JP7447163B2 - Conveyance system and processing system - Google Patents

Description

The present invention relates to a conveyance system and a processing system.

Generally, on a production line for assembling industrial products, a plurality of so-called stations for carrying out specific work steps are installed at predetermined intervals. A conveyance device for conveying the workpiece is disposed between these stations. Conventionally, a workpiece is once transferred from a transfer device to a holding section of each station, subjected to a predetermined processing, and after processing is transferred to the transfer device again to be transferred to a station for the next process.

In recent years, conveyance systems have come into use that allow processing to be performed at a station while holding a workpiece on a cart, and after processing, transport the workpiece while being held on the cart to a station for the next process. As such a conveyance system, a moving magnet type linear motor system (moving magnet type linear motor) has been proposed. A movable magnet type linear motor system consists of a movable element mounted on a truck with multiple permanent magnets arranged in alternating north and south poles, a stator with multiple coils arranged in the running direction of the truck, and a current applied to the coils. It is configured in combination with a supply current controller. This movable magnet type linear motor system has the advantage of being able to process the workpiece while it is held on the cart, as well as eliminating the need for wiring on the mover side, which eases restrictions on the transport route.

Further, Patent Document 1 proposes a conveyance device for conveying pallets loaded with parts and workpieces by branching them to each station in an assembly line or between a plurality of conveyance lines. The conveying device described in Patent Document 1 includes a branching device that branches and delivers pallets between an assembly line, a return line, and other processes.

Further, Patent Document 2 proposes a conveyance device having a traveling carriage loading station provided outside the turntable on an extension of the conveyance path. In the conveyance device described in Patent Document 2, the traveling bogie loading station allows the traveling bogie to be loaded or collected while other traveling bogies are traveling on the loop-shaped conveyance path of the main line.

Patent Document 3 discloses that a stopper for mechanically fixing the cart is provided and the cart is fixed at a positioning position.

Patent No. 2904967 Patent No. 3450887 Patent No. 2801442

However, the conventional conveyance systems described in Patent Documents 1 to 3 have the following first to third problems.

First, the first issue is as follows. In a conveyance device such as that described in Patent Document 1, when a truck is moved onto a transfer device such as a branching device that transfers a pallet or a truck, the transfer device is moved between the transfer device and the conveyance path. There was a problem in that positional deviation occurred in the direction of movement. If there is such a positional shift, in a conveyance system in which a trolley runs, an impact is generated when the truck passes through a connecting portion between the conveyance path and the trolley transfer device, making it difficult to run at high speed. Furthermore, there is a concern that damage to the cart or conveyance path may occur due to the impact when passing through the connecting portion. Furthermore, when transferring, unless the carriage is run in a state where the conveyance path on which the carriage is traveling and the transfer device are connected and the carriage can enter, there is a risk that the carriage will come off the conveyance path.

The present invention has been made in view of the first problem described above, and is directed to a transport system and its transport system that can reduce damage to the transport path or the cart when transferring the cart and can transfer the cart at high speed. The object is to provide a processing system having a conveyance system.

Moreover, the second problem is as follows. In the conveyance device described in Patent Document 2, since the traveling trolley loading station is arranged only outside the turntable on the extension of the conveying path, the locations from which the trolley can be taken out or put in are limited. Furthermore, with respect to a closed conveyance path including a curved conveyance section, it is difficult to install a traveling vehicle loading station itself as described in Patent Document 2. Even if the conveyance path is closed, it is required to efficiently take out a cart from the conveyance path or to put the cart into the conveyance path in a short time and efficiently.

The present invention has been made in view of the second problem described above, and the present invention is directed to a conveyance system that can efficiently access a specific cart even in a closed conveyance path in a short time, and a processing system having the conveyance system. for other purposes.

Additionally, the third issue is as follows. The positioning of the trolley relative to the station during machining work is performed using servo control using a motor controller based on position information detected by an encoder installed on the transport path of the scale attached to the trolley. The work processes at the station include processes that apply strong stress, such as the process of attaching parts to a held workpiece by pressure bonding. Therefore, in order to achieve highly accurate positioning of the cart even in work processes where the cart is subjected to large disturbances due to stress, etc., it is necessary to maintain high rigidity through high-speed, high-performance servo control and a high-output motor. be. However, using a high-performance servo control and a high-output motor results in an increase in cost. In the conveying device described in Patent Document 3, a stopper piece for positioning the cart is provided at each station where the cart stops. For this reason, in the technique described in Patent Document 3, unnecessary stopper pieces are arranged even at a stop position where positioning accuracy by servo control is sufficient, leading to an increase in costs.

The present invention has been made in view of the third problem described above, and provides a conveyance system that can more reliably stop a cart and achieve high-precision positioning at low cost, and a processing system that includes the conveyance system. and for other purposes.

In order to solve the above-mentioned first problem, according to one aspect of the present invention, a first transport module whose cart moves in a first direction, and a first transport module which is movable in a second direction intersecting the first direction, a second transport module in which the cart is movable between the first transport module; a position detection section that detects the position of the second transport module and outputs position information; a control unit that controls movement of the module, and the control unit is configured to move the trolley between the first transport module and the second transport module based on the position information output by the position detection unit. The conveying system is characterized in that the trolley is moved from the first conveying module to the second conveying module by correcting the stop position of the second conveying module to a position where it can be moved between the first and second conveying modules. provided.

In order to solve the above-mentioned first problem, according to another aspect of the present invention, there is provided a first transport module whose cart moves in a first direction, and a first transport module which is movable in a second direction intersecting the first direction. , a second transport module in which the cart is movable between the first transport module; a position detection unit that detects the position of the second transport module and outputs position information; A control method for a transport system, comprising: a control unit that controls movement of a transport module, wherein the control unit determines whether the trolley is connected to the first transport module based on the position information output by the position detection unit. and the second transport module, correcting the stop position of the second transport module , and moving the trolley from the first transport module to the second transport module. A control method is provided.

According to still another aspect of the present invention, there is provided a processing system comprising the above-described transport system and a processing section that processes a workpiece transported by the trolley.

According to the transport system provided by one aspect of the present invention, it is possible to reduce damage to the transport path or the trolley when transferring the trolley, and to transfer the trolley at high speed.

According to the conveyance system provided by another aspect of the present invention, it is possible to efficiently access a specific cart even in a closed conveyance path in a short time.

According to the conveyance system provided by yet another aspect of the present invention, it is possible to stop the cart more reliably and achieve highly accurate positioning at low cost.

1 is a schematic diagram showing the overall configuration of a processing system according to a first embodiment of the present invention. FIG. 2 is a schematic diagram showing the configuration of a trolley and a transport module in the transport system according to the first embodiment of the present invention. FIG. 2 is a schematic diagram showing the configuration of a trolley and a transport module in the transport system according to the first embodiment of the present invention. FIG. 2 is a schematic diagram showing the configuration of a truck fixing mechanism in the transport system according to the first embodiment of the present invention. 1 is a control block diagram showing a control configuration of a processing system according to a first embodiment of the present invention. FIG. FIG. 3 is a schematic diagram showing the procedure of a cart transfer process in the processing system according to the first embodiment of the present invention. FIG. 3 is a schematic diagram showing the procedure of a cart transfer process in the processing system according to the first embodiment of the present invention. FIG. 3 is a schematic diagram showing the procedure of a cart transfer process in the processing system according to the first embodiment of the present invention. FIG. 3 is a schematic diagram showing the procedure of a cart transfer process in the processing system according to the first embodiment of the present invention. FIG. 3 is a schematic diagram showing the procedure of a cart transfer process in the processing system according to the first embodiment of the present invention. FIG. 6 is a schematic diagram showing the configuration of a truck fixing mechanism according to a second embodiment of the present invention. FIG. 6 is a schematic diagram showing the configuration of a truck fixing mechanism according to a second embodiment of the present invention. FIG. 2 is a control block diagram showing a control configuration of a processing system according to a second embodiment of the present invention. FIG. 3 is a schematic diagram showing the overall configuration of a processing system according to a third embodiment of the present invention. FIG. 7 is a control block diagram showing a control configuration of a processing system according to a third embodiment of the present invention. FIG. 3 is a schematic diagram showing the overall configuration of a processing system according to a fourth embodiment of the present invention. FIG. 3 is a schematic diagram showing the overall configuration of a processing system according to a fifth embodiment of the present invention. FIG. 7 is a schematic diagram showing the overall configuration of a processing system according to a sixth embodiment of the present invention. It is a control block diagram which shows the control structure of the processing system by 6th Embodiment of this invention. FIG. 7 is a schematic diagram showing the overall configuration of a processing system according to a seventh embodiment of the present invention. FIG. 7 is a control block diagram showing a control configuration of a processing system according to a seventh embodiment of the present invention.

Embodiments of the present invention will be described with reference to the drawings. In the following explanations and drawings, when distinguishing between multiple identical components, a lowercase alphabet is added to the end of the same numerical code as an identifier, and when there is no particular need to distinguish, the identifier is used. Omit it and use a code with only numbers.

[First embodiment]
A first embodiment of the present invention will be described using FIGS. 1 to 5E.

First, the configuration of the processing system according to this embodiment will be explained using FIGS. 1 to 2B. FIG. 1 is a schematic diagram showing the overall configuration of a processing system 1 according to this embodiment, and is a top view of the entire processing system 1 including a transport system 4 viewed from above. FIG. 2A is a plan view showing the configuration of the mover-side carriage 20 and the stator-side linear transport module 10 that constitute the linear motor in the transport system 4 according to the present embodiment. FIG. 2B is a side view showing the configuration of the trolley 20 and the linear conveyance module 10.

As shown in FIG. 1, the processing system 1 according to this embodiment includes a conveyance path 101, a cart transfer device 11, a processing station 30, and a cart 20. The processing system 1 according to this embodiment includes a conveyance system 4 that conveys a workpiece W that is a target to be machined. The processing system 1 constitutes a production line such as an assembly line for workpieces W. Note that in the drawings, each workpiece W is distinguished by a code represented by "Wn" (n is a positive integer). The transport system 4 includes a transport path 101, a cart transfer device 11, and a cart 20.

Here, the X-axis, Y-axis, and Z-axis of the XYZ coordinate system, which is an orthogonal coordinate system used in the following explanation, will be defined. First, the X-axis is taken along the transport direction of the cart 20 that is transported horizontally. With respect to a horizontally placed pedestal (not shown), the vertical direction is the Z axis, and the axis orthogonal to the X axis and the Z axis is the Y axis. Note that the processing system 1 is installed on the pedestal. In the XYZ coordinate system in which the coordinate axes are defined in this way, the direction along the X axis is called the X-axis direction, the direction along the Y-axis is called the Y-axis direction, and the direction along the Z-axis is called the Z-axis direction.

The conveyance system 4 in the processing system 1 is a circulation type conveyance system in which a plurality of carts 20 are circulated and conveyed. In the conveyance system 4, the conveyance path 101 along which the trolley 20 is conveyed has two conveyance paths: a conveyance path 101a that is an outbound path and a conveyance path 101b that is a return path. The conveyance path 101a, which is the outward path, and the conveyance path 101b, which is the return path, are installed parallel to each other.

The conveyance path 101 is a conveyance path for the trolley 20, and is configured by connecting a plurality of linear conveyance modules 10. The linear conveyance module 10 is a linear conveyance module in which a cart 20 moves linearly.

As shown in FIGS. 2A and 2B, the linear conveyance module 10 includes a linear guide rail 9 and a plurality of coils 19 that are stators of a linear motor. The plurality of coils 19 constitute a coil group and function as a drive unit that drives the trolley 20 in the following manner. In the linear conveyance module 10, a guide rail 9 is installed along the X-axis direction at the upper part thereof. Further, a plurality of coils 19 are arranged in the X-axis direction along which the truck 20 travels. The linear conveyance module 10 constructed in this manner is a module having a shorter dimension than the conveyance path 101, and the plurality of linear conveyance modules 10 are connected to form the conveyance path 101. FIG. 1 illustrates a case where five linear conveyance modules 10 are connected to form a conveyance path 101. Furthermore, in FIG. 2A, a case is illustrated in which the guide rail 9 is configured with the same length as the linear conveyance module 10, but the guide rail 9 is configured with a length that straddles a plurality of linear conveyance modules 10. It's okay.

The trolley 20 holds and mounts a workpiece W to be processed, and transports the workpiece W. The truck 20 has a plurality of permanent magnets 21 in which N poles and S poles are alternately arranged in the X-axis direction, which is the traveling direction of the truck 20. An electromagnetic force that drives the cart 20 is generated between the plurality of permanent magnets 21 and the coil 19 of the linear conveyance module 10 by applying a current to the coil 19 serving as a drive section. In this way, the trolley 20 is driven by the electromagnetic force generated between the plurality of permanent magnets 21 and the coil 19 as a movable element of the linear motor, and is guided on the guide rail 9 installed on the upper surface of the linear transport module 10. Run along rail 9. In this manner, in this embodiment, the transport system 4 is configured using a moving magnet type linear motor. Note that instead of the permanent magnet 21, a ferromagnetic material such as an iron core may be used to configure a reluctance type linear motor.

The processing station 30 functions as a processing section that processes the workpiece W. The processing station 30 is installed along a conveyance path 101 inside a processing work area 100, which will be described later. Note that although FIG. 1 illustrates a case where the processing station 30 is installed only on the forward transport path 101a side and the processing station 30 is not installed on the return transport path 101b side, the present invention is not limited to this. isn't it. The processing station 30 may also be installed on the return transport path 101b side. Further, the number of processing stations 30 is not particularly limited, and may be one or more.

A processing robot 31 is installed in the processing station 30 to perform processing on a workpiece W transported by the trolley 20. The processing robot 31 is, for example, a two-axis orthogonal robot, an articulated robot, or the like. The trolley 20 stops at a predetermined stop position on the conveyance path 101 with respect to the processing station 30 . The workpiece W on the cart 20 stopped on the transport path 101 is processed by the processing robot 31 under the control of the robot controller (see FIG. 3). The processing robot 31 performs predetermined processing operations, such as assembling parts and coating, on the workpiece W mounted on the trolley 20. Note that the processing robot 31 is not particularly limited, and robots that perform various processing operations on the workpiece W can be used.

Here, the length of the transport path 101 can be changed by changing the number of linear transport modules 10 to be connected, so there is a high degree of freedom in designing the length of the transport path. Therefore, the length of the transport path 101 can be easily changed depending on the number of processing stations 30 in the processing system 1.

In this way, by processing the workpiece W by the processing robot 31 of the processing station 30 functioning as a processing section, an article such as an electronic device is manufactured. The manufactured article is not limited to a specific one, and may be any type of article. Various articles can be manufactured by the article manufacturing method using the processing system 00 according to this embodiment.

The trolley transfer device 11 is a device for transferring the trolley 20 between mutually different transport paths, that is, between transport modules that are not connected to each other. The transport system 4 is equipped with two trolley transfer devices 11a and 11b that transfer the trolley 20 between the outward transport path 101a and the return transport path 101b.

The trolley transfer device 11 has a movable linear transport module 12 that is movable in the Y-axis direction. The trolley transfer device 11 is capable of moving the linear transport module 12 in the Y-axis direction and stopping the linear transport module 12 adjacent to the end of the transport path 101. Although the mechanism for moving the linear conveyance module 12 in the Y-axis direction is not particularly limited, for example, a uniaxial actuator including a ball screw or the like can be used.

The movable linear transport module 12 installed on the trolley transfer device 11 has the same configuration as the linear transport module 10 that constitutes the transport path 101, and includes a guide rail 9 and a coil 19 that is a stator of a linear motor. It has In the movable linear transport module 12 as well, in order to move the trolley 20 similarly to the linear transport module 10 on the transport path 101, a guide rail 9 is installed on the upper part along the X-axis direction. A plurality of coils 19 are arranged in the axial direction.

In this way, the linear transport module 12 of the trolley transfer device 11 is configured to be movable to a position where it is connected to the linear transport module 10 on the transport path 101, and the trolley 20 is movable between it and the linear transport module 10 on the transport path 101. It has become. As a result, the linear transport module 12 pulls in the trolley 20 on one transport path 101, moves in the Y-axis direction with the trolley 20 placed thereon and stopped, and transfers the trolley 20 to the other transport path 101. can be transferred.

Specifically, as shown in FIG. 1, the trolley transfer device 11a is installed at the downstream end (the right end in the figure) of the outbound transport path 101a and the upstream end of the return transport path 101b. (the right end in the figure). The linear conveyance module 12a of the trolley transfer device 11a is configured to be connectable to the linear conveyance module 10e at the downstream end of the outward conveyance path 101a. Thereby, the trolley 20 can be transferred from the linear transport module 10e to the linear transport module 12a. Further, the linear conveyance module 12a is configured to be connectable to the linear conveyance module 10f at the upstream end of the return conveyance path 101b. Thereby, the trolley 20 can be transferred from the linear transport module 12a to the linear transport module 10f. Via such a linear transport module 12a, the cart transfer device 11a transfers the cart 20 on the outbound transport path 101a from the linear transport module 10e at its downstream end to the upstream end of the return transport path 101b. It can be transferred to module 10f.

Similarly, as shown in FIG. 1, the trolley transfer device 11b has an upstream end (the left end in the figure) of the outgoing conveyance path 101a and a downstream end (the left end in the figure) of the backward conveyance path 101b. , left end). The linear transport module 12b of the trolley transfer device 11b is configured to be connectable to the linear transport module 10j at the downstream end of the return transport path 101b. Thereby, the trolley 20 can be transferred from the linear transport module 10j to the linear transport module 12b. Moreover, the linear conveyance module 12b is configured to be connectable with the linear conveyance module 10a at the upstream end of the outward conveyance path 101a. Thereby, the trolley 20 can be transferred from the linear transport module 12b to the linear transport module 10a. Through such a linear transport module 12b, the cart transfer device 11b transfers the cart 20 on the return transport path 101b from the linear transport module 10j at its downstream end to the linear transport at the upstream end of the outgoing transport path 101a. It can be transferred to module 10a.

In this way, in the transport system 4, the transport path 101a, the trolley transfer device 11a, the transport path 101b, and the trolley transfer device 11b constitute a circulation transport path, making it possible to transport the trolley 20 in a circular manner as a whole. There is. Note that the conveyance system 4 includes a maintenance linear conveyance module 13, which will be described later, and constitutes a conveyance path separate from the circulation conveyance path.

Here, when transferring the trolley 20 between the linear transport modules 10 and 12, if the positions of the linear transport module 12 and the linear transport module 10 in the Y-axis direction do not match with high precision, both the linear transport modules 10 and 12 , 12. Specifically, a positional shift occurs between the guide rails 9 of both the linear conveyance modules 10 and 12. If the cart 20 is transferred with the guide rail 9 misaligned, a high load will be applied to the cart 20 or the linear transport modules 10, 12 due to impact, etc., and there is a risk that the cart 20 or the linear transport modules 10, 12 will be damaged. be. For this reason, there is a possibility that the cart 20, the linear conveyance modules 10, 12, and other components in the processing system 1 may be damaged, or the workpiece W held by the cart 20 may be defective. Furthermore, if the carriage 20 is transferred in a state where the linear transport module 12 of the carriage transfer device 11 is not located at a position where the carriage 20 can be transferred, there is a risk that the carriage 20 may fall off the conveyance path 101. There is also.

In order to prevent these, the transport system 4 according to the present embodiment includes a position detection sensor 14 provided on the trolley transfer device 11. The position detection sensor 14 functions as a position detection unit that detects the position of the linear conveyance module 12 of the trolley transfer device 11 in the moving direction (Y-axis direction) and outputs an output signal containing the position information.

As shown in FIG. 1, the trolley transfer device 11a includes a position detection sensor 14a that detects the position in the Y-axis direction of the linear transport module 12a connected to the linear transport modules 10e and 10f, respectively. 14b is provided. Of these, the position detection sensor 14a also detects the position in the Y-axis direction of a linear conveyance module 12a connected to a maintenance linear conveyance module 13b, which will be described later.

Further, the trolley transfer device 11b is provided with position detection sensors 14c and 14e, each of which detects the position in the Y-axis direction of the linear transport module 12b connected to the linear transport modules 10j and 10a, respectively. There is. Further, the trolley transfer device 11b is provided with a position detection sensor 14d as the position detection sensor 14, which detects the position in the Y-axis direction of a linear conveyance module 12b connected to a maintenance linear conveyance module 13a, which will be described later.

The position detection sensor 14 is, for example, a linear encoder, although it is not particularly limited. In this embodiment, as will be described later, the transport controller 40 moves the linear transport module 12 in the Y-axis direction before starting the movement of the trolley 20 based on an output signal including position information output by the position detection sensor 14. You can check the position and correct the position. Thereby, in this embodiment, the linear conveyance module 12 of the trolley transfer device 11 can be positioned with high accuracy with respect to the linear conveyance module 10 also in the Y-axis direction.

As shown in FIG. 1, in the machining system 1, a machining work area 100 indicated by a dashed line in the figure is defined. The processing work area 100 is an area including a transport path 101a, a trolley transfer device 11a, a transport path 101b, a trolley transfer device 11b, and a processing station 30. The processing work area 100 is an area where operators should be prohibited from entering when the processing system 1 is operating in automatic operation mode, for example, because there is a risk of contact with the processing robot 31 or the trolley transfer device 11 in operation. be. In actual operation, for example, a safety fence, a door, and a door opening/closing detection sensor are installed at the boundary of the processing work area 100 to monitor the opening/closing state of the door, or an intrusion is detected to detect an intrusion into the processing work area 100. A detection sensor may also be installed to monitor intrusions.

The conveyance system 4 includes a maintenance linear conveyance module 13 installed outside the processing work area 100. The linear conveyance module 13 for maintenance is installed adjacent to the trolley transfer device 11 inside the processing work area 100 . In FIG. 1, a maintenance linear transport module 13b is installed adjacent to the cart transfer device 11a. The maintenance linear transport module 13b is installed on an extension of the transport path 101a. Further, a linear transport module 13a for maintenance is installed adjacent to the trolley transfer device 11b. The maintenance linear conveyance module 13a is installed between the conveyance path 101a and the conveyance path 101b.

The maintenance linear transport module 13 is a linear transport module for performing maintenance of the trolley 20, and functions as a means for manually accessing a specific trolley 20 on the transport path 101. Note that, as will be described later, the maintenance linear transport module 13 can also be used for purposes other than maintaining the trolley 20, such as collecting the work W on the trolley 20, overtaking the trolley 20, etc. can.

The linear conveyance module 13 for maintenance has the same configuration as the linear conveyance module 10 that constitutes the conveyance path 101, and includes a guide rail 9 and a coil 19 that is a stator of a linear motor. In the maintenance linear transport module 13 as well, in order to move the trolley 20 in the same way as the linear transport modules 10 and 12, a guide rail 9 is installed along the X-axis direction on the upper part, and the guide rail 9 is installed along the X-axis direction in which the trolley 20 runs. A plurality of coils 19 are arranged.

The linear transport module 12 of the trolley transfer device 11 adjacent to the linear transport module 13 for maintenance is configured to be movable to a position where it is connected to the linear transport module 13 for maintenance. Thereby, the trolley 20 can be transferred between the linear transport module 12 and the maintenance linear transport module 13.

For example, the linear transport module 12b of the trolley transfer device 11b pulls in the trolley 20 from the transport path 101b, places the trolley 20 thereon, stops it, and moves in the Y-axis direction, and the maintenance linear transport module 13a The cart 20 can be moved and transferred. Further, the linear transport module 12b, for example, pulls in the trolley 20 from the maintenance linear transport module 13a, places the trolley 20 thereon, moves in the Y-axis direction in a stopped state, and moves the trolley 20 onto the transport path 101a. It can be moved and transferred. Note that the linear transport module 12a of the other trolley transfer device 11a can also operate in the same manner as the maintenance linear transport module 13b.

The maintenance linear conveyance module 13 is installed outside the processing work area 100 that includes the conveyance path 101. Therefore, unlike the linear transport modules 10 and 12 inside the processing work area 100, the maintenance linear transport module 13 allows the operator to safely operate the trolley 20 even when the processing system 1 is operating in automatic operation mode, for example. is accessible. Therefore, even when the processing system 1 is in operation, the operator can safely access the trolley 20 transferred to the maintenance linear transport module 13 and perform maintenance on the trolley 20.

Other purposes for accessing the trolley 20 transferred to the maintenance linear transport module 13 include collecting processed workpieces W and inserting new unprocessed workpieces W. In this case, for example, the carriage 20a carrying the processed workpiece W-1 is transferred to the maintenance linear conveyance module 13a from the return conveyance path 101b via the linear conveyance module 12b of the carriage transfer device 11b. and collect the workpiece W-1. Next, a new unprocessed workpiece W-6 is loaded onto the carriage 20a that has been transferred to the maintenance linear conveyance module 13a, and transferred to the outbound conveyance path via the linear conveyance module 12b of the carriage transfer device 11b. 101a.

At this time, the linear conveyance module 12b of the trolley transfer device 11b provides high precision in the Y-axis direction for the maintenance linear conveyance module 13a as well as for the linear conveyance modules 10a and 10j of the conveyance paths 101a and 101b. Positioning is required. As described above, the cart transfer device 11b is provided with the position detection sensor 14d as the position detection sensor 14, which detects the position in the Y-axis direction of the linear transfer module 12b connected to the maintenance linear transfer module 13a. . Therefore, the linear transport module 12b can be positioned with high accuracy in the Y-axis direction also with respect to the maintenance linear transport module 13a. Note that the linear transport module 12a of the other trolley transfer device 11a can also be positioned with high precision in the Y-axis direction with respect to the maintenance linear transport module 13b by the position detection sensor 14a.

Further, for example, a malfunction may occur during the processing performed at the processing stations 30a to 30e on the forward transport path 101a, and the workpiece W may become defective. In this case, the trolley 20 carrying the defective workpiece W is transferred to the maintenance linear transport module 13b installed on the extension of the outward transport path 101a. Subsequently, the defective workpiece W is recovered from the cart 20 that has been transferred to the maintenance linear transport module 13b. Here, since the maintenance linear transport module 13b is arranged outside the processing work area 100, it is possible to collect the cart 20 carrying the defective workpiece W without stopping the other carts 20. Can be done. Note that the processing at the processing station 30 after the occurrence of the malfunction can be skipped as unnecessary processing by issuing a NOP (No Operation) command from the system controller 50, which will be described later.

Furthermore, it is also possible to perform maintenance on the trolley 20 using the maintenance linear transport module 13b. At this time, only the specific cart 20 can be accessed on the maintenance linear transport module 13 without affecting other carts 20 in operation.

In addition, it is also possible to temporarily evacuate the preceding cart 20 to the maintenance linear transport module 13b and allow the following cart to proceed to the next process first, that is, to overtake the cart 20 in operation.

As described above, according to the present embodiment, it is possible to efficiently access a specific trolley 20 in a short time, and therefore it is possible to perform collection, input, maintenance, etc. of the trolley 20 without stopping other trolleys 20. Can be done.

Furthermore, the processing system 1 according to this embodiment includes a transport controller 40 and a system controller 50. The transport controller 40 is connected to the controllers of the linear transport modules 10, 12, 13 and the trolley transfer device 11 in the processing system 1, as well as the position detection sensor 14 through a transport system serial communication network 41, which is the same communication network. There is. The conveyance controller 40 controls the energization of the coils 19 in each of the linear conveyance modules 10, 12, and 13. The system controller 50 is connected to a robot controller (not shown) and a transport controller 40 in the processing system 1 via an overall serial communication network 51. The system controller 50 realizes synchronous control of the processing robot 31 and the transport controller 40.

Further, the conveyance system 4 according to this embodiment includes a trolley fixing mechanism 15 installed on the conveyance path 101. The trolley fixing mechanism 15 functions as a fixing section that fixes the trolley 20 to the transport path 101 at a predetermined stop position on the transport path 101 . Here, the predetermined stopping position on the conveyance path 101 is a stopping position of the cart 20 at which a specific processing station 30 among the plurality of processing stations 30 processes the work W on the cart 20. The trolley fixing mechanism 15 fixes the trolley 20 on the transport path 101 to prevent the trolley 20 from shifting during processing of the workpiece W by the processing station 30 .

FIG. 1 shows a trolley fixing mechanism 15 that fixes the trolley 20 to the transport path 101a at a stop position where one of the five processing stations 30a to 30e, 30d, processes the workpiece W. . Hereinafter, with further reference to FIG. 3, the truck fixing mechanism 15, which functions as a fixing section for preventing displacement of the truck 20 during processing, will be described. FIG. 3 is a schematic diagram showing the configuration of the truck fixing mechanism 15 according to the present embodiment, and is a top view of the truck fixing mechanism 15 and the truck 20 fixed thereby, viewed from above.

Some processing stations 30 perform a process in which a large external force is applied to the cart 20 via the work W on the cart 20 when the processing robot 31 processes the work W. Examples of processes in which a large external force is applied to the trolley 20 include, but are not particularly limited to, processes such as press-fit assembly. During processing, the trolley 20 is positioned at a predetermined stop position by servo control under the control of the transport controller 40. However, if the cart 20 receives an external force of a predetermined magnitude or more via the workpiece W being processed, there is a risk that the cart 20 will be displaced. If a positional shift occurs in the cart 20 on which the workpiece W being processed is mounted, the workpiece W being processed becomes a defective product. The truck fixing mechanism 15 prevents the truck 20 from shifting during processing of the workpiece W by fixing the truck 20 to the transport path 101 at a predetermined stop position as described above.

FIG. 3 shows how the truck fixing mechanism 15 fixes the truck 20. Fences 1011 such as guardrails are installed along the transport path 101 at both ends of the transport path 101 where the trolley fixing mechanism 15 is installed. The trolley fixing mechanism 15 includes a pair of fixing units 150 installed on fences 1011 at both ends of the conveyance path 101, respectively. Each fixed unit 150 has a fixed pad 151 and a fixed actuator 152. The fixing pad 151 is configured to be able to press the cart 20 on the transport path 101 from the side of the cart 20 toward the center line of the transport path 101 in the Y-axis direction. The fixed actuator 152 drives the fixed pad 151 in the Y-axis direction. The fixed actuator 152 is, for example, a solenoid, and is driven under a command from the system controller 50.

The truck fixing mechanism 15 installed on the transport path 101 drives the pair of fixing pads 151 by the fixed actuators 152 of the pair of fixing units 150, and the truck 20 is moved by the pair of fixing pads 151 that press the truck 20 in opposite directions. Pinch and secure.

Here, under a command from the transport controller 40, the module controller 110 (see FIG. 4) controls the energization of the coil 19 of the linear transport module 10 to control the transport of the cart 20 on the transport path 101. When the trolley 20 is fixed by the trolley fixing mechanism 15, the module controller 110 uses servo control to position and stop the trolley 20 at a target stop position on the transport path 101.

Before and after the trolley 20 is fixed by the trolley fixing mechanism 15, the module controller 110 switches the servo control of the trolley 20 on and off as follows. First, as described above, the trolley 20 is positioned at the stop position and stopped by the servo control by the module controller 110. Then, under a command from the system controller 50, the trolley fixing mechanism 15 turns on the fixing actuator 152 and drives it. As a result, the truck fixing mechanism 15 fixes the truck 20 on the conveyance path 101 by pressing and sandwiching the truck 20 with the fixing pads 151 of the pair of fixing units 150 . When the carriage 20 is fixed by the carriage fixing mechanism 15, the module controller 110 turns off the servo control of the carriage 20 to stop it.

The workpiece W on the fixed cart 20 is processed by the processing robot 31 of the processing station 30. After the machining is completed, before turning off the fixed actuator 152 and releasing the fixation of the carriage 20, the module controller 110 sets the current position of the carriage 20 to the target position, turns on the servo control of the carriage 20 again, and starts. do. This is to avoid servo errors and sudden correction drive of the truck 20.

After servo control of the truck 20 is restarted, the truck fixing mechanism 15 turns off the fixing actuator 152 under a command from the system controller 50. Thereby, the truck fixing mechanism 15 separates the fixing pads 151 of the pair of fixing units 150 from the truck 20, and releases the fixation of the truck 20.

Through the above series of controls, when the processing robot 31 processes the workpiece W on the trolley 20, the trolley fixing mechanism 15 mechanically fixes the trolley 20 to the transport path 101, thereby increasing the apparent rigidity of the trolley 20. can be raised. Thereby, even if a large external force is applied to the trolley 20, highly accurate positioning of the trolley 20 can be maintained, and processing defects of the workpiece W can be prevented.

In this embodiment, the above-mentioned trolley fixing mechanism 15 is not installed at all of the stop positions where the processing robots 31a to 31e perform the processing process on the work W in the processing stations 30a to 30e. That is, as shown in FIG. 1, the trolley fixing mechanism 15 fixes the trolley 20 only at the stop position where the processing step by the processing robot 31d of the processing station 30d among the processing stations 30a to 30e is performed. It is set up to do so.

The processing robot 31d, to which the carriage 20 is fixed by the carriage fixing mechanism 15 during processing, processes the workpiece W while applying an external force of a predetermined magnitude or more to the carriage 20 via the workpiece W. On the other hand, the other processing robots 31a to 31c, 31e whose carts 20 are not fixed by the cart fixing mechanism 15 during machining process the work W without applying a predetermined amount of external force to the cart 20. As described above, in this embodiment, the trolley fixing mechanism fixes the trolley 20 at only the stop position where an external force of a predetermined magnitude or more is applied to the trolley 20 among the plurality of stop positions at which the trolley 20 stops. 15 have been installed. Among the plurality of stop positions, the cart 20 is not fixed by the cart fixing mechanism 15 at a stop position where an external force of a predetermined magnitude or more is not applied. As a result, compared to the case where the trolley fixing mechanism 15 is uniformly installed for each of a plurality of stop positions, in the case of this embodiment, the number of installed trolley fixing mechanisms 15 can be reduced, so that cost can be reduced. be able to.

In this way, in this embodiment, the number of installed truck fixing mechanisms 15, which are means for fixing the truck 20, can be reduced, so that the cost of the processing system 1 including the transport system 4 can be reduced. In this embodiment, the trolley fixing mechanism 15 installed as described above makes it possible to more reliably stop the trolley 20 and realize highly accurate positioning at low cost.

FIG. 4 is a control block diagram showing the control configuration of the processing system 1 according to this embodiment. The system controller 50 is a control unit that controls the entire processing system 1. As shown in FIG. 3, the system controller 50 is connected to a transport controller 40 and a robot controller 32 that controls the processing robots 31 in each processing station 30 through an overall serial communication network 51. Note that the robot controller 32 is provided corresponding to each of the plurality of processing robots 31.

The transport controller 40 is connected to a module controller 110 that controls the linear transport module 10 that constitutes the transport path 101 via a transport serial communication network 41 . A module controller 110 is provided corresponding to each of the plurality of linear conveyance modules 10. Each module controller 110 is connected to a position detection sensor 114 that detects the position of the trolley 20 on the corresponding linear transport module 10 in the transport direction (X-axis direction). The position detection sensor 114 as a position detection unit is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 114 is not shown in FIG.

Further, the transport controller 40 is connected to a device controller 111 that controls the trolley transfer device 11 via a transport serial communication network 41 . The device controller 111 is provided corresponding to each of the plurality of trolley transfer devices 11. Each device controller 111 is connected to a position detection sensor 14 as the above-mentioned position detection section that detects the position of the linear conveyance module 12 of the corresponding trolley transfer device 11 in the moving direction (Y-axis direction).

Further, the transport controller 40 is connected to a module controller 112 that controls the linear transport module 12 of the trolley transfer device 11 via a transport serial communication network 41 . A module controller 112 is provided corresponding to each of the plurality of linear conveyance modules 12. Each module controller 112 is connected to a position detection sensor 214 that detects the position of the trolley 20 on the corresponding linear transport module 12 in the transport direction (X-axis direction). The position detection sensor 214 as a position detection section is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 214 is not shown in FIG.

Further, the transport controller 40 is connected to a module controller 113 that controls the maintenance linear transport module 13 via a transport serial communication network 41 . The module controller 113 is provided corresponding to the plurality of maintenance linear transport modules 13. Each module controller 113 is connected to a position detection sensor 314 that detects the position of the trolley 20 on the corresponding maintenance linear transport module 13 in the transport direction (X-axis direction). The position detection sensor 314 as a position detection unit is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 314 is not shown in FIG.

In this way, the transport controller 40 is connected to the module controllers 110, 112, and 113, which are control units that control the movement of the trolley 20 on the corresponding transport module. Further, the transport controller 40 is connected to a device controller 111 that is a control unit that controls movement of the linear transport module of the trolley transfer device 11.

The transport controller 40 functions as a control unit that controls the module controllers 110, 112, 113 and the device controller 111 connected to the transport serial communication network 41 as described above. Further, position detection sensors 14, 114, 214, and 314 are connected to the transport controller 40 through a transport system serial communication network 41, and output signals from each sensor are transmitted. Latency in the transport system 4 can be reduced by connecting these various controllers and sensors to the transport serial communication network 41, which is the same communication network.

In response to a command from the transport controller 40, each module controller 110, 112, 113 controls the energization of the coil 19 of the corresponding linear transport module 10, 12, 13 under its control. Thereby, each module controller 110, 112, 113 functions as a control unit and controls the movement of the cart 20 on the corresponding linear transport module 10, 12, 13. In addition, according to instructions from the transport controller 40, the device controller 111 functions as a control section and controls the movement of the linear transport module 12 by the trolley transfer device 11. In this way, the transport controller 40 can control each of the module controllers 110, 112, 113 and the device controller 111 to individually control the plurality of carts 20 on the transport path 101 with desired drive profiles.

Further, the trolley fixing mechanism 15 is connected to an input/output control port of the system controller 50. The system controller 50 controls the operation of the trolley fixing mechanism 15 in accordance with the transportation of the trolley 20. Note that depending on the command system, the trolley fixing mechanism 15 may be connected to the input/output control port of the transport controller 40. In this case, the transport controller 40 controls the operation of the trolley fixing mechanism 15 in accordance with the transport of the trolley 20.

The transport controller 40 synchronizes and controls each linear transport module 10 on the transport path 101 and the trolley transfer device 11. Thereby, in this embodiment, it is possible to shorten the takt time in the processing system 1. Hereinafter, a specific procedure for transferring the trolley 20 will be explained in chronological order using FIGS. 5A to 5E. 5A to 5E are schematic diagrams showing the procedure for transferring the trolley 20 between the transport path 101 and the trolley transfer device 11, and the positions of the linear transport module 12 of the trolley 20 and the trolley transfer device 11. are shown in chronological order. Note that, hereinafter, the module controllers 110 shown in FIG. 4 provided corresponding to the linear conveyance modules 10a to 10j shown in FIG. 1 will be appropriately referred to as module controllers 110a to 110j, respectively. Further, the device controllers 111 shown in FIG. 4 provided corresponding to the trolley transfer devices 11a and 11b shown in FIG. 1 are appropriately referred to as device controllers 111a and 111b, respectively. Further, the module controllers 112 shown in FIG. 4 provided corresponding to the linear conveyance modules 12a and 12b shown in FIG. 1 are appropriately referred to as module controllers 112a and 112b, respectively. Further, the module controller 113 shown in FIG. 4 provided corresponding to the maintenance linear conveyance module 13a shown in FIG. 1 is appropriately referred to as a module controller 113a.

FIG. 5A shows that after the processing of the work W at the processing stations 30a, 30c, 30d, and 30e installed along the outbound transport path 101a has been completed, the carts 20a, 20b, 20c, and 20d are moved to the next process. It shows the started state. That is, the cart 20a has started moving after the workpiece W-1 has been processed at the processing station 30e. The cart 20b has started moving after the workpiece W-2 has been processed at the processing station 30d. The cart 20c has started moving after the workpiece W-3 has been processed at the processing station 30c. The cart 20d has started moving after the workpiece W-4 has been processed at the processing station 30a.

First, the transport controller 40 detects, based on the output signal of the position detection sensor 14a, that the linear transport module 12a of the trolley transfer device 11a is in a connected state with the linear transport module 10e of the transport path 101a. Then, the transport controller 40 transmits a drive command for the trolley 20a to the module controllers 110e and 112a. The module controllers 110e and 112a that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear transport modules 10e and 12a, respectively. Thereby, the module controllers 110e and 112a move the cart 20a from above the linear transport module 10e to above the linear transport module 12a and stop it, as shown in FIG. 5A.

Next, the transport controller 40 detects, based on the output signal of the position detection sensor 214, that the trolley 20a has been moved onto the linear transport module 12a of the trolley transfer device 11a. Then, the transport controller 40 transmits a drive command for the linear transport module 12a in a direction from the transport path 101a side to the transport path 101b side (-Y-axis direction) along the Y-axis to the device controller 111a. The device controller 111a, which has received this drive command for the linear transport module 12a, moves the linear transport module 12a of the trolley transfer device 11a in the −Y-axis direction, as shown in FIG. 5B. Thereby, the device controller 111a connects the linear conveyance module 12a with the linear conveyance module 10f of the return conveyance path 101b.

Next, the transport controller 40 detects that the linear transport module 12a of the trolley transfer device 11a is connected to the linear transport module 10f based on the output signal of the position detection sensor 14b. Then, the transport controller 40 transmits a drive command for the trolley 20a to the module controllers 112a and 110f. The module controllers 112a and 110f that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear transport modules 12a and 10f, respectively. Thereby, the module controllers 112a and 110f move the cart 20a from above the linear transport module 12a to above the linear transport module 10f, as shown in FIG. 5C.

Note that after the trolley 20a moves from above the linear transport module 12a to above the linear transport module 10f, the transport controller 40 performs control to return the linear transport module 12a of the trolley transfer device 11a that has discharged the trolley 20a. That is, the transport controller 40 transmits a drive command for the linear transport module 12a in a direction (+Y-axis direction) from the transport path 101b side to the transport path 101a side along the Y-axis to the device controller 111a. The device controller 111a, which has received the drive command for the linear transport module 12a, moves the linear transport module 12a of the trolley transfer device 11a in the +Y-axis direction, as shown in FIGS. 5D and 5E. Thereby, the device controller 111a reconnects the linear conveyance module 12a with the linear conveyance module 10e of the outward conveyance path 101a.

As described above, the trolley 20a carrying the workpiece W-1 that has been processed on the outbound transport path 101a is transferred from the outbound transport path 101a to the return transport path 101b. Since no processing is performed on the return transport path 101b, the cart 20a on the linear transport module 10f is subsequently recovered. Therefore, the transport controller 40 transmits a drive command for the trolley 20a of the trolley transfer device 11b up to the linear transport module 12b to the module controllers 110f to 110j and 112b. The module controllers 110f to 110j, 112b that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear conveyance modules 10f to 10j, 12b, respectively. Thereby, the module controllers 110f to 110j, 112b move the cart 20a from above the linear transport module 10f to above the linear transport module 12b, as shown in FIG. 5D.

As shown in FIG. 5C, at the time when the carriage 20a of the carriage transfer device 11b starts moving above the linear conveyance module 12b, the linear conveyance module 12b is transferred to the linear conveyance module 10a at the upstream end of the outward conveyance path 101a. It is stopped at the stop position connected to. That is, at this point, the linear transport module 12b of the trolley transfer device 11b is not connected to the linear transport module 10j at the downstream end of the return transport path 101b. Therefore, the transport controller 40 transmits a drive command for the linear transport module 12b in a direction (-Y-axis direction) from the transport path 101a side to the transport path 101b side along the Y-axis to the device controller 111b. The device controller 111b, which has received the drive command for the linear transport module 12b, moves the linear transport module 12b in the -Y-axis direction, as shown in FIG. It is connected to module 10j.

Here, the transport controller 40 takes into consideration the moving distance and speed of the trolley 20a and the moving distance and speed of the linear transport module 12b, and issues drive commands to the module controllers 110f to 110j and the device controller 111b. Send drive commands. That is, the transport controller 40 sends a drive command for the trolley 20a to the module controllers 110f to 110j to drive the trolley 20a without waiting for the linear transport module 12b of the trolley transfer device 11b to be connected to the linear transport module 10j. let In this way, by moving the cart 20a without waiting for the connection between the linear transport module 12b and the linear transport module 10j, the overall processing time can be shortened. Then, the transport controller 40 controls the module controllers 110f to 110j and the device controller 111b so that the linear transport module 12b is connected to the linear transport module 10j before the trolley 20a passes a predetermined position on the transport path 101b. .

Next, the transport controller 40 detects that the linear transport module 12b of the trolley transfer device 11b is connected to the linear transport module 10j based on the output signal of the position detection sensor 14c. Then, the transport controller 40 transmits a drive command for the trolley 20a to the module controllers 110j and 112b. The module controllers 110j and 112b that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear transport modules 10j and 12b, respectively. Thereby, the module controllers 110j and 112b move the cart 20a from above the linear transport module 10j to above the linear transport module 12b and stop it, as shown in FIG. 5E. In this way, the trolley 20a carrying the processed workpiece W-1 is transferred from the forward transport path 101a to the return transport path 101b and recovered. Note that the trolley 20a can be loaded with the workpiece W again and transferred to the outgoing transport path 101a by the trolley transfer device 11b.

Note that at the time shown in FIG. 5E, the linear transport module 12a of the trolley transfer device 11a is moving in the +Y-axis direction toward the forward transport path 101a, and is no longer connected to the linear transport module 10e. Not yet. Therefore, the transport controller 40 does not transmit a drive command for the carts 20b and 20c. On the other hand, the following trolley 20d can be moved to a stop position in the linear transport module 10c. For this reason, the transport controller 40 transmits a drive command for the cart 20d to the module controllers 110b and 110c.

Further, the movement of the trolley 20 between the linear transport module 13 for maintenance and the linear transport module 12 of the trolley transfer device 11 is similar to the movement of the trolley 20 between the linear transport module 10 and the linear transport module 12 described above. can be executed. Hereinafter, the movement of the trolley 20 between the linear transport module 13a for maintenance installed adjacent to the trolley transfer device 11b and the linear transport module 12b of the trolley transfer device 11b will be described as an example.

The trolley 20 can be transferred from the linear transport module 12b of the trolley transfer device 11b to the maintenance linear transport module 13a as follows. Note that the trolley 20 can be moved and stopped on the linear conveyance module 12b in the same manner as described above, for example.

First, the transport controller 40 detects, based on the output signal of the position detection sensor 214, that the trolley 20 has been moved onto the linear transport module 12b of the trolley transfer device 11b. Then, the transport controller 40 transmits a drive command for the linear transport module 12b in the Y-axis direction toward the maintenance linear transport module 13a to the device controller 111b. The device controller 111b, which has received the drive command for the linear conveyance module 12b, moves the linear conveyance module 12b of the cart transfer device 11b in the Y-axis direction, and connects the linear conveyance module 12b with the maintenance linear conveyance module 13a.

Next, the transport controller 40 detects that the linear transport module 12b of the trolley transfer device 11b has been connected to the maintenance linear transport module 13a based on the output signal of the position detection sensor 14d. Then, the transport controller 40 transmits a drive command for the trolley 20 to the module controllers 112b and 113a.

The module controllers 112b and 113a that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear transport modules 12b and 13a, respectively. Thereby, the module controllers 112b and 113a move the cart 20 from above the linear transport module 12b to above the maintenance linear transport module 13a and stop it.

On the other hand, the trolley 20 can be transferred from the maintenance linear transport module 13a onto the linear transport module 12b of the trolley transfer device 11b as follows.

First, the transport controller 40 transmits to the device controller 111b a command to drive the linear transport module 12b in the Y-axis direction toward the maintenance linear transport module 13a where the cart 20 is stopped. The device controller 111b, which has received the drive command for the linear conveyance module 12b, moves the linear conveyance module 12b of the cart transfer device 11b in the Y-axis direction, and connects the linear conveyance module 12b with the maintenance linear conveyance module 13a.

Next, the transport controller 40 detects that the linear transport module 12b of the trolley transfer device 11b has been connected to the maintenance linear transport module 13a based on the output signal of the position detection sensor 14d. Then, the transport controller 40 transmits a drive command for the trolley 20 to the module controllers 113a and 112b. The module controllers 113a and 112b that have received the drive command for the trolley 20a control the energization of the coils 19 of the linear transport modules 13a and 12b, respectively. Thereby, the module controllers 113a and 112b move the cart 20 from above the maintenance linear transport module 13a to above the linear transport module 12b and stop it. Thereafter, the trolley 20 on the linear transport module 12b can be transferred and put into the outgoing transport path 101a by the trolley transfer device 11b, for example.

As described above, in the processing system 1 according to the present embodiment, the module controllers 110 , 112 , 113 of the linear transport modules 10 , 12 , 13 and the device controller 111 of the trolley transfer device 11 are under the control of the transport controller 40 . Therefore, in this embodiment, all the carts 20 can be efficiently and safely controlled according to the progress status of the processing system 1 as a whole.

In addition, when connecting the linear transport module 12 of the trolley transfer device 11 and the linear transport module 10 of the transport path 101, as described above, the linear transport module 12 is placed at a height in the Y-axis direction relative to the linear transport module 10. It is necessary to position accurately. In this embodiment, positional deviation is corrected using the position detection sensor 14, and highly accurate positioning of the linear conveyance module 12 in the Y-axis direction is realized. Below, as shown in FIG. 5D, a case where the linear transport module 12b of the trolley transfer device 11b is connected to the linear transport module 10j of the return transport path 101b will be described as an example. Note that in other cases of connection, positional deviations can be similarly corrected and connections can be made. Furthermore, when connecting the linear conveyance module 13 for maintenance and the linear conveyance module 12, the positional deviation can be similarly corrected and the connection can be performed.

As described above, the device controller 111b moves the linear transport module 12b in the −Y-axis direction and stops the linear transport module 12b at the target stop position for coupling with the linear transport module 10j on the return transport path 101b. . A positional shift may occur in the Y-axis direction between the stopped linear transport module 12b and the linear transport module 10j.

At this time, the transport controller 40 calculates the amount of positional deviation in the Y-axis direction between the stopped linear transport module 12b and the linear transport module 10j based on the output signal of the position detection sensor 14c. Specifically, the amount of positional deviation in the Y-axis direction between the guide rail 9 of the linear transport module 12b and the guide rail 9 of the linear transport module 10j is calculated.

Next, the transport controller 40 sends a correction drive command to the device controller 111b to correct the positional deviation by driving the linear transport module 12b for correction. The correction drive command is a command to drive and move the linear conveyance module 12b by a correction movement amount corresponding to the calculated positional deviation amount in a direction that cancels out the calculated positional deviation amount. In this way, the transport controller 40 corrects the position where the linear transport module 12b is connected to the linear transport module 10j so as to reduce the amount of positional deviation.

Note that if the amount of positional deviation is too large, there is a risk of a malfunction in the trolley transfer device 11b, etc., and even if there is no malfunction, if the positional displacement is corrected, the processing efficiency in the processing system 1 may be impaired. be. Therefore, when the amount of positional deviation exceeds a predetermined threshold, instead of correcting the positional deviation of the connected position, a process of notifying that the threshold has been exceeded can be performed. In this case, the transport controller 40 can be configured to output a notification signal indicating that the amount of positional deviation exceeds a predetermined threshold and send it to the system controller 50 via the overall serial communication network 51. . The system controller 50 that has received the notification signal can temporarily stop the processing system 1 or perform warning processing such as displaying a warning to the operator.

The device controller 111b, which has received the above correction drive command, moves the linear transport module 12b of the trolley transfer device 11b by the corrected movement amount in a direction that cancels out the positional deviation amount. In this way, the device controller 111b corrects the positional deviation and connects the linear transport module 12b to the linear transport module 10j. In this way, in this embodiment, when connecting the linear transport module 12b of the trolley transfer device 11b with the linear transport module 10j, the linear transport module 12b can be positioned with high precision in the Y-axis direction with respect to the linear transport module 10j. Can be done. Further, in this embodiment, as described above, the module controllers 110, 112, 113, the device controller 111, and the position detection sensor 14 are connected to the transport controller 40 through the transport serial communication network 41, which is the same communication network. There is. Therefore, in this embodiment, the positional deviation can be corrected at high speed and the trolley 20 can be transferred at high speed.

In the present embodiment, the transport controller 40 can detect the amount of positional deviation of the connecting portion of the linear transport module 12 of the trolley transfer device 11 as a positional change of the linear transport module 12 itself, and It can be controlled as position correction. Furthermore, in the present embodiment, a warning can be issued when a positional deviation greater than a predetermined value is recognized.

In this manner, in this embodiment, damage to the transport path 101 or the trolley 20 when transferring the trolley 20 can be reduced, and the trolley 20 can be transferred at high speed.

Note that the amount of positional deviation between the linear conveyance module 12 of the above-mentioned trolley transfer device 11 and the linear conveyance module 10 of the conveyance path 101 may change due to changes over time or the like. Specifically, the amount of positional deviation may increase. The same applies to the amount of positional deviation between the linear transport module 12 of the trolley transfer device 11 and the maintenance linear transport module 13. In this case, the transport controller 40 may monitor the output signal of the position detection sensor 14 in the trolley transfer device 11. Thereby, the transport controller 40 can appropriately calculate the correction drive amount of the linear transport module 12 of the trolley transfer device 11 according to the amount of positional deviation that changes due to changes over time, etc., and drive the linear transport module 12 for correction. Can be done. Therefore, in this case, the linear conveyance module 12 of the trolley transfer device 11 can be positioned with respect to the linear conveyance modules 10 and 13 with always high positioning accuracy according to the varying amount of positional deviation.

[Second embodiment]
A second embodiment of the present invention will be described using FIGS. 6 and 7. Note that the same components as those in the first embodiment are given the same reference numerals, and the description thereof will be omitted or simplified.

6A and 6B are schematic diagrams showing the configuration of the truck fixing mechanism 15' according to the present embodiment, and are top views of the truck fixing mechanism 15' according to the present embodiment and the truck 20 fixed thereby, respectively, as viewed from above. and a side view seen from the side. FIG. 7 is a control block diagram showing the control configuration of the processing system according to this embodiment.

The trolley fixing mechanism 15' according to the present embodiment fixes the trolley 20 on the transport path 101 at a predetermined stop position on the transport path 101, similar to the trolley fixing mechanism 15 according to the first embodiment, but the installation location is different. This is different from the first embodiment. That is, the difference between this embodiment and the first embodiment is that the trolley fixing mechanism 15 according to the first embodiment is installed on the transport path 101, whereas the trolley fixing mechanism 15' according to the present embodiment is installed on the trolley 20. The point is that it is installed in

As shown in FIGS. 6A and 6B, the truck fixing mechanism 15' according to this embodiment includes a pair of fixing units 150' installed on the truck 20. Each fixing unit 150' has a fixing pad 151' and a fixing actuator 152'. The fixing pad 151' is configured to be able to be stretched against the fence 1011 of the conveyance path 101 toward the outside of the trolley 20 in the Y-axis direction. The fixed actuator 152' is an actuator that drives the fixed pad 151' in the Y-axis direction. In addition to the permanent magnet 21 for moving the truck 20, a permanent magnet 22 installed on the truck 20 is connected to the fixed actuator 152'. The permanent magnet 22 is a permanent magnet that functions as a force receiving part for driving the fixed actuator 152' by the electromagnetic force generated between the permanent magnet 22 and the coil 19 of the linear conveyance module 10. Note that instead of the permanent magnet 22, a ferromagnetic material such as an iron core may be used as the force receiving portion.

The electromagnetic force generated between the force-receiving permanent magnet 22 and the coil 19 is converted from rotational motion to linear motion by a transmission mechanism such as a rack and pinion, and is then transferred as a driving force to the fixed actuator 152'. to drive. Note that the fixed actuator 152' is driven under a command from the module controller 110.

The truck fixing mechanism 15' installed on the truck 20 drives the fixed actuators 152' of the pair of fixing units 150' to extend toward the outside of the truck 20 in the Y-axis direction. Thereby, the truck fixing mechanism 15' fixes the truck 20 in place by pushing the pair of fixing pads 151' against the fences 1011 at both ends of the conveyance path 101.

In the first embodiment, since the cart fixing mechanism 15 is installed on the transport path 101, the position where the cart 20 is fixed by the cart fixing mechanism 15 is determined when the transport path 101 is designed. In contrast, in this embodiment, the trolley fixing mechanism 15' is installed on the trolley 20, and by changing the energization control of the coil 19 of the linear conveyance module 10, the trolley fixing mechanism 15' fixes the trolley 20. The position can be changed. Therefore, in this embodiment, the position where the trolley 20 is fixed by the trolley fixing mechanism 15' can be set and changed with a high degree of freedom. When producing a wide variety of products within the same processing system, the location where the processing is performed and the external forces applied to the workpieces often differ depending on the product being produced. In this regard, in this embodiment, the position where the trolley 20 is fixed by the trolley fixing mechanism 15' can be changed simply by changing the software control. Therefore, this embodiment has the advantage of being able to shorten the downtime of the processing system required for setup changes.

In this manner, in this embodiment, by installing the truck fixing mechanism 15' on the truck 20, it is possible to provide flexibility in determining the fixing position of the truck 20. According to this embodiment, even if the fixing position of the truck 20 is modified, the truck stop command and the truck fixing command can be changed using software, and no hardware changes are required. Therefore, in this embodiment, the number of correction steps required to correct the fixing position of the trolley 20 can be reduced.

Furthermore, in this embodiment, as described above, the fixed actuator 152' of the trolley fixing mechanism 15' is driven by controlling the energization of the coil 19 of the linear conveyance module 10. Therefore, unlike the control configuration of the first embodiment shown in FIG. 4, in this embodiment, as shown in FIG. 7, the trolley fixing mechanism 15' is not connected to the input/output control port of the system controller 50.

Control of the truck fixing mechanism 15' according to this embodiment is executed as follows. First, the system controller 50 notifies the transport controller 40 of information about the processing station 30 where the trolley 20 needs to be fixed. The transport controller 40 transmits control information for the coil 19 for fixing the trolley 20 to the module controller 110 of the linear transport module 10 to which the trolley 20 is to be fixed. The module controller 110 controls the energization of the coil 19 according to the received control information, drives the truck fixing mechanism 15', and fixes the truck 20.

Note that the truck fixing mechanism 15' according to this embodiment can also be used in combination with the truck fixing mechanism 15 according to the first embodiment. By using both mechanisms together, it is possible to avoid displacement of the cart 20 at its stop position even in a process where a larger external force is applied.

[Third embodiment]
A third embodiment of the present invention will be described using FIGS. 8 and 9. Note that the same components as those in the first and second embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

FIG. 8 is a schematic diagram showing the overall configuration of the processing system 2 according to this embodiment, and is a top view of the entire processing system 2 including the transport system 5 viewed from above.

In the first and second embodiments, an annular conveyance path is constituted by two conveyance paths 101a and 101b and two trolley transfer devices 11a and 11b connected to both ends thereof. In contrast, in the present embodiment, a curved conveyance module 16 is used instead of the trolley transfer device 11, and a closed-loop, more specifically oval-shaped circulation conveyance path 101' is configured. has been done. In this point, this embodiment differs from the first and second embodiments.

As shown in FIG. 8, in the conveyance system 5 according to this embodiment, curved conveyance modules 16b and 16c are installed in place of the trolley transfer device 11a. The curved conveyance modules 16b and 16c are adjacent to each other and form a semicircular conveyance path. An end of the curved conveyance module 16b is connected to an end of the linear conveyance module 10e on the outward conveyance path 101a. An end of the curved conveyance module 16c is connected to an end of the linear conveyance module 10f on the return conveyance path 101b.

Moreover, in the conveyance system 5 according to this embodiment, curved conveyance modules 16d and 16a are installed in place of the trolley transfer device 11b. The curved transport modules 16d and 16a are adjacent to each other and form a semicircular transport path.The end of the curved transport module 16d is connected to the end of the straight transport module 10j of the return transport path 101b. . An end of the curved conveyance module 16a is connected to an end of the linear conveyance module 10a of the outward conveyance path 101a.

The curved conveyance module 16 is a curved conveyance module in which the cart 20 moves in a curved manner, specifically, in an arc shape. The curved conveyance module 16 has substantially the same configuration as the linear conveyance module 10, except that it has a curved guide rail 9 instead of the straight guide rail 9. In each curved conveyance module 16, similarly to the linear conveyance module 10, the module controller 116 (see FIG. 9) controls the energization of its coil 19, and controls the movement of the cart 20 thereon.

In this way, the conveyance system 5 according to the present embodiment has a closed conveyance path 101' having a closed loop, that is, a configuration in which there is no terminal end on the outward and return paths. Therefore, in this embodiment, drive control of the trolley 20 can be executed without requiring confirmation of the connection state between the linear conveyance modules 10 and 12 as in the first embodiment. Therefore, the processing system 2 according to the present embodiment can make the cart 20 travel faster and more safely than the processing system 1 according to the first embodiment.

Specifically, in the first embodiment, for example, as shown in FIG. 5E, even though the process at the processing station 30e has been completed, the linear transport module 10e and the linear transport module of the trolley transfer device 11a 12a may not be connected. In this case, in order to move the cart 20b that has completed the process at the processing station 30e, it is necessary to wait for the connection between the linear transport modules 10e and 12a to be established. On the other hand, in this embodiment, there is no need to wait for the establishment of such a connection between the linear conveyance modules 10 and 12, so it is possible to eliminate the waste of the cart 20 being in a standby state.

On the other hand, in the transport system 5 according to this embodiment, the closed transport path 101' does not have an end. Therefore, in the conveyance system 5 according to the present embodiment, in order to enable the maintenance linear conveyance module 13 to be connected to the conveyance path 101', some of the linear conveyance modules 10 in the conveyance path 101' are connected to the carriage transfer device 11. It has been replaced by a linear transport module 12.

Specifically, in this embodiment, as shown in FIG. 8, a cart transfer device 11c is installed on the return transport path 101b so as to straddle the boundary of the processing work area 100. Outside the processing work area 100, a maintenance linear transport module 13c is installed adjacent to one side of the trolley transfer device 11c.

The trolley transfer device 11c includes a movable linear transport module 12c that is movable in the Y-axis direction, similar to the trolley transfer devices 11a and 11b according to the first embodiment. The linear conveyance module 12c is configured to be able to function as a part of the linear conveyance module 10 that constitutes the return path 101b.

The linear transport module 12c of the trolley transfer device 11c is configured to be movable to a position where it is connected to the linear transport modules 10g and 10h of the return transport path 101b. This allows the linear conveyance module 12c to constitute a part of the return conveyance path 101b. Further, the linear conveyance module 12c is configured to be movable to a position where it is connected to the maintenance linear conveyance module 13c. Thereby, the trolley 20 can be transferred between the linear transport module 12c and the maintenance linear transport module 13c.

The maintenance linear conveyance module 13c is installed outside the processing work area 100 including the conveyance path 101', similarly to the maintenance linear conveyance modules 13a and 13b according to the first embodiment. Therefore, in the maintenance linear transport module 13c, as well as the maintenance linear transport modules 13a and 13b, the workpiece W is loaded onto the trolley 20, the trolley 20 is collected, and the trolley 20 is maintained without stopping the process operation. It can be carried out.

In this manner, in this embodiment, the maintenance linear conveyance module 13c can be connected to the closed conveyance path 101' without stopping the work process. Therefore, according to the present embodiment, even if the conveyance path 101' is closed, it is possible to efficiently access a specific cart 20 in a short time, and therefore, the specific cart 20 can be accessed efficiently without stopping other carts 20. Collection, input, maintenance, etc. can be performed.

FIG. 9 is a control block diagram showing the control configuration of the processing system 2 according to this embodiment. Note that the control configuration shown in FIG. 9 is for the case where a truck fixing mechanism 15' installed on the truck 20 is used, similar to the control configuration of the second embodiment shown in FIG. In this embodiment as well, similarly to the first embodiment, the carriage 20 can be fixed using the carriage fixing mechanism 15 installed on the conveyance path 101' instead of or together with the carriage fixing mechanism 15'.

This embodiment differs from the first embodiment in that, as shown in FIG. 9, a module controller 116 that controls a curved conveyance module 16 is connected to a conveyance controller 40 via a conveyance system serial communication network 41. . A module controller 116 is provided corresponding to each of the plurality of curved conveyance modules 16. Each module controller 116 is connected to a position detection sensor 414 that detects the position of the carriage 20 on the corresponding curved conveyance module 16 in the conveyance direction. The position detection sensor 414 as a position detection unit is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 414 is not shown in FIG.

In response to a command from the transport controller 40, the module controller 116 controls the energization of the coil 19 of the corresponding curved transport module 16 under its control. Thereby, the module controller 116 controls the movement of the trolley 20 on the corresponding curved conveyance module 16.

Further, the trolley transfer device 11c is provided with a device controller 111, similar to the trolley transfer devices 11a and 11b according to the first embodiment. Further, the linear transport module 12c of the trolley transfer device 11c is provided with a module controller 112, similar to the linear transport modules 12a and 12b according to the first embodiment. Further, the maintenance linear transport module 13c is provided with a module controller 113, similar to the maintenance linear transport modules 13a and 13b according to the first embodiment.

Further, the trolley transfer device 11c is provided with a position detection sensor 14f as the position detection sensor 14 that detects the position in the Y-axis direction of the linear conveyance module 12c connected to the maintenance linear conveyance module 13c. Further, the trolley transfer device 11c includes a position detection sensor 14g as a position detection sensor 14 that detects the position in the Y-axis direction of the linear transfer module 12c connected to the linear transfer module 10g, 10h of the return path 101b. It is provided.

Movement of the trolley 20 between the linear transport module 13c for maintenance and the linear transport module 12c of the trolley transfer device 11c can also be performed in the same manner as in the first embodiment. That is, this movement of the trolley 20 can be executed in the same manner as the movement of the trolley 20 between the maintenance linear transport module 13a and the linear transport module 12b of the trolley transfer device 11b in the first embodiment.

Also, in this embodiment, similarly to the first embodiment, positional shift correction using the position detection sensor 14f allows the linear transport module 12c of the trolley transfer device 11c to be moved along the Y axis relative to the maintenance linear transport module 13c. It is possible to position with high precision in the direction. Further, similarly to the first embodiment, the linear transport module 12c is positioned with high accuracy in the Y-axis direction with respect to the linear transport modules 10g and 10h of the transport path 101b by correcting positional deviation using the position detection sensor 14g. be able to.

[Fourth embodiment]
A fourth embodiment of the present invention will be described using FIG. 10. Note that the same components as those in the first to third embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

FIG. 10 is a schematic diagram showing the overall configuration of the processing system 2' according to the present embodiment, and is a top view of the entire processing system 2' including the transport system 5 viewed from above. Note that in this embodiment as well, a control configuration similar to the control configuration shown in FIG. 9 can be adopted.

The basic configuration of the processing system 2' according to this embodiment is the same as the configuration of the processing system 2 according to the third embodiment. The processing system 2' according to this embodiment differs from the processing system 2 according to the third embodiment in that the linear transport module 12c of the trolley transfer device 11c is connected to the maintenance linear transport module 13c, The point is that it can also be connected to the linear conveyance module 13d. That is, in the conveyance system 5 according to this embodiment, the linear conveyance modules 13c and 13d for maintenance can be connected to both ends of the linear conveyance module 12c.

In the conveyance system 5 according to this embodiment, as shown in FIG. 10, another linear conveyance module 13d for maintenance is installed outside the processing work area 100. The other linear transport module 13d for maintenance is installed adjacent to the other side of the trolley transfer device 11c opposite to the side where the linear transport module 13c for maintenance is installed. The module controller 113 is also provided for the maintenance linear transport module 13d, similarly to the maintenance linear transport module 13c.

The linear transport module 12c of the trolley transfer device 11c is configured such that one end thereof is at a stop position where it is connected to the maintenance linear transport module 13c, and the other end is connectable to another maintenance linear transport module 13d. has been done. That is, in this embodiment, the linear conveyance module 12c is configured to be connectable with the maintenance linear conveyance modules 13c and 13d at both ends thereof at the same stop position. Thereby, the trolley 20 can be transferred between the linear transport module 12c and either of the maintenance linear transport modules 13c and 13d.

In this way, in the transport system 5 according to the present embodiment, the linear transport module 12c of the trolley transfer device 11c can be simultaneously connected to both of the two maintenance linear transport modules 13c and 13d at one stop position. can. Thereby, in this embodiment, the following movement of the trolley 20 is possible. In this embodiment, since the linear transport module 12c of the trolley transfer device 11c connects both of the two maintenance linear transport modules 13c and 13d at the same time, the operation can be performed in a shorter time without human intervention.

For example, the trolley 20e on which the workpiece W-5 to be processed is mounted is prepared in advance on the maintenance linear transport module 13d. On the other hand, the cart 20a on which the processed workpiece W-1 is mounted is recovered to the maintenance linear transport module 13c. At the timing of recovering the cart 20a, the cart 20e carrying the work W-5 is moved to the linear transport module 12c of the cart transfer device 11c. The trolley 20e that has been moved to the linear transport module 12c is placed into the transport path 101' by the trolley transfer device 11c. The cart 20e placed in the transport path 101' is moved to the forward transport path 101a, and the workpiece W-5 is processed. In this way, in this embodiment, the workpiece W to be machined can be introduced at the same time as the workpiece W that has been processed is collected, so that the workpiece W can be collected and introduced more efficiently in a shorter time. .

[Fifth embodiment]
A fifth embodiment of the present invention will be described using FIG. 11. Note that the same components as those in the first to fourth embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

FIG. 11 is a schematic diagram showing the overall configuration of the processing system 2'' according to the present embodiment, and is a top view of the entire processing system 2'' including the transport system 5 viewed from above. Note that in this embodiment as well, a control configuration similar to the control configuration shown in FIG. 9 can be adopted.

The basic configuration of the processing system 2'' according to this embodiment is the same as the configuration of the processing systems 2 and 2' according to the third and fourth embodiments.The difference from the third and fourth embodiments is that The device 11d intersects with the transport path at two places, and the trolley transfer device 11d has two linear transport modules 12d and 12e.

In the conveyance system 5 according to the present embodiment, as shown in FIG. 11, the trolley transfer device 11d intersects with the forward and backward conveyance paths 101a and 101b, and provides a processing work area on each side of the conveyance paths 101a and 101b. It is set up so as to straddle 100 boundaries.

Further, in this embodiment, processing stations 30a to 30d are installed along the forward transport path 101a, and processing stations 30e to 30h are installed along the return transport path 101b. The trolley transfer device 11d intersects the conveyance path 101a between the processing stations 30c and 30d. Moreover, the trolley transfer device 11d intersects with the conveyance path 101b between the processing stations 30e and 30f.

On the outside of the processing work area 100 on the transport path 101b side, maintenance linear transport modules 13c and 13d are installed adjacent to both sides of the trolley transfer device 11d, similar to the fourth embodiment. Outside the processing work area 100 on the transport path 101a side, maintenance linear transport modules 13e and 13f are installed adjacent to both sides of the trolley transfer device 11d, similar to the maintenance linear transport modules 13c and 13d. ing.

The trolley transfer device 11d includes movable linear transport modules 12d and 12e that are movable in the Y-axis direction. The trolley transfer device 11d drives the linear transport modules 12d and 12e in the Y-axis direction using mutually independent uniaxial actuators (not shown). The linear conveyance module 12d is configured to be able to function as a part of the linear conveyance module 10 that constitutes the return conveyance path 101b, and can also function as a part of the linear conveyance module 10 that constitutes the outward conveyance path 101a. It is composed of The linear conveyance module 12e is configured to be able to function as a part of the linear conveyance module 10 that constitutes the outward conveyance path 101a, and can also function as a part of the linear conveyance module 10 that constitutes the backward conveyance path 101b. It is composed of

One linear transport module 12d of the trolley transfer device 11d is configured to be movable to a position where it is connected to the linear transport modules 10g and 10h on the return transport path 101b. Thereby, the linear conveyance module 12d can constitute a part of the return conveyance path 101b. Further, the linear conveyance module 12d is configured to be movable to a position where it is connected to the linear conveyance modules 10c and 10d on the outbound conveyance path 101a. Thereby, the linear conveyance module 12d can constitute a part of the outward conveyance path 101a. Furthermore, the linear conveyance module 12d is configured to be movable to a position where it is connected to the maintenance linear conveyance modules 13c and 13d. Thereby, the trolley 20 can be transferred between the linear transport module 12d and either of the maintenance linear transport modules 13c and 13d. The stop position where the linear conveyance module 12d connects with the maintenance linear conveyance modules 13c and 13d is the retracted position of the linear conveyance module 12d when another linear conveyance module 12e forms part of the return path 101b. It has become.

The other linear conveyance module 12e of the trolley transfer device 11d is configured to be movable to a position where it is connected to the linear conveyance modules 10c and 10d on the outbound conveyance path 101a. Thereby, the linear conveyance module 12e can constitute a part of the outward conveyance path 101a. Further, the linear conveyance module 12e is configured to be movable to a position where it is connected to the linear conveyance modules 10g and 10h on the return path 101b. Thereby, the linear conveyance module 12e can constitute a part of the return conveyance path 101b. Furthermore, the linear conveyance module 12e is configured to be movable to a position where it is connected to the maintenance linear conveyance modules 13e and 13f. Thereby, the trolley 20 can be transferred between the linear transport module 12e and either of the maintenance linear transport modules 13e and 13f. The stop position where the linear conveyance module 12e connects with the maintenance linear conveyance modules 13e and 13f is the retracted position of the linear conveyance module 12e when another linear conveyance module 12d constitutes a part of the outward conveyance path 101a. It has become.

The trolley transfer device 11d is provided with a device controller 111, similar to the trolley transfer devices 11a and 11b according to the first embodiment. Further, the linear transport modules 12d and 12e of the trolley transfer device 11d are provided with a module controller 112, similar to the linear transport modules 12a and 12b according to the first embodiment. Further, the maintenance linear transport modules 13c, 13d, 13e, and 13f are each provided with a module controller 113, similarly to the maintenance linear transport modules 13a, 13b according to the first embodiment.

Further, the trolley transfer device 11d is provided with a position detection sensor 14f as the position detection sensor 14 that detects the position in the Y-axis direction of the linear conveyance module 12d connected to the maintenance linear conveyance modules 13c and 13d. In addition, the trolley transfer device 11d includes a position detection sensor 14g as a position detection sensor 14 that detects the position in the Y-axis direction of the linear transfer module 12d connected to the linear transfer modules 10g and 10h of the return path 101b, respectively. It is provided.

In addition, the trolley transfer device 11d includes a position detection sensor 14h as a position detection sensor 14 that detects the position in the Y-axis direction of the linear conveyance module 12e connected to the linear conveyance modules 10c and 10d of the outward conveyance path 101a. It is provided. The trolley transfer device 11d is provided with a position detection sensor 14i as the position detection sensor 14 that detects the position in the Y-axis direction of the linear conveyance module 12e connected to the maintenance linear conveyance modules 13e and 13f.

Movement of the trolley 20 between the linear transport modules 13c and 13d for maintenance and the linear transport module 12d of the trolley transfer device 11d can also be performed in the same manner as in the first embodiment. Furthermore, movement of the trolley 20 between the maintenance linear transport modules 13e and 13f and the linear transport module 12e of the trolley transfer device 11d can be performed in the same manner as in the first embodiment. That is, the movement of these carts 20 can be performed in the same manner as the movement of the carts 20 between the maintenance linear transfer module 13a and the linear transfer module 12b of the cart transfer device 11b in the first embodiment.

Further, in this embodiment as well, as in the first embodiment, the linear transport modules 12d and 12e of the trolley transfer device 11d can be positioned with high precision.

That is, as in the first embodiment, one linear transport module 12d is positioned with high precision in the Y-axis direction with respect to the maintenance linear transport modules 13c and 13d by positional deviation correction using the position detection sensor 14f. be able to. In addition, as in the first embodiment, by correcting positional deviation using the position detection sensor 14g, one linear transport module 12d can be moved with high accuracy in the Y-axis direction relative to the linear transport modules 10g and 10h on the transport path 101b. Can be positioned. Furthermore, as in the first embodiment, by correcting positional deviation using the position detection sensor 14h, one linear transport module 12d can be moved with high accuracy in the Y-axis direction relative to the linear transport modules 10c and 10d of the transport path 101a. Can be positioned.

In addition, similarly to the first embodiment, by correcting the positional deviation using the position detection sensor 14h, the other linear transport module 12e can be moved with high accuracy in the Y-axis direction relative to the linear transport modules 10c and 10d of the transport path 101a. Can be positioned. Further, similarly to the first embodiment, the other linear transport module 12e is positioned with high precision in the Y-axis direction with respect to the maintenance linear transport modules 13e and 13f by correcting the positional deviation using the position detection sensor 14i. be able to. Furthermore, similarly to the first embodiment, by correcting the positional deviation using the position detection sensor 14g, the other linear transport module 12e can be moved with high precision in the Y-axis direction relative to the linear transport modules 10g and 10h on the transport path 101b. Can be positioned.

In the processing system 2'' according to the present embodiment, the cart transfer device 11d is located between the processing stations 30.Thereby, the processing system 2'' according to the present embodiment changes the processing order by the processing stations 30, Furthermore, it is possible to omit processing by some of the processing stations 30.

For example, if the processing steps performed by the processing stations 30d and 30e are not necessarily necessary for all the workpieces W, after the processing steps performed by the processing station 30c are completed, the cart 20 on the transport path 101a is transferred linearly by the cart transfer device 11d. Move to module 12e. Next, the linear transport module 12e is moved in the Y-axis direction toward the transport path 101b, and the linear transport module 12e is connected to the linear transport modules 10g and 10h on the transport path 101b at a position that can be detected by the position detection sensor 14g. Next, the cart 20 on the linear transport module 12e is moved to the linear transport module 10h and sent to the processing station 30f. In this way, the processing steps by the processing stations 30d and 30e can be omitted.

Conversely, for example, the machining steps performed by the machining stations 30d and 30e can be repeated multiple times in succession. In this case, after the processing step by the processing station 30e is completed, the trolley 20 on the transport path 101b is moved to the linear transport module 12d of the trolley transfer device 11d. Next, the linear conveyance module 12d is moved in the Y-axis direction toward the conveyance path 101a, and the linear conveyance module 12d is connected to the linear conveyance modules 10c and 10d on the conveyance path 101a at a position that can be detected by the position detection sensor 14h. Next, the cart 20 on the linear transport module 12d is moved to the linear transport module 10d, and sent to the processing station 30d again. In this way, the processing steps by the processing stations 30d and 30e can be repeated.

Furthermore, for example, the order of the processing steps performed by the processing stations 30e and 30d can be changed. In this case, after the processing step by the processing station 30c is completed, the trolley 20 on the transport path 101a is moved to the linear transport module 12e of the trolley transfer device 11d. Next, the linear transport module 12e is moved in the Y-axis direction toward the transport path 101b, and the linear transport module 12e is connected to the linear transport modules 10g and 10h on the transport path 101b at a position that can be detected by the position detection sensor 14g. Next, the cart 20 on the linear transport module 12e is moved to the linear transport module 10g and sent to the processing station 30e. After the machining process by the machining station 30e is completed, the cart 20 is sent to the machining station 30d by the curved conveyance modules 16c and 16b. After the machining process by the machining station 30d is completed, the trolley 20 on the transport path 101a is again moved to the linear transport module 12e of the trolley transfer device 11d. Next, the linear transport module 12e is moved in the Y-axis direction toward the transport path 101b, and the linear transport module 12e is reconnected to the linear transport modules 10g and 10h on the transport path 101b. Next, the cart 20 on the linear transport module 12e is moved to the linear transport module 10h, and sent to the processing station 30f.

In short, in this embodiment, the processing stations 30c, 30d, 30e, and 30f can be arbitrarily connected via the cart transfer device 11d, and the cart 20 can be moved between them.

Further, in this embodiment, the retracted positions of the linear transport modules 12d and 12e of the trolley transfer device 11d are provided outside the processing work area 100, respectively. These retreat positions also serve as connecting positions between the linear conveying module 12d and the maintenance linear conveying modules 13c and 13d, and connecting positions between the linear conveying module 12e and the maintenance linear conveying modules 13e and 13f. Since the retracted position also serves as the connection position in this manner, in this embodiment, it is possible to save space in the installation location of the processing system 2''.

[Sixth embodiment]
A sixth embodiment of the present invention will be described using FIGS. 12 and 13. Note that the same components as those in the first to fifth embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

FIG. 12 is a schematic diagram showing the overall configuration of the processing system 3 according to the present embodiment, and is a top view of the entire processing system 3 including the transport system 6 viewed from above. FIG. 13 is a control block diagram showing the control configuration of the processing system 3 according to this embodiment.

In the conveyance system 6 included in the processing system 3 according to the present embodiment, a plurality of curved conveyance modules 16 having the same curvature are connected to form a circular circular conveyance path 101''. In the oval circulation type conveyance path 101' according to the third to fifth embodiments, two types of conveyance modules, the linear conveyance module 10 and the curved conveyance module 16, are connected. In the circulation type conveyance path 101'', only one type of conveyance module, ie, curved conveyance modules 16 and 17 having the same curvature, is connected. Note that among the plurality of curved conveyance modules 16 and 17, the curved conveyance module 17 is the curved conveyance module 17 of the trolley transfer device 11e.

Specifically, as shown in FIG. 12, the annular conveyance path 101'' is configured by connecting curved conveyance modules 16a to 16g and 17 having the same curvature in an annular shape.This embodiment In this case, since the curvature of the conveyance path 101'' is uniform, it is possible to suppress fluctuations in the magnitude and direction of the external force applied to the cart 20 traveling on the conveyance path 101'' and to maintain these constant. According to this embodiment, it is possible to suppress the influence of positional shift due to external force of the trolley 20 traveling on the conveyance path 101'' and the work W mounted on the trolley 20.

In this embodiment, processing stations 30a to 30g are installed along the annular transport path 101''. A trolley transfer device 11e is installed. Outside the processing work area 100, a maintenance linear transport module 13g is installed adjacent to one side of the trolley transfer device 11e.

The trolley transfer device 11e has a movable curved conveyance module 17. The trolley transfer device 11e drives the curved conveyance module 17 in the OA direction, which will be described later, using a uniaxial actuator (not shown). The curved conveyance module 17 has the same configuration as the curved conveyance module 16 that constitutes the conveyance path 101'', and has the same curvature as the curved conveyance module 16. 16, the module controller 117 (see FIG. 13) controls the energization of the coil 19, and controls the movement of the cart 20 thereon.

The curved conveyance module 17 of the trolley transfer device 11e is configured to be able to function as part of the curved conveyance module 16 that constitutes the conveyance path 101''. It is configured to be movable to a position where it is connected to the modules 16a and 16g. This allows the curved conveyance module 17 to constitute a part of the conveyance path 101''.

The trolley transfer device 11e drives the curved transport module 17 in the OA direction, which is the direction connecting the end surface A of the curved transport module 17 and the center O of the transport path 101''.On the other hand, the maintenance linear transport module 13g , are installed along a direction parallel to the tangential direction of the annular conveyance path 101'', which is a direction perpendicular to the OA direction. In FIG. 12, the OA direction is along the Y-axis direction, and the maintenance linear conveyance module 13g is installed along the X-axis direction, which is a direction perpendicular to the OA direction.

Further, the curved conveyance module 17 of the trolley transfer device 11e is configured to be movable to a position where it is connected to the maintenance linear conveyance module 13g installed adjacent to the trolley transfer device 11e as described above. Thereby, the trolley 20 can be transferred between the curved conveyance module 17 and the maintenance linear conveyance module 13g.

As described above, the maintenance linear transport module 13g is installed along the direction perpendicular to the OA direction. Therefore, when the curved conveyance module 17 is connected to the maintenance linear conveyance module 13g, the trolley 20 travels in the tangential direction of the curved conveyance module 17 at the connecting portion of both module conveyances 17 and 13g. Therefore, in this embodiment, it is possible to suppress the external force that the trolley 20 receives when transferring between the two transport modules 17 and 13g.

FIG. 13 is a control block diagram showing the control configuration of the processing system 3 according to this embodiment. Note that the control configuration shown in FIG. 13 is similar to the control configuration of the second embodiment shown in FIG. 4, in which a truck fixing mechanism 15' installed on the truck 20 is used. In this embodiment as well, similarly to the first embodiment, the trolley 20 can be fixed using the trolley fixing mechanism 15 installed on the transport path 101'' instead of or together with the trolley fixing mechanism 15'.

In this embodiment, since the linear conveyance module 10 is not used in the conveyance path 101'', the module controller 110 that controls the linear conveyance module 10 is not provided, as shown in FIG. 13.

Further, the trolley transfer device 11e is provided with a device controller 111, similar to the trolley transfer devices 11a and 11b according to the first embodiment.

A module controller 117 that controls the curved conveyance module 17 of the trolley transfer device 11e is connected to the conveyance controller 40 via a conveyance system serial communication network 41. A position detection sensor 514 that detects the position of the carriage 20 on the curved conveyance module 17 in the conveyance direction is connected to the module controller 117 . The position detection sensor 514 as a position detection unit is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 514 is not shown in FIG.

In response to a command from the transport controller 40, the module controller 117 controls the energization of the coil 19 of the curved transport module 17. Thereby, the module controller 117 controls the position of the carriage 20 on the curved conveyance module 17.

Further, the trolley transfer device 11e is provided with a position detection sensor 14j as the position detection sensor 14, which detects the position in the OA direction of the curved conveyance module 17 connected to the curved conveyance module 16a of the conveyance path 101''. Further, the trolley transfer device 11e is provided with a position detection sensor 14k as the position detection sensor 14, which detects the position in the OA direction of the curved conveyance module 17 connected to the maintenance linear conveyance module 13g.

The maintenance linear conveyance module 13g is provided with a module controller 113, similar to the maintenance linear conveyance modules 13a and 13b according to the first embodiment.

Movement of the trolley 20 between the maintenance linear transport module 13g and the curved transport module 17 of the trolley transfer device 11e can also be performed in the same manner as in the first embodiment. That is, this movement of the trolley 20 can be executed in the same manner as the movement of the trolley 20 between the maintenance linear transport module 13a and the linear transport module 12b of the trolley transfer device 11b in the first embodiment.

Also, in this embodiment, similarly to the first embodiment, the curved conveyance module 17 of the trolley transfer device 11e is moved in the OA direction with respect to the maintenance linear conveyance module 13g by positional deviation correction using the position detection sensor 14k. Positioning can be performed with high precision. Further, as in the first embodiment, the curved conveyance module 17 can be positioned with high precision in the OA direction with respect to the curved conveyance module 16 of the conveyance path 101'' by correcting the positional deviation using the position detection sensor 14j. can.

In addition, in this embodiment, the case where the trolley transfer device 11e and the maintenance linear transport module 13g are installed on the annular transport path 101'' has been described, but the present invention is not limited to this. Similarly to the present embodiment, the trolley transfer device 11e and the maintenance linear conveyance module 13g can be installed on the curved portion of the oval conveyance path 101' according to the third embodiment.

[Seventh embodiment]
A seventh embodiment of the present invention will be described using FIGS. 14 and 15. Note that the same components as those in the first to sixth embodiments are designated by the same reference numerals, and the description thereof will be omitted or simplified.

FIG. 14 is a schematic diagram showing the overall configuration of the processing system 3' according to the present embodiment, and is a top view of the entire processing system 3' including the conveyance system 6 viewed from above. FIG. 15 is a control block diagram showing the control configuration of the processing system 3' according to this embodiment.

The basic configuration of the processing system 3' according to this embodiment is the same as the configuration of the processing system 3 according to the sixth embodiment. The processing system 3' according to this embodiment differs from the processing system 3 according to the sixth embodiment in the shape of the end face of the curved transport module 17' of the trolley transfer device 11f and the shape of the maintenance transport module.

In this embodiment, as shown in FIG. 14, a cart transfer device 11f is installed on the annular conveyance path 101'' so as to straddle the boundary of the processing work area 100. Curved maintenance modules 18a and 18b are installed on the outside so as to be adjacent to both sides of the trolley transfer device 11f. Note that even if both of the maintenance curved transportation modules 18a and 18b are not installed, Often, either one may be installed.

The trolley transfer device 11f has a movable curved conveyance module 17'. The trolley transfer device 11f drives the curved conveyance module 17' in a movement direction that is a predetermined radial direction of the annular conveyance path 101'' using a uniaxial actuator (not shown). It has the same configuration and the same curvature as the curved conveyance module 16 that constitutes the curved conveyance module 16. Similarly to the curved conveyance module 16, the curved conveyance module 17' has its coil 19 energized by a module controller 117 (see FIG. 15), and the movement of the cart 20 thereon is controlled.

The curved conveyance module 17' of the trolley transfer device 11f is configured to be able to function as part of the curved conveyance module 16 that constitutes the conveyance path 101''. It is configured to be movable to a position where it is connected to the curved conveyance modules 16a and 16g.

In this embodiment, both end surfaces B of the curved conveyance module 17' of the trolley transfer device 11f are parallel to the moving direction of the curved conveyance module 17' driven by the trolley transfer device 11f. On the other hand, the end surfaces of the curved conveyance modules 16a and 16g of the conveyance path 101'' that connect with the curved conveyance module 17' are also parallel to the moving direction of the curved conveyance module 17'. A transport module 17' is connectable with the curved transport modules 16a, 16g.

Further, the curved conveyance module 17' of the trolley transfer device 11f is configured such that its both ends can be connected to the maintenance curved conveyance modules 18a and 18b installed adjacent to the trolley transfer device 11f as described above. ing. The maintenance curved conveyance modules 18a, 18b are installed outside the processing work area 100 including the conveyance path 101''.The curved conveyance modules 17' and the maintenance curved conveyance modules 18a, 18b are installed at the same stop position. This allows the trolley 20 to transfer between the curved conveyance module 17' and either of the maintenance curved conveyance modules 18a and 18b.The maintenance curved conveyance module 18a, 18b each has the same configuration as the curved conveyance module 16 constituting the conveyance path 101'', and has the same curvature as the curved conveyance module 16. Similarly to the curved conveyance module 16, the maintenance curved conveyance modules 18a and 18b are each energized by a module controller 118 (see FIG. 15), and the movement of the cart 20 thereon is controlled.

Also in this embodiment, similarly to the processing system 2' according to the fourth embodiment, the curved conveyance module 17' of the trolley transfer device 11f is connected to the two maintenance curved conveyance modules 18a and 18b at one stop position. Can be done. Thereby, in this embodiment as well, similarly to the fourth embodiment, the work W can be efficiently collected and loaded in a short time.

In this way, in order for the curved transport module 17' to move in a straight line on a plane from the inside of the circle to the outside and connect with the maintenance curved transport modules 18a and 18b at the same position, the curved transport module 17' is moved as described above. Both end faces B of the module 17' must be parallel to its moving direction. That is, in a curved conveyance module having a shape in which both end faces each form a fan-shaped outer periphery parallel to the radial direction of a circle, connection with the maintenance curved conveyance modules 18a and 18b is impossible.

In addition, in order to install the maintenance curved conveyance modules 18a and 18b outside the machining work area 100 so as not to interfere with the outer shape of the conveyance path 101'', that is, the machining work area 100, the distance y and the angle θ must meet predetermined conditions. Here, the distance y is the distance from the transport path 101'' to connect the curved transport module 17' of the trolley transfer device 11f with the maintenance curved transport modules 18a and 18b. . The angle θ is a distance y from the centers of the outer end surfaces C and D of the maintenance curved conveyance modules 18a and 18b, respectively, and the center O of the annular conveyance path 101'' in the moving direction of the curved conveyance module 17'. The angle ∠CO'D formed by the center O' is 1/2 of the angle ∠CO'D.The conditions to be satisfied by the distance y and the angle θ are expressed by the following equation (1).
y(y+2r ₁ cosθ) ≧ r ₂ ² -r ₁ ² … (1)
Here, r ₁ is the inner diameter of the conveyance path 101'' defined by the fence 1011 inside the conveyance path 101''. Further, _r2 is the outer diameter of the conveyance path 101'' defined by the fence 1011 on the outside of the conveyance path 101''.

Note that in the sixth embodiment, unlike the present embodiment, the maintenance linear transport module 13g is a linear transport module, and is installed along a direction parallel to the tangential direction of the transport path 101''. In the sixth embodiment, the maintenance curved transport module 13g is installed at a position where the curved transport module 17 of the trolley transfer device 11e can be connected to the maintenance linear transport module 13g at a position where it does not interfere with the processing work area 100. be able to.

Furthermore, in the present embodiment, a case has been described in which the trolley transfer device 11f and the maintenance curved conveyance modules 18a and 18b are installed on the annular conveyance path 101'', but the present invention is not limited to this. For example, Similarly to the present embodiment, the trolley transfer device 11f and the maintenance curved conveyance modules 18a and 18b can be installed on the curved portion of the oval conveyance path 101' according to the third embodiment.

FIG. 15 is a control block diagram showing the control configuration of the processing system 3' according to this embodiment. The control configuration shown in FIG. 15 is similar to the control configuration of the second embodiment shown in FIG. 4, in which a truck fixing mechanism 15' installed on the truck 20 is used. In this embodiment as well, similarly to the first embodiment, the trolley 20 can be fixed using the trolley fixing mechanism 15 installed on the transport path 101'' instead of or together with the trolley fixing mechanism 15'.

The trolley transfer device 11f is provided with a device controller 111, similar to the trolley transfer device 11e according to the sixth embodiment. The curved conveyance module 17' of the trolley transfer device 11f is provided with a module controller 117, similar to the curved conveyance module 17 according to the sixth embodiment.

The trolley transfer device 11f is provided with a position detection sensor 14l as the position detection sensor 14, which detects the position in the moving direction of the curved conveyance module 17' connected to the curved conveyance modules 16a and 16g of the conveyance path 101''. Further, the trolley transfer device 11f is provided with a position detection sensor 14m as the position detection sensor 14, which detects the position in the movement direction of the curved conveyance module 17' connected to the maintenance curved conveyance modules 18a and 18b. .

A module controller 118 that controls the maintenance curved conveyance modules 18a and 18b is connected to the conveyance controller 40 through a conveyance system serial communication network 41, respectively. Each module controller 118 is connected to a position detection sensor 614 that detects the position of the carriage 20 on the maintenance curved conveyance module 18a, 18b in the conveyance direction. The position detection sensor 614 as a position detection unit is, for example, a linear encoder, although it is not particularly limited. Note that the position detection sensor 614 is not shown in FIG.

Movement of the trolley 20 between the maintenance curved transport modules 18a, 18b and the curved transport module 17' of the trolley transfer device 11f can also be performed in the same manner as in the first embodiment. That is, this movement of the trolley 20 can be executed in the same manner as the movement of the trolley 20 between the maintenance linear transport module 13a and the linear transport module 12b of the trolley transfer device 11b in the first embodiment.

Also, in this embodiment, similarly to the first embodiment, the curved conveyance module 17' of the trolley transfer device 11f is moved relative to the maintenance curved conveyance modules 18a and 18b by positional deviation correction using the position detection sensor 14m. positioning with high accuracy in the direction of movement. Further, similarly to the first embodiment, the curved conveyance module 17' can be positioned with high accuracy in the moving direction with respect to the curved conveyance module 16 of the conveyance path 101'' by correcting the positional deviation using the position detection sensor 14l. Can be done.

[Other embodiments]
The present invention is not limited to the above embodiments, and various modifications are possible.
For example, in the above embodiment, a case has been described in which the cart transfer device 11 is used to move the transport modules 12, 17, 17' within a plane formed by a transport path such as the Y-axis direction, but the invention is not limited to this. It is not something that will be done. As the cart transfer device, for example, a cart transfer device in which the moving direction of the linear or curved transport module, that is, the transfer direction of the cart, is the Z-axis direction can also be used. In this case, the trolley transfer device moves the transport module upward or downward with respect to the plane formed by the transport path, and moves the transport module from one transport path to another transport path or for maintenance at different positions in the Z-axis direction. The trolley can be transferred to the transport module. This allows maintenance of a specific trolley to be performed without enlarging the footprint of the transport system and without stopping the processing of other trolleys.

The transport module connection surfaces of the fixed transport path may be configured to engage with each other with projections and recesses in the traveling direction of the trolley. In such a case, it is difficult to use a trolley transfer device having a transport module that moves in a direction different from the traveling direction of the trolley within a plane formed by the transport path. Even in such a case, by using the trolley transfer device that moves the transport module in the Z-axis direction as described above, it is possible to move the trolley between different transport paths or between the transport path and the maintenance transport module. movement can be realized.

Moreover, in the above case, the maintenance transport module can be arranged at a position in the Z-axis direction different from the processing work area that does not interfere with the processing work area, and can be configured to be connectable to the trolley transfer device. As a result, even in the portion of the transport path where a curved transport module is used, restrictions regarding the end face shape of the transport module and constraints to avoid interference between the maintenance transport module and the processing work area can be significantly relaxed. can.

Further, in the above embodiment, the case where the conveyance system is configured using a synchronous linear motor has been described as an example, but the present invention is not limited to this, and the conveyance system can also be configured using a reluctance type linear motor.

Further, in the above embodiment, the case where the processing system constitutes a production line such as a workpiece assembly line has been described as an example, but the present invention is not limited to this. The present invention can be applied to a line in which a series of work steps is divided and executed at a plurality of stations, and can also be applied to a variety of work lines other than production lines.

1, 2, 2', 3, 3' Processing systems 4, 5, 6 Transport system 10 Linear transport module 11 Cart transfer device 12 Linear transport module 13 Linear transport module for maintenance 14 Position detection sensor 15, 15' Cart fixing mechanism 16 Curved transfer module 17, 17' Curved transfer module 18 Curved transfer module for maintenance 20 Cart 30 Processing station 32 Robot controller 40 Transfer controller 110 Module controller 111 Device controller 112 Module controller 116 Module controller 117 Module controller 118 Module controller W Work

Claims (21)

a first transport module in which a cart moves in a first direction;
a second transport module that is movable in a second direction intersecting the first direction, and in which the cart is movable between the first transport module and the first transport module;
a position detection unit that detects the positions of the trolley and the second transport module and outputs position information of each;
a control unit that controls movement of the trolley and the second transport module;
has
The control unit includes:
The second transport module moves the trolley located in the first transport module before the trolley reaches a position where it can move between the first transport module and the second transport module. Start a moving operation to move toward the movable position,
After the second transport module stops at the movable position, the cart is moved to the second transport module by the movement operation ,
A conveyance system , wherein a stop position of the second conveyance module is corrected based on the position information of the second conveyance module output by the position detection section . The control unit moves the cart from the first transport module to the second transport module while keeping the trolley moving without stopping.
The conveyance system according to claim 1, characterized in that: The control unit corrects the position at which the second transport module stops based on the position information output by the position detection unit after stopping the second transport module at a predetermined position. The conveyance system according to claim 1 or 2, characterized in that: The conveyance system according to claim 3, wherein the control unit calculates a positional shift amount of the second conveyance module with respect to the movable position based on the position information output by the position detection unit. . The conveyance system according to claim 4, wherein the control unit corrects a position at which the second conveyance module stops so as to reduce the amount of positional deviation. When the amount of positional deviation exceeds a predetermined threshold, the control unit outputs a notification signal indicating that the threshold has been exceeded, instead of correcting the position at which the second transport module stops. The conveyance system according to claim 4, characterized in that: The conveyance system according to any one of claims 4 to 6, wherein the positional deviation amount is a positional deviation amount in the second direction. The first transport module and the second transport module each have a coil group,
The truck has a permanent magnet or a ferromagnetic body that receives electromagnetic force from the coil group, and the permanent magnet or the ferromagnetic body is driven by the electromagnetic force received from the coil group. 8. The conveyance system according to any one of 1 to 7. further comprising a third transport module on which the trolley moves;
The second transport module is configured to be movable between the first and third transport modules to a position where it is connected to the first and third transport modules, and the second transport module is configured to be movable between the first and third transport modules. The conveyance system according to any one of claims 1 to 8, wherein the trolley is movable between. further comprising a fourth transport module on which the trolley moves;
a transport path including the first and fourth transport modules;
The conveyance system according to claim 9, wherein the third conveyance module is installed outside an area including the conveyance path. a fifth transport module installed outside the area including the transport path, in which the trolley moves;
The conveyance system according to claim 10, wherein the second conveyance module is configured to be connectable with the third and fifth conveyance modules between the third and fifth conveyance modules. The conveyance path includes sixth and seventh conveyance modules in which the trolley moves,
11. The second transport module is configured to be movable between the sixth and seventh transport modules to a position where it is connected to the sixth and seventh transport modules. 12. The conveyance system according to 11. The second transport module is a curved transport module,
The conveyance system according to any one of claims 9 to 12, wherein the third conveyance module is a linear conveyance module. The second transport module is a curved transport module,
The conveyance system according to any one of claims 9 to 13, wherein the third conveyance module is a curved conveyance module having the same curvature as the second conveyance module. The conveyance system according to any one of claims 1 to 14, wherein the second direction is a direction perpendicular to the first direction. The conveyance system according to any one of claims 1 to 14, wherein the second direction is a horizontal direction. The conveyance system according to any one of claims 1 to 14, wherein the second direction is a vertical direction. The conveyance system according to any one of claims 1 to 16, wherein the position detection section is an encoder. a first transport module in which the trolley moves in a first direction; and a second transport module in which the trolley is movable between the first transport module and the first transport module; a transport module; a position detection unit that detects the positions of the trolley and the second transport module and outputs position information of each; and a control unit that controls movement of the trolley and the second transport module. A method for controlling a conveyance system comprising:
The control unit includes:
The second transport module moves the trolley located in the first transport module before the trolley reaches a position where it can move between the first transport module and the second transport module. Start a moving operation to move toward the movable position,
After the second transport module stops at the movable position, the cart is moved to the second transport module by the movement operation ,
A control method comprising : correcting a stop position of the second transport module based on the position information of the second transport module output by the position detection section . The conveyance system according to any one of claims 1 to 18,
A processing system comprising: a processing section that processes a workpiece transported by the trolley. A method for manufacturing an article, comprising manufacturing the article using the processing system according to claim 20,
a step of transporting the workpiece by the trolley;
A method for manufacturing an article, comprising: processing the workpiece transported by the trolley by the processing section.

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