JP2009226540A - Verification device for random sewing machine processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a verification device for a random sewing machine processor which verifies whether or not sewing machine processing is properly performed in the random sewing machine processor. <P>SOLUTION: The random sewing machine processor is equipped with a running detection means for detecting the running on a continuous form, a timing mark sensor for detecting a timing mark, a bar code reader for reading a bar code including sewing machine pattern information, a control means for performing arithmetic control based on the sewing machine pattern information, a lateral sewing machine processing means for performing lateral sewing machine processing, and a longitudinal sewing machine processing means for performing longitudinal sewing machine processing. The verification device for the random sewing machine processor includes: a sewing machine pattern information determining means determining whether the sewing machine pattern information is proper or not; a lateral sewing machine processing determining means determining whether the lateral sewing machine processing is proper or not by detecting the movement of the lateral sewing machine processing means; and a longitudinal sewing machine processing determining means determining whether the longitudinal sewing machine processing is proper or not by detecting the movement of the longitudinal sewing machine processing means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention belongs to the technical field of sewing a continuous foam. In particular, a verification device for a random sewing machine that verifies whether or not a random sewing machine that performs an atypical sewing process by reading a barcode that includes sewing pattern information printed on a continuous form performs an appropriate operation. About.

An apparatus that performs sewing on a continuous form in which the same pattern is repeatedly printed in synchronization with the printed pattern is well known (for example, Patent Document 1). In this case, the repetition interval of the same printed pattern is equal to the circumference of the printing plate cylinder. Therefore, when performing the sewing process, a sewing machine cylinder having a circumference that matches the circumference of the printing plate cylinder and its receiving cylinder are used. However, this conventional sewing processing method cannot be applied to a continuous form in which the same pattern is not repeatedly printed, that is, a continuous form in which aperiodic and atypical printing is performed.
In view of this, there are inventions relating to an apparatus that performs atypical random sewing on a continuous form on which atypical printing is performed (Patent Documents 2 and 3). According to the present invention, the mark sensor reads a mark printed on a continuous form and outputs a mark reading signal. The differential reading device of the sewing machine processing unit is driven by the mark reading signal, and the differential shaft is rotated. As a result, the sewing machine machining the differential mechanism is performed. That is, a sewing process is performed by printing a mark indicating the position of the sewing process on the continuous form, and the sewing process is not performed when the mark is not printed. As a result, random sewing processing is performed.
JP2002-273858 JP2000-061888 JP2000-061889

However, in this conventional method, since whether or not to perform the sewing process is determined only by the presence or absence of the printed mark, it is difficult to perform various types of sewing processes. For example, depending on the form of the sewing machine pattern, marks must be printed at many locations. At that time, there is a problem in that performing the printing accurately without making a mistake causes a heavy administrative burden. Further, considering the coexistence of other print marks, cutting marks, and the like, there is a problem that there is no blank space for printing the marks and the sewing process is impossible.
In addition, the conventional method has a problem that there is no method for verifying whether or not the sewing process is properly performed on the printed mark. The invention of a system for verifying whether or not proper collation has been performed in a collation form obtained by cutting a continuous form on which atypical printing is performed into a plurality of sheet forms is known. Yes (Patent Document 4, Patent Document 5). However, verification is only performed for collation, not for sewing. Also, the verification target is a collated form, which is a processed product, and not a random sewing machine, which is a processing machine.
JP 2004-262031 A JP 2005-088504 A

  The present invention has been made to solve the above problems. The purpose is to verify whether or not the machine has been properly machined in a random machine that can carry out a wide variety of sewing machines without difficulty, with a small administrative burden and a small margin for printing marks. An object of the present invention is to provide a verification device for a random sewing machine.

A verification apparatus for a random sewing machine according to claim 1 of the present invention includes a plurality of single-wafer forms, a timing mark indicating the position of each sheet of the single-wafer form, and a sewing pattern of each sheet of the single-wafer form. A verification device for a random sewing machine that performs atypical sewing on a continuous form on which a barcode including information is printed, and a reading check means for checking barcode reading by the barcode reader; Format check means for checking the format of the content read by the bar code reader, operation signal check means for checking the output of the sewing operation signal, machine operation check means for checking the machine operation of the sewing machine, Log data generating means for generating check log data.
Further, the verification device for a random sewing machine according to claim 2 of the present invention is the verification device for the random sewing machine according to claim 1, wherein the random sewing machine detects travel in the continuous form that travels. A traveling detection means for outputting a traveling signal, a timing mark sensor for detecting the timing mark in the traveling continuous form and outputting a mark signal, and a sewing machine that reads the barcode in synchronization with the mark signal and the traveling signal. A bar code reader for outputting pattern information, control means for performing control calculation based on the sewing machine pattern information and generating an operation signal for the sewing machine in synchronization with the mark signal and the running signal, and the operation signal The horizontal sewing machine processing signal that is one of Cormorants and lateral perforation processing means, in which so as to comprise a longitudinal perforation processing means for performing a vertical perforation processing with respect to the longitudinal perforation operation signal said continuous form to input, which is one of the operation signal.
Further, the verification device for the random sewing machine according to claim 3 of the present invention is the verification device for the random sewing machine according to claim 1 or 2, wherein the OK machine (good product) and the NG product (defective product) are distinguished. A log data output means for specifying either one of or both of the full result output for explicitly displaying or printing all the log data and the NG product output for displaying or printing only the NG product is provided. It is.

According to the verification apparatus for a random sewing machine according to claim 1 of the present invention, the reading check means checks the reading of the barcode by the barcode reader, and the format of the reading content read by the barcode reader by the format checking means is the same. The operation signal check means checks the output of the operation signal of the sewing machine, the machine operation check means checks the machine operation of the sewing machine, and the log data generation means generates log data of the check. Therefore, a verification device for a random sewing machine for verifying whether or not the sewing machine has been properly performed in the random sewing machine is provided. Further, by verifying the random sewing machine, it is possible not only to prevent the introduction of defective products but also to quickly and easily cope with the cause of occurrence. As a result, the defect rate in the processed product can be significantly reduced, and the stop time of the processing machine can be shortened to improve the productivity.
According to the verification device for a random sewing machine according to claim 2 of the present invention, in the verification device for the random sewing machine according to claim 1, an atypical type independent of the vertical sewing machine and the horizontal sewing machine is used. Sewing machine processing is suitable for random sewing machines that can perform sewing machines in various forms without difficulty, with a small management burden in the sewing machine, a small margin for printing marks, and a wide variety of sewing machines. An apparatus for verifying a random sewing machine for verifying whether or not the process has been performed is provided.
According to the verification apparatus for a random sewing machine according to claim 3 of the present invention, in the verification apparatus for the random sewing machine according to claim 1 or 2, an OK product (good product) and an NG product are provided by the log data output means. Either the whole result output in which all of the log data is displayed or printed with the distinction of (defective product), the NG product output in which only the NG product is displayed or printed, or both are performed by designation. Therefore, it is possible for the operator to easily grasp whether or not the random sewing machine is operating properly, and it is possible to reliably carry out a reproduction or the like for the NG product.

Next, embodiments of the present invention will be described with reference to the drawings. An example of the configuration of the verification apparatus for the random sewing machine according to the present invention is shown in FIG. 1 as a block diagram. In FIG. 1, the verification apparatus side and the random sewing machine side are separated from each other with a broken line as a boundary line. On the verification apparatus side of FIG. 1, 1 is a data processing means, 21 is a vertical sewing machine (OS) machine operation detecting means, 22 is a horizontal sewing machine (OS) machine operation detecting means, and 31 is a vertical sewing machine (GS) machine. An operation detection unit 32 is a horizontal sewing machine (GS) machine operation detection unit. On the random sewing machine side of FIG. 1, 50 is a traveling detection means, 60 is a timing mark sensor, 70 is a bar code reader, 80 is a control means, 210 is a vertical sewing machine (OS) processing means, and 220 is a horizontal sewing machine. (OS) processing means, 310 is a vertical sewing machine (GS) processing means, and 320 is a horizontal sewing machine (GS) processing means.
Here, the continuous foam to be machined by the random sewing machine machine has two independent areas arranged in a direction perpendicular to the running direction (lateral direction), so-called 2UP continuous foam (with two surfaces). Continuous form). Therefore, means (OS notation) for performing sewing on the region on the OS side of the 2UP continuous form (the side where the machine element is installed in the random sewing machine), and the GS side (operator in the random sewing machine) There is a means (notation of GS) for performing sewing on the area on the operation side.

First, the verification device portion of the present invention will be described, and then the random processing device portion will be described.
The data processing means 1 inputs data relating to the operating state of the random machining apparatus, such as read errors, sewing pattern information, sewing machine instructions, etc. from the control means 80 of the random machining apparatus. Further, the data processing means 1 detects the operation state of the random machining device by a sensor provided in the random machining device, and inputs the detection signal. The data processing means 1 performs data processing for verifying whether or not the operation state of the random processing apparatus is appropriate based on the input data. For example, data processing related to verification such as reading check, format check, operation signal check, machine operation check, and the like is performed. The data processing means 1 generates log data based on the data obtained by the verification. In addition, a process for displaying the generated log data on a display monitor or a data process for printing with a printer is performed.
The data processing means 1 can be realized by hardware and software of a data processing system such as a microcomputer or a PLC (programmable logic controller) personal computer.

The vertical sewing machine processing (OS) machine operation detecting means 21 is a means for detecting the mechanical operation of the vertical sewing machine processing means (OS) 210.
The horizontal sewing (OS) machine operation detecting means 22 is a means for detecting the mechanical operation of the horizontal sewing machine (OS) 220.
The vertical sewing machine processing (GS) machine operation detecting means 31 is a means for detecting the mechanical operation of the vertical sewing machine processing means (GS) 310.
The horizontal sewing machine processing (GS) machine operation detecting means 32 is a means for detecting the mechanical operation of the horizontal sewing machine processing means (GS) 320.
As these mechanical operation detecting means, for example, a magnetic sensor for detecting a magnetic material, an eddy current sensor for detecting a conductor, a photoelectric sensor for detecting a light amount change in light projection and reception, and the like can be used. One of the sensors is installed in the vicinity of the part so that the target sewing machine means for detecting the mechanical movement can detect the part that performs the mechanical movement when performing the sewing process.

Next, the process of data processing in the verification device for the random sewing machine according to the present invention will be described. FIG. 2 is a flowchart showing a data processing process in the verification apparatus for the random sewing machine according to the present invention.
First, in step S1 (bar code reading check) in FIG. 2, the data processing means 1 of the verification apparatus inputs from the control means 80 data that the barcode reader 70 reads and outputs in a specific period. The control unit 80 inputs signals output from the travel detection unit 50 and the timing mark sensor 60. Based on the signal, the control means 80 calculates a period during which the sewing instruction bar code printed on the continuous form reaches the reading area of the bar code reader 70 and exists in that area. A specific period is that period. The data output from the barcode reader 70 is a reading error (NoRead) when the reading of the sewing machine instruction barcode is unsuccessful. The data output from the barcode reader 70 is the data read when the sewing instruction barcode is read. Therefore, the data processing means 1 checks whether or not there is a reading error (NoRead).
Next, in step S2 (whether it has been read?), The data processing means 1 of the verification device performs the process of proceeding to step S8 when the data is a reading error (NoRead), and proceeds to step S3 when the data is the read data. Perform forward processing.

Here, timing marks and sewing instruction bar codes in a continuous form which is a processing target (raw material) of the random sewing machine according to the present invention will be described. An example of a continuous form that is a processing target (raw fabric) of a random sewing machine is shown in FIGS. 3 and 4, 101 is a timing mark, 102 is a sewing machine instruction bar code, 103 is a vertical sewing machine mark, and 104 is a horizontal sewing machine mark.
The timing mark 101 is a mark indicating the position of each sheet of the continuous form. The continuous foam is constituted by a plurality of uncut (uncut) single wafer foams. In the example shown in FIG. 3, the timing mark 101 is printed as a rectangular mark in a margin (margin) portion near the boundary line of each sheet of the sheet form indicated by the page number. Although the continuous form is a 2UP continuous form, the timing mark 101 is printed only at one location in units of 4 pages on both sides, as can be seen by comparing FIG. 3 and FIG. In other words, one timing mark 101 indicates the position of a four-page sheet form on both sides. In the example shown in FIGS. 3 and 4, the timing mark 101 is printed on the margin (margin) portion on the fourth page, the eighth page, the twelfth page, the sixteenth page, and the like.

  The sewing instruction bar code 102 is a bar code including sewing pattern information for performing an atypical sewing process. In the example shown in FIG. 3, printing is performed as a bar code of a long rectangular area near the right boundary line of the even page of the sheet form indicated by the page number. Since the continuous form 100 is a 2UP continuous form, one sewing instruction bar code 102 is printed on each of the left and right (GS side and OS side) sheet forms. Thereby, a random sewing machine process can be performed independently with respect to the area | region on the OS side and area | region on the GS side of a continuous form. As can be seen from a comparison between FIG. 3 and FIG. 4, the sewing machine instruction bar code 102 is printed only on one side, that is, only on the back side of the continuous form. Needless to say, since the sewing process is a process for both sides, if one sewing instruction bar code 102 is printed on one side of a single sheet form, it can be completed.

  4 is a register mark printed on the continuous form 100 in order to indicate an appropriate position of the perforation in the vertical sewing process. 4 is a register mark printed on the continuous form 100 to indicate an appropriate position of the perforation in the horizontal sewing process. These are sewing marks that are provided to visually determine whether or not the random sewing process has been performed properly.

Returning to FIG. 2, the description of the data processing process in the verification apparatus will be continued.
Next, in step S3 (format check of read contents), the data processing means 1 of the verification apparatus uses the read contents of the data (read data) that the bar code reader 70 reads and outputs the machine instruction bar code 102 as the read contents. It is checked whether or not it is appropriate. Appropriate reading contents include other information along with the sewing pattern information. For all of these data, the data processing means 1 determines whether or not an appropriate numerical symbol is read, whether or not the numerical value range is appropriate, and the numerical value in the current reading content relative to the previous reading content. Check whether or not continuity is appropriate.
Next, in step S4 (format OK?), The data processing means 1 of the verification device performs the process of proceeding to step S8 if even one check result is inappropriate, and all the check results are appropriate. If so, the process proceeds to step S5.

Here, an example of the contents of the sewing instruction bar code 102 will be described. FIG. 5 is an explanatory diagram showing an example of the contents of the sewing instruction bar code 102 printed on the continuous form to be processed in the present invention. FIG. 5A shows the contents (items, number of digits, etc.) of the sewing instruction bar code 102 as a table. FIG. 5B is a diagram showing the contents of the sewing instruction bar code 102 as an example (when the read result is “a0123450010121036a”) and the print position.
In the example shown in FIG. 5, the sewing machine instruction bar code 102 includes not only the sewing pattern information but also other information. That is, the sewing instruction bar code 102 includes a start character, a serial number, a current sheet, a total sheet, a form type, a sewing pattern, a check digit, and an end character.

  As the start character, one digit is assigned to the first digit of the sewing machine instruction bar code 102 and is always “a”. The serial number is assigned 6 digits from the 2nd digit to the 7th digit of the sewing machine instruction barcode 102, for example, “012345”. As the current sheet, the third digit from the eighth digit to the tenth digit of the sewing machine instruction barcode 102 is assigned, for example, “001”. As the total number of sheets, three digits from the 11th digit to the 13th digit of the sewing machine instruction bar code 102 are assigned, for example, “012”. As the form type, one digit is assigned to the 14th digit of the machine instruction bar code 102, for example, “1”. As the sewing pattern, two digits from the 15th digit to the 16th digit of the sewing instruction bar code 102 are assigned, and for example, “01”. As the check digit, one digit is assigned to the 17th digit of the sewing machine instruction bar code 102 and is, for example, “1”. As the end character, one digit is assigned to the 18th digit of the sewing machine instruction bar code 102 and is always “a”.

  In the sewing instruction bar code 102 having the above contents, the sewing pattern information is a part of the sewing pattern to which two digits from the 15th digit to the 16th digit are assigned. In the example shown here, the sewing pattern information is a sewing pattern determined by a character string expressed by two-digit alphanumeric characters. The actual sewing machine pattern of the sewing pattern is registered in advance in a random sewing machine (a storage device of a control unit in the machine) in association with the character string. The form of sewing is a position where vertical sewing is performed in the continuous form 100 and a position where horizontal sewing is performed. The position may be a plurality of positions. The number of forms of sewing that can be registered is a number that can be expressed by a two-digit character string, but if necessary, the number of forms of sewing that can be registered may be increased by increasing the number of digits of the character string. A complicated sewing pattern having a plurality of machining positions corresponding to a plurality of vertical sewing machines and a plurality of horizontal sewing machines can be designated by a short character string. Therefore, the load on management is small, the margin for printing the mark is small, and it is possible to perform various forms of sewing without difficulty.

Returning to FIG. 2, the description of the data processing process in the verification apparatus will be continued.
Next, in step S5 (sewing machine operation signal check), the data processing unit 1 of the verification apparatus inputs a sewing machine operation signal from the control unit 80 of the random sewing machine. Of course, this operation signal is based on the sewing pattern information, and the control means 80 uses the vertical sewing machine processing means (OS) 210, the horizontal sewing machine processing means (OS) 220, the vertical sewing machine processing means (GS) 310, and the horizontal sewing machine processing means ( GS) 320 corresponds to an operation signal generated to operate 320, that is, a control command. The data processing means 1 correctly matches the correspondence between the sewing pattern information in the sewing instruction bar code data obtained from the control means 80 in step S1 and the operation signal obtained from the control means 80 in step S5. Check if it has. That is, the data processing unit 1 checks whether or not the operation signal output to each of the sewing machine processing units matches the sewing pattern information.
Next, in step S6 (operation output OK), the data processing means 1 of the verification apparatus performs the process of proceeding to step S8 if any of the results of checking the output of those operation signals is inappropriate. When all the results are proper, the process proceeds to step S7.

Next, in step S7 (machine operation check of the sewing machine processing), the data processing means 1 of the verification apparatus inputs an operation signal that each machine operation detection means of the sewing machine processing means detects and outputs. The details of these operation signals are the operation signal output by the vertical sewing machine processing (OS) machine operation detecting means 21 for detecting the mechanical operation of the vertical sewing machine processing means (OS) 210, and the horizontal sewing machine processing means (OS) 220. The horizontal sewing machine (OS) machine motion detection means 22 for detecting the mechanical movement of the machine and the vertical sewing machine (GS) machine movement detection for detecting the mechanical movement of the vertical sewing machine machining means (GS) 310. The operation signal output by the means 31 and the operation signal output by the horizontal sewing machine processing (GS) machine operation detection means 32 for detecting the mechanical operation of the horizontal sewing machine processing means (GS) 320.
Then, the data processing unit 1 determines the correspondence between the sewing pattern information in the sewing instruction bar code data acquired from the control unit 80 in step S1 and the operation signal acquired from each machine operation detection unit in step S7. Check if is correctly consistent. That is, the data processing means 1 checks whether or not the presence or absence of detection of the mechanical operation in each of the sewing machine processing means coincides with the sewing pattern information.

Next, in step S8 (log data generation), the data processing means 1 of the verification apparatus stores the data obtained by the verification process of the sewing machine processing in steps S1 to S7 as log data. A series of steps from S1 to S7 is a step performed for each sheet of the continuous form. That is, in this series of steps, in the case of a 2UP continuous form, verification processing for the sewing processing of a sheet-fed form with two sides (four pages on the front and back) is performed, and log data is generated. This series of steps is repeated in step S10. Therefore, the log data of this time is added to the log data accumulated up to the previous time, and the log data is accumulated as many times as the number of repetitions. The accumulated log data is stored in a storage device such as a hard disk as a log file.
Next, in step S9 (log data output), the data processing means 1 of the verification apparatus outputs all results that display or print all the log data by clearly indicating the OK product (good product) and the NG product (defective product). I do. Alternatively, NG product output for displaying or printing only NG products is performed.
Next, in step S10 (sewing machine end?), The data processing means 1 of the verification device inputs data relating to the continuation of the sewing machine from the control means 80, that is, whether or not the operation mode of the random sewing machine is finished. . When the operation mode is finished, the data processing means 1 finishes the sewing process verification process. Otherwise, the data processing means 1 returns to step S1 and repeats the subsequent steps described above.

Here, an example of display of log data on a display monitor (not shown) of the verification apparatus will be described. An example of the display of log data in the verification device for the random sewing machine according to the present invention is shown in FIG. When the screen (window) of the machining data recording system is opened in the verification device, the screen shown in FIG. 6 is displayed on the display monitor. On the screen of this processed data recording system, an information input column, a communication log column, and an error log column are provided. The screen when displayed is shown.
The information input column is a column for inputting log file attribute values. The attribute value fields to be entered include customer name, product name, lot name, and worker. In the example shown in FIG. 6, “test customer” is displayed in the “customer name” field, “test item” is displayed in the “product name” field, “9001” is displayed in the “lot name” field, In the “worker” column, “IPS technology” is entered. These attribute values are registered at the same time when the log file is registered (saved) in a database or the like, and the log file can be searched and specified not only from the file name of the log file but also from the attribute value.

The communication log column is a column for displaying all the results of the communication log in the sewing machine processing specified by the information input column. This communication log includes all results of the verification process of the sewing machine processing in the random sewing machine of the present invention. As an attribute value column to be displayed, No. , Barcode, judgment, date, time. In the example illustrated in FIG. 6, “501645” or the like is displayed in the “No.” column, “a9999999929921031a” or the like is displayed in the “barcode” column, and “OK” or “NG” or “ “2008/03/23” or the like is displayed in the “Date” column, and “15:26:22” or the like is displayed in the “Time” column.
These attribute values are displayed in a form in which new data is added in parallel with the progress of the sewing machine processing when the random sewing machine processing is performed. In a series of steps in the above-described verification process of the sewing machine processing, when a 2UP continuous form is used, the verification process for the sewing process of a sheet-fed form with two sides (front and back four pages) is performed. Therefore, two rows are added in a series of steps. For example, two lines of “501645” and “501646” are added to the “No.” column in a series of steps.
These attribute values are displayed by opening the log file when the random sewing machine has already been processed and the log file is registered.

The error log column is a column that displays only the error result of the communication log in the sewing machine processing specified by the information input column. This communication log includes all results of the verification process of the sewing machine processing in the random sewing machine of the present invention. As an attribute value column to be displayed, No. , Barcode, judgment, date, time, barcode (front), barcode (back). In the example shown in FIG. 6, the “No.” column includes “501650” and the “barcode” column includes “a999999969921061a” and the “judgment” columns all include “NG” and “date” columns. “2008/03/23”, “15:26:23”, etc. in the “time” column, “a9999999929921050a”, etc. in the “barcode (front)” column, “barcode (rear)” In the column, “a9999999929821015a” and the like are displayed.
These attribute values are displayed in a form in which new data is added in parallel with the progress of the sewing machine processing when the random sewing machine processing is performed. In a series of steps in the above-described verification process of the sewing machine processing, when a 2UP continuous form is used, the verification process for the sewing process of a sheet-fed form with two sides (front and back four pages) is performed. However, since the OS-side machining unit 20 and the GS-side machining unit 30 are independent, machining errors do not always occur at the same time, and therefore, two rows are not necessarily added in a series of steps.
These attribute values are displayed by opening the log file when the random sewing machine has already been processed and the log file is registered.

Next, an example of printing log data in a printer (not shown) of the verification apparatus will be described. An example of printing log data in the verification device for the random sewing machine according to the present invention is shown in FIG. In the example shown in FIG. 7, log data (only error results) is included in the print output of the “sewing machine verification system warning communication form”. In this sewing machine verification system warning communication form, as a column of attribute values to be displayed, No. , Customer name, product name, lot name, worker, date, time, barcode, barcode (front), barcode (rear). In the example shown in FIG. 6, “501651” or the like in the “No.” column, “Test customer” or the like in the “Customer name” column, “9001” or the like in the “Lot name” column, etc. , “IPS technology” in the “worker” column, “2008/02/23” in the “date” column, “15:26:23” in the “time” column, “barcode” "A99999999298921051a" etc. are entered in the "" column, "a9999999929921050a" etc. are entered in the "Barcode (front)" column, and "a999999829921015a" etc. are entered in the "Barcode (back)" column.
With this machine processing machine verification system warning communication form, it is possible to reliably perform work to remove defective products from continuous forms after sewing and to prevent missing parts to be reprinted and replenished. It becomes possible.

Heretofore, the verification device portion of the present invention has been described. Next, the part of the random processing apparatus will be described.
First, the overall configuration of the random sewing machine will be described. An example of the overall configuration of the random sewing machine is shown in FIG. 8 as an explanatory diagram. In FIG. 8, 10 is a paper feeding unit, 20 is an OS side processing unit, 30 is a GS side processing unit, 40 is a folding unit, 100 is a continuous winding form, and 200 is a continuous folding form.
As shown in FIG. 8, the continuous form 100 of the winding body is fed from the paper supply unit 10 to the OS side processing unit 20 and the GS side processing unit 30 and zigzag folded at the folding unit 40 to form a folded continuous form 200. . In the continuous form 100, the contents of the form, control marks, and the like are printed along with the processing of the feed holes in the margin portions on both sides. In the example described here, the continuous foam 100 is a so-called 2UP continuous foam (two-sided continuous foam) having two independent regions arranged in a direction perpendicular to the traveling direction.

The paper feeding unit 10 is a part of a random sewing machine that unwinds the continuous form 100 from the winding body of the continuous form 100 and feeds it to the random sewing machine processing unit, that is, the OS side processing unit 20 and the GS side processing unit 30. The paper feed unit 10 feeds the continuous form 100 by inserting the pin of the pin tractor into the feed hole of the continuous form 100.
The OS side processing unit 20 is a part of a random sewing machine that performs a sewing process on an area on the OS side of the 2UP continuous form (the side on which the machine elements are installed in the random sewing machine). The OS side processing unit 20 performs random sewing processing under the control of the control means 80.
The GS side processing unit 30 is a part of a random sewing machine that performs sewing on the GS side (side on which the operator performs operations on the random sewing machine) of the 2UP continuous form. The GS side machining unit 30 performs random sewing machining under the control of the control means 80.
The folding part 40 is a part of a random sewing machine that obtains a folded continuous form 200 by zigzag-folding the continuous form 100 subjected to random sewing. The zigzag fold is performed at the portion where the sewing machine for folding is performed.

Next, the structure of the part deeply related to the random sewing machine processing in the random sewing machine will be described. An example of a configuration of a portion deeply related to random sewing machine processing in a random sewing machine is shown in FIG. 1 as a block diagram. In FIG. 1, 50 is a travel detection means, 60 is a timing mark sensor, 70 is a bar code reader, 80 is a control means, 210 is a vertical sewing machine processing means (OS), 220 is a horizontal sewing machine processing means (OS), and 310 is a vertical machine. Sewing machine processing means (GS) and 320 are horizontal sewing machine processing means (GS).
The travel detection means 50 is a sensor that detects travel in the continuous form 100 and outputs a travel signal. For example, the travel detection means 50 can be composed of a rotary encoder provided on the drive shaft of the pin tractor in the paper feed unit 10 and its arithmetic unit. The shaft of the rotary encoder rotates in proportion to the travel of the continuous form 100. The rotary encoder outputs a number of rectangular wave signals corresponding to the amount of rotation, and the arithmetic unit inputs the rectangular wave signals. The computing device computes the traveling speed, traveling distance, etc. of the continuous foam 100 based on the rectangular wave signal. Those data obtained by calculation, that is, the running signal is input by the control means 80.

The timing mark sensor 60 is a sensor that detects a timing mark 101 printed on each sheet in the continuous form 100 and outputs a mark signal. For example, as the timing mark sensor 60, a photoelectric sensor provided on the traveling path of the continuous form 100 in the paper feeding unit 10 can be used. A mark signal output from the timing mark sensor 60 is input by the control means 80.
The bar code reader 70 is a sensor that reads the sewing instruction bar code 102 in synchronization with the mark signal and the running signal and outputs the sewing pattern information. The sewing pattern information output from the barcode reader 70 is input by the control means 80.
The control means 80 performs control calculation based on the sewing pattern information and generates an operation signal for sewing processing as an operation signal synchronized with the mark signal and the travel signal. The control means 80 can be realized by hardware and software of a data processing device such as a PLC (programmable logic controller).

  The vertical sewing machine processing means (OS) 210 is an apparatus that is provided in the OS side processing unit 20 and performs vertical sewing on the OS side region of the continuous form 100. The vertical sewing machine processing means (OS) 210 operates under the control of the control means 80 and inputs a vertical sewing machine operation signal which is one of operation signals output from the control means 80 to perform vertical sewing. For example, the vertical sewing machine processing means (OS) 210 can be constituted by a vertical sewing wheel, a vertical sewing blade receiver, a bracket, an air cylinder, and a solenoid valve. A vertical sewing wheel is a wheel having a cutting edge formed in a circumferential portion. The vertical sewing wheel is supported by a bracket via a holder. The bracket is driven by an air cylinder, and the vertical sewing wheel can be moved to a processing position where vertical sewing is performed and a retreat position where vertical sewing is not performed. The vertical sewing machine blade support is disposed opposite the vertical sewing machine wheel, and the vertical sewing machine blade support and the cutting edge of the vertical sewing machine wheel are close to each other at the machining position. At that time, if there is a continuous form 100 between them, the continuous form 100 is subjected to a horizontal sewing process.

  The air cylinder is operated by an electromagnetic valve that selects a high-pressure air supply port, and the operation of the electromagnetic valve is performed by the control means 80. The control means 80 calculates the position of the vertical sewing process in the continuous form 100 based on the sewing pattern information. Then, a vertical sewing machine operation signal is output so that processing is performed by the vertical sewing wheel provided at that position. The control means 80 operates the electromagnetic valve by this vertical sewing machine operation signal to operate the air cylinder and set the vertical sewing wheel to the machining position. When there are a plurality of vertical sewing machine positions, a vertical sewing wheel is arranged for each of the positions. Then, the control means 80 performs an operation of selectively setting a vertical sewing wheel that actually performs vertical sewing on the basis of the sewing pattern information as a processing position and setting the rest as a retracted position.

  The horizontal sewing machine processing means (OS) 220 is an apparatus that is provided in the OS side processing unit 20 and performs horizontal sewing on the OS side region of the continuous form 100. The horizontal sewing machine processing means (OS) 220 operates under the control of the control means 80 and inputs a horizontal sewing machine operation signal output from the control means 80 to perform vertical sewing. For example, the horizontal sewing machine processing means (OS) 220 can be constituted by a sewing machine cylinder, a receiving cylinder, a servo motor for driving them, and a driver thereof. The sewing machine cylinder is a cylinder in which sewing blades are provided along the cylinder axis direction so that the cutting edge protrudes from the cylinder surface. The receiving cylinder is a cylinder provided with a protruding blade receiving portion for receiving the sewing machine blade (the cutting edge) along the cylinder axis direction of the cylinder surface. If the continuous form 100 exists when the sewing machine blade and the receiving part come close to each other by rotating the sewing machine cylinder and the receiving cylinder synchronously, the continuous form 100 is subjected to horizontal sewing.

  The control means 80 calculates the position of the horizontal sewing machine processing in the continuous form 100 based on the sewing machine pattern information. Further, in the control calculation, the control means 80 calculates an operation signal so that the horizontal sewing is accurately performed at the position of the horizontal sewing, and outputs the operation signal to the servo motor driver. In this control, the control means 80 sets a control target that the position of the horizontal sewing machined portion in the continuous foam 100 and the position of the cutting edge of the sewing machine blade coincide with each other at the moment when the horizontal sewing is performed. . Further, in this control, the control means 8 at the moment when the horizontal sewing is performed at least, the traveling speed of the portion of the horizontal sewing machine in the continuous form 100 and the speed of the rotating surface of the cutting edge of the sewing machine blade in the sewing machine cylinder coincide with each other. It is a control target to do. When the horizontal sewing is not performed, the continuous foam 100 and the sewing blade in the horizontal sewing machine (OS) 22 are separated from each other, and the horizontal sewing machine (OS) 22 prevents the continuous foam 100 from traveling. There is no. A cylindrical shaft can be used as a receiving cylinder for receiving the cutting edge of the sewing machine blade. Moreover, the receiving cylinder which has a blade receiving part may be sufficient.

A vertical sewing machine processing means (GS) 310 is an apparatus that is provided in the GS side processing unit 30 and performs vertical sewing on the GS side region of the continuous foam 100. The vertical sewing machine processing means (GS) 310 is the same as the vertical sewing machine processing means (OS) 210 except that the area to be processed in the continuous form 100 is different.
The horizontal sewing machine processing means (GS) 320 is an apparatus that is provided in the GS side machining unit 30 and performs horizontal sewing on the GS side region of the continuous foam 100. Since the horizontal sewing machine processing means (GS) 320 is the same as the horizontal sewing machine processing means (OS) 220 except that the area to be processed in the continuous form 100 is different, description thereof will be omitted.

The configuration has been described above. Next, the operation in the random sewing machine will be described. FIG. 9 shows a flow chart of the operation process in the random sewing machine. In particular, although not described, the following operation process is performed as an independent sewing process for both the OS-side area and the GS-side area of the continuous form 100.
First, in step S101 (continuous form feeding) in FIG. 9, the sheet feeding unit 10 unwinds the continuous form 100 of the winding body and performs sewing on the OS side processing unit 20 and the GS side processing unit 30 with the continuous form 100. To send. This feeding is normally performed continuously and is continued until the random sewing machine processing is finished (machine stop) in step S109 (end).
Next, in step S102 (travel detection), the travel detection means 50 detects the travel of the continuous form 100 and outputs a travel signal such as the travel speed and travel distance of the continuous form 100. The control means 80 inputs the travel signal. This running detection is normally performed continuously, and continues until the random sewing machine processing ends (machine stop) in step S109 (end).

Next, in step S103 (timing mark detection), the timing mark sensor 60 detects the timing mark 101 printed on each sheet of the continuous form 100 and outputs a mark signal. The control means 80 inputs the mark signal. This timing mark detection is naturally performed intermittently.
Next, in step S104 (bar code detection), the bar code reader 70 reads the sewing instruction bar code 102 in synchronization with the mark signal and the travel signal and outputs the sewing pattern information. As a method of reading in synchronization with the mark signal and the running signal, for example, the following method is applied. The barcode reader 70 can repeatedly perform the barcode reading operation, but outputs a reading error when there is no barcode in the reading area. On the other hand, the control means 80 inputs the mark signal and the running signal, and can calculate the period during which the sewing instruction bar code 102 printed on the continuous form 100 reaches the reading area and exists in that area. The bar code reader 70 outputs the sewing pattern information obtained by reading the sewing instruction bar code 102 during that period.

Next, in step S105 (sewing pattern information input), the controller 80 reads the sewing pattern information read by the barcode reader 7 during a period in which the sewing instruction barcode 102 reaches the reading area of the barcode reader 7 and exists in that area. Enter.
Next, in step S106 (control calculation), the control means 80 performs control calculation based on the sewing pattern information, and generates an operation signal for sewing processing as an operation signal synchronized with the mark signal and the travel signal. As already described, the sewing pattern information is a part of the sewing pattern to which two digits from the 15th digit to the 16th digit are assigned in the sewing machine designation bar code 102. Therefore, based on the sewing pattern information which is a two-digit character string, the control means 80 reads the actual sewing machine form registered in the storage device. That is, the control means 80 acquires the position for performing vertical sewing and the position for performing horizontal sewing on the continuous form 100. Then, the control means 80 selects the vertical sewing wheel provided for machining the vertical sewing machine at that position, operates the corresponding electromagnetic valve to operate the air cylinder, and uses the selected vertical sewing machine wheel as the machining position. An operation signal is output at a predetermined timing. The control means 80 calculates a horizontal sewing operation signal so that the horizontal sewing is accurately performed at the position of the horizontal sewing, and outputs the horizontal sewing operation signal to the driver of the servo motor.

Next, in step S107 (sewing machine processing), each of the vertical sewing machine processing means (OS) 210, the horizontal sewing machine processing means (GS) 220, the vertical sewing machine processing means (OS) 310, and the horizontal sewing machine processing means (GS) 320 includes: Input each operation signal. The sewing machine processing means performs sewing on the continuous form 100 according to the operation signal while the continuous form 100 travels through the OS side processing unit 20 and the GS side processing unit 30.
Next, in step S108 (zigzag folding), the folding portion 40 zigzags the continuous form 100 subjected to random sewing processing to obtain a folded continuous form 200. The perforation at the boundary in each single wafer form, that is, the perforation for zigzag folding, can be performed in the above-described random perforation. Moreover, you may perform the sewing process for the zigzag folding as a process different from a random sewing process.
Next, in step S109 (end?), When not all the parts to be machined in the continuous form 100 have been machined, the process returns to step S101 and the above-described steps are repeated. When all of the sewing machines have been processed, or when an end interrupt input by an operator's operation, etc., or other stop signal input, etc., are received, a series of random sewing processes are terminated. In the process of steps S101 to S108, in the case of a 2UP continuous form, the sewing process for each single sheet form disposed on the left and right sides (GS side and OS side) of the continuous form 100 is completed. Therefore, the process of steps S101 to S108 is repeated by the number of each single sheet form bonded in the continuous form 100.

  The operation has been described above. Next, an example of the sewing machine processing in the continuous form 200 that has been machined by the random sewing machine will be described. An example of the sewing machine processing in the continuous foam 200 subjected to the sewing machine processing by the random sewing machine is shown in FIGS. Assuming that an example of the sewing pattern that is not subjected to random sewing processing is the sewing pattern 1, the sewing pattern that is subjected to random sewing processing starts from the sewing pattern 2.

FIG. 10 is a diagram showing the sewing machine pattern 2. In the sewing machine pattern 2, the same random sewing process is performed on the OS side region and the GS side region. In the area on the OS side, the vertical sewing machine processing is performed at one position of the vertical sewing machine 1, and the horizontal sewing machine processing is performed at three positions of the horizontal sewing machine 1, the horizontal sewing machine 2, and the horizontal sewing machine 3. Further, in the region on the GS side, the vertical sewing process is performed at one position of the vertical sewing machine 3, and the horizontal sewing process is performed at three positions of the horizontal sewing machine 5, the horizontal sewing machine 6, and the horizontal sewing machine 7.
FIG. 11 is a view showing the sewing machine pattern 3. In the sewing machine pattern 3, the same random sewing process is performed on both the OS side area and the GS side area. In the area on the OS side, the vertical sewing machine processing is performed at two positions of the vertical sewing machine 1 and the vertical sewing machine 2, and the horizontal sewing machine processing is performed at three positions of the horizontal sewing machine 1, the horizontal sewing machine 2, and the horizontal sewing machine 3. Further, in the region on the GS side, the vertical sewing machine processing is performed at two locations of the vertical sewing machine 3 and the vertical sewing machine 4, and the horizontal sewing machine processing is performed at the horizontal sewing machine 5, the horizontal sewing machine 6, and the horizontal sewing machine 7.
FIG. 12 is a view showing the sewing machine pattern 4. In this sewing pattern 4, the same random sewing processing is performed on both the OS side region and the GS side region. In the region on the OS side, the vertical sewing machine processing is performed at one position of the vertical sewing machine 1, and the horizontal sewing machine processing is performed at two positions of the horizontal sewing machine 1 and the horizontal sewing machine 2. Further, in the region on the GS side, the vertical sewing process is performed at one position of the vertical sewing machine 3, and the horizontal sewing process is performed at two positions of the horizontal sewing machine 5 and the horizontal sewing machine 6.
FIG. 13 is a view showing the sewing machine pattern 5. In this sewing machine pattern 5, the same random sewing processing is performed on both the OS side region and the GS side region. In the area on the OS side, the vertical sewing machine processing is performed at one position of the vertical sewing machine 1, and the horizontal sewing machine processing is performed at one position of the horizontal sewing machine 4. Further, in the region on the GS side, the vertical sewing machine processing is one place of the vertical sewing machine 3, and the horizontal sewing machine processing is one place of the horizontal sewing machine 8.
FIG. 14 is a view showing the sewing machine pattern 6. In the sewing pattern 6, the same random sewing processing is performed on both the OS side region and the GS side region. In the area on the OS side, the vertical sewing machine has one place of the vertical sewing machine 1 and the horizontal sewing machine has zero place. Further, in the region on the GS side, the vertical sewing machine processing is one place of the vertical sewing machine 3, and the horizontal sewing machine processing is 0 place.

  The example shown in FIGS. 10 to 14 is an example in which the same random sewing machine processing is performed in both the OS side area and the GS side area. However, as is apparent from the configuration of the random sewing machine, A completely different random sewing process can be performed on each of the region and the region on the GS side. Further, the vertical sewing machine is not limited to the vertical sewing machine 1 to the vertical sewing machine 4, and any number of vertical sewing machines at any position can be performed (the upper limit depends on the number of installed vertical sewing wheels). Similarly, the horizontal sewing machine is not limited to the horizontal sewing machine 1 to the horizontal sewing machine 8, and any number of horizontal sewing machines at any position can be performed (the upper limit depends on the number of installed sewing machine cylinders).

It is a figure which shows an example of a structure in the verification apparatus of the random sewing machine processing machine of this invention as a block diagram. It is a flowchart which shows the process of the data processing in the verification apparatus of the random sewing machine processing machine of this invention. It is a figure (the 1) which shows an example of the continuous form which is a process target (original fabric) of a random sewing machine. It is FIG. (The 2) which shows an example of the continuous form which is a process target (original fabric) of a random sewing machine. It is explanatory drawing which shows an example about the content of the barcode (sewing instruction barcode) printed on the continuous form to be processed. It is a figure which shows an example of the display of the log data in the verification apparatus of the random sewing machine processing machine of this invention. It is a figure which shows an example of the printing of log data in the verification apparatus of the random sewing machine processing machine of this invention. It is explanatory drawing which shows an example of the whole structure in a random sewing machine. It is a flowchart which shows the process of the operation | movement in a random sewing machine. It is a figure which shows an example (the 1) of the sewing machine in the continuous form 200 by which the sewing machine process was performed with the random sewing machine. It is a figure which shows an example (the 2) of the sewing process in the continuous form 200 by which the sewing machine process was performed with the random sewing machine. It is a figure which shows an example (the 3) of a sewing process in the continuous form 200 by which the sewing machine process was performed with the random sewing machine. It is a figure which shows an example (the 4) of the sewing process in the continuous form 200 by which the sewing machine process was performed with the random sewing machine. It is a figure which shows an example (the 5) of a sewing machine in the continuous form 200 by which the sewing machine process was performed with the random sewing machine.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Data processing means 21 Longitudinal sewing (OS) machine operation detection means 22 Horizontal sewing (OS) machine movement detection means 31 Vertical sewing (GS) machine movement detection means 32 Horizontal sewing (GS) machine movement detection means 10 Supply Paper part 20 OS side processing part 30 GS side processing part 40 Folding part 100 Winding continuous form 200 Folding continuous form 50 Travel detection means 60 Timing mark sensor 70 Bar code reader 80 Control means 210 Vertical sewing machine processing means (OS)
220 Horizontal sewing machine processing means (OS)
310 Vertical sewing machine processing means (GS)
320 Sewing machine processing means (GS)
101 Timing mark 102 Sewing machine instruction bar code 103 Vertical sewing mark 104 Horizontal sewing mark

Claims (3)

Atypical for a continuous form on which multiple sheets are printed, a timing mark indicating the position of each sheet on the sheet form, and a bar code containing sewing pattern information for each sheet on the sheet form This is a verification device for a random sewing machine that performs the sewing process of
Reading check means for checking the reading of the barcode by the barcode reader;
Format check means for checking the format of the content read by the barcode reader;
Operation signal check means for checking the output of the operation signal of the sewing machine;
Machine operation check means for checking the machine operation of the sewing machine;
Log data generating means for generating log data of the check;
The verification apparatus of the random sewing machine characterized by comprising. The verification apparatus for a random sewing machine according to claim 1, wherein the random sewing machine is
Travel detection means for detecting travel in the continuous form that travels and outputting a travel signal;
A timing mark sensor that detects the timing mark in the running continuous form and outputs a mark signal;
A barcode reader that reads the barcode in synchronization with the mark signal and the traveling signal and outputs sewing pattern information;
Control means for performing a control calculation based on the sewing pattern information and generating an operation signal for the sewing machine in synchronization with the mark signal and the travel signal;
Horizontal sewing machine means for inputting a horizontal sewing machine operation signal as one of the operation signals and performing horizontal sewing on the continuous form;
Vertical sewing machine processing means for inputting a vertical sewing machine operation signal as one of the operation signals and performing vertical sewing on the continuous form;
The verification apparatus of the random sewing machine characterized by comprising. 3. The apparatus for verifying a random sewing machine according to claim 1 or 2, wherein all results output for displaying or printing all of the log data by clearly indicating an OK product (good product) and an NG product (defective product), and NG An apparatus for verifying a random sewing machine, comprising: log data output means for designating either or both of NG product output for displaying or printing only products.

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