KR101888125B1 - Method and Control Device for testing secondary cell battery using measurement sequence - Google Patents

Abstract

The secondary battery test method includes generating a measurement sequence, transferring the generated measurement sequence to a secondary battery measurement device, receiving measurement data of the secondary battery measured by the secondary battery measurement device And generating meta data of the received measurement data.

Description

TECHNICAL FIELD [0001] The present invention relates to a secondary cell test method and a control device using a measurement sequence,

The present disclosure relates to a secondary battery test method and a control device using a measurement sequence.

Recently, rechargeable batteries such as Ni-Cd, Ni-MH, Li-ion, and lithium polymer batteries are increasing in popularity. Various tests have been conducted to evaluate the characteristics of the secondary battery. The charging / discharging test and the open-circuit voltage stabilization test of the secondary battery require much time, and the amount of measurement data is also large, and it takes a long time to process data and extract meaningful test results. Further, measurement of various test items is required to evaluate the characteristics of the secondary battery. Therefore, research on a secondary battery test method for quickly and easily measuring the characteristics of the secondary battery has been continued.

The present disclosure seeks to provide a secondary cell test method and a control device using a measurement sequence. The present disclosure provides a method and a control device for allowing a measuring instrument to automatically perform a plurality of test items in a sequential manner by combining various types of secondary battery measurement tests in the form of measurement sequences.

A method for testing a secondary battery according to an embodiment includes: generating a measurement sequence; Transmitting the measurement sequence to a secondary battery measurement device; Receiving measurement data of the secondary battery measured by the secondary battery measuring device; And generating meta data from the received measurement data.

The step of generating the measurement sequence may be such that the user selects a sequence block through the user input and the measurement sequence is generated.

The step of generating the measurement sequence may comprise generating a sequence block by a user through a user input unit, wherein the sequence of measurements is generated.

The step of generating the measurement sequence may include generating a sequence sequence by a user through a user input unit, and the sequence unit may include at least two sequence blocks.

The number of repetitions of the sequence unit may be input through the user input unit.

The sequence unit may include a first sequence unit and a second sequence unit, the first sequence unit may include at least two sequence blocks, and the second sequence unit may include at least two sequence blocks.

The sequence unit may correspond to a secondary battery test item.

The secondary battery test item may include at least one of a charge / discharge item, a transient response item, a frequency response item, an open voltage item, and a charge / discharge cycle item.

The step of generating the measurement sequence may include inputting the number of repetitions of the measurement sequence through the user input unit.

The sequence block may correspond to a test item of the secondary battery.

The test items of the secondary battery include at least one of charge, discharge, charge / discharge, frequency response test, AC impedance measurement, transient response test, DC resistance measurement, AC resistance measurement, open voltage measurement, .

The generating of the metadata may include extracting characteristic data corresponding to a predetermined characteristic parameter from the measurement data; And generating metadata from the characteristic parameter and the characteristic data.

The metadata may be generated as an electronic file.

A control device according to an embodiment includes: a communication unit; A user input unit through which a user's command can be input; And a control unit for executing at least one program, generating a measurement sequence according to a user's instruction from the user input unit, and transmitting the generated measurement sequence to the outside through the communication unit, Generating a measurement sequence; Transmitting the measurement sequence to a secondary battery measurement device; Receiving measurement data of the secondary battery measured by the secondary battery measuring device; And generating meta data of the received measurement data.

The generating the measurement sequence may include generating a measurement sequence by the user selecting a sequence block through the user input.

The step of generating the measurement sequence may include generating a sequence sequence by a user through the user input unit, and the sequence unit may include at least two sequence blocks.

The number of repetitions of the sequence unit may be input through the user input unit.

The step of generating the measurement sequence may include inputting the number of repetitions of the measurement sequence through the user input unit.

The generating of the metadata may include extracting characteristic data corresponding to a predetermined characteristic parameter from the measurement data; And generating metadata from the characteristic parameter and the characteristic data.

The metadata may be generated as an electronic file.

The program may cause the output section to display the sequence block as an icon.

The program may provide an interface for arranging the sequence blocks in a row to generate a measurement sequence.

The program may provide an interface for generating the sequence unit.

The program may provide an interface capable of specifying the number of repetitions of the measurement sequence.

The program may display the measurement data in a graph.

The secondary battery test method and the control device according to one embodiment can manage various types of secondary battery test items in a measurement sequence to automate and standardize a series of operations required in the secondary battery test to easily perform testing .

The test method and the control device of the secondary battery according to the embodiment can easily test the characteristics of the secondary battery by iconizing the test items of various kinds of secondary batteries into a sequence block.

The secondary battery test method and the control device according to the embodiment can easily test the secondary battery characteristics using the measurement sequence generated by arranging the iconized sequence blocks.

 The secondary battery test method and the control device according to an embodiment can easily test the secondary battery characteristics by allowing the measurement sequence to include a sequence unit including a plurality of sequence blocks. If a repeat test is required, repeat tests can be performed on a sequence unit basis.

The secondary battery test method and the control device according to an embodiment can easily generate a secondary cell characteristic test by allowing a measurement sequence to be generated, manufactured, stored, and edited.

The secondary battery test method and the control device according to the embodiment can generate the meta data from the measurement data transmitted from the test device so that significant information related to the test can be confirmed with only the meta data without storing or reading the large- .

The secondary battery test method and control device according to one embodiment may plot a graph from the measurement data transmitted from the test device.

1 is a block diagram of a control device and a secondary battery measurement device according to an embodiment.
2 is a block diagram illustrating a sequence block according to an exemplary embodiment of the present invention.
3 is a diagram illustrating a measurement sequence according to one embodiment.
4 is a flowchart showing a method of testing a secondary battery according to an embodiment.
5 is a flowchart illustrating a method of generating a measurement sequence according to an embodiment.
6 is a flowchart showing a method of testing a secondary battery according to another embodiment.
7 is a screen showing an interface shown at the output of the control device according to an embodiment.
8 is a graph showing a graph shown at the output of the control device according to an embodiment.
9 is a graph showing a graph shown at the output of the control device according to another embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a secondary battery test method and a control device according to an exemplary embodiment will be described in detail with reference to the accompanying drawings. The size of each component in the drawings may be exaggerated for clarity and convenience of explanation. Furthermore, the embodiments described below are merely illustrative, and various modifications are possible from these embodiments. Hereinafter, what is referred to as "front" or "front " The term " control unit " and " memory unit " used herein are used to refer to a unit that performs each role, rather than to a separate component device. The terms " control unit " It can be a term.

1 is a block diagram of a control-controlling device 1000 and a secondary battery-measuring apparatus 2000 according to an embodiment. The control device 1000 according to the present embodiment may include a user input unit 1100, an output unit 1200, a control unit 1300, and a communication unit 1500.

The user input unit 1100 means means for the user to input data for controlling the control device 1000. [ For example, the user input unit 1100 may include a keyboard, a mouse, a key pad, a dome switch, a touch pad (a contact type capacitance type, a pressure type resistive type, A sensing method, a surface ultrasonic wave propagation method, an integral type tension measuring method, a piezo effect method, etc.), a jog wheel, a jog switch, and the like.

The output unit 1200 can output an audio signal or a video signal. For example, the output unit 1200 may include an output unit for outputting a video signal or an audio output unit for outputting an audio signal.

The control unit 1300 typically controls the overall operation of the control device 1000. For example, the control unit 1300 can generally control the user input unit 1100, the output unit 1200, the communication unit 1500, and the like by executing programs stored in a memory (not shown).

Specifically, the control unit 1300 generates a measurement sequence by selecting a sequence block provided by the measurement sequence management program installed in the control device 1000, or receives user data through the user input unit 1100, Can be generated. The control unit 1300 may generate a measurement sequence including the sequence block by the measurement sequence management program installed in the control device 1000 and transmit the measurement sequence to the communication unit 1500. [ The communication unit may transmit (I1) the control signal I1 including the measurement sequence to the secondary battery measurement apparatus 2000. [ In addition, the controller 1300 may output the generated measurement sequence and the measurement sequence to the output unit 1200 so that the user can check the measurement sequence in real time.

The sequence block means a unit unit corresponding to each secondary battery measurement test content. The secondary battery measurement test may include, for example, six test items, charge / discharge test item, frequency response item, transient response item, DC resistance measurement item, AC resistance measurement item, Specific test content may be included. For example, specific test contents of the secondary battery include charge capacity, discharge capacity, coulomb efficiency, constant current charge capacity, constant voltage charge capacity, current decay rate, maximum power during discharge, minimum power during discharge, A complex impedance measurement value, a DC resistance value, an AC resistance value, an open voltage value, and the like.

The sequence block may be prepared in advance and stored in a memory (not shown). For example, the control unit 1300 may read the sequence blocks from the memory (not shown) and display the corresponding sequence blocks in the output unit. For example, the program may previously store a plurality of sequence blocks expected to correspond to the secondary battery test items and specific test contents. The user can select, edit, and arrange sequence blocks through the user input unit 1100 to generate a measurement sequence as desired. The user may generate a new sequence block through the user input unit 1100. [ The measurement sequence management program provided by the control unit 1300 may provide a user with an interface capable of selecting, editing, and creating such a sequence block. In addition, the measurement sequence management program can provide an interface by which a user can arrange sequence blocks to generate measurement sequences.

The measurement sequence may comprise a sequence unit comprising a plurality of sequence blocks. The sequence unit may be a unit group including a plurality of sequence blocks. For example, the test items of the secondary battery can largely include charge / discharge items, frequency response items, transient response items, DC resistance measurement items, AC resistance measurement items, and open voltage items. . Therefore, in order to generate the measurement sequence, it is easier to arrange the sequence blocks for each sequence unit, which is an intermediate group, than to arrange only the sequence blocks which are the basic unit units, in the sequence management of the secondary battery test measurement. For example, the sequence unit may correspond to any one of the secondary battery characteristic test items that the user wants to measure. For example, the sequence unit may correspond to any one of a charge / discharge item, a frequency response item, a transient response item, and an open-circuit voltage item. However, the sequence unit is not limited to correspond to the above-described test items. For example, assuming that the sequence unit corresponds to a charge / discharge item, the charge / discharge sequence unit may include a charge test sequence block and a discharge test sequence block. For example, the frequency response sequence unit may comprise a frequency test sequence block. In the rechargeable battery test measurement, one test item can be repeatedly measured to confirm the characteristics of the corresponding test item. Therefore, when defining each test item by a sequence unit, the number of repetitions is specified for each sequence unit, . ≪ / RTI > For example, if the measurement sequence includes the charge / discharge sequence unit and the frequency response sequence unit, the charge / discharge sequence unit may be specified to be repeated m times, and the frequency response sequence may be designated to be repeated n times. Therefore, once the one measurement sequence is transmitted to the secondary battery measuring apparatus 2000, the charge / discharge sequence unit can be repeatedly tested m times, and the frequency response sequence can be repeatedly tested n times.

The communication unit 1500 may include one or more components that enable communication between the control device 1000 and the secondary battery measurement device 2000. [ For example, the communication unit 1500 may include at least one of a local communication unit, a mobile communication unit, and a direct connection unit.

A short-range wireless communication unit includes a Bluetooth communication unit, a Bluetooth low energy (BLE) communication unit, a near field communication unit, a WLAN communication unit, a Zigbee communication unit, Data Association) communication unit, a WFD (Wi-Fi Direct) communication unit, an UWB (ultra wideband) communication unit, an Ant + communication unit, and the like.

The mobile communication unit transmits and receives radio signals to at least one of a base station, an external terminal, and a server on a mobile communication network. Here, the wireless signal may include various types of data depending on a voice call signal, a video call signal, or a text / multimedia message transmission / reception.

The direct connection means a communication unit for physically connecting a plurality of devices to transmit and receive data. The direct connection unit can transmit and receive data through various types of cables including a USB cable, a serial cable, a parallel cable, a LAN cable, and a data cable And a communication unit.

The control device 1000 may further include a memory (not shown). The memory (not shown) may be included inside the control unit 1300 or may be provided outside the control unit 1300 as a separate component. The memory may be a flash memory type, a hard disk type, a multimedia card micro type, a card type memory (e.g., SD or XD memory), a RAM (RAM, (Random Access Memory) SRAM (Static Random Access Memory), ROM (Read Only Memory), EEPROM (Electrically Erasable Programmable Read-Only Memory), PROM (Programmable Read-Only Memory), magnetic memory, magnetic disk, And may include at least one type of storage medium.

The memory may store at least one or more programs including a measurement sequence management program. For example, the memory may store a measurement data management program. Details will be described later with reference to FIGS.

The secondary battery measuring apparatus 2000 may include a secondary battery testing unit 2100 and a communication unit 2200. The secondary battery measurement device 2000 and the control device 1000 may be configured as separate devices, but the present invention is not limited thereto and may be configured by the same device.

The secondary battery testing unit 2100 can test the characteristics of the secondary battery to confirm characteristics of the secondary battery. For example, the secondary battery test section 2100 can test the secondary battery characteristics for at least one test item. The test items may include, for example, charge / discharge items, transient response items, frequency response items, DC resistance measurement items, AC resistance measurement items, open voltage items, and charge / discharge cycle items. The test items are not limited to the above-described embodiments, and may include various test items capable of testing the characteristics of the secondary battery. The test items may correspond to the sequence units described above, but are not limited thereto.

Specifically, the secondary battery test unit 2100 can perform specific test contents according to the test items. The test contents of the secondary battery include, for example, charge capacity, discharge capacity, coulomb efficiency, constant current charge capacity, constant voltage charge capacity, current decay rate, maximum power during discharge, minimum power during discharge, An impedance measurement value, a DC resistance value, an AC resistance value, an open-circuit voltage value, and the like. The contents of the test may correspond to the above-described sequence block. The sequence block can be newly defined, created and edited by the user.

The communication unit 2200 as the measurement object receives the control signal I1 received from the control device 1000 and can transmit the result signal I2 including the measurement data as a result of testing the characteristics of the secondary battery. The specific configuration of the communication unit 2200 may be substantially the same as that of the communication unit 1500 described above, so redundant contents are omitted.

The control signal I1 may comprise a measurement sequence. The measurement sequence may be a command instructing the secondary battery test unit 2100 to perform a measurement test of the secondary battery in a sequential manner. The measurement sequence may include the type of measurement test, the number of repetitions, and measurement test sequence information. For example, the measurement sequence may comprise a plurality of sequence blocks. For example, the measurement sequence may include at least one sequence unit, and one sequence unit may comprise a plurality of sequence blocks. For example, the measurement sequence may include at least one sequence unit, and the at least one sequence unit may be assigned a repetition number. For example, the number of repetitions of the measurement sequence may be specified. Details will be described later with reference to FIG. 2 and FIG.

The resulting signal I2 may include measurement data that is the result of a secondary battery measurement test performed in accordance with the measurement sequence. For example, the result signal I2 may further include at least one of secondary battery information data and secondary battery test data. The secondary battery information data means information related to the secondary battery to be measured. For example, the secondary battery information data may include product information and constituent material information. For example, the product information may include product model name, serial number, form, specification, weight, volume, nominal capacity, and the like. For example, the constituent material information may include anode information, cathode information, electrolyte information, and the like. Such secondary battery basic information is merely an example and is not limited to the above-described embodiments. The secondary battery test data may include the date and time of test, the time and place, the type of test apparatus, the model of test apparatus, and the user information. For example, the test data may include test control variables. For example, test control variables may include test items, open voltage, charge current, discharge current, charge rate, discharge rate, charge rate, temperature, cycle, AC perturbation current, These test conditions are merely illustrative and are not limited to the above-described embodiments.

The result signal I2 may be transmitted to the control device 1000 in real time during the measurement sequence of the secondary cell measurement apparatus 2000. [ When the result signal I2 is transmitted to the control device 1000 in real time, the user may be able to check the test characteristics of the secondary battery in real time through the output unit. In this case, the user may be able to verify the characteristics of the secondary battery without waiting for the delivered measurement sequence to be completed, thereby saving time and money.

 The result signal I2 may be transmitted when the user transmits the control signal I1 requesting the measurement data. In this case, the secondary battery measurement field secondary battery measurement device 2000 includes a separate memory unit (not shown), stores the measurement data derived in the course of performing the measurement sequence in a memory unit (not shown) , And transmit the measurement data read out from the memory unit (not shown) to the resultant signal I2 when the user transmits the control signal I1. In this case, the communication between the control device 1000 and the communication unit of the secondary battery measurement apparatus 2000 does not need to be always maintained in a connected state, and measurement data can be stored in a memory unit (not shown), thereby preventing data loss.

2 is a block diagram illustrating a sequence block according to an exemplary embodiment of the present invention. Referring to FIG. 2, sequence blocks corresponding to various kinds of rechargeable battery test items are shown.

The sequence block may be represented by an icon. For example, the sequence block may be displayed in the output portion as an icon in a block form. The measurement sequence management program provided by the control unit 1300 can control the output unit 1200 such that the sequence block is displayed as a block-shaped icon. The user can select the corresponding secondary battery test by selecting the sequence block. For example, if a sequence block described as green C, 50% is selected, a charge test for charging the secondary battery up to 50% can be selected. The user can edit the sequence block to change the specific test conditions of the corresponding secondary battery test. For example, it is possible to edit a sequence block described as 50% C in green and change it to a charge test in which the secondary battery is charged up to 100%. The control unit 1300 may control the output unit 1200 to display the icon in a form reflecting the edited content of the user.

Referring to FIG. 2, the D icon represents a discharge test, the C / D icon represents a charge / discharge test, the FR icon represents a frequency test, the ACR icon represents an AC impedance measurement test, and the TR icon represents a transient response test , The DCR icon represents a DC resistance measurement, the OCV icon represents an open voltage measurement, the Rest icon represents a dormancy, the Cycle icon represents a cycle test, and the T icon represents a temperature change and measurement test item. The user can add another test item as needed and newly generate a corresponding sequence block. The measurement sequence management program provided by the control unit 1300 can provide an editing tool capable of editing the icon shape of the sequence block.

FIG. 3 is a diagram illustrating a measurement sequence 3000 according to one embodiment. 3, the measurement sequence 3000 may include a plurality of sequence blocks 3111, 3112, 3211, 3212, 3213, 3311, 3312, 3313 and a plurality of sequence units 3100, 3200, 3300 . The number of repetitions 3100-1, 3200-1, and 3300-1 can be specified for the plurality of sequence units 3100, 3200, and 3300. [

The measurement sequence management program provided by the control unit 1300 may provide an interface by which a user can arrange sequence blocks in a row to generate a measurement sequence. For example, the user can select a sequence block through the user input unit 1100 and drag and drop the sequence block to arrange the sequence block in the measurement sequence generation field. For example, if sequential blocks are sequentially arranged from left to right, the secondary battery measurement test can be performed sequentially from the sequence block on the left. The present invention is not limited thereto.

The measurement sequence management program provided by the control unit 1300 may provide an interface through which a user creates a sequence unit. For example, the measurement sequence management program may provide an interface so that a user can generate sequence units in the form of parentheses, figures, and regions. The measurement sequence management program provided by the control unit 1300 may provide an interface through which the user can designate the number of repetitions of the sequence unit. For example, the user can create a sequence unit corresponding to a test item to be confirmed, and arrange a sequence block corresponding to the test item in the sequence unit. For example, the sequence unit may correspond to any of charge / discharge items, transient response items, frequency response items, open-circuit voltage items, and charge / discharge cycle items.

Referring to FIG. 3, the first sequence unit 3100, the second sequence unit 3200, and the third sequence unit 3300 may be included in the measurement sequence 3000. The first sequence unit 3100 corresponds to the charge / discharge test item, and the second sequence unit 3200 and the third sequence unit 3300 can correspond to the frequency response test item. The first sequence unit 3100 may include a charge test sequence block 3111 and a discharge test sequence block 3112. It is possible to arrange the charge test sequence block 3111 on the left side of the discharge test sequence block 3112 to determine the sequence order. For example, the charge test sequence block 3111 may be performed prior to the discharge test sequence block 3112, and the discharge test sequence block 3112 may be sequentially performed. For example, the number of repetitions 3100-1 of the first sequence unit 3100 can be specified. For example, the number of repetitions 3100-1 of the first sequence unit 3100 may be designated as 9. For example, the second sequence unit 3200 may include a charge test sequence block 3211, a dormant sequence block 3212, and a frequency test sequence block 3213. For example, in the second sequence unit 3200, the number of repetitions 3200-1 may be set to 5. [ For example, the third sequence unit 3300 may include a discharge test sequence block 3311, a dormant sequence block 3212, and a frequency test sequence block 3313. For example, the number of repetitions 3300-1 of the third sequence unit 3300 may be set to five.

The measurement sequence management program provided by the control unit 1300 may specify the number of repetitions 3000-1 of the entire measurement sequence generated by the user. For example, in the measurement sequence 3000, the number of repetitions 3000-1 may be set to 1000. [ The meaning of the repetition count 3000-1 of the measurement sequence 3000 is the same as that of all the sequence units 3100, 3200 and 3300 included in the measurement sequence 3000 and its sequence blocks 3111, 3112, 3211, 3212 and 3213 , 3311, 3312, and 3313 is performed once for the measurement sequence 3000, the measurement sequence 3000 is repeatedly performed for the number of iterations (3000-1) Quot;

The measurement sequence 3000 according to the present embodiment can be generated and edited by the measurement sequence management program. The measurement sequence management program provides an interface for easily and repeatedly performing the secondary battery measurement test based on the iconized sequence block and the sequence unit and the measurement sequence and can be controlled by the control unit (1300 in FIG. 1) have.

4 is a flowchart showing a method of testing a secondary battery according to an embodiment. 5 is a flowchart illustrating a method of generating a measurement sequence according to an embodiment.

Referring to FIG. 4, the method includes generating a measurement sequence through a user input unit (S101), transmitting the generated measurement sequence to a secondary battery measurement device (S102), measuring the measured sequence from the secondary battery measurement device Receiving the measurement data of the secondary battery (S103), and generating the received measurement data as metadata (S104).

The step of generating a measurement sequence through a user input (S101) may allow a user to arrange at least two sequence blocks to generate a measurement sequence. The user can select at least two of the sequence blocks shown in the output unit through the user input unit (110 in FIG. 1) and arrange them on the measurement sequence. The measurement sequence management program may provide an interface for the user to arrange the sequence blocks to generate the measurement sequence. For example, the measurement sequence management program may display a previously stored sequence block on the output unit according to the user's input, and display the measurement sequence column being generated on the screen. The user can arrange the sequence block through the user input section in the measurement sequence field. For example, the user can arrange the sequence block in the measurement sequence column by clicking or dragging and dropping the sequence block.

The step of generating a measurement sequence (S101) through a user input may allow a user to generate at least one sequence unit to generate a measurement sequence. The at least one sequence unit may comprise at least two sequence blocks. The sequence unit includes at least two sequence blocks, and the sequence unit may correspond to the secondary battery test item. If the sequence block is a unit unit, the sequence unit may correspond to a unit group including a unit unit. It is possible to manage the secondary battery characteristic test more easily by generating the measurement sequence in units of the sequence unit corresponding to the test item. The measurement sequence management program may provide an interface for a user to create a sequence unit to generate a measurement sequence. The user can generate a sequence unit in the measurement sequence field through the user input unit (110 in FIG. 1). For example, the sequence unit may be represented by parentheses, figures, regions, and the like. It is possible to generate a sequence unit in the measurement sequence generation field displayed on the output unit and to select and arrange at least two of the sequence blocks shown in the output unit in the sequence unit. The user can designate a different number of repetitions for each sequence unit. It is also possible not to specify the number of repetitions of the sequence unit. The user can specify the number of repetitions in the measurement sequence. It is also possible not to designate the number of repetitions of the measurement sequence.

5, in step S101, the user generates or selects a sequence block through a user input unit (S101-1). The user creates a sequence unit through the user input unit (S101 -2), the generated sequence unit can be arranged to generate a measurement sequence (S101-3).

The user can create, select, and edit the sequence block according to the interface provided by the measurement sequence management program (S101-1). The user can create a sequence unit (S101-2) according to the interface provided by the measurement sequence management program. The step of generating a sequence unit (S101-2) may be performed by providing a sequence unit indicated by parentheses, figures, areas, and the like, and arranging at least two sequence blocks in the sequence unit. The generated sequence units can be arranged to generate a measurement sequence (S101-3). The flowchart shown in FIG. 5 is only one embodiment and is not limited to the above-described sequence. A measurement sequence can be generated by only a sequence block without generating a sequence unit. Furthermore, the step of designating the number of repetitions of the sequence unit and the step of designating the number of repetitions of the measurement sequence may be additionally included.

The step of generating a measurement sequence through the user input unit (S101) may specify the number of repetitions of the measurement sequence by the user. It may be possible to instruct to perform the secondary battery characteristic test repeatedly for a specified number of repetitions instead of performing the measurement sequence once.

The step of transferring the generated measurement sequence to the secondary battery measurement device (S102) may be the step of the control device (1000 of FIG. 1) transmitting the measurement sequence to the secondary battery measurement device (2000 of FIG. For example, the measurement sequence generated by the user may be transmitted to the communication unit 1500 and transmitted to the secondary battery measurement apparatus (2000 in FIG. 1) under the control of the control unit (1300 in FIG. 1).

The step (S103) of receiving the measurement data of the secondary battery measured according to the measurement sequence from the secondary battery measuring device is a step of measuring the measurement according to the test contents performed by the secondary battery measuring device (2000 in FIG. 1) May be the step of receiving data at the control device (1000 of FIG. 1). For example, the control device (1000 in FIG. 1) can receive the measurement data of the secondary battery in real time in the process of performing the secondary battery test according to the measurement sequence of the secondary battery measurement device (2000 in FIG. 1) have. For example, the control device (1000 in FIG. 1) can receive asynchronously measurement data of the secondary battery stored in a memory unit (not shown) of the secondary battery measurement apparatus (2000 in FIG. 1). For example, the control device (1000 in FIG. 1) may transmit the control signal I1 to the secondary battery measurement device (2000 in FIG. 1), at the request of the user. The secondary battery measuring device (2000 in FIG. 1) receives the control signal I1 and may transmit the measurement data stored in the memory unit (not shown) to the control device (1000 in FIG. 1).

The step of generating the received measurement data as metadata (S104) may be performed by processing the measurement data and generating the metadata.

The measurement data may include a plurality of data related to the sequence block measured by the secondary battery measurement apparatus (2000 in Fig. 1). The contents of the measurement data can be changed according to the test items measured by the secondary battery measuring device (2000 in Fig. 1). From the measurement data, characteristic data corresponding to the pre-determined characteristic parameter can be extracted according to the test item. The characteristic parameter may be preset for each test item and stored in the control unit 1300, memory (not shown), or the like of the control device (1000 of FIG. 1). The characteristic parameter may be a characteristic parameter that can characterize the secondary battery. The characteristic parameter can be changed by external input. For example, when the user changes the characteristic parameter in the user input unit 1100, the characteristic parameter stored in the memory (not shown) may be changed. The characteristic data is data corresponding to the characteristic parameter. For example, the characteristic data may correspond to a part of the measurement data. For example, the characteristic data may be data derived by converting measured data by a mathematical operation algorithm. A mathematical operation algorithm can include mathematical methods such as fitting, differentiation, and integration. The mathematical operation algorithm may include all of the code that the control unit 1300 can perform by accessing the mathematical method described above in a programmatic manner. It can be determined whether to derive the characteristic data directly from the measured data according to the type of the predetermined characteristic factor or to calculate and convert the measured data using a mathematical operation algorithm. This determination may be made in the control unit 1300, but is not limited thereto. For example, when a characteristic parameter and a characteristic data derivation method are stored in advance in a memory (not shown) and the secondary battery test method is executed, the control unit 1300 reads the characteristic parameter and characteristic data stored in the memory And the characteristic parameter and the characteristic data can be automatically derived from the measurement data. Therefore, the user can perform the characteristic test of the secondary battery more easily by performing the calculation automatically by the control unit 1300 or the memory (not shown) without directly performing an operation for deriving a meaningful result from the measurement data .

The generation of the metadata can generate the characteristic data by the characteristic parameter and the characteristic parameter by the metadata. Metadata is data structured by data, which means data for describing other data. For example, the meta data is generated so as to include characteristic parameters and characteristic data for each test item, so that measurement data can be simply described. Accordingly, instead of storing the result of testing the characteristics of the secondary battery as the measurement data, the secondary battery measurement apparatus (2000 in FIG. 1) can generate and store metadata including the characteristic parameter and the characteristic data.

Metadata can be generated in electronic file format. For example, the metadata may be generated as a digital or electronic document that can be created, edited and stored by a computer. For example, the metadata may be generated as a digital or electronic document written in a searchable structured language, such as an extensible markup language. For example, the metadata may be generated to have a predetermined characteristic factor as a field. For example, the metadata may be generated as an electronic document in a spreadsheet format in which predetermined characteristic parameters and corresponding extracted characteristic data are arranged in rows and columns.

6 is a flowchart showing a method of testing a secondary battery according to another embodiment. Referring to FIG. 6, the method includes generating a measurement sequence through a user input unit (S201), transmitting the generated measurement sequence to a secondary battery measurement device (S202), measuring the measured sequence from the secondary battery measurement device (S203) of receiving the measurement data of the secondary battery (S203), generating the received measurement data as metadata (S204), and displaying the received measurement data as a graph (S205).

Step S205 of displaying the received measurement data as a graph can convert the measurement data received by the control unit 1300 in the control device 1000 (FIG. 1) into a graph and display it on the output unit. For example, when the measurement data is transmitted in real time to the control device (1000 of FIG. 1), the graph may be updated to reflect the continuously transmitted measurement data. For example, if measurement data is transmitted asynchronously to a control device (1000 of FIG. 1), the graph may show a graph reflecting the transmitted measurement data.

The control unit (1300 in FIG. 1) can display the graph without converting the measurement data into a mathematical algorithm. The control unit (1300 in FIG. 1) may display the graph using numerical values obtained by converting measurement data into a mathematical algorithm.

7 is a screen showing an interface shown at the output of the control device according to an embodiment. 7, the measurement sequence management program 700 includes a measurement sequence management unit 710, a graph display unit 720, a control panel 730, a status display unit 740, a secondary battery basic information display unit 750, A test condition display unit 760, and a measurement data display unit 770.

The measurement sequence management unit 710 can generate and edit a measurement sequence and display a measurement sequence currently in progress. If the measurement sequence is delivered to the current secondary battery measurement device (2000 in FIG. 1) and the test is being performed according to the measurement sequence, a bar indicating the progress state may be shown together.

The graph display unit 720 can display a graph according to measurement data.

The control panel 730 may include various control icons for controlling the measurement sequence management program 700. [ The control panel 730 can perform functions such as transmission of a measurement sequence, storage, loading, interruption of measurement test, graph display, program end, setting change, and the like.

The status display unit 740 can display and reflect the status of various variables applied to the secondary battery under test by the secondary battery measuring apparatus (2000 in FIG. 1) in real time. For example, the status display unit 740 may display variables such as voltage, current, time, temperature, and the corresponding values.

The secondary battery basic information display unit 750 can display basic information related to the secondary battery under test. The basic information may include at least one of product information and constituent material information. For example, the product information may include product model name, serial number, form, specification, weight, volume, nominal capacity, and the like. For example, the constituent material information may include anode information, cathode information, electrolyte information, and the like. Such secondary battery basic information is merely an example and is not limited to the above-described embodiments.

The test condition display unit 760 may display test conditions related to the secondary battery under test. For example, the test conditions may include the date and time of the test, the time and place, the type of test device, the test device model, and the user information. For example, the test conditions may include test control variables. For example, test control variables may include test items, open voltage, charge current, discharge current, charge rate, discharge rate, charge rate, temperature, cycle, AC perturbation current, These test conditions are merely illustrative and are not limited to the above-described embodiments.

The measurement data display unit 770 can display the measurement data transmitted from the secondary battery measurement apparatus (2000 in FIG. 1). The measurement data display unit 770 can be interlocked with the graph display unit 720. For example, some of the numerical values of the measurement data displayed on the measurement data display unit 770 may be plotted on the x-axis and some of the values on the y-axis in the graph display unit 720.

8 is a graph showing a graph shown at the output of the control device according to an embodiment. 9 is a graph showing a graph shown at the output of the control device according to another embodiment. The control unit (1300 in Fig. 1) may include a measurement data management program separate from the measurement sequence management program. The measurement data management program may include a function of displaying the measurement data as a graph or metadata. Referring to FIG. 8, the measurement data management program may show a plurality of separate graphs for each test item on the same output unit. Referring to FIG. 9, the measurement data management program can compare measured data or compare graphs for different test items.

Up to now, to facilitate understanding of the present invention, exemplary embodiments of a secondary battery test method and control device have been described and shown in the accompanying drawings. It should be understood, however, that such embodiments are merely illustrative of the present invention and not limiting thereof. And it is to be understood that the invention is not limited to the illustrated and described parts. Since various other modifications may occur to those of ordinary skill in the art.

1000: Control device
1100: User input
1200: output section
1300:
1500:
2000: Secondary battery measuring device
2100: secondary battery test section
2200:
3000: Measurement sequence
3100, 3200, 3300: Sequence unit
3111, 3112, 3211, 3212, 3213, 3311, 3312, 3313: Sequence block
3100-1, 3200-1, 3300-1: Sequence unit repetition times
3000-1: Number of repetition of measurement sequence
700: Screen
710: Measurement sequence
720: Graph
730: Control Panel
740: Secondary Battery Status Window
750: Rechargeable battery basic information
760: Secondary battery test information
770: Measurement data

Claims (23)

Generating a measurement sequence;
Transmitting the measurement sequence to a secondary battery measurement device;
Receiving measurement data of the secondary battery measured by the secondary battery measuring device; And
And generating meta data of the received measurement data
Wherein the generating the measurement sequence comprises:
A user creates a sequence unit through a user input unit to generate the measurement sequence,
Wherein the sequence unit comprises at least two sequence blocks. The method according to claim 1,
Wherein the generating the measurement sequence comprises:
Wherein the measurement sequence is generated by arranging at least two sequence blocks selected by a user through a user input unit. The method according to claim 1,
Wherein the generating the measurement sequence comprises:
Wherein the measurement sequence is generated by arranging at least two sequence blocks generated by a user through a user input unit. delete The method according to claim 1,
Wherein the number of repetitions of the sequence unit is input through the user input unit. The method according to claim 1,
Wherein the sequence unit includes a first sequence unit and a second sequence unit, the first sequence unit includes at least two sequence blocks, and the second sequence unit includes at least two sequence blocks. The method according to claim 6,
Wherein the generating the measurement sequence comprises:
Wherein the number of repetitions of the measurement sequence is input through the user input unit. The method according to claim 2 or 3,
Wherein the sequence block corresponds to a test item of the secondary battery. 9. The method of claim 8,
The test items of the secondary battery include at least one of charge, discharge, charge / discharge, frequency response test, AC impedance measurement, transient response test, DC resistance measurement, AC resistance measurement, open voltage measurement, Containing secondary battery. The method according to claim 1,
Wherein the generating the metadata comprises:
Extracting characteristic data corresponding to a predetermined characteristic factor from the measurement data; And
And generating metadata from the characteristic parameter and the characteristic data. The method according to claim 1,
Wherein the metadata is generated as an electronic file. A communication unit;
A user input unit through which a user's command can be input;
A control unit for executing at least one program, generating a measurement sequence according to a user's instruction from the user input unit, and transmitting the generated measurement sequence to the outside through the communication unit; And
And an output unit for displaying the executed program,
Wherein the at least one program comprises:
Generating a measurement sequence;
Transmitting the generated measurement sequence to a secondary battery measurement device;
Receiving measurement data of the secondary battery measured from the secondary battery measuring device; And
Generating meta data of the received measurement data;
Wherein the generating the measurement sequence comprises:
A user generates a sequence unit through the user input unit to generate the measurement sequence,
Wherein the sequence unit comprises at least two sequence blocks. 13. The method of claim 12,
Wherein the generating the measurement sequence comprises:
Wherein the user selects a sequence block through the user input unit to generate the measurement sequence. delete 13. The method of claim 12,
And the number of repetitions of the sequence unit is input through the user input unit. 13. The method of claim 12,
Wherein the generating the measurement sequence comprises:
Wherein the number of repetitions of the measurement sequence is input through the user input unit. 13. The method of claim 12,
Wherein the generating the metadata comprises:
Extracting characteristic data corresponding to a predetermined characteristic factor from the measurement data; And
And generating metadata from the characteristic parameter and the characteristic data. 13. The method of claim 12,
Wherein the metadata is generated as an electronic file. 14. The method of claim 13,
Wherein the program causes the output block to output the sequence block as an icon. 14. The method of claim 13,
Wherein the program provides an interface for arranging the sequence blocks in a row to generate a measurement sequence. 13. The method of claim 12,
Wherein the program provides an interface for generating the sequence unit. 13. The method of claim 12,
The program providing an interface capable of specifying the number of repetitions of the measurement sequence. 13. The method of claim 12,
Wherein the program displays the measurement data in a graph.

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