WO2015174115A1 - Data management device and data management program - Google Patents

Abstract

The purpose of the present invention is, with respect to a data management device that manages data on workpieces processed by production devices in a factory automation system, to facilitate acquisition of inspection data of inspections by workers that corresponds to performance data pertaining to processing by a production device. The data management device (50) manages performance data along with lot numbers and processing dates/times while managing inspection data along with the lot numbers and inspection dates/times. Furthermore, the data management device (50) extracts, as data corresponding to performance data, inspection data having a matching lot number and an inspection date/time that falls within a reference time period which uses the processing data/time as reference.

Description

Data management apparatus and data management program

This invention relates to a technique for managing data on a workpiece (hereinafter referred to as a workpiece) processed by a production facility in a factory automation system (hereinafter referred to as an FA system).

In the FA system, data management is performed so that the status of the produced product in each production process can be tracked at a later date.

In the FA system, a production facility such as a processing machine or an inspection machine, and a programmable logic controller (hereinafter, PLC) that controls the production facility are provided for each production process.
In a production facility, when processing a workpiece, the lot number assigned to the workpiece is read, and actual data such as the weight, temperature, voltage value, and current value of the workpiece at the time of processing is measured. The PLC associates the lot number read by the production facility with the performance data measured by the production facility and stores it in a database (hereinafter referred to as DB).
In the DB, records of corresponding works in each production process are linked. That is, when the work A is processed in the process 1 to produce the work B and the work B is processed in the process 2 to produce a product, the record for the work A in the process A and the record for the work B in the process B Are linked. Thereby, for example, when a product has a defect, it is possible to track the performance data of each workpiece in each production process of the product.

Here, the lot number is not a number uniquely assigned to a work, but the same number is often assigned to a plurality of works. For example, the same number may be assigned to a plurality of works delivered in one case. This is because if a lot number is uniquely assigned to a work, the management becomes complicated and the management cost is often not commensurate with the price of the work.

JP 2006-301937 A

The worker may visually check each workpiece processed in the production facility for defects, and may enter, for example, inspection data indicating the confirmation result together with the lot number of the workpiece on a sheet. Information entered on the form is later entered into the computer and managed.
However, as described above, since the lot number is not a number uniquely assigned to the workpiece, the actual data stored in the DB cannot be associated with the inspection data. Therefore, when tracking the actual data and investigating the cause of the defect, the inspection data corresponding to the actual data cannot be acquired, and the inspection data is not utilized.
An object of the present invention is to facilitate acquisition of inspection data corresponding to performance data and to promote the utilization of inspection data.

The data management device according to the present invention is:
It is a data management device that manages data about workpieces processed at production facilities in a factory automation system.
For each workpiece processed at the production facility, acquisition of the actual data of the processing of the workpiece is acquired together with the lot number assigned to the workpiece and the processing date and time when the workpiece was processed, and stored in the storage device. And
Acquires inspection data indicating the result of the operator inspecting each workpiece processed in the production facility, together with the lot number assigned to the workpiece and the inspection date and time when the workpiece was inspected, and stores it in the storage device. A test data acquisition unit to store;
When the actual data acquired by the actual data acquisition unit is selected, among the inspection data acquired by the inspection data acquisition unit, the lot number and the lot number acquired together with the selected actual data are the same, and A data extraction unit for extracting inspection data that includes the inspection date and time within a first reference period based on the processing date and time acquired together with the selected result data;
And a data output unit for outputting the data extracted by the data extraction unit.

The data management device further includes:
An image data acquisition unit that acquires image data of each workpiece processed in the production facility, together with a lot number attached to the workpiece and a shooting date and time of imaging the workpiece, and stores it in a storage device;
The data extraction unit is a process in which the lot number and lot number acquired together with the selected record data are the same among the image data acquired by the image data acquisition unit, and the process is acquired together with the selected record data Image data in which the shooting date / time falls within a second reference period based on the date / time is extracted.

In the factory automation system, processing of a plurality of processes is executed sequentially,
The data extraction unit has the same lot number and lot number acquired together with the selected result data, and the inspection is performed within a first reference period based on the processing date and time acquired together with the selected result data. It is characterized in that inspection data is extracted that has a date and time and that has a date before the processing date and time of the next process after the process of the selected result data.

The inspection by the worker is performed only on a workpiece determined to be defective by a PLC that controls the production facility.

The lot number is characterized in that the same number is assigned to a plurality of workpieces.

The data management program according to the present invention includes:
A data management program that manages data about workpieces processed by production equipment in a factory automation system.
For each work processed in the production facility, the actual data of the processing of the work, the lot number attached to the work, and the actual data acquisition process for acquiring the processing date and time when the work was processed,
Inspection data acquisition processing for acquiring inspection data indicating a result of an inspection performed on each workpiece processed by the production facility, together with a lot number assigned to the workpiece and an inspection date and time when the workpiece was inspected When,
When the actual data acquired in the actual data acquisition process is selected, among the inspection data acquired in the inspection data acquisition process, the lot number and the lot number acquired together with the selected actual data are the same, and A data extraction process for extracting inspection data in which the inspection date / time falls within a first reference period based on the processing date / time acquired together with the selected result data;
A data output process for outputting data extracted by the data extraction process is executed by a computer.

The data management apparatus according to the present invention manages the performance data together with the lot number and the processing date and time, and manages the inspection data together with the lot number and the inspection date and time. Then, the inspection data in which the lot numbers match and the inspection date / time falls within the first reference time based on the processing date / time is extracted as corresponding to the actual data. Thereby, acquisition of the inspection data corresponding to the result data is facilitated, and utilization of the inspection data is promoted.

1 is a configuration diagram of an FA system 1 according to Embodiment 1. FIG. 2 is a functional configuration diagram of a data management device 50 according to Embodiment 1. FIG. 5 is a flowchart showing processing during product production of the FA system 1 according to the first embodiment. 5 is a flowchart showing processing during product production of the FA system 1 according to the first embodiment. The figure which shows the data which the performance data storage part 54 memorize | stores. The figure which shows the data which the image data memory | storage part 55 memorize | stores. The figure which shows the data which the test | inspection data memory | storage part 56 memorize | stores. 5 is a flowchart showing processing when data is used by the data management apparatus 50 according to the first embodiment. The figure which shows the state which displayed the information of each workpiece | work in each production process as a chart. The figure which shows the state which displayed the performance data etc. about the selected workpiece | work. The figure which shows the state which displayed as a list the image data and inspection data with high possibility corresponding to the selected workpiece | work. FIG. 3 is a diagram illustrating an example of a hardware configuration of the data management apparatus 50 illustrated in the first embodiment.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram of an FA system 1 according to the first embodiment.
The FA system 1 includes a production facility 10, a PLC 20, a photographing device 30, a reading device 40, and a data management device 50.
There are a plurality of production facilities 10, and the PLC 20 and the imaging device 30 are provided for each production facility 10. Between the PLC 20 corresponding to the production facility 10, between the imaging device 30 corresponding to the PLC 20, between each PLC 20 and the data management device 50, between each imaging device 30 and the data management device 50, between the reading device 40 and data The management device 50 is connected to each other by a network.

FIG. 2 is a functional configuration diagram of the data management apparatus 50 according to the first embodiment.
The data management device 50 includes an actual result data acquisition unit 51, an image data acquisition unit 52, an inspection data acquisition unit 53, an actual result data storage unit 54, an image data storage unit 55, an inspection data storage unit 56, and a data extraction unit 57.

3 and 4 are flowcharts showing processing at the time of product production of the FA system 1 according to the first embodiment.
Actually, the processing is executed in each production facility 10 included in the FA system 1, and accordingly, the processing is also executed in the corresponding PLC 20, imaging device 30, reading device 40, and data management device 50. Here, in order to simplify the description, one production facility 10 will be described. In particular, here, the case where the production facility 10 is an inspection apparatus that inspects the quality of a workpiece will be described as an example.

Work arrives at the production facility 10 (S1). Then, the production facility 10 reads the barcode attached to the workpiece and acquires the lot number of the workpiece (S2). The PLC 20 transmits the lot number acquired in S2 and the date and time (start date and time) when the work arrives at the production facility 10 to the data management device 50 (S3). The actual data acquisition unit 51 of the data management device 50 acquires the lot number and start date and time transmitted in S3 and stores them in the actual data storage unit 54 (S4).

The work is carried by the belt conveyor and enters the photographing region of the photographing device 30 (S5). Then, the imaging device 30 images the workpiece (S6). The imaging device 30 reads the lot number written on the workpiece from the image data of the workpiece captured in S6 (S7). The photographing apparatus 30 analyzes the image data of the work photographed in S6 and determines the quality of the work (S8). The photographing device 30 transmits the image data of the work photographed in S6, the photographing date and time (shooting date and time), the lot number read in S7, and the determination result determined in S8 to the data management device 50 (S9). ). The image data acquisition unit 52 of the data management device 50 acquires the image data, the shooting date and time, the lot number, and the determination result transmitted in S9 and stores them in the image data storage unit 55 (S10).

Work is carried on the belt conveyor and enters the processing area of the production facility 10 (S11). Then, the production facility 10 measures performance data such as the weight, temperature, voltage value, and current value of the workpiece (S12). The PLC 20 performs work quality determination based on the performance data measured in S12 (S13). The PLC 20 transmits the result data measured in S12, the determination result determined in S13, and the date and time (processing date and time) when the result data was acquired in S12 to the data management device 50 (S14). The record data acquisition unit 51 of the data management device 50 stores the record data, the determination result, and the processing date / time transmitted in S14 in the record data storage unit 54 in association with the lot number stored in S4 (S15). .

Work is carried on the belt conveyor and exits the processing area of the production facility 10 (S16). Then, the PLC 20 transmits the date and time (completion date and time) when the workpiece leaves the processing area to the data management device 50, assuming that the processing in the production facility 10 is completed (S17). The record data acquisition unit 51 of the data management device 50 stores the completion date and time transmitted in S17 in the record data storage unit 54 in association with the lot number stored in S4 (S18).

The worker visually inspects the work judged as NG in S8 or S13 (S19). The worker enters the inspection data indicating the result of the inspection in S19, the lot number of the workpiece, and the inspection date and time when the determination is performed by handwriting on a predetermined entry sheet (S20). At the end of the shift, the worker sequentially reads the entry sheets entered during the shift with the reading device 40 (S21). The reading device 40 transmits to the data management device 50 the data (inspection data, lot number, inspection date and time) entered on each entry sheet read in S21 and the reading date and time that is the date and time read in S21. (S22). The inspection data acquisition unit 53 of the data management device 50 stores the data transmitted in S22 in the inspection data storage unit 56 (S23).

FIG. 5 is a diagram illustrating data stored in the record data storage unit 54.
The record data storage unit 54 stores a lot number, process name, equipment number, start date / time, processing date / time, record data, determination result, and completion date / time.
As described above, the lot number is a number assigned to the workpiece, but is not a number that can uniquely identify the workpiece. The process name is identification information of the production process. The equipment number is identification information of the production equipment 10. The start date / time, processing date / time, result data, determination result, and completion date / time are as described above. The determination result includes, for example, a value 0 (OK) indicating that the product is a non-defective product and a value 1 (NG) indicating that the product is a defective product.

FIG. 6 is a diagram illustrating data stored in the image data storage unit 55.
The image data storage unit 55 stores an image ID, a lot number, a process name, an equipment number, a shooting date / time, a file name, and a file path.
The image ID is identification information of image data. The lot number, process name, equipment number, and shooting date and time are as described above. The file name is the file name of the image data. The file path is information indicating the position where the image data file is stored.

FIG. 7 is a diagram illustrating data stored in the inspection data storage unit 56.
The inspection data storage unit 56 stores the document ID, lot number, process name, equipment number, inspection date / time, reading date / time, file name, and file path.
The document ID is identification information of inspection data. The lot number, process name, equipment number, inspection date / time, and reading date / time are as described above. The file name is a file name of a file obtained by imaging the test data entry form. The file path is information indicating a position where a file in which an examination data entry form is imaged is stored.

FIG. 8 is a flowchart showing processing at the time of data use of the data management apparatus 50 according to the first embodiment.
The data extraction unit 57 displays a search screen on the display device and allows the user to input a search condition such as a product ID (S31). As shown in FIG. 9, the data extraction unit 57 displays the information of each workpiece in each production process as a chart for products that match the search condition (S32).
Records stored by the record data storage unit 54 for the corresponding workpieces in each production process are linked by existing technology. For example, there is a table for each arrow connecting the process of FIG. 9 and other processes, and the correspondence between the lot number and the lot number is stored in the table. One lot number and a plurality of lot numbers may be associated with each other. In this case, FIG. 9 is a branched chart. Therefore, if the product is specified, the data extraction unit 57 can specify the record stored in the record data storage unit 54 for each work in each production process for the product.
In FIG. 9, when one product corresponding to the product ID input as the search condition is produced, information on each workpiece used in the five production processes from process 1 to process 5 is displayed. FIG. 9 shows an example in which one workpiece is used in each production process in order to simplify the description. However, there is also a process of assembling a single object by combining a plurality of works and a process of producing a plurality of goods using a single work. In this case, a chart having a structure in which one work branches into a plurality of works, or a chart having a structure in which a plurality of works are integrated into one work.

When any work is selected by the user from the work displayed in the chart as shown in FIG. 9, the data extraction unit 57 displays the actual data and the like for the selected work as actual data as shown in FIG. 10. Extracted from the storage unit 54 and displayed (S33).
In S32, the record stored by the record data storage unit 54 for each workpiece is specified. Therefore, the data extraction unit 57 can easily specify a record for the selected work.

When the user presses the document search button while the information about the selected work is displayed as shown in FIG. 10, the data extraction unit 57 corresponds to the selected work as shown in FIG. Image data and inspection data that are likely to be extracted are extracted, and the extracted image data and inspection data are displayed in a list (S34).
Specifically, the data extraction unit 57 takes an image within the reference period (second reference period) in which the lot number and the lot number of the selected work are the same and the processing date and time of the selected work is used as a reference. Image data containing the date and time is extracted from the image data storage unit 55 as image data that is highly likely to correspond to the selected work. Similarly, the data extraction unit 57 has the same lot number and lot number of the selected workpiece, and the inspection date and time is within the reference period (first reference period) based on the processing date and time of the selected workpiece. The inspection data to be entered is extracted from the inspection data storage unit 56 as inspection data having a high possibility of corresponding to the selected workpiece.
The reference period based on the processing date / time is, for example, a period around the processing date / time. Of course, only a certain period after the processing date may be used.

When image data or inspection data is selected by the user from the image data and inspection data displayed in a list as shown in FIG. 11, the data extraction unit 57 extracts the selected image data or inspection data file, etc. Displayed (S35).

As described above, the lot number is not a number that can uniquely identify the workpiece. Therefore, even if the lot number of the record data is used as a search key, the corresponding image data and inspection data cannot be uniquely specified. In some cases, when searching using the lot number of the record data as a search key, a huge number of image data and inspection data are hit.
However, as described above, in the FA system 1 according to the first embodiment, the data management device 50 uses not only the lot number but also the processing date and time of the workpiece as a search key, and image data and inspection data corresponding to the actual data. Search for. The processing date / time of the workpiece, the shooting date / time, and the inspection date / time are expected to be close to some extent. Therefore, it is possible to narrow down image data and inspection data corresponding to the result data.
As a result, image data and inspection data are also used together with the result data, and a more detailed analysis is possible.

In S34, the data extraction unit 57 further extracts only the inspection data whose inspection date is earlier than the processing date (or start date) of the workpiece in the production process next to the selected workpiece. Good.
As described above, the worker enters the date and time when the worker conducted the inspection. The worker may inspect the workpiece that has been determined to be NG as soon as possible. However, the worker may prioritize other operations and inspect the workpiece after a while. Therefore, a certain amount of difference occurs between the processing date and time and the inspection date and time.
However, in principle, inspection is performed before the workpiece is processed in the next production process. For this reason, if the condition that the inspection date / time is earlier than the processing date / time of the workpiece in the next production process is added to the condition, the inspection data can be further narrowed down.

In addition, since the inspection is performed on the workpiece that has been determined to be NG, the inspection date / time is at least later than the start date / time. Therefore, it may be added as a condition that the inspection date is later than the start date.
Further, the inspection is performed not only when the quality is determined to be NG by the PLC 20 but also when the quality is determined to be NG by the photographing apparatus 30. Therefore, strictly speaking, there is a possibility that the inspection is performed before the processing date and time. However, since it is considered that there is no significant difference in the time at which the quality judgment is performed between the PLC 20 and the imaging device 30, the condition that the inspection date is later than the processing date may be added as a condition.

In S34, the data extraction unit 57 extracts image data whose shooting date / time falls within the second reference period based on the processing date / time, and the inspection whose inspection date / time falls within the first reference period based on the processing date / time. Data was extracted.
The first reference period and the second reference period are predetermined periods. The first reference period and the second reference period may be the same period or different periods.
Usually, since the workpiece is automatically photographed, the difference between the processing date and time and the photographing date and time is small and can be assumed in advance to some extent. On the other hand, as described above, since the inspection depends on the worker, the difference between the processing date and time and the inspection date may be large and cannot be assumed in advance. Therefore, for example, the first reference period may be longer than the second reference period.

In the above description, the worker visually inspects the work whose quality is determined to be NG in S8 or S13. However, the operator may inspect all the workpieces visually.
When the worker inspects only the work judged as NG and quality, the number of works to be inspected is small. For this reason, there is a high possibility that the worker can immediately inspect. On the other hand, when an operator inspects all workpieces, the number of workpieces to be inspected is large. For this reason, it is unlikely that the worker can perform the inspection immediately.
Therefore, when the worker inspects all the workpieces, the first reference period may be made longer than when the worker inspects only the workpieces that have been judged to be NG quality.

Further, as described above, the PLC 20 and the photographing apparatus 30 are connected via a network. Therefore, instead of using the shooting date and time as the shooting date and time, the processing date and time may be stored as the shooting date and time.
In this case, it is only necessary to narrow the second reference period and extract only image data whose shooting date and time are equal to the processing date and time.

In the above description, the data management device 50 is a single device. However, the data management device 50 includes, for example, an application server including an actual data acquisition unit 51, an image data acquisition unit 52, an inspection data acquisition unit 53, and a data extraction unit 57, an actual data storage unit 54, an image data storage unit 55, It may be divided into a DB server including the inspection data storage unit 56.

Also, a plurality of photographing devices 30 may be provided for each production facility 10. The workpiece may be photographed from various angles by the plurality of photographing devices 30. Alternatively, the belt conveyor may be transparent, and the workpiece may be photographed from the lower side of the belt conveyor. As a result, a three-dimensional model of the workpiece can be generated, and can be used for quality determination or for investigation of the cause when there is a defect in the product.

FIG. 12 is a diagram illustrating an example of a hardware configuration of the data management apparatus 50 illustrated in the first embodiment.
The data management device 50 is a computer. Each element of the data management device 50 can be realized by a program.
As a hardware configuration of the data management device 50, an arithmetic device 901, an external storage device 902, a main storage device 903, a communication device 904, and an input / output device 905 are connected to the bus.

The computing device 901 is a CPU (Central Processing Unit) that executes a program. The external storage device 902 is, for example, a ROM (Read Only Memory), a flash memory, a hard disk device, or the like. The main storage device 903 is, for example, a RAM (Random Access Memory). The communication device 904 is, for example, a communication board. The input / output device 905 is, for example, a mouse, a keyboard, a display device, or the like.

The program is normally stored in the external storage device 902, and is loaded into the main storage device 903 and sequentially read into the arithmetic device 901 and executed.
The program is a program that realizes the functions described as the result data acquisition unit 51, the image data acquisition unit 52, the inspection data acquisition unit 53, and the data extraction unit 57.
Furthermore, an operating system (OS) is also stored in the external storage device 902. At least a part of the OS is loaded into the main storage device 903, and the arithmetic device 901 executes the above program while executing the OS.
In the description of the first embodiment, the information described as being stored by the record data storage unit 54, the image data storage unit 55, and the inspection data storage unit 56 is stored in the main storage device 903 as a file.

The configuration of FIG. 12 is merely an example of the hardware configuration of the data management device 50, and the hardware configuration of the data management device 50 is not limited to the configuration described in FIG. Also good.

1 FA system, 10 production equipment, 20 PLC, 30 imaging device, 40 reading device, 50 data management device, 51 actual data acquisition unit, 52 image data acquisition unit, 53 inspection data acquisition unit, 54 actual data storage unit, 55 image Data storage unit, 56 inspection data storage unit, 57 data extraction unit.

Claims (6)

1. It is a data management device that manages data about workpieces processed at production facilities in a factory automation system.
   For each workpiece processed at the production facility, acquisition of the actual data of the processing of the workpiece is acquired together with the lot number assigned to the workpiece and the processing date and time when the workpiece was processed, and stored in the storage device. And
   Acquires inspection data indicating the result of the operator inspecting each workpiece processed in the production facility, together with the lot number assigned to the workpiece and the inspection date and time when the workpiece was inspected, and stores it in the storage device. A test data acquisition unit to store;
   When the actual data acquired by the actual data acquisition unit is selected, among the inspection data acquired by the inspection data acquisition unit, the lot number and the lot number acquired together with the selected actual data are the same, and A data extraction unit for extracting inspection data that includes the inspection date and time within a first reference period based on the processing date and time acquired together with the selected result data;
   A data management apparatus comprising: a data output unit that outputs data extracted by the data extraction unit.
2. The data management device further includes:
   An image data acquisition unit that acquires image data of each workpiece processed in the production facility, together with a lot number attached to the workpiece and a shooting date and time of imaging the workpiece, and stores it in a storage device;
   The data extraction unit is a process in which the lot number and lot number acquired together with the selected record data are the same among the image data acquired by the image data acquisition unit, and the process is acquired together with the selected record data The data management apparatus according to claim 1, wherein image data in which the shooting date / time falls within a second reference period based on the date / time is extracted.
3. In the factory automation system, processing of a plurality of processes is executed sequentially,
   The data extraction unit has the same lot number and lot number acquired together with the selected result data, and the inspection is performed within a first reference period based on the processing date and time acquired together with the selected result data. 3. The inspection data is extracted, wherein the inspection date is extracted and the inspection date and time is earlier than the processing date and time of the next process after the process of processing the selected result data. The data management device described.
4. 4. The inspection according to claim 1, wherein the inspection by the worker is performed only on a work determined to be defective by a PLC (programmable logic controller) that controls the production facility. 5. Data management device.
5. 5. The data management apparatus according to claim 1, wherein the same lot number is assigned to a plurality of workpieces.
6. A data management program that manages data about workpieces processed by production equipment in a factory automation system.
   For each work processed in the production facility, the actual data of the processing of the work, the lot number attached to the work, and the actual data acquisition process for acquiring the processing date and time when the work was processed,
   Inspection data acquisition processing for acquiring inspection data indicating a result of an inspection performed on each workpiece processed by the production facility, together with a lot number assigned to the workpiece and an inspection date and time when the workpiece was inspected When,
   When the actual data acquired in the actual data acquisition process is selected, among the inspection data acquired in the inspection data acquisition process, the lot number and the lot number acquired together with the selected actual data are the same, and A data extraction process for extracting inspection data in which the inspection date / time falls within a first reference period based on the processing date / time acquired together with the selected result data;
   A data management program for causing a computer to execute data output processing for outputting data extracted in the data extraction processing.

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