122 does not generate an inrush current, that is, the total of the assumed cell rows 11 and 12 described above. The magnitude of the resistor to be added to the replacement cell 14 may be such that the voltage difference becomes zero. The selection unit 122 may calculate by itself the magnitude of the resistance to be added to the replacement cell 14 so that the total voltage difference between the assumed cell row 11 and the cell row 12 becomes 0.

According to such a predictor 100, if the magnitude of the predicted inrush current is greater than the permissible current value described above, the user has been selected by the predictor 100 prior to the actual replacement described above. As a resistance element that adjusts the resistance magnitude of the resistance element added to the replacement cell 14 so as to have the resistance magnitude, or adds a resistance element having the selected resistance magnitude to the replacement cell 14. It can be selected, and it is possible to prevent the secondary battery 10 from being damaged due to an inrush current exceeding the allowable current value flowing between the plurality of cell rows 11 and 12 in the secondary battery 10.

In the above embodiment, the user obtains the information of any one of the above from the prediction device 100 before the actual replacement, and then the plurality of cell rows 11 and 12 connected in parallel in the secondary battery 10. Therefore, at least one deteriorated cell 13 to be replaced may be extracted and an appropriate replacement cell 14 may be inserted. When the replacement cell 14 is inserted with the resistance element added, the resistance element is left attached until the voltage difference between the plurality of cell rows 11 and 12 disappears after the insertion, and the voltage difference disappears. Depending on the situation, only the resistance element may be taken out.

By removing at least one deteriorated cell 13 from the secondary battery 10, the cell row to which the cell 13 is connected in series is opened, and the current flowing in the cell row is parallel to the cell row. It wraps around to other connected cell rows, but the wraparound current is equal to or less than the allowable current value of the plurality of cells 13. Further, at the same time as removing the at least one deteriorated cell 13 from the secondary battery 10, the electric wire at the position where the cell 13 is located is connected, so that the cell row in which the cell 13 is connected in series is connected. May remain closed.

In the above embodiment, the display unit 105 of the prediction device 100 additionally or alternatively informs the user that the magnitude of the predicted inrush current is larger than the allowable current value of the plurality of cells 13. It may include a lamp that can be lit or blinking.

The secondary battery according to another embodiment includes the prediction device 100 described in the above embodiment. The secondary battery prediction device according to the embodiment has at least the same configuration as the calculation unit 113 and the prediction unit 116 included in the prediction device 100 according to the above embodiment. The secondary battery prediction device according to the embodiment may have the same configuration as the other configurations included in the prediction device 100 according to the above embodiment.

Various embodiments of the present invention may be described with reference to flowcharts and block diagrams, wherein the block is (1) a stage of the process in which the operation is performed or (2) a device responsible for performing the operation. May represent a section of. Specific stages and sections are implemented by dedicated circuits, programmable circuits supplied with computer-readable instructions stored on a computer-readable medium, and / or processors supplied with computer-readable instructions stored on a computer-readable medium. You can. Dedicated circuits may include digital and / or analog hardware circuits, and may include integrated circuits (ICs) and / or discrete circuits. Programmable circuits are memory elements such as logical AND, logical OR, logical XOR, logical NAND, logical NOR, and other logical operations, flip-flops, registers, field programmable gate arrays (FPGA), programmable logic arrays (PLA), etc. May include reconfigurable hardware circuits, including.

The computer-readable medium may include any tangible device capable of storing instructions executed by the appropriate device, so that the computer-readable medium having the instructions stored therein is specified in a flowchart or block diagram. It will be equipped with a product that contains instructions that can be executed to create means for performing the operation. Examples of computer-readable media may include electronic storage media, magnetic storage media, optical storage media, electromagnetic storage media, semiconductor storage media, and the like. More specific examples of computer-readable media include floppy (registered trademark) disks, diskettes, hard disks, random access memory (RAM), read-only memory (ROM), erasable programmable read-only memory (EPROM or flash memory), Electrically erasable programmable read-only memory (EEPROM), static random access memory (SRAM), compact disk read-only memory (CD-ROM), digital versatile disc (DVD), Blu-ray (RTM) disc, memory stick, integrated A circuit card or the like may be included.

Computer-readable instructions are assembler instructions, instruction set architecture (ISA) instructions, machine instructions, machine-dependent instructions, microcode, firmware instructions, state-setting data, or object-oriented programming such as Smalltalk, JAVA®, C ++, etc. Contains either source code or object code written in any combination of one or more programming languages, including languages and traditional procedural programming languages such as the "C" programming language or similar programming languages. Good.

Computer-readable instructions are applied locally or to a processor or programmable circuit of a general purpose computer, special purpose computer, or other programmable data processing device, or to a wide area network (WAN) such as the local area network (LAN), the Internet, etc. ) May be executed to create a means for performing the operation specified in the flowchart or block diagram. Examples of processors include computer processors, processing units, microprocessors, digital signal processors, controllers, microcontrollers and the like.

FIG. 4 shows an example of a computer 1200 in which a plurality of aspects of the present invention can be embodied in whole or in part. The program installed on the computer 1200 causes the computer 1200 to function as an operation associated with the device according to an embodiment of the present invention or as one or more "parts" of the device, or the operation or the one or more "parts". A unit can be run and / or a computer 1200 can be run a process according to an embodiment of the invention or a stage of the process. Such a program may be executed by the CPU 1212 to cause the computer 1200 to perform a specific operation associated with some or all of the blocks of the flowcharts and block diagrams described herein.

The computer 1200 according to this embodiment includes a CPU 1212, a RAM 1214, a graphic controller 1216, and a display device 1218, which are interconnected by a host controller 1210. The computer 1200 also includes input / output units such as a communication interface 1222, a hard disk drive 1224, a DVD-ROM drive 1226, and an IC card drive, which are connected to the host controller 1210 via the input / output controller 1220. The computer also includes legacy I / O units such as the ROM 1230 and keyboard 1242, which are connected to the I / O controller 1220 via the I / O chip 1240.

The CPU 1212 operates according to the programs stored in the ROM 1230 and the RAM 1214, thereby controlling each unit. The graphic controller 1216 acquires image data generated by the CPU 1212 in a frame buffer or the like provided in the RAM 1214 or in the graphic controller 1216 itself, and displays the image data on the display device 1218.

The communication interface 1222 communicates with other electronic devices via a network. The hard disk drive 1224 stores programs and data used by the CPU 1212 in the computer 1200. The DVD-ROM drive 1226 reads the program or data from the DVD-ROM 1201 and provides the program or data to the hard disk drive 1224 via the RAM 1214. The IC card drive reads the program and data from the IC card and / or writes the program and data to the IC card.

The ROM 1230 internally stores a boot program or the like executed by the computer 1200 at the time of activation, and / or a program depending on the hardware of the computer 1200. The input / output chip 1240 may also connect various input / output units to the input / output controller 1220 via a parallel port, a serial port, a keyboard port, a mouse port, and the like.

The program is provided by a computer-readable storage medium such as a DVD-ROM 1201 or an IC card. The program is read from a computer-readable storage medium, installed on a hard disk drive 1224, RAM 1214, or ROM 1230, which is also an example of a computer-readable storage medium, and executed by the CPU 1212. The information processing described in these programs is read by the computer 1200 and provides a link between the program and the various types of hardware resources described above. The device or method may be configured to implement the operation or processing of information in accordance with the use of computer 1200.

For example, when communication is executed between the computer 1200 and an external device, the CPU 1212 executes a communication program loaded in the RAM 1214, and performs communication processing on the communication interface 1222 based on the processing described in the communication program. You may order. Under the control of the CPU 1212, the communication interface 1222 reads and reads the transmission data stored in the transmission buffer area provided in the recording medium such as the RAM 1214, the hard disk drive 1224, the DVD-ROM 1201, or the IC card. The data is transmitted to the network, or the received data received from the network is written to the reception buffer area or the like provided on the recording medium.

Further, the CPU 1212 allows the RAM 1214 to read all or necessary parts of a file or database stored in an external recording medium such as a hard disk drive 1224, a DVD-ROM drive 1226 (DVD-ROM1201), or an IC card. Various types of processing may be performed on the data on the RAM 1214. The CPU 1212 may then write back the processed data to an external recording medium.

Various types of information, such as various types of programs, data, tables, and databases, may be stored on recording media for information processing. The CPU 1212 describes various types of operations, information processing, conditional judgment, conditional branching, unconditional branching, and information retrieval described in various parts of the present disclosure with respect to the data read from the RAM 1214, and is specified by the instruction sequence of the program. Various types of processing may be performed, including / replacement, etc., and the results are written back to the RAM 1214. Further, the CPU 1212 may search for information in a file, a database, or the like in the recording medium. For example, when a plurality of entries each having an attribute value of the first attribute associated with the attribute value of the second attribute are stored in the recording medium, the CPU 1212 is the first of the plurality of entries. The attribute value of the attribute of is searched for the entry that matches the specified condition, the attribute value of the second attribute stored in the entry is read, and the first attribute satisfying the predetermined condition is selected. You may get the attribute value of the associated second attribute.

The program or software module according to the above description may be stored on the computer 1200 or in a computer-readable storage medium near the computer 1200. In addition, a recording medium such as a hard disk or RAM provided in a dedicated communication network or a server system connected to the Internet can be used as a computer-readable storage medium, whereby the program can be sent to the computer 1200 via the network. provide.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. It will be apparent to those skilled in the art that various changes or improvements can be made to the above embodiments. Further, to the extent that there is no technical contradiction, the matters described for the specific embodiment can be applied to other embodiments. Further, each component may have the same characteristics as other components having the same name but different reference numerals. It is clear from the description of the claims that such modified or improved forms may also be included in the technical scope of the present invention.

The order of execution of each process such as operation, procedure, step, and step in the device, system, program, and method shown in the claims, specification, and drawings is particularly "before" and "prior to". It should be noted that it can be realized in any order unless the output of the previous process is used in the subsequent process. Even if the scope of claims, the specification, and the operation flow in the drawings are explained using "first," "next," etc. for convenience, it means that it is essential to carry out in this order. It's not a thing.

10 Secondary battery, 11, 12 cell row, 13, 14 cell, 15 Measuring instrument, 100 Predictor, 101 Control unit, 103 Storage unit, 105 Display unit, 110 Acquisition unit, 113 Calculation unit, 116 Prediction unit, 119 Judgment Unit, 122 Selection, 1200 Computer, 1201 DVD-ROM, 1210 Host Controller, 1212 CPU, 1214 RAM, 1216 Graphic Controller, 1218 Display Device, 1220 I / O Controller, 1222 Communication Interface, 1224 Hard Disk Drive, 1226 DVD-ROM Drive 1230 ROM, 1240 I / O chip, 1242 keyboard

Claims (9)

Assuming that at least one of the plurality of cells connected in series contained in each of the plurality of cells connected in parallel in the secondary battery is replaced with a replacement cell, the cells are connected in parallel after the replacement. Obtain the information of the total voltage value and the total resistance value of each of the plurality of cell rows that are assumed to be, and obtain the difference of the total voltage value and the difference of the total resistance value between the plurality of assumed cell rows. The first calculation unit to calculate each and
By exchanging at least one of the plurality of cells with the replacement cell based on the difference in the total voltage value and the difference in the total resistance value, the current can flow between the assumed plurality of cell rows. A prediction device including a prediction unit that predicts the magnitude of the expected inrush current. Claim 1 further includes a determination unit for determining whether or not the predicted magnitude of the inrush current is equal to or less than the permissible current values of the plurality of cells included in each of the plurality of cell rows after the replacement. The predictor described in. When it is determined that the predicted magnitude of the inrush current is larger than the permissible current values of the plurality of cells, the predicted magnitude of the inrush current is equal to or less than the permissible current values of the plurality of cells. The prediction device according to claim 2, further comprising a first selection unit for selecting at least one of a voltage magnitude for the replacement cell and a cell having the voltage magnitude. When it is determined that the predicted magnitude of the inrush current is larger than the allowable current values of the plurality of cells, it is added to the replacement cell to increase the predicted magnitude of the inrush current. The second aspect of claim 2, further comprising a second selection unit for selecting at least one of a resistance element having a resistance magnitude equal to or less than the allowable current value of the plurality of cells and a resistance element having the resistance magnitude. Predictor. The prediction device according to claim 3 or 4, further comprising a display unit that displays information selected by the selection unit to the user. An acquisition unit that acquires information on the voltage value and resistance value of each of the plurality of cells that are assumed to be connected in series, which are included in each of the plurality of assumed cell rows.
From claim 1, further comprising a second calculation unit for calculating the total voltage value and the total resistance value of each of the assumed plurality of cell rows based on the information of the voltage value and the resistance value. 5. The predictive device according to any one of 5. A secondary battery comprising the prediction device according to any one of claims 1 to 6. Assuming that at least one of the plurality of cells connected in series contained in each of the plurality of cells connected in parallel in the secondary battery is replaced with a replacement cell, the cells are connected in parallel after the replacement. Obtain the information of the total voltage value and the total resistance value of each of the plurality of cell rows that are assumed to be, and obtain the difference of the total voltage value and the difference of the total resistance value between the plurality of assumed cell rows. The calculation stage to calculate each and
By exchanging at least one of the plurality of cells with the replacement cell based on the difference in the total voltage value and the difference in the total resistance value, the current can flow between the assumed plurality of cell rows. A prediction method including a prediction stage for predicting the magnitude of the expected inrush current. A program for causing a computer to execute the prediction method according to claim 8.