JP5347178B2 - Production sequence replanning system, production sequence replanning apparatus and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve the replanning of a production planning order in consideration of a delay vehicle when a vehicle, which does not observe a preliminarily planned production planning order, such as the delay vehicle occurs. <P>SOLUTION: A production order replanning system includes: a vehicle passage detection device 4 for detecting a vehicle input to a correcting operation process; correcting operation requirement time input devices 2A and 2B, to which the requirement time of the correcting operation of the vehicle is input; and a production order replanning device 1. When receiving notification indicating that the vehicle, which is input from the vehicle passage detection device 4 to a correcting operation process, has been detected, the production order replanning device 1 replans the vehicle production order in an assembly process, based on the correcting operation requirement time input from the correcting operation requirement time input devices 2A and 2B. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a production sequence re-planning system and a production sequence re-plan that execute re-planning of a production sequence when a vehicle that cannot comply with the planned production plan sequence occurs in a multi-mix production line. The present invention relates to an apparatus and a method.

In automobile production lines, etc., multi-mix mixed production is possible, in which multiple models can be produced on one line. In such multi-product mixed production, the workload of workers varies depending on the vehicle type. Therefore, in order to carry out efficient production, a production plan has been made with the aim of leveling the entire work load based on different work loads for each vehicle type. For example, a vehicle type with a high work load, such as a four-wheel drive (4WD), is planned so as to take into consideration a constraint condition such that three or more vehicles are not continuously put on the line.
In general, an automobile is produced through a process such as a body process, a painting process, and an assembly process in order, and operations are performed based on a planned vehicle production sequence throughout these processes. Therefore, it is important to observe the order of production plans.

In parts inventory management of automobile production lines, parts are supplied in synchronization with production plans for efficient parts supply. For example, for an assembling process for assembling parts to the vehicle body, the assembling parts used in the assembling process are conveyed to the assembly line in synchronization with the production plan. For this reason, when the vehicle bodies input from the previous process are not in the planned order, it is necessary to separately manage the assembly parts that have already been supplied to the assembly line. For example, if quality defects such as coating unevenness occur in the painting process and correction work is required, it becomes impossible to comply with the production plan order, and it is not possible to enter the vehicle according to the production plan order in the next assembly process. There is a case. In such a case, the vehicle after the vehicle that performs the correction work is put into the assembly process first, and the vehicle that performs the correction work is delayed, which also affects parts management in the assembly process.
As described above, particularly in the assembly process, it is strongly demanded to observe the order of the production plan because assembly parts are supplied to the assembly line based on the planned production plan.

  Conventionally, in such a case, the situation of the delayed vehicle that the worker should perform correction work is managed and the production plan order is adjusted. Specifically, in the automobile production line, a storage with a plurality of parallel lines was provided between the painting process and the assembly process, and the order in which the vehicles were transported from the storage to the assembly process was adjusted, resulting in a collapse in the painting process. The production plan order was adjusted.

  Patent Document 1 discloses an example of an input product determination method in a multi-product mixed production line using a storage carry-out plan determination logic that takes into account the leveling of an assembly work load in an assembly process.

JP-A-62-74559

  In the prior art described in Patent Document 1, a plurality of constraint conditions are weighted on the basis of the production plan order, and the optimum storage carry-out order is determined by calculating the weight. Restrictions include the number of vehicle carry-out intervals (restrictions that require several different vehicle types to be spaced between the same vehicle type, and a gap), and the continuous number restriction (upper limit on the number of vehicles that can be carried out continuously from the same vehicle type). ), Inventory parts allocation, offline deadline (deadline for vehicle production to be completed), etc.

  However, since the conventional storage carry-out order gradually determines the carry-out vehicles in accordance with the vehicle carry-in to the storage, the carry-out order is determined up to several units ahead. For this reason, it has not been possible to determine to what extent a vehicle delayed from the production plan order is carried out from the production plan order.

  On the other hand, when a delayed vehicle is brought into the storage, the lane has a superior carry-out lane in which the distance to the lane carry-out is short, that is, there are few registered vehicles for the purpose of carrying out the vehicle earlier than a general vehicle (a vehicle not delayed). We were carrying in to.

However, in the conventional storage carry-out plan determination logic, there has been no logic for preferentially carrying out the delayed vehicle from the storage because it has not been considered such as processing the delayed vehicle separately from a general vehicle. For this reason, there is a possibility that the delayed vehicle is not taken out of storage until the offline deadline. When the delayed vehicle could not be taken out and the offline deadline was reached, it was necessary to forcibly carry it out to the assembly process.
As a result, the automatic unloading system that automatically unloads the vehicle from the storage to the assembly process must be stopped, and the constraint conditions such as the number of vehicle unloading intervals and the number of continuous units must be ignored and entered into the assembly process. .
Thus, conventionally, the occurrence of a delayed vehicle has increased the burden on the worker in the assembly process, which has led to a reduction in work efficiency of the entire production process and hindered efficiency.

In addition, in the assembly process, since the delay time of the vehicle cannot be predicted, the worker puts the assembled part of the vehicle that has been supplied to the line in synchronization with the production plan order, outside the line, Needed to be managed individually. Furthermore, a space for placing the parts was also required.
As described above, the occurrence of the delayed vehicle affects the transportation plan of the assembly parts supplied to the line and the management of the parts already supplied to the line side, thereby increasing the load on the worker. Under these circumstances, in order to improve the efficiency of vehicle production, the vehicle production sequence in the assembly process is re-planned when a delayed vehicle occurs, and the vehicle is transferred from the storage to the assembly process line based on the re-planned vehicle production sequence. It was hoped that this was carried out.

  The present invention has been made in view of such problems, and when a vehicle such as a delayed vehicle that cannot comply with a pre-planned production plan sequence is generated, the production plan sequence considering the delayed vehicle is set. Allow replanning. Accordingly, it is an object to minimize the influence on the vehicle production in the subsequent processes and improve the efficiency of the vehicle production.

  The present invention has a line for producing a plurality of vehicle types on the same line, and in a vehicle production line that produces vehicles by a plurality of processes based on a vehicle production order that is planned in advance, according to a vehicle production order that is planned in advance. This is a production sequence re-planning system that re-plans the vehicle production sequence when it becomes impossible to input a vehicle to the vehicle. The vehicle production line of the present invention includes a process for performing a quality inspection between a painting process for performing work on the vehicle body and an assembly process for assembling the parts to the vehicle body, and a vehicle that has been determined to be defective as a result of the quality inspection. There is a step of performing correction work on the machine. In addition, a storage process having a plurality of parallel lanes for temporarily holding the vehicle is provided before the vehicle is put into the assembly process from the joining process of the painting process and the correction work process. In the vehicle production line, the present invention re-plans the vehicle production order in the assembly process when the vehicle cannot be put into the assembly process according to the vehicle production order planned in advance in order to perform the correction work. It is a sequence rescheduling system. The production sequence re-planning system according to the present invention includes a vehicle passage detection device that detects a vehicle that is input to the correction work process, and a correction work required time in which the time required for the correction work of the vehicle input to the correction work process is input. An input device. When receiving a notification from the vehicle passage detection device that a vehicle to be input to the correction work process has been detected, the vehicle production sequence in the assembly process is determined based on the correction work time input from the correction work time input device. A production sequence replanning device for replanning.

  The production sequence re-planning apparatus according to the present invention stores a vehicle passage time interval information storage unit for storing a vehicle passage time interval defined for each passage point provided in the production line, and a vehicle production order of the painting process. A painting process vehicle production sequence storage unit, and a correction work required time storage unit that stores the correction work required time input from the correction work required time input device. Furthermore, a corrected vehicle line re-insertion position prediction unit for predicting a re-input position of the vehicle performing the correction work on the production line based on the vehicle passage time interval, the painting process vehicle production order, and the time required for the correction operation, and the correction vehicle Based on the re-input position of the vehicle that has performed the correction work predicted by the line re-input position prediction unit and the painting process vehicle production order, the storage carry-in order planning unit that plans the order to carry into the storage process, and the planned storage carry-in order And an assembly process production plan order planning unit for re-planning the production order of the assembly process.

ADVANTAGE OF THE INVENTION According to this invention, when a delay vehicle generate | occur | produces, the production plan order of the assembly process which carries out a delay vehicle with priority from a storage can be re-planned. As a result, it is possible to automatically carry out the storage in consideration of the delayed vehicle, so that the burden on the worker can be reduced. Further, since the delayed vehicle can be carried out earlier than in the past, the residence time of the assembled components of the delayed vehicle in the assembling process can be shortened, and the load for the worker to manage can be reduced. In addition, the space for placing in-process parts can be reduced.
As described above, according to the present invention, even when a delayed vehicle occurs, the influence on vehicle production can be minimized, and the working efficiency can be improved as compared with the prior art.

It is explanatory drawing which shows the outline | summary of the production sequence re-planning apparatus by one embodiment of this invention, and the whole vehicle production process. It is explanatory drawing which showed the relationship and the structural example of the production order re-planning apparatus by one embodiment of this invention, and a vehicle production line. It is explanatory drawing which shows the example of the storage by one embodiment of this invention. It is a block diagram which shows the structural example of the production order rescheduling system by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the vehicle passage time interval information storage part by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the painting process vehicle production order memory | storage part by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the storage carrying-in plan order storage part by one embodiment of this invention. It is explanatory drawing which shows the data structural example of the storage vehicle enrollment status memory | storage part by one embodiment of this invention. It is explanatory drawing which shows the example of a data structure of the assembly process production plan order storage part by one embodiment of this invention. It is a flowchart showing the example of a correction vehicle line insertion position prediction process by one embodiment of this invention. It is a flowchart showing the example of a storage carrying-in order plan process by one embodiment of this invention. It is a flowchart showing the example of an assembly process production plan order plan process by one embodiment of this invention. It is explanatory drawing which shows the vehicle enrollment situation example of the storage at the time of implementation of the correction work with respect to the vehicle o by one embodiment of this invention being determined. It is explanatory drawing which shows the vehicle registration status example of the storage in case the correction vehicle o by one embodiment of this invention is the head of a delay vehicle carrying-in lane. It is explanatory drawing which shows the vehicle registration status example of the storage at the time of the correction vehicle o by one embodiment of this invention having been determined as a carrying-out vehicle. It is a block diagram which shows the structural example by other embodiment of this invention. It is a block diagram which shows the structural example by further another embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the present invention, it is assumed that the vehicle is provided with an ID storage device such as RFID (Radio Frequency Identification) or a barcode in order to identify and identify the vehicle.

FIG. 1 shows an outline of a production order re-planning apparatus 1 and an entire vehicle production process according to an embodiment of the present invention.
A vehicle such as an automobile is generally produced through a vehicle body process 71, a painting process 72, and an assembly process 76. Further, the quality of the vehicle that has finished the painting process 72 is checked in the inspection process 73. As a result of the inspection, the vehicle having no quality problem moves to the next process as it is. A vehicle that is judged to be of poor quality (such as uneven color) by inspection moves to the correction step 77 and is subjected to correction work. After the correction work is completed, the corrected vehicle is reintroduced into the normal production line at the merging step 74. At this time, the modified vehicle is re-entered on the line after a time required for the correction, so that the vehicle is introduced into a position different from the originally planned production order.

  The vehicle that has passed through the merging step 74 is carried into a storage step 75 in which a plurality of lanes for temporarily waiting the vehicle are arranged in parallel. In this example, when the corrected vehicle in which the delay has occurred is detected by the reading device 3 of the ID storage device or the like, based on the correction work required time input from the correction work required time input device 2 for inputting the time required for the correction work, The production order replanning apparatus 1 replans the production order in the next assembly process 76. Then, based on the re-planned production order, the order of the vehicles is adjusted in the storage process 75 and is carried out to the assembly process 76 which is the next process.

  FIG. 2 shows the relationship between the production sequence rescheduling apparatus 1 and the vehicle production line according to an embodiment of the present invention.

  The vehicle production line is provided with a line corresponding to each process, and an operator performs the work of each process on the vehicle flowing on the line. The production line is provided with a plurality of passing points, and includes a reading device that reads information of an ID storage device such as an RFID attached to the vehicle, thereby detecting the vehicle that has passed the point and passing the vehicle. It is configured to collect information such as intervals.

  As a result of passing through the inspection line 703 corresponding to the inspection process, the vehicle determined to be of poor quality moves to the correction line 707. The passage point reading device 3 provided in front of the correction line 707 reads the ID information of the vehicle moved to the correction line 707 and inputs the information to the vehicle passage detection / ID reading device 4. Then, the vehicle passage detection / ID reading device 4 notifies the production sequence re-planning device 1 of information such as the generation of the corrected vehicle and the vehicle ID of the corrected vehicle based on the input information.

  Then, the worker estimates the time required for the correction work based on the correction content required for the correction vehicle, and inputs the time required for the correction work from the input terminal. In FIG. 2, corrective work required time input devices 2A and 2B are provided in the vicinity of the body line 701 and the paint line 702, and after the work on each line is completed, the corrective work required time for the vehicle determined to be required by the worker is input. To do. As described above, in addition to the configuration in which the correction work required time input device is provided for each line of each work process, the correction work required time input device is provided in the vicinity of the inspection line 703. For example, the time required for the correction work may be input.

Further, the vehicle production line is provided with an automatic carry-out device 5 that automatically carries out vehicles one by one from a plurality of lanes of the storage 705 to the assembly line 706. In the production order replanning apparatus 1 according to the embodiment of the present invention, the production order in the assembly line 706 is replanned based on the time required for the correction work for the corrected vehicle, and the vehicle is stored from the storage 705 based on the production order. The automatic unloader 5 is instructed to unload.
In addition, a display device 6 for presenting the vehicle production order of the assembly line re-planned by the production order re-planning apparatus 1 to the worker of the assembly line 706 may be provided. The display device 6 may be configured to display a screen on a display such as a personal computer, or to print on a form or the like. As a result, when the order of the vehicles carried out from the storage 705 is changed from the original plan, the worker of the assembly line 706 can grasp the order in advance, so that a delayed vehicle due to correction work occurs. However, it does not hinder the efficiency of work.

  FIG. 3 shows an example of the storage 705 according to an embodiment of the present invention. The storage 705 is provided between the assembly point 704 between the painting line 702 and the correction line 707 and the assembly line 706 in order to adjust the deviation of the assembly process production plan order generated by the correction work. The storage 705 includes a plurality of normal vehicle carry-in lanes 51 to 54 that carry in a vehicle that has no correction work and is in accordance with a production plan sequence planned in advance. Further, one or more delayed vehicle carry-in lanes 55 for carrying only delayed vehicles that are vehicles that are delayed from the production planning order planned in advance due to the occurrence of correction work or the like (that can predict the delay time of the vehicles). Prepare. Also, there is a single unloadable vehicle loading lane 56 for loading only unloadable vehicles that are vehicles that cannot be unloaded into the assembly process due to lack of assembly parts inventory (the vehicle cannot predict the delay time). Have more than one. Further, a forward lane 57 for moving the leading vehicle in the lane to the tail of the lane is provided for adjusting the order of loading.

  Here, there is one line from the joining point 704 of the painting line 702 and the correction line 707 to the storage carry-in entrance, and after passing through the join point, the order of the vehicles is changed until the storage is carried in. Absent. In the storage 705 of this example, the vehicle production order is adjusted using a plurality of carry-in lanes so that the vehicle order is the same as the production order in the assembly line 706 re-planned by the production order re-planning apparatus 1. The production order re-planning apparatus 1 determines which lane among a plurality of lanes the vehicle carried into the storage carry-in port is to be carried in, and simulates the situation of the vehicle in each lane. Then, based on the vehicle storage status of the simulated storage, the vehicle to be carried out to the assembly line 706 is determined, and the production order of the vehicle is adjusted in the storage 705 so that the determined order is obtained. Take it out.

  FIG. 4 is a configuration diagram showing an example of the internal configuration of the production order rescheduling apparatus 1 which is an embodiment of the present invention. In the production sequence rescheduling apparatus 1 of this example, for example, a program for performing processing corresponding to an electronic computer is mounted, and realized by using an arithmetic processing function, a storage function, and the like included in the electronic computer.

  The production sequence re-planning apparatus 1 includes a correction work required time input unit 11, a corrected vehicle line re-insertion position prediction unit 12, a storage carry-in sequence planning unit 13, and an assembly process production plan sequence planning unit 14 as processing units. Further, as a storage unit for storing information used in each processing unit, a correction work required time storage unit 15, a vehicle transit time interval information storage unit 16, a painting process vehicle production sequence storage unit 17, a storage carry-in plan sequence storage unit 18, a storage A vehicle enrollment status storage unit 19 and an assembly process production plan order storage unit 20 are provided.

  Next, processing contents of each processing unit and information used in each processing unit will be described.

  The correction work required time input unit 11 inputs the correction work required time of the corrected vehicle input by the worker via the correction work required time input devices 2 </ b> A and 2 </ b> B, and stores it in the correction work required time storage unit 15. The correction work required time storage unit 15 stores an ID for identifying a vehicle performing the correction work and information on the time required for the correction work of the vehicle in association with each other.

The corrected vehicle line re-insertion position prediction unit 12 predicts a position at which the corrected vehicle is re-input to the normal production line after the correction work (a vehicle that comes ahead of the corrected vehicle when the corrected vehicle is re-input). The corrected vehicle line re-insertion position prediction unit 12 starts the process upon receiving a notification of the generation of a corrected vehicle from the vehicle passage detection / ID reading device 4.
In the process of predicting the re-input position by the corrected vehicle line re-input position prediction unit 12, the correction work required time storage unit 15, the vehicle transit time interval information storage unit 16, and the painting process vehicle production order storage unit 17 are referred to. . The vehicle passage time interval information storage unit 16 is shown in FIG. 5, and the painting process vehicle production order storage unit 17 is shown in FIG.

  The storage carry-in order planning unit 13 plans the storage carry-in order from the corrected vehicle re-injection position obtained by the corrected vehicle line re-injection position prediction unit 12, and stores the created storage carry-in plan order information as the storage carry-in plan. Stored in the order storage unit 18. The storage carry-in plan order storage unit 18 is shown in FIG.

The assembly process production plan order planning unit 14 performs an assembly process from the storage based on the storage carry-in plan order obtained by the storage carry-in order plan unit 13 and the storage vehicle enrollment status indicating the position information of the vehicle in each lane in the storage. Create the order of vehicle delivery to The created delivery order to the assembly process is stored in the assembly process production plan order storage unit 20 as an assembly process production plan order.
The storage vehicle enrollment status storage unit 19 stores the storage vehicle enrollment status required when the assembly process production plan sequence planning unit 14 creates the assembly process production plan sequence (that is, the order of carrying out the vehicle from the storage to the assembly process). To store. The assembly process production plan order planning unit 14 sequentially simulates the storage vehicle enrollment status along with the planning process, and executes the process while updating the storage vehicle enrollment status storage unit 19 based on the simulated information. The storage vehicle enrollment status storage unit 19 is shown in FIG. 8, and the assembly process production plan order storage unit 20 is shown in FIG.

  Next, a data configuration example of the information storage unit referred to in each processing unit will be described.

  FIG. 5 shows a data configuration example of the vehicle passage time interval information storage unit 16. The vehicle passage time interval information stored in the vehicle passage time interval information storage unit 16 predefines a time interval through which the vehicle should pass for each passage point provided in the production line. In the example of FIG. 5, data is constituted by a passing point 161 for setting the name of a point provided on the production line and a passing time interval 162 of the vehicle.

  FIG. 6 shows a data configuration example of the painting process vehicle production order storage unit 17. The painting process vehicle production order stored in the painting process vehicle production order storage unit 17 records the order in which vehicles are produced in the painting process. In the example of FIG. 6, data is constituted by a vehicle 172 that is identification information such as a vehicle ID corresponding to the production order 171.

  FIG. 7 shows a data configuration example of the storage carry-in plan order storage unit 18. The storage carry-in plan order stored in the storage carry-in plan order storage unit 18 records the order of vehicles carried into the storage carry-in port. In the example of FIG. 7, data is configured by a vehicle 182 that is identification information such as a vehicle ID corresponding to the carry-in order 181.

  FIG. 8 shows a data configuration example of the storage vehicle enrollment status storage unit 19. The storage vehicle enrollment status stored in the storage vehicle enrollment status storage unit 19 is a record of the vehicle enrolled in each lane of the storage and the order in that lane. In the example of FIG. 8, data is configured by a lane 191 that is data for identifying a lane, an in-lane order 192, and a vehicle 193 that is identification information such as a vehicle ID.

  FIG. 9 shows a data configuration example of the assembly process production plan order storage unit 20. The assembly process production plan order stored in the assembly process production plan order storage unit 20 is a record of the vehicle production plan order in the assembly process, that is, the vehicle delivery order from the storage to the assembly process. In the example of FIG. 9, data is configured by a vehicle 202 that is identification information such as a vehicle ID corresponding to the storage carry-out order 201.

  Next, processing examples performed by each processing unit will be described.

  FIG. 10 is a flowchart illustrating an example of a corrected vehicle line input position prediction process by the corrected vehicle line re-input position prediction unit 12. This process is started when a vehicle that has moved to the correction line 707 is generated and the vehicle passing detection / ID reading device 4 notifies the production sequence rescheduling device 1 of the generation of the corrected vehicle and the vehicle ID of the corrected vehicle. The

First, the estimated required time required for the correction work of the corrected vehicle is acquired from the correction work required time storage unit 15 (step S101). Next, the passage time interval at the junction is acquired from the vehicle passage time interval information storage unit 16 (step S102). Then, the number of vehicles passing through the junction is obtained while the corrected vehicle is performing the correction work by dividing the acquired correction work estimated required time by the vehicle passage time interval (step S103).
Then, from the obtained number of passing vehicles and the vehicle production order of the painting process acquired from the painting process vehicle production order storage unit 17, the position where the corrected vehicle is re-introduced to the normal line at the junction, that is, re-enter the normal line The vehicle in front of the corrected vehicle when it is done (which vehicle will be reintroduced after) is determined (step S104).

  FIG. 11 is a flowchart illustrating an example of a storage carry-in order planning process performed by the storage carry-in order planning unit 13. This process is started after the process of the corrected vehicle line re-insertion position prediction unit 12 is completed.

  First, the corrected vehicle line re-input position prediction unit 12 obtains the re-input position of the corrected vehicle to the production line (step S111), and further acquires the vehicle production order of the painting process (step S112). Next, a storage carry-in order plan is created from the re-input position of the corrected vehicle to the production line and the painting process vehicle production order (step S113). The storage loading sequence is the same as the vehicle passing sequence at the junction. Therefore, the vehicle passing order at the merging point where the order of the vehicles before and after the modified vehicle is rearranged based on the merging position of the modified vehicle is obtained from the re-input position of the modified vehicle and the painting process vehicle production order, and is stored in the storage The planning order. The created storage carry-in order plan is stored in the storage carry-in plan order storage unit 18 (step S114).

FIG. 12 is a flowchart showing an example of an assembly process production plan order planning process by the assembly process production plan order planning unit 14.
In this process, the vehicle carry-out order from the storage to the assembly process is created based on the storage carry-in plan order obtained by the storage carry-in order planning unit 13 and the enrollment status of the vehicle in each lane in the storage. In this example, the order of carrying out the vehicles from the created storage to the assembly process is the assembly process production plan order. In this example, when the assembly process production plan order is created, the order of loading / unloading vehicles to / from the storage is simulated. As a precondition, storage loading and unloading are performed alternately one by one. And The storage loading / unloading simulation is performed using existing loading lane determination logic / unloading plan determination logic. The existing carry-in / carry-out logic weights a plurality of constraint conditions and determines the optimum storage carry-in / carry-out order by calculating the weight.

This process is started after the notification of the generation of the corrected vehicle is received and the process of the storage carry-in order planning unit 13 is completed. First, the storage vehicle enrollment status storage unit 19 stores the storage enrollment status when the corrected vehicle is generated as an initial value (step S121). Next, the parameter S _in representing the storage carry-in plan order of the vehicle that is the storage carry-in target is initialized (step S122), and the parameter S _out representing the assembly process production plan order is initialized (step S123).
First, based on the existing storage carry-out plan determination logic, a vehicle carry-out plan in the vehicle enrollment status of the storage stored in the storage vehicle enrollment status storage unit 19 is created (step S124). Here, the order of vehicles to be carried out from the storage is planned in consideration of each constraint condition based on the existing storage carry-out plan decision logic. Note that the number of vehicles that create the carry-out plan in one process is a predetermined number.

  Next, it is determined whether the corrected vehicle can be taken out from the storage. In the storage carry-out in this example, the corrected vehicle is handled preferentially. Therefore, if the corrected vehicle can be carried out, the corrected vehicle is carried out with the highest priority separately from the carry-out plan determined in step S124. For this purpose, as a determination as to whether or not the corrected vehicle can be taken out of storage, it is first determined whether or not the corrected vehicle is at the head of the delayed vehicle entry lane (step S125). As a result of the determination, if the corrected vehicle is at the head of the delayed vehicle carry-in lane, it is determined whether carrying out of the corrected vehicle violates the carry-out restriction (step S126). Here, the carry-out restrictions are set in consideration of the leveling of the workload in the assembly process and parts inventory management in order to improve the efficiency of vehicle production. There are inventory parts allocation, offline deadline, etc.

As a result of the determination in step S126, when the corrected vehicle is not violated, the corrected vehicle can be carried out, so that the corrected vehicle is determined as a carry-out vehicle (step S127). Then, the corrected vehicle is stored at the position of assembly process production plan order = _{Sout in} the assembly process production plan order storage unit 20 (step S128), and the assembly process production plan order planning process is terminated.

If it is determined in step S125 that the corrected vehicle is not at the head of the delay lane, and if it is determined in step S126 that the corrected vehicle is out of compliance with the carry-out restriction, the carry-out plan already determined in step S124 is The leading vehicle is determined as a carry-out vehicle (step S129). And a carrying-out vehicle is stored in the position of assembly process production plan order = _Sout of the assembly process production plan order plan memory | storage part 20 (step S130).
Subsequently, the assembly process production plan order: the values of the S _out 1 to increase (step S131). Then, the storage vehicle enrollment status is updated to the storage vehicle enrollment status after the vehicle is carried out (step S132). Specifically, the information about the unloading vehicle is deleted from the storage vehicle enrollment status data, and the other lanes registered in the lane where the unloading vehicle is registered are reduced and stored in order in the lane.

Next, the storage carry- _in lane of the vehicle with the storage carry-out plan order = Sin is determined based on the existing storage carry-in lane determination logic (step S133). Then, the storage vehicle enrollment status is updated to the storage vehicle enrollment status after the vehicle is carried into the determined lane (step S134). Specifically, the lane determined as the carry-in lane is set for the carry-in vehicle, and a value obtained by adding 1 to the end of the carry-in lane is set as the intra-lane order, and stored in the storage vehicle enrollment status storage unit 19. .
The storage loading planning sequences: the value of S _in 1 increases (step S135). Then, the process returns to step S124, the process of determining the next storage carry-out vehicle is executed based on the updated storage vehicle enrollment status, and the process is repeated until it is determined that the corrected vehicle can be carried out.

  Thereby, in this invention, when it detects that the correction vehicle generate | occur | produced, the production plan order in the assembly process of the vehicle can be re-planned. Further, when determining a vehicle to be carried out from the storage, it is possible to plan to carry out the modified vehicle with priority, so that the delay time of the modified vehicle can be shortened compared to the conventional case.

  Next, an example of assembly process production plan order planning processing by the production order re-planning apparatus of the present invention will be described using a specific vehicle example.

  Here, the vehicle production order in the painting process is as shown in the painting process vehicle production order example shown in FIG. 6, and vehicles from vehicles a to z and A to Z have finished the painting process or are in production. And Here, a case where the vehicle o is judged to be defective in quality by the inspection process and correction work for 20 minutes is required will be described as an example.

FIG. 13 shows the vehicle enrollment status of the storage at the time when execution of the correction work on the vehicle o is determined. At this point, the vehicles a to m in the painting process vehicle production order are in the storage. In FIG. 13, a rectangle located on each lane represents one vehicle. In the vehicle notation described in the rectangle, the alphabet represents a vehicle ID, and the number on the right of the underbar is currently registered in the storage. It shows the storage carry-out plan order in the vehicle that is. A vehicle whose storage carry-out plan order number is “???” indicates that the carry-out order has not yet been determined. The numbers in parentheses indicate the order of importing into the storage. For example, “c_2 (3)” means that the vehicle c is planned to be carried in for the third time and storage carried out for the second time. Note that (F) lane is the unloadable vehicle carry-in lane 56, and the vehicles of “xxxx” and “yyyy” who are registered in this lane are not subject to the assembly process production plan sequence planning process according to this example. .
Here, the storage vehicle enrollment situation shown in FIG. 13 corresponds to the storage vehicle enrollment situation example shown in FIG.

  When the correction work for the vehicle o occurs, first, a corrected vehicle line input position prediction process by the corrected vehicle line re-input position prediction unit 12 is executed. First, the correction work of the vehicle o is estimated to be 20 minutes, and from the vehicle passage time interval information shown in FIG. 5, the vehicle passage time interval at the junction is 1 (minute / unit). It can be seen that there are 20 vehicles passing through the merge point while performing the correction work.

  In this example, the inspection line and the merging point are considered to be close, and the time taken from the start of the correction work to the merging to the normal line is only the correction work time, and the traveling time from the correction line to the merging point is not considered. Thereby, after the correction vehicle o moves to the correction line, it is considered that 20 vehicles that have passed through the line immediately after the vehicle o first pass the junction. Then, as a result of the corrected vehicle line input position prediction processing, the corrected vehicle line input position is set after 20 vehicles after the vehicle o based on the painting process vehicle production sequence example shown in FIG.

  Next, the storage carry-in order planning process by the storage carry-in order planning unit 13 is executed. Here, the vehicle o is taken out from the painting process vehicle production order, the subsequent vehicles are packed one by one, the order in which the vehicle o is inserted behind the vehicle J is created, and the storage loading plan order is set. The created storage carry-in plan order corresponds to the storage carry-in plan order example shown in FIG.

  Next, an assembly process production plan order planning process by the assembly process production plan order planning unit 14 is executed. First, an unloading plan is made based on the storage vehicle enrollment status based on the storage unloading plan decision logic. Here, it is assumed that the order of carrying out five vehicles is planned by the storage carry-out plan decision logic. In the example of FIG. 13, a plan for carrying out vehicle a, vehicle c, vehicle b, vehicle d, and vehicle e in that order is made. In the assembly process production plan order planning process, after the first vehicle in the carry-out plan is carried out, the storage carry-in lane decision logic is determined for the next vehicle that is planned to be carried in the storage carry-in plan sequence shown in FIG. Determine the loading lane and carry in the vehicle. This process of simulating unloading / loading is repeated until the corrected vehicle o can be unloaded.

  FIG. 14 shows the storage vehicle enrollment status when the modified vehicle o is at the head of the delayed vehicle carry-in lane (e) and does not violate the carry-out restrictions. In FIG. 14, the vehicles a to l, m to z, and A to E that have already been carried into the storage prior to the corrected vehicle o in the storage carry-in plan order have been carried out, and vehicles F, G, The case where the carrying-out was planned in order of the vehicle H, the vehicle I, and the vehicle J is represented. Here, when it is determined in the assembly process production plan sequence planning process that the corrected vehicle o can be carried out, the corrected vehicle o is determined as the carry-out vehicle in order to carry out the correction vehicle o with the highest priority.

  FIG. 15 shows a state in which the corrected vehicle o is determined as a carry-out vehicle. FIG. 15 shows that the carry-out order of the corrected vehicle o is determined to be 31.

  As a result of the above processing, the vehicle order in which storage unloading is performed from the time when the correction work is performed on the vehicle o until the unloading of the corrected vehicle o from the storage is determined is the assembly process production plan order. To do. In this way, the planned assembly process production plan order corresponds to the assembly process production plan order example shown in FIG.

  In this way, a re-plan of the production plan order of the assembly process can be created at the start of the correction work for a vehicle that is delayed from the production plan order due to the correction work that has occurred in the painting process or the like. As a result, since the export plan from the storage of the modified vehicle to the assembly process is made in advance, systematic parts inventory management and supply of assembly parts in the assembly process can be performed, reducing the burden on workers. be able to.

  Another embodiment of the present invention is shown in FIG. 16, components corresponding to the configuration example of the production order re-planning system according to the present invention described in FIG. 4 are denoted by the same reference numerals, and the description thereof is omitted.

In the configuration of FIG. 4, for a vehicle that has been determined to require correction work as a result of the inspection, the worker directly determines the condition of the vehicle and inputs the time required for the correction work by the worker. Input was performed via the devices 2A and 2B.
On the other hand, in FIG. 16, the monitoring device 8 including a camera for monitoring a vehicle moving from the inspection line 703 to the correction line 707 and information such as image information are input from the monitoring device 8, and the worker is based on the information. A vehicle state input device 91 for inputting the vehicle state is provided. Further, the production order re-planning system 1 is provided with a correction work required time estimation unit 21 and a correction work time data storage unit 22.

In the present embodiment, the worker determines the state of the vehicle by looking at the image of the vehicle displayed on the input / output device 92 connected to the vehicle state input device 91, and inputs the vehicle state. For example, the vehicle state is determined by dividing the level of quality of the painting performed in the painting process into a plurality of levels, and there are minor defects such as uneven color (A), while there are defects such as uneven color. It is determined that the degree of defect (B) or the degree of defect such as uneven color (C) is remarkable. Further, the color unevenness area, the number of color unevenness, and the like may be input.
The vehicle state input by the worker is input from the vehicle state input device 91 to the correction work required time estimation unit 21 of the production sequence rescheduling system 1. The correction work required time estimation unit 21 refers to the correction work time data storage unit 22 defining the vehicle state and the correction work required time corresponding to the state, and performs the correction work based on the input vehicle state of the correction vehicle. The required time is estimated and stored in the correction work required time storage unit 15. Subsequent operations are the same as those in FIG. In the correction work time data storage unit 22, for example, work time is defined as 5 minutes for A, 10 minutes for B, and 20 minutes for C according to the degree of color unevenness.

  By configuring in this way, the worker only needs to determine the state of the vehicle, and the work burden can be reduced. In addition, in order to estimate the time required for the correction work comprehensively by judging the state of the vehicle, it is necessary to arrange workers with knowledge and experience for that purpose. Need only be able to determine the state of the vehicle.

  FIG. 17 shows still another embodiment of the present invention. In FIG. 17, components corresponding to the configuration example of the production order re-planning system according to the present invention described with reference to FIG.

  In FIG. 17, similar to the configuration of FIG. 16, the production sequence re-planning system 1 includes the correction work required time estimation unit 21 that estimates the required time for the correction work from the vehicle state, and the correction work required time corresponding to the vehicle state. A defined correction work time data storage unit 22 is provided. In FIG. 17, a monitoring device 8 including a camera for monitoring a vehicle moving from the inspection line 703 to the correction line 707, and a vehicle state in which information such as image information is input from the monitoring device 8 and the vehicle state is automatically determined. A determination device 9 is provided. The vehicle state determination device 9 performs an image analysis process based on the vehicle image information captured by the monitoring device 8 and determines, for example, the degree of color unevenness of the vehicle paint. The image analysis process performed by the vehicle state determination device 9 is, for example, a process of comparing pixels of a normal painted vehicle image and a corrected vehicle image and calculating the difference. And the grade of a vehicle state is determined based on the value of the difference. The vehicle state determined by the vehicle state determination device 9 is input to the correction work required time estimation unit 21 of the production order re-planning system 1, and the subsequent processing is the same as the configuration of FIG.

  With this configuration, since the vehicle state is automatically determined by the vehicle state determination device 9, it is not necessary for the worker to determine the state of the vehicle, and the load on the worker can be further reduced. it can.

  DESCRIPTION OF SYMBOLS 1 ... Production order rescheduling device 2, 2A, 2B ... Correction work time input device, 3 ... Reading device, 4 ... Vehicle passage detection / ID reading device, 5 ... Automatic carry-out device, 6 ... Display device, 8 ... Monitoring 9 ... Vehicle state determination device, 91 ... Vehicle state input device, 92 ... Input / output device, 11 ... Corrected work required time input unit, 12 ... Corrected vehicle line re-insertion position prediction unit, 13 ... Storage loading order plan unit, DESCRIPTION OF SYMBOLS 14 ... Assembly process production plan order plan part, 15 ... Correction work required time memory | storage part, 16 ... Vehicle passage time interval information storage part, 17 ... Painting process vehicle production order memory part, 18 ... Storage carrying-in plan order memory part, 19 ... Storage vehicle enrollment status storage unit, 20 ... assembly process production plan order storage unit, 21 ... correction work required time estimation unit, 22 ... correction work time data storage unit, 51 to 54 ... normal vehicle carry-in lane, 55 ... slow Vehicle carry-in lane, 56: Unloadable vehicle carry-in lane, 57: Forwarding lane, 71 ... Car body process, 72 ... Painting process, 73 ... Inspection process, 74 ... Merge process, 75 ... Storage process, 76 ... Assembly process, 77 ... Modification Process, 701 ... Body line, 702 ... Paint line, 703 ... Inspection line, 704 ... Junction point, 705 ... Storage, 706 ... Assembly line, 707 ... Correction line

Claims (8)

In a vehicle production line that has a line for producing a plurality of vehicle types on the same line and produces vehicles by a plurality of processes based on a vehicle production order that is planned in advance, a painting process for painting a vehicle body and parts for the vehicle body A step of performing a quality inspection between the assembly steps to be assembled, a correction operation step of performing a correction operation on a vehicle determined as a quality defect as a result of the quality inspection , the coating step and the correction operation step confluence before turning the vehicle to the assembly process from step Bei example the storage process with multiple parallel lanes for temporarily waiting the vehicle, for carrying out the correction operation, the vehicle production sequence which is pre-planned and A production sequence re-planning system for re-planning the vehicle production sequence in the assembly process when the vehicle cannot be introduced into the assembly process as described above,
A vehicle passage detection device for detecting a vehicle to be put into the correction work process;
A correction work time input device for inputting the time required for the correction work of the vehicle to be input to the correction work process;
Upon receiving notification from the vehicle passage detection device that a vehicle to be input to the correction work process has been detected, vehicle production in the assembly process is performed based on the correction work time input from the correction work time input device. A production sequence replanning system comprising a production sequence replanning device for replanning a sequence. The production sequence replanning system according to claim 1, wherein the production sequence replanning device includes:
A vehicle passage time interval information storage unit for storing a passage time interval of the vehicle defined for each passage point provided in the vehicle production line;
A painting process vehicle production order storage unit for storing a vehicle production order of the painting process;
A correction work required time storage unit for storing the correction work required time input from the correction work required time input device;
A corrected vehicle line re-insertion position prediction unit for predicting a re-input position of the vehicle performing the correction work to the vehicle production line based on the vehicle transit time interval, the vehicle production order of the painting process , and the time required for the correction operation; ,
A storage carry-in order planning unit that plans a storage carry-in order to be carried into the storage process based on the re-feed position of the correction work execution vehicle predicted by the modified vehicle line re-fill position prediction unit and the vehicle production order in the painting process. When,
An assembly process production planning sequence planning unit that re-plans the vehicle production order of the assembly process based on the planned storage delivery order. In the production sequence rescheduling system according to claim 1 or 2,
An automatic carry-out device for automatically carrying out the vehicle from the storage process to the vehicle production line of the assembly process;
The production sequence replanning system, wherein the automatic carry-out device carries out the vehicle according to the vehicle production order of the assembly process replanned by the production sequence replanning device. In the production order rescheduling system according to any one of claims 1 to 3,
In the vicinity of the vehicle production line of the assembly process, comprising an output device for outputting the production status of the vehicle,
The production order re-planning system, wherein information relating to the vehicle production order of the assembly process re-planned by the production order re-planning device is output to the output device. In the production order rescheduling system according to any one of claims 1 to 4,
A vehicle state input device including a monitoring device that monitors a vehicle that is put into the correction work process; and an input device that allows an operator to input a quality state of the vehicle based on a monitoring result of the monitoring device;
In the production sequence re-planning device,
A correction work time data storage unit that defines the time required for the correction work corresponding to the quality state of the vehicle;
A production order re-planning system, comprising: a correction work time estimation unit that estimates a correction work time from the quality state of the vehicle input from the vehicle state input device and the correction work time data. In the production order rescheduling system according to any one of claims 1 to 4,
A monitoring device that monitors a vehicle that is put into the correction work process; and a vehicle state determination device that analyzes a monitoring result of the monitoring device and automatically determines a quality state of the vehicle,
In the production sequence re-planning device,
A correction work time data storage unit that defines the time required for the correction work corresponding to the quality state of the vehicle;
A production order re-planning system, comprising: a correction work time estimation unit that estimates a correction work time from the vehicle quality state input from the vehicle state determination device and the correction work time data. In a vehicle production line that has a line for producing a plurality of vehicle types on the same line and produces vehicles by a plurality of processes based on a vehicle production order that is planned in advance, a painting process for painting a vehicle body and parts for the vehicle body A step of performing a quality inspection between the assembly steps to be assembled, a correction operation step of performing a correction operation on a vehicle determined as a quality defect as a result of the quality inspection, and
Before turning the vehicle to the assembly process from the merging process of the correction operation step and the coating step, e Bei storage process with multiple parallel lanes for temporarily waiting the vehicle, for implementing the corrective action A production sequence re-planning device for re-planning the vehicle production sequence in the assembly process when it becomes impossible to input a vehicle into the assembly process according to a vehicle production sequence planned in advance;
A vehicle passage time interval information storage unit for storing a passage time interval of the vehicle defined for each passage point provided in the vehicle production line;
A painting process vehicle production order storage unit for storing a vehicle production order of the painting process;
A correction work required time storage unit for storing a time required for the correction work of the vehicle to be input to the correction work process;
A corrected vehicle line re-insertion position prediction unit for predicting a re-input position of the vehicle performing the correction work to the vehicle production line based on the vehicle transit time interval, the vehicle production order of the painting process , and the time required for the correction operation; ,
A storage carry-in order planning unit that plans a storage carry-in order to be carried into the storage process based on the re-feed position of the correction work execution vehicle predicted by the modified vehicle line re-fill position prediction unit and the vehicle production order in the painting process. When,
A production sequence replanning apparatus, comprising: an assembly process production plan sequence planning unit that replans a vehicle production order of the assembly process based on the planned storage delivery order. In a vehicle production line that has a line for producing a plurality of vehicle types on the same line and produces vehicles by a plurality of processes based on a vehicle production order that is planned in advance, a painting process for painting a vehicle body and parts for the vehicle body A step of performing a quality inspection between the assembly steps to be assembled, a correction operation step of performing a correction operation on a vehicle determined as a quality defect as a result of the quality inspection , the coating step and the correction operation step confluence before turning the vehicle to the assembly process from step Bei example the storage process with multiple parallel lanes for temporarily waiting the vehicle, for carrying out the correction operation, the vehicle production sequence which is pre-planned and A production sequence re-planning method for re-planning the vehicle production sequence in the assembly process when the vehicle cannot be introduced into the assembly process as described above,
Correction based on the vehicle passing time interval defined for each passing point provided in the vehicle production line, the vehicle production sequence of the painting process, and the time required for the vehicle correction work to be input to the correction work process A process for predicting the re-input position of the work execution vehicle to the vehicle production line;
Based on the predicted re-input position of the corrective operation execution vehicle and the vehicle production order of the painting process , a process of planning a storage carry-in order to be carried into the storage process;
A production order rescheduling method comprising: performing a process of rescheduling a vehicle production order of the assembly process based on the planned storage delivery order.

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