KR20210023543A - Apparatus and method for determining pass of battery cell - Google Patents

Abstract

According to an embodiment of the present invention, provided is a battery cell path determination method, which comprises: a battery cell connection step of connecting a battery cell for determining a battery cell path to a battery cell path determining device; a full charge-complete discharge cycle performance step of repeatedly performing a full charge-complete discharge cycle for the battery cell; a cycle-by-cycle capacity value deriving step of deriving a capacity (t) value of a battery cell for each cycle, while performing the full charge-complete discharge cycle; a slope calculation step of calculating a slope between the derived capacity value for each cycle and the initial capacity value; and a determining step of determining whether to pass the battery cell based on the calculated slope.

Description

Apparatus and method for determining pass of battery cell

The present invention relates to an apparatus and method for predicting the capacity of a battery cell and determining whether a battery cell passes.

Batteries are widely used in mobile terminals represented by mobile phones as a power source. In recent years, with the rise of environmental protection, renewable energy such as solar power generation or wind power generation has been attracting attention, and batteries are being popularized as a use for storing the energy. As for automobiles, hybrid vehicles and electric vehicles equipped with batteries are being popularized.

On the other hand, after the manufacture of such a battery is completed, a capacity verification process is performed to confirm whether the battery cell is manufactured to satisfy a predetermined reference capacity.

In the conventional method of verifying the capacity of the battery cell, it was confirmed whether the battery cell was manufactured to satisfy the reference capacity through a high-temperature high-rate experiment (full charge-complete discharge cycle) of 300 cycles or more.

Such a conventional technique has a problem in that it takes about 750 hours or more because the battery cell needs to be fully charged-completely discharged 300 times.

Accordingly, the present invention proposes an apparatus and method capable of performing a conventional method of verifying the capacity of a battery cell faster.

Korean Patent Application Publication KR 1440719 B1

The present invention provides an apparatus and method capable of performing capacity verification of a battery cell faster.

In addition, the present invention provides an apparatus and method capable of quickly performing battery cell capacity verification according to a desired reliability.

A battery cell path determination apparatus according to an embodiment of the present invention includes a battery cell mounting unit in which a battery cell for determining a battery cell path is mounted, a charging/discharging module for charging and discharging the battery cell, and determining whether or not the battery cell is passed. It may be configured to include a battery cell path determination unit.

The battery cell path determination unit includes a capacity derivation unit for deriving a capacity value (capacity(t)) of a battery cell for each cycle while performing a full charge-complete discharge cycle of the battery cell, and the derived capacity value for each cycle and the initial A slope calculation unit that calculates a slope with an initial capacity value of the battery cell derived after performing a full charge-complete discharge cycle of, and a determination unit that determines whether to pass the battery cell based on the calculated slope. have.

When the reliability value is set to the first reliability value, the determination unit calculates a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a first number of times, and a first reference slope. When the reliability value is set as the second reliability value, the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times and a second reference slope are compared. I can.

The determination unit determines a full charge-complete discharge cycle as a result of comparing a slope between a capacity value of a battery cell and an initial capacity value derived after performing the full charge-complete discharge cycle a first number of times and a first reference slope. When the slope between the capacity value of the battery cell derived after performing one number of times and the initial capacity value is less than the first reference slope, or the capacity of the battery cell derived after performing the full charge-complete discharge cycle a second number of times As a result of comparing the slope between the value and the initial capacity value and the second reference slope, the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times is the second criterion. If it is less than the slope, it can be determined as a battery cell path.

Meanwhile, the determination unit is a result of comparing a slope between a capacity value of a battery cell and an initial capacity value derived after performing the full charge-complete discharge cycle a first number of times and a first reference slope, and a full charge-complete discharge cycle When the slope between the capacity value of the battery cell derived after performing the first number of times and the initial capacity value is equal to or greater than the first reference slope, or the battery derived after performing the full charge-complete discharge cycle a second number of times As a result of comparing the slope between the cell capacity value and the initial capacity value and the second reference slope, the slope between the capacity value of the battery cell and the initial capacity value derived after proceeding the full charge-complete discharge cycle a second number of times is the above. If the slope is greater than or equal to the second reference slope, it may be determined that the battery cell is defective.

The first reference slope and the second reference slope may be values preset according to the reliability value.

A battery cell path determination method according to an exemplary embodiment of the present invention includes a battery cell connection step of connecting a battery cell for determining a battery cell path to a battery cell path determination apparatus, and repeating a full charge-complete discharge cycle for the battery cell. Performing a full charge-complete discharge cycle, a cycle-by-cycle capacity value derivation step of deriving a capacity value (capacity(t)) of a battery cell for each cycle while performing the full charge-complete discharge cycle, the derived cycle A slope calculation step of calculating a slope between a respective capacity value and an initial capacity value, and a determination step of determining whether to pass a battery cell based on the calculated slope.

On the other hand, the battery cell path detection method according to an embodiment of the present invention is configured to further include a reliability value setting step of setting a reliability value, and the determining step includes a comparison step of comparing the calculated slope with a reference slope. And a reference slope may be set according to the set reliability value.

In the comparing step, when the reliability value setting step is set to the first reliability value, the slope and the difference between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a first number of times 1 When the first comparison step of comparing the reference slope and the second reliability value setting step are set as the second reliability value, the capacity value and the initial capacity of the battery cell derived after proceeding a second number of full charge-complete discharge cycles It may be configured to include a second comparison step of comparing the slope with the value and the second reference slope.

The determining step may be a case where, as a result of the comparison in the first comparison step, a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a first number of times is less than the first reference slope, or As a result of the comparison of the first comparison step, when the slope between the capacity value of the battery cell derived after performing the full charge-complete discharge cycle a second number of times and the initial capacity value is less than the second reference slope, a battery cell path is performed. I can judge.

Meanwhile, in the determining step, as a result of the comparison of the first comparison step, the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a first number of times is equal to or greater than the first reference slope. When the slope between the capacity value and the initial capacity value of the battery cell derived after performing a full charge-complete discharge cycle a second number of times or greater than the second reference slope as a result of the comparison of the first comparison step, the battery cell It can be judged as bad.

According to the present invention, it is possible to quickly determine whether a battery cell is passed or not.

In addition, according to the present invention, it is possible to quickly determine whether a battery cell is passed according to a desired reliability.

1 is a block diagram showing a battery cell pass device according to an embodiment of the present invention.
2 is a graph showing a correlation between a slope between a capacity value for each full charge-complete discharge cycle and an initial capacity value of a normal battery cell and a capacity value of a normal battery cell actually performed 300 times according to an embodiment of the present invention. to be.
3 is a flowchart illustrating a method of determining a battery cell path according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are assigned to similar parts throughout the specification.

Terms including ordinal numbers such as first and second may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only the case that it is “directly connected”, but also the case that it is “electrically connected” with another element in between. . In addition, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary. As used throughout the specification of the present application, the term "step (to)" or "step of" does not mean "step for".

Terms used in the present invention have selected general terms that are currently widely used as possible while taking functions of the present invention into consideration, but this may vary according to the intention or precedent of a technician working in the field, the emergence of new technologies, and the like. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning of the terms will be described in detail in the description of the corresponding invention. Therefore, the terms used in the present invention should be defined based on the meaning of the term and the overall contents of the present invention, not a simple name of the term.

1. Battery cell pass judgment device.

The battery cell path determination apparatus 100 according to an embodiment of the present invention verifies whether the capacity of the battery cell after the battery cell is manufactured and repeatedly charged and discharged a predetermined number of times satisfies a predetermined reference capacity. It is a device to do.

1 is a diagram showing the configuration of a cell path determination apparatus 100 according to an embodiment of the present invention.

Hereinafter, an apparatus 100 for determining a cell path according to an embodiment of the present invention will be described with reference to FIG. 1.

The cell path determination apparatus 100 according to an exemplary embodiment of the present invention includes a battery cell mounting unit 110 in which the battery cell 10 to be determined is mounted, and a charge/discharge module 120 for charging and discharging the battery cell 10. ), a battery cell path determination unit 130 that determines whether or not the battery cell 10 is passed.

Specifically, the battery cell mounting unit 110 is configured to fix the battery cell 10 for determining the battery cell path, and may be configured in various forms.

For example, the battery cell mounting unit 110 may be configured in a jig shape, and the battery cell 10 may be fixed on the top of the jig.

Meanwhile, the charge/discharge module 120 may fully charge the battery cell 10 -> rest for a predetermined time -> complete discharge -> rest for a predetermined time.

In this case, the battery cell 10 may be charged or discharged with 1CP (Constant Power) during a full charge or complete discharge process.

On the other hand, the battery cell path determination unit 130, the capacity value after the battery cell 10 performs a full charge-complete discharge cycle a predetermined number of times and the first full charge-complete discharge cycle. Whether or not the battery cell passes may be determined based on the slope with the initial capacity value of the battery cell.

Specifically, the battery cell path determination unit 130 is a capacity value derivation unit 131 that derives a capacity (t) value for each cycle while performing a full charge-complete discharge cycle for the battery cell 10. ), a slope calculation unit 132 that calculates a slope between the derived capacity value for each cycle and an initial capacity value, and a determination unit 133 that determines whether or not to pass a battery cell based on the calculated slope. I can.

Meanwhile, the capacity value derivation unit 131 may derive the capacity of the battery cell using various known techniques.

For example, the capacity of the battery cell may be derived based on the open-circuit voltage of the battery cell, or the capacity of the battery cell may be derived by calculating the amount of current used in the full charge-complete discharge cycle.

Meanwhile, the determination unit 133 may perform the following operation according to the reliability value. The reliability value refers to the reliability of a reserved battery cell capacity value when a corresponding battery cell is actually performed 300 full charge-complete discharge cycles.

Specifically, when the reliability value is set as the first reliability value, the slope between the capacity of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a first number of times and a first reference slope are compared. .

On the other hand, when the reliability value is set as the second reliability value, the slope between the capacity of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times, and a second reference slope may be compared. .

That is, the number of cycles for performing full charge-complete discharge and a reference slope value may vary according to the set reliability value.

Meanwhile, the determination unit 133 is a result of comparing the slope between the capacity of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times, and a first reference slope, and a full charge- When the slope between the capacity of the battery cell and the initial capacity value derived after the complete discharge cycle proceeds a first number of times is less than the first reference slope, or after the complete charge-complete discharge cycle proceeds a second number of times As a result of comparing the slope between the derived capacity of the battery cell and the initial capacity value and the second reference slope, the slope between the capacity of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a second number of times If it is less than the second reference slope, it is determined as a battery cell path.

Meanwhile, the determination unit 133 is a result of comparing the slope between the capacity of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times, and a first reference slope, and a full charge- When the slope between the capacity of the battery cell and the initial capacity value derived after performing the complete discharge cycle a first number of times is greater than the first reference slope, or derived after the full charge-complete discharge cycle proceeds a second number of times As a result of comparing the slope between the capacity of the battery cell and the initial capacity value and the second reference slope, the slope between the capacity of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times 2 If the slope is greater than or equal to the reference slope, it is determined that the battery cell is defective.

For example, the predetermined first number and the first reference slope may be values for determining whether to pass the battery cell in 300 cycles with 90% reliability for the battery cell, and the predetermined second number and the second reference slope 2 The reference slope may be a value for determining whether to pass the battery cell in 300 cycles with 95% reliability for the battery cell.

Specifically, FIG. 2 is a graph showing a correlation between a slope between a capacity value for each full charge-complete discharge cycle and an initial capacity value of a normal battery cell and a capacity value of a normal battery cell that has been actually performed 300 times.

The correlation between the slope of the capacity value for each full charge-complete discharge cycle and the initial capacity value of the normal battery cell and the capacity value of the normal battery cell actually performed 300 times can be calculated by the following (Equation).

(Equation)

(However, slope: the slope between the capacity value and the initial value for each full charge-complete discharge cycle of the battery cell, capacity(t): the capacity value at t cycles, capacity(1): the initial capacity value, capacity(300) ): Capacity value at actual 300 cycles)

In other words, the graph of FIG. 2 is a graph derived by substituting the slope and capacity (300) into the pearson technique, which is a known statistical technique.

Referring to FIG. 2, it can be seen that the number of full charge-complete discharge cycles having a correlation of 90% is 85 times, and the number of full charge-complete discharge cycles having a correlation of 95% is 130 times.

In other words, 85 cycles are required to verify the capacity of the battery cell with 90% reliability in 300 cycles, and if the slope calculated in the 85 cycles is less than the first reference slope, the corresponding battery cell is determined as a pass. On the other hand, 130 cycles are required for the battery cell to perform capacity detection verification with 95% reliability in 300 cycles, and if the slope calculated in 130 cycles is less than the second reference slope, the corresponding battery cell is passed. It can be judged as.

2. A method of determining a battery cell path according to an embodiment of the present invention.

3 is a flowchart illustrating a method of determining a battery cell path according to an exemplary embodiment of the present invention.

Hereinafter, a method of determining a battery cell path according to an embodiment of the present invention will be described with reference to FIG. 3.

A battery cell path determination method according to an embodiment of the present invention includes a battery cell connection step (S100) of connecting a battery cell for determining a battery cell path to a battery cell path determination apparatus, and a full charge-complete discharge cycle for the battery cell. A step of performing a full charge-complete discharge cycle repeatedly performing (S200), a step of deriving a capacity value for each cycle of deriving a capacity value (capacity(t)) of a battery cell for each cycle while performing the full charge-complete discharge cycle (S300), a slope calculation step (S400) of calculating a slope between the derived capacity value for each cycle and an initial capacity value of the battery cell derived after performing the first full charge-complete discharge cycle (S400), the calculated slope It may be configured to include a determination step (S600) of determining whether to pass the battery cell based on the battery cell pass.

Specifically, the step of performing the charge-complete discharge cycle (S200) includes a process of fully charging the battery cell -> rest for a predetermined time -> complete discharge -> rest for a predetermined time. .

In this case, the battery cell may be charged or discharged with 1CP (Constant Power) during the process of full charge or complete discharge.

Meanwhile, the battery cell path determination method may further include a reliability value setting step (S500) of setting a reliability value, and the reliability value setting step (S500) may be performed before performing the determination step. have. Meanwhile, a reference slope to be described later may be set according to the set reliability value.

Meanwhile, the determining step S600 may include comparing steps S630 and S640 of comparing the calculated slope with a reference slope.

Specifically, in the comparison step (S630, S640), when the reliability value setting step is set to the first reliability value (S610), the battery cells derived after performing a full charge-complete discharge cycle a first number of times When the first comparison step (S630) of comparing the slope between the capacity value and the initial capacity value and the first reference slope and the second reliability value is set in the reliability value setting step (S620), a full charge-complete discharge cycle is performed. It may be configured to include a second comparison step (S640) of comparing the slope between the capacity value of the battery cell derived after the second number of times and the initial capacity value and the second reference slope.

On the other hand, in the determination step (S600), as a result of the comparison of the first comparison step (S630), the slope between the capacity value of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times is When the slope is less than the first reference slope or as a result of the comparison of the second comparison step (S640), the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times is the If it is less than the second reference slope, it may be determined as a battery cell path (S650).

On the other hand, in the determination step (S600), as a result of the comparison of the first comparison step (S630), the slope between the capacity value of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times is When the slope is greater than or equal to the first reference slope or as a result of the comparison of the second comparison step (S640), the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times is the If it is equal to or greater than the second reference slope, it may be determined that the battery cell is defective (S660).

For example, the predetermined first number and the first reference slope may be values for determining whether to pass the battery cell in 300 cycles with 90% reliability for the battery cell, and the predetermined second number and the second reference slope 2 The reference slope may be a value for determining whether to pass the battery cell in 300 cycles with 95% reliability for the battery cell.

Specifically, FIG. 2 is a graph showing a correlation between a slope between a capacity value for each full charge-complete discharge cycle and an initial capacity value of a normal battery cell and a capacity value of a normal battery cell that has been actually performed 300 times.

The correlation between the slope of the capacity value for each full charge-complete discharge cycle and the initial capacity value of the normal battery cell and the capacity value of the normal battery cell actually performed 300 times can be calculated by the following (Equation).

(Equation)

(However, slope: the slope between the capacity value and the initial value for each full charge-complete discharge cycle of the battery cell, capacity(t): the capacity value at t cycles, capacity(1): the initial capacity value, capacity(300) ): Capacity value at actual 300 cycles)

In other words, the graph of FIG. 2 is a graph derived by substituting the slope and capacity (300) into the pearson technique, which is a known statistical technique.

Referring to FIG. 2, it can be seen that the number of full charge-complete discharge cycles having a correlation of 90% is 85 times, and the number of full charge-complete discharge cycles having a correlation of 95% is 130 times.

In other words, 85 cycles are required to verify the capacity of the battery cell with 90% reliability in 300 cycles, and if the slope calculated in the 85 cycles is less than the first reference slope, the corresponding battery cell is determined as a pass. On the other hand, 130 cycles are required for the battery cell to perform capacity detection verification with 95% reliability in 300 cycles, and if the slope calculated in 130 cycles is less than the second reference slope, the corresponding battery cell is passed. It can be judged as.

On the other hand, the battery cell path determination method according to the embodiment of the present invention may further include a display step of displaying the result of the determination step (S600). Meanwhile, the technical idea of the present invention is according to the above embodiment. Although described in detail, it should be noted that the above embodiments are for the purpose of explanation and not for the limitation thereof. In addition, those skilled in the art in the technical field of the present invention will be able to understand that various embodiments are possible within the scope of the technical idea of the present invention.

10: battery cell
100: battery cell path determination device
110: battery cell mounting unit
120: charge/discharge module
130: battery cell path determination unit
131: capacity derivation unit
132: slope calculation unit
133: judgment unit

Claims (10)

A battery cell mounting unit in which a battery cell for determining a battery cell path is mounted;
A charge/discharge module for charging and discharging the battery cell;
A battery cell path determination unit determining whether to pass the battery cell;
Battery cell path determination apparatus comprising a.
The method according to claim 1,
The battery cell path determination unit,
A capacity derivation unit for deriving a capacity value (capacity(t)) of the battery cell for each cycle while performing a full charge-complete discharge cycle of the battery cell;
A slope calculation unit that calculates a slope between the derived capacity value for each cycle and an initial capacity value of the battery cell derived after performing an initial full charge-complete discharge cycle;
A determination unit determining whether to pass the battery cell based on the calculated slope;
Battery cell path determination apparatus comprising a.
The method according to claim 2,
The determination unit,
When the reliability value is set to the first reliability value, the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a first number of times and a first reference slope are compared,
When the reliability value is set as the second reliability value, a second reference slope is compared with a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a second number of times. Battery cell path determination device.
The method of claim 3,
The determination unit,
As a result of comparing the slope between the capacity value of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times and the first reference slope, the full charge-complete discharge cycle proceeds the first number of times. A slope between the capacity value of the battery cell and the initial capacity value derived after the operation is less than the first reference slope; or
As a result of comparing the slope between the battery cell capacity value and the initial capacity value derived after performing the full charge-complete discharge cycle a second number of times and the second reference slope, the complete charge-complete discharge cycle proceeds a second number of times. A slope between the capacity value of the battery cell and the initial capacity value derived after the operation is less than the second reference slope;
Judging by the battery cell pass,
As a result of comparing the slope between the capacity value of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a first number of times and the first reference slope, the full charge-complete discharge cycle proceeds the first number of times. When the slope between the battery cell capacity value and the initial capacity value derived after operation is greater than or equal to the first reference slope, or
As a result of comparing the slope between the battery cell capacity value and the initial capacity value derived after performing the full charge-complete discharge cycle a second number of times and the second reference slope, the complete charge-complete discharge cycle proceeds a second number of times. The battery cell path determination apparatus, characterized in that when a slope between the battery cell capacity value and the initial capacity value derived after operation is equal to or greater than the second reference slope, it is determined that the battery cell is defective.
The method of claim 3,
The first reference slope and the second reference slope,
A battery cell path determination apparatus, characterized in that the value is preset according to the reliability value.
A battery cell connection step of connecting a battery cell for determining a battery cell path to a battery cell path determination apparatus;
Performing a full charge-complete discharge cycle of repeatedly performing a full charge-complete discharge cycle for the battery cell;
Deriving a capacity value for each cycle of deriving a capacity value (capacity(t)) of a battery cell for each cycle while performing the full charge-complete discharge cycle;
A slope calculation step of calculating a slope between the derived capacity value for each cycle and an initial capacity value of the battery cell derived after performing an initial full charge-complete discharge cycle;
A determining step of determining whether to pass a battery cell based on the calculated slope;
Battery cell path determination method comprising a.
The battery cell path determination method according to claim 6,
It is configured to further include a step of setting a confidence value for setting a confidence value,
The determining step,
A comparison step of comparing the calculated slope with a reference slope;
Consists of including,
The battery cell path determination method, characterized in that the reference slope is set according to the set reliability value.
The method of claim 7,
The comparison step,
When it is set as the first reliability value in the reliability value setting step,
And a first comparison step of comparing a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a first number of times, and a first reference slope,
When the second reliability value is set in the reliability value setting step,
And a second comparison step of comparing a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a second number of times and a second reference slope How to determine the cell path.
The method of claim 8,
The determining step,
A case in which a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a first number of times as a result of the comparison in the first comparison step is less than the first reference slope; or
As a result of the comparison of the second comparison step, when the slope between the capacity value of the battery cell and the initial capacity value derived after performing the full charge-complete discharge cycle a second number of times is less than the second reference slope; in case the battery cell path Judging by,
A case in which a slope between a capacity value of a battery cell and an initial capacity value derived after performing a full charge-complete discharge cycle a first number of times as a result of the comparison in the first comparison step is greater than or equal to the first reference slope; or
As a result of the comparison in the second comparison step, when the slope between the capacity value of the battery cell and the initial capacity value derived after performing a full charge-complete discharge cycle a second number of times is greater than or equal to the second reference slope; if the battery cell is defective Battery cell path determination method, characterized in that the determination as.
The method of claim 6,
And a determination result display step of displaying a determination result of the determination step.

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