JP2005119752A - Zone controller, controller and conveyor system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a zone controller capable of creating a conveyor line corresponding to objects to be conveyed having various kinds of shapes and weight by interlocking control units each other. <P>SOLUTION: The zone controller has a signal output terminal 15 for outputting a driving state signal indicating the driving state of a driving roller; a signal input terminal 16 for inputting the transmitted driving state signal; and a control means 10 for generating a control signal for driving the driving roller. The control means 10 is constituted such that it generates the control signal by determining the requirement of driving of the driving roller, and main control for outputting the driving state signal through the signal output terminal 15 using the control signal and driven control for driving the driving roller by interlocking with the control by the zone controller 1 at the transmission side are switchable using the driving state signal transmitted through the signal input terminal 16 as the control signal. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a zone controller used in a zone-controlled conveyor system. More specifically, the present invention relates to a configuration in which adjacent control zones are independently operated or linked to each other by switching the wiring and setting of the zone controller so that a conveyor line can be constructed in accordance with the shape and weight of the object to be conveyed.
[0002]
[Prior art]
As a conventional roller conveyor system, a system in which a conveyance line is divided into a plurality of control zones and a conveyor unit having a zone controller is provided for each control zone to perform conveyance control is disclosed in, for example, JP-A-11-199030. It is disclosed in the publication.
[0003]
In this conventional conveyor system, a conveying motor roller and a free roller are provided for each zone, and the motor roller and the free roller are connected to each other by a winding belt wound around each other. In addition, each unit is provided with a photoelectric driver for detecting a stock and a motor driver (controller) for driving a motor roller.
[0004]
Each zone controller is connected to each other, and rotates, brakes, and stops the motor roller according to the load signal of its own zone while referring to the load signal transmitted from the upstream zone and the downstream zone. Is. By such cooperation control between zone controllers, zero pressure accumulation control is performed in which conveyance is performed while avoiding collision between objects to be conveyed.
[0005]
In other words, in such a roller conveyor system, a unit having a uniform shape is used for each control zone, and the required number of units are arranged according to the length of the conveyor line, so that zero pressure accumulation and conveyance can be achieved by distributed control. The conveyor system to perform can be constructed easily.
[0006]
[Problems to be solved by the invention]
However, such a conveyor system has the advantage of improving the versatility by unifying the shape and specifications of each unit. However, on the other hand, there is also an adverse effect caused by the unit having the same shape and conveyance capability.
[0007]
For example, as shown in FIG. 11, when the article to be conveyed W is longer than the unit U, the article to be conveyed W straddles a plurality of units Ua and Ub during conveyance. Could not do. For this reason, when conveying a long thing, the to-be-conveyed object W had to be mounted and conveyed so that it might protrude in the width direction of the unit U, and the stable conveyance could not be performed.
[0008]
Further, as shown in FIG. 12, when the width of the transported object W is larger than the width of the unit U, the support of the transported object W becomes unstable and stable transport cannot be performed. .
[0009]
Furthermore, even if the shape of the object to be conveyed W is within the specification range of the unit U, the weight of the object to be conveyed W exceeds the conveying capacity of the unit U, or as shown in FIG. In the arrangement in which Ub is inclined upward (or downward), there is a problem that the driving force and braking force for conveyance are insufficient.
[0010]
In other words, in order to carry out stable conveyance corresponding to the shape and weight of the object to be conveyed or the inclination state of the conveyor line, a number of conveyor units having different shapes and specifications had to be prepared. For this reason, the construction of the conveyor line is complicated, and the cost is increased.
[0011]
The present invention is proposed in view of such circumstances, and by switching and setting the zone controller of each unit or changing the wiring between the controllers, a plurality of units are operated in an interlocked manner. An object of the present invention is to provide a zone controller capable of carrying an object to be conveyed having a shape and weight.
[0012]
[Means for Solving the Problems]
The zone controller of the present invention proposed to achieve the above object is a zone controller of a predetermined control zone of a roller conveyor line divided into a plurality of control zones arranged in the transport direction, and is provided in the predetermined control zone. For driving control of the transport driving roller, a signal output terminal for outputting a driving state signal indicating the driving state of the driving roller to another zone controller and a driving state signal transmitted from the other zone controller are input. A signal input terminal; and a control unit that generates a control signal for driving the drive roller. The control unit determines whether or not the drive roller needs to be driven and generates a control signal. Driving control signals using signals are output to other zone controllers via signal output terminals, and via signal input terminals With the driving status signal transmitted from the zone controller as a control signal, there is a switchable configuration and a driven control for driving the driving roller in conjunction with the control of the transmission source zone controller. Switching between the main control and the follow control can be performed by forcibly setting a predetermined signal to a predetermined value using a switch or the like, and the main control and the follow control can be performed by changing the wiring between the controllers. It is also possible to adopt a logic circuit configuration that can be switched.
[0013]
Here, the zone controller of the present invention avoids the collision between the objects to be conveyed while conveying the objects to be conveyed downstream by performing the conveyance control for each control zone in cooperation between the control zones. The roller conveyor line that performs the zero pressure accumulation operation is preferably employed. It is preferable that conveyance at the same speed is performed in each control zone.
[0014]
Here, for convenience, in the following description, it is assumed that one control zone is composed of one unit (conveyor unit). However, each control zone does not have to be an independent configuration as one unit. For example, a plurality of control zones are provided in one unit, and a zone controller is provided for each control zone to drive a conveyance drive roller. You can also
[0015]
According to the zone controller of the present invention, the conveyance control can be performed by switching the control by the control means to either the main drive control or the driven control.
[0016]
In the main control, a control signal is generated by determining whether or not the drive roller needs to be driven, and control is performed to output a drive state signal using the generated control signal to another zone controller via a signal output terminal. .
[0017]
In the follow-up control, it is not determined whether the drive roller needs to be driven, and the drive roller is driven using a drive state signal transmitted from another zone controller via the signal input terminal as a control signal. Is called.
[0018]
In other words, according to the zone controller of the present invention, switching between the main driving control for determining whether or not the driving roller needs to be driven and the driven control for performing the operation linked to the driving of the driving roller of another controller is performed. Is possible.
[0019]
By adopting a control unit using the zone controller of the present invention, various conveyor systems can be configured.
[0020]
As one configuration example of the conveyor system, a plurality of units are arranged in a line in the conveyance direction of the object to be conveyed, and a group is formed for each predetermined number of adjacent units. Then, one zone controller in each group is set to perform the main drive control and the other zone controller is set to perform the follow control, and the signal output terminal of the zone controller that performs the main drive control and each zone controller that performs the follow control. Connect to the signal input terminal. As a result, the driving roller is driven in an interlocked manner for each group, and each group can be transported equivalently as one control zone.
[0021]
According to the conveyor system having this configuration, a new control zone that is equivalently long can be created by grouping every two units or three or more units in the transport direction. .
[0022]
Thereby, even when the length of the object to be conveyed exceeds the length of the unit, stable zero pressure accumulation and conveyance can be performed only by switching the control of the zone controller.
[0023]
As another configuration example of the conveyor system, a plurality of units are arranged in parallel in the transport direction of the object to be transported, and the control zones adjacent in the row direction (unit width direction) are grouped together. Form. Each zone controller is configured to perform main drive control with one zone controller in each group and to perform follow-up control with other zone controllers in the group. Connect the signal input terminal of the zone controller. As a result, the driving roller is driven in an interlocked manner for each group, and each group can be transported equivalently as one control zone.
[0024]
According to the conveyor system having this configuration, the units can be grouped in the width direction of the conveyor line to create a new control zone that is equivalently widened. Thereby, a to-be-conveyed object can be mounted and the stable conveyance can be performed so that the several unit arranged in parallel in the width direction may be straddled.
[0025]
As a result, when the width of the object to be conveyed exceeds the width of the conveyor unit, the weight of the object to be conveyed exceeds the specification of the unit, or the unit is mounted with an inclination so that the conveying force and the braking force are insufficient. Even in this case, it is possible to cope with this by simply switching the control of the zone controller.
[0026]
Further, as another configuration example, a mode in which a group is formed in the width direction of the unit and a new group is formed by collecting a predetermined number of groups adjacent to the upstream side or the downstream side in the transport direction is adopted. be able to.
[0027]
According to the conveyor system having this configuration, it is possible to equivalently form a new control zone in which both the length and width of each unit in the transport direction are enlarged.
[0028]
This makes it possible to perform stable zero-pressure accumulation and conveyance even for large shapes and heavy objects to be conveyed that exceed the specifications of the unit.
[0029]
In the present invention, the control means determines whether or not it is necessary to drive the driving roller by referring to the loaded state or the driving state of the driving roller in at least one of the control zones including the predetermined control zone during the main control. It can be.
[0030]
For example, it is possible to determine whether or not it is necessary to drive the driving roller for performing zero pressure accumulation and conveyance with reference to the loading state of the predetermined control zone and the upstream and downstream control zones adjacent to the zone.
[0031]
Further, in addition to the loaded state, it is also possible to determine whether or not it is necessary to drive the driving roller for performing zero-pressure accumulation and conveyance by referring to the driving state of the driving roller in the downstream control zone adjacent to the predetermined control zone. it can.
[0032]
In particular, according to the configuration in which the driving state of the downstream zone is referred to, even if the object to be transported exists in the predetermined control zone and all the upstream and downstream control zones of the zone, if the downstream side is in the driving state, The objects to be conveyed in the predetermined control zone and the upstream control zone can be conveyed all at once. Thereby, efficient conveyance is possible without causing a control zone in which no object is present.
[0033]
The present invention also relates to a conveyor system including a first conveyor unit that constitutes a part of a conveyor line, and a first controller related to the first conveyor unit. In the conveyor system of the present invention, the first conveyor unit can include a transport drive motor for transporting a transported object on the conveyor line. Further, the controller determines whether or not the motor of the first conveyor unit needs to be driven by calculating a predetermined parameter, and inputs a second signal from the outside, and a calculation circuit that generates a first signal. A signal input terminal, a driving state signal generating circuit for generating a third signal based on the first signal and / or the second signal, and a signal output terminal for outputting the third signal to the outside Can be provided.
[0034]
In the conveyor system of the present invention described above, the conveyor line includes a second conveyor unit arranged in series in the transport direction on the first conveyor unit, a second controller related to the second conveyor unit, It is possible to further include a first wiring that electrically connects the signal output terminal of the second controller and the signal input terminal of the first controller. According to this, the third signal generated by the second controller can be input as the second signal to the first controller via the first wiring, and is driven by the second conveyor unit. The drive motor for conveyance of the first conveyor unit can be driven and controlled.
[0035]
The conveyor line includes a third conveyor unit arranged in parallel with the first conveyor unit, a third controller related to the third conveyor unit, a signal output terminal of the third controller, and a first controller And a second wiring for electrically connecting the signal input terminal of the controller.
[0036]
The present invention also relates to a controller that performs drive control of a transport drive motor of a first conveyor unit that constitutes a part of a conveyor line. The controller according to the present invention determines whether or not the motor of the first conveyor unit needs to be driven by calculating a predetermined parameter and generates a first signal, and inputs the second signal from the outside. A signal input terminal for generating a signal, a driving state signal generating circuit for generating a third signal based on the first signal and / or the second signal, and a signal output terminal for outputting the third signal to the outside Can be provided. As the predetermined parameter, a detection signal of a load sensor that detects the presence or absence of a transported object on the first conveyor unit, or a transport signal on another conveyor unit on the downstream side in the transport direction of the first conveyor unit. A detection signal of a stock sensor that detects presence / absence can be used, and a signal indicating a conveyance drive state of another conveyor unit on the upstream and downstream sides in the conveyance direction of the first conveyor unit can also be used. The arithmetic circuit and the drive state signal generation circuit may be a logic circuit constituted by a combination of appropriate logical arithmetic units, or may be constituted by a microcomputer. The driving state signal generation circuit may generate the third signal by a logical operation of the first signal and the second signal. Moreover, a single controller may be provided in the first conveyor unit, or a plurality of controllers may be provided.
[0037]
According to the controller of the present invention, by connecting the signal input terminal to the signal output terminal of the other controller, the third signal of the other controller is input as the second signal. Since the third signal can be generated based on the control signal, it is possible to control the drive of the transport motor of the first conveyor unit so that it is driven by the transport drive motor controlled by another controller. It is. Further, when no signal is input to the signal input terminal, it is possible to determine whether the motor needs to be driven by the arithmetic circuit, and to control the driving of the motor according to the result.
[0038]
The controller of the present invention may further include a motor drive circuit that is electrically connected to the transport drive motor of the first conveyor unit and that inputs the third signal. The motor drive circuit may generate a drive control signal for driving or stopping the transport drive motor of the first conveyor unit based on the third signal and output the drive control signal to the motor.
[0039]
In the controller of the present invention, each of the first, second and third signals may be a digital signal indicating one of a driving state and a stopped state. The driving state signal generation circuit can be configured or programmed to generate a third signal indicating the driving state when the second signal indicates the driving state.
[0040]
The first, second, and third signals are digital signals that indicate one of the driving state and the stopped state, respectively, and the driving state signal generation circuit is configured such that when the second signal indicates the driving state, The third signal indicating the driving state may be generated regardless of the signal of 1.
[0041]
The first, second, and third signals are digital signals indicating either the driving state or the stopped state, respectively, and the first signal is forced regardless of the predetermined parameter used for the calculation of the calculation circuit. In addition, there may be further provided a setting device for setting either the driving state or the stopped state. According to this, a driving state signal generating circuit that outputs the second signal as the third signal regardless of the original first signal calculated by the predetermined parameter by switching the setting device. Can be configured simply and easily.
[0042]
The first, second, and third signals are digital signals that indicate either the driving state or the stopped state, respectively, and input predetermined parameters used for arithmetic operation of the arithmetic circuit from the outside of the controller. A plurality of external signal input terminals, and when no external input is made to the terminals, the arithmetic circuit generates a first signal indicating one of a driving state and a stopped state, and driving The state signal generation circuit generates a third signal indicating the driving state when the second signal indicates the driving state and stops when the second signal indicates the stopping state regardless of the first signal. A third signal indicating the state may be generated.
[0043]
Furthermore, in the controller of the present invention, it is preferable that the connector shape of the signal input terminal and the connector shape of the signal output terminal are the same.
[0044]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic block diagram showing an internal configuration of a zone controller 1 according to an embodiment of the present invention. The zone controller 1 can be provided for each conveyor unit U. The conveyor unit U may be a conventionally known or an appropriate form improved therefrom, for example, as shown in FIGS. 2 to 5, a plurality of conveyance rollers are provided in the conveyance direction between the left and right frames, These conveyance rollers can be linked together. By interlocking in this way, if at least one of the plurality of transport rollers is rotationally driven, all the transport rollers can be rotated in the same direction and at the same speed. This rotationally driven transport roller is hereinafter referred to as “transport roller”. The conveyance drive motor that rotationally drives the conveyance drive roller may be built in the conveyance drive roller itself, or may be externally attached. In addition, each unit U can be provided with a stock sensor S that detects the presence or absence of a transported object on the unit, and a detection signal of the sensor S can be input to the zone controller 1. This stock sensor S may be in any form, for example, an optical sensor, a load sensor, or the like. The in-stock sensor S is preferably provided at the center in the transport direction of each unit, but the present invention is not limited to a specific location.
[0045]
The zone controller 1 is electrically connected to a drive motor M that rotationally drives a conveyance drive roller (not shown) and a stock sensor S. The zone controller 1 receives the control motor 10 for controlling the driving of the driving motor M to perform the zero pressure accumulation conveyance control, and the control motor RUN (third signal) generated by the controlling means 10 to receive the driving motor M. And a control setting unit 12 for setting each unit including the control of the control means 10.
[0046]
Further, the zone controller 1 sends a stock signal terminal 13 for inputting the stock signal Sin of the stock sensor S and a drive state signal Syout (third signal) indicating the drive state of the drive motor M to other zones. It has a signal output terminal (signal output connector) 15 for output to the controller, and a signal input terminal (signal input connector) 16 for inputting the drive state signal Syin (second signal) output from another zone controller. doing.
[0047]
Furthermore, an upstream connector 17 connected to the upstream zone controller 1 and a downstream connector 18 connected to the downstream zone controller 1 are provided.
[0048]
The control means 10 includes the presence signal Sin of the own zone output from the arrival sensor S, the upstream zone presence signal SUin transmitted via the terminal 17b of the upstream connector 17, the terminal 18a of the downstream connector 18, and The drive signal of the drive motor M is determined in response to the downstream zone occupancy signal SDin and the drive state signal RDin transmitted via the terminal 18c.
[0049]
That is, the control means 10 refers to the in-zone loading signal Sin, the upstream and downstream loading signals SUin and SDin, and the downstream driving state signal RDin, and performs logical operations based on these parameters. Thus, it is determined whether or not the drive motor M needs to be driven, and a control signal (third signal) indicating whether to drive or stop the motor M is generated and output to the motor drive circuit.
[0050]
In other words, when it is determined by the control means 10 that the drive motor M needs to be driven, a control signal RUN for driving the motor M is sent to the motor drive circuit 11 to drive the drive motor M to carry the transport roller. Drive.
[0051]
In the zone controller 1 of this embodiment, a drive state signal (Syout: the same as the drive state signal output from the terminal 17c in this embodiment) can be output from the control means 10 via the signal output terminal 15. Further, the driving state signal Syin transmitted from the other zone controller 1 through the signal input terminal 16 can be input to the control means 10. The drive state signal may be the control signal itself or a signal generated based on the control signal.
[0052]
Further, the control means 10 outputs the own zone presence signal Sout via the terminal 17a of the upstream connector 17, and also outputs the own zone drive state signal Rout via the terminal 17c. Further, the in-zone signal Sout is output via the terminal 18b of the downstream connector 18.
[0053]
In the zone controller 1 configured as described above, the control means 10 uses the upstream connector 17 and the downstream connector 18 to transmit and receive a loading signal and a driving state signal to and from the upstream and downstream zone controllers 1. A main control is performed to determine whether the drive motor M is driven.
[0054]
On the other hand, when the upstream connector 17 and the downstream connector 18 are opened, the drive means signal transmitted from the other zone controller 1 is input to the signal input terminal 16 so that the control means 10 is interlocked with the transmitted drive condition signal. The follow-up control operation is performed.
[0055]
In other words, in the zone controller 1 of the present embodiment, the driving state generated by the control means of a certain zone controller is configured to switch between the main driving control and the driven control only by changing the connection without performing switching setting. According to the signal, a drive motor M connected to another zone controller can be driven. A more detailed configuration of such a zone controller 1 will be described later.
[0056]
It should be noted that the main driving control and the driven control are not limited to the configuration that switches between the main driving control and the driven control by changing the wiring between the plurality of zone controllers 1, but the main driving control and the driven control are switched and set by, for example, the control setting unit 12 including a switch. It is also possible to adopt a simple configuration.
[0057]
By using a control unit including the zone controller 1 of the present embodiment, various conveyor lines can be formed. A configuration example of the conveyor line will be described below.
(Conveyor line configuration example 1)
FIG. 2 shows a conveyor line L1 in which control units U (Ua, Ub, Uc) having the zone controller 1 of the present embodiment are arranged in series in the conveyance direction of the object to be conveyed. FIG. 3 is an explanatory diagram showing the connection state of the zone controller 1 provided in the control unit U in correspondence with the arrangement of the control unit U. With reference to these drawings, the basic operation of the conveyor line L1 using the zone controller 1 of the present embodiment will be described.
[0058]
For convenience of explanation, the control zones are classified into zones A, B, and C, and the zone controllers 1 provided in the control units U (Ua, Ub, Uc) of the control zones are respectively designated as zone controllers 1a, 1b, 1c.
[0059]
As shown in FIG. 6, the connection cable C sequentially connects the upstream connector 17 of the zone controller 1 in each zone and the downstream connector 18 of the zone controller 1 in the upstream zone.
[0060]
Thereby, the zone controller 1b in the zone B receives the presence signal of the zone A through the terminal 17b, and receives the arrival signal of the zone C through the terminal 18a. Further, the driving state signal of the zone C is received through the terminal 18c. Then, the received presence signal and driving state signal are transmitted to the control means 10.
[0061]
The control means 10 determines whether or not it is necessary to drive a driving roller (not shown) with reference to the loading signal of the own zone (zone B) in addition to the received loading signal and driving state signal. When the drive is required, the drive roller is driven by generating a control signal and sending it to the motor drive circuit 11.
[0062]
As a result, the basic operation of performing the zero-pressure accumulation conveyance linked as the conveyor line L1 is performed while determining whether or not the driving roller needs to be driven independently for each of the control units Ua to Uc.
[0063]
By the way, if the control unit U adopting the zone controller 1 of the present embodiment is used, it is possible to create conveyor lines having various configurations without being limited to such a basic configuration.
[0064]
(Conveyor line configuration example 2)
FIG. 3 shows that the same control units U (Ua, Ub, Uc) are arranged in series in the transport direction of the object to be transported, and the same control units Ua ′, Ub ′ are adjacent to the control units Ua, Ub, Uc. , Uc ′ is shown as a conveyor line L2 configured in parallel.
[0065]
FIG. 7 is an explanatory diagram showing the connection state of the zone controllers 1 provided in each control unit U of the conveyor line L2 shown in FIG.
[0066]
In this configuration, the same connection as the configuration shown in FIG. 6 is performed between the zone controllers 1a, 1b, and 1c. A connection cable C1 (second wiring) is attached between the signal output terminal 15 of the zone controller 1a and the signal input terminal 16 of the zone controller 1a ′. Similarly, the connection cables C1 are respectively attached between the signal output terminals 15 and 15 of the zone controllers 1b and 1c and the signal input terminals 16 of the zone controllers 1b ′ and 1c ′.
[0067]
Here, the upstream connector 17 and the downstream connector 18 of the zone controllers 1a ′, 1b ′, and 1c ′ are opened, and the drive state signals output from the signal output terminals 15 of the zone controllers 1a, 1b, and 1c are the zone controllers 1a ′, 1b 'and 1c' are applied to the signal input terminal 16.
[0068]
As a result, the zone controllers 1a ′, 1b ′, and 1c ′ perform follow-up control synchronized with the driving of the zone controllers 1a, 1b, and 1c.
That is, in the conveyor line L2, the conveyor line L2 is equivalently widened by driving the control units U adjacent to each other in the lateral direction (direction orthogonal to the transport direction).
[0069]
As a result, as shown in FIG. 3, even when the width of the article to be conveyed W exceeds the control unit Ua, the article to be conveyed W is placed so as to straddle the control units Ua and Ua ′ for stable conveyance. It can be carried out. Further, by transporting the transported object W across the control units Ua and Ua ′, stable transport can be performed even when the weight of the transported object W exceeds the specification of the control unit Ua.
[0070]
(Conveyor line configuration example 3)
FIG. 4 shows a conveyor line L3 in which the same control units Ua, Ua ′, Ub, Ub ′ are arranged in a line in the conveyance direction of the object to be conveyed.
FIG. 8 is an explanatory diagram showing the connection state of the zone controllers 1 provided in each control unit U of the conveyor line L3 shown in FIG.
[0071]
The conveyor line L3 can be configured by changing the arrangement of the control units U of the conveyor line L2 shown in FIG. That is, in the arrangement of FIG. 3, the conveyor unit line is arranged by sequentially changing the arrangement so that the control unit Ua ′ is arranged downstream of the control unit Ua and the control unit Ub ′ is arranged downstream of the control unit Ub. L3 can be constructed.
[0072]
According to such a conveyor line L3, the lengths of the control zones A and B are equivalently extended approximately twice. Thereby, even when the length of the article to be conveyed W exceeds the length of the control unit U, stable zero pressure accumulation and conveyance can be performed.
[0073]
(Conveyor line configuration example 4)
FIG. 5 shows a conveyor line L4 having an inclination constructed using the same control unit U (Ua, Ub, Ub ′, Uc). In the conveyor line L4, the inclined conveyance is performed in the zone B, and the control unit Ub ′ is arranged adjacent to the control unit Ub. That is, each control unit U is arranged so that the article W to be transported from the zone A to the zone B rises over the control units Ub and Ub ′.
[0074]
FIG. 9 is an explanatory diagram showing the connection state of the zone controllers 1 provided in each control unit U of the conveyor line L4 shown in FIG.
[0075]
The connection of the zone controllers 1a to 1c is the same as the connection configuration shown in FIG. The signal output terminal 15 of the zone controller 1b and the signal input terminal 16 of the zone controller 1b ′ are connected by a connection cable C1.
[0076]
In the conveyor line L4, the control unit Ub ′ in the zone B is driven in conjunction with the control unit Ub. As a result, even in the zone B, even when the ability to lift and transport the transported object W only by the control unit Ub is insufficient, the transported object W is equivalently driven with the two control units Ub and Ub ′. It can be increased and transported upward.
In the example of FIG. 5, the zone B is shown as being configured to be inclined upward, but even when the zone B is inclined downward, the same configuration can be adopted to enable conveyance with improved braking force.
[0077]
【Example】
Next, an example that more specifically shows the configuration of the zone controller 1 shown in the embodiment will be described.
FIG. 10 is a block circuit diagram showing the internal configuration of the zone controller 1 of the present invention in more detail. Parts corresponding to those shown in FIG. To do.
[0078]
In the zone controller 1 of the present embodiment, the upstream connector 17 and the downstream connector 18 each have seven terminals.
The upstream connector 17 transmits / receives the next signal to / from the upstream zone controller 1.
(1) Output the own zone stock signal Sout via the terminal 17a.
(2) The upstream zone unloading signal SUin is input via the terminal 17b.
(3) The driving state signal Rout of the own zone is output via the terminal 17c.
(4) The upstream zone drive state signal RUin is input via the terminal 17d.
(5) The conveyance direction signal Dir is transmitted through the terminal 17e.
(6) Output the error signal Eout of the downstream zone including its own zone via the terminal 17f.
(7) Transmit conveyance speed signal Vin via terminal 17g.
[0079]
On the other hand, the downstream connector 18 transmits / receives the next signal to / from the downstream zone controller 1.
(1) The downstream zone stock signal SDin is input via the terminal 18a.
(2) The in-zone signal Sout is output via the terminal 18b.
(3) The drive state signal RDin of the downstream zone is input via the terminal 18c.
(4) The driving state signal Rout of the own zone is output via the terminal 18d.
(5) The conveyance direction signal Dir is transmitted through the terminal 18e.
(6) The downstream zone error signal Errin is input via the terminal 18f.
(7) Transmit conveyance speed signal Vin via terminal 18g.
[0080]
In other words, between the adjacent zone controllers 1, the connection cable C is laid between the upstream connector 17 and the downstream connector 18 so as to bridge the terminals 17 a to 17 g of the upstream connector 17 and the downstream connector 18. Terminals 18a to 18g are connected in a corresponding state. Thereby, it is set as the structure which can transmit / receive the above-mentioned signal between zone controllers 1 mutually.
[0081]
The zone controller 1 further includes three terminals 14 to 16. The terminal 14 can select either the output of the error signal (Err) of the downstream zone including the own zone or the output of the presence signal (Sen) of the own zone by switching the jumper line JP2. ing.
When the jumper line JP2 is connected between ca (the stock signal Sen side), the stock signal Sen output from the control means 10 is output from the terminal 14 via the transistor Q1 connected in an open collector.
When jumper line JP2 is connected between cb (error signal Err side), the logical product of the error signal of the own zone output from control means 10 and the error signal transmitted from the downstream side via terminal 18f is obtained. The signal is output from the terminal 14 via the transistor Q2 connected in an open collector. Further, the error signal obtained by the logical product is output as an error signal Eout through the terminal 17f.
[0082]
The terminal 15 can select either the output of the driving state signal Syout (third signal) of the own zone or the input of the transport speed signal (Vin) by switching the jumper line JP3.
When the jumper line JP3 is connected between ca (drive state signal Syout side), the drive state signal (third signal) output from the control means 10 is output from the terminal (signal output terminal) 15. This signal is simultaneously sent to the motor drive circuit 11 to drive the drive motor M.
When jumper line JP3 is connected between cb (conveying speed signal Vin side), a conveying speed signal (Vin: voltage of 0 to 10 V) inputted through terminal 15 is inputted to control means 10 and terminal 17g and sent to the other zone controller 1 through the terminal 18g. In other words, the conveyance speed signal Vin can be transmitted to all the zone controllers 1 by inputting the conveyance speed signal Vin to any one of the zone controllers 1.
[0083]
The terminal 16 can select either the transport direction signal Dir or the drive state signal Syin (second signal) by switching the jumper line JP1.
When jumper line JP1 is connected between ca (drive state signal Sin side), drive signal RUN based on drive state signal Sin transmitted from other zone controller 1 via terminal 16 is transmitted to motor drive circuit 11. Then, the drive motor M is driven.
Further, when the jumper line JP1 is connected between cb (carrying direction signal Dir side), the carrying direction signal Dir inputted through the terminal 15 is inputted to the control means 10, and other signals are inputted through the terminals 17e and 18e. Are sent to the zone controller 1. In other words, the conveyance direction signal Dir can be transmitted to all the zone controllers 1 by inputting the conveyance direction signal Dir to any one of the zone controllers 1.
[0084]
Further, the zone controller 1 includes a control setting unit 12 for performing settings including control switching of the control means 10. The control setting unit 12 includes a dip switch having four switches (SW1 to SW4).
The switch SW1 performs input switching of the conveyance speed signal Vin, performs speed control based on the conveyance speed signal Vin input from the outside to the terminal 15 in the ON setting, and sets the conveyance speed signal Vin generated internally in the OFF setting. Based on speed control.
The switch SW2 sets the downstream end of the conveyor line. In the ON setting, the downstream end is set to prohibit downstream conveyance, and in the OFF setting, normal conveyance control is performed.
[0085]
The switch SW3 switches the transport mode of the object to be transported by the control means 10, and is switched to the separation transport mode when it is set to ON, and switched to the simultaneous transport mode when it is set to OFF. Here, the separation conveyance mode is a mode in which a predetermined number of control zones in which no object is present is generated between the control zones in which the objects are present, and the simultaneous conveyance mode is a mode in which the object is conveyed. In this mode, the objects are conveyed all at once while maintaining the arrangement of the objects.
In this embodiment, the control processing for performing the separation transport mode and the simultaneous transport mode is performed by the logic circuit provided in the control means 10, but the operation by the program processing may be performed using the CPU. Is possible.
[0086]
The switch SW4 is used to set an interface for the driving state signal Dir and the conveyance direction signal Dir input to the in-stock sensor S and the terminal 16, and performs switching setting to correspond to the NPN output and the PNP output.
Here, the detection signal of the stock sensor S is transmitted to the control means 10 and the terminals 17a and 18b via the photocoupler PC1. When the jumper line JP1 is connected to the drive state signal Sin, the drive state signal Syin input via the terminal 16 is transmitted to the motor drive circuit 11 via the photocoupler PC2. Further, when the jumper JP1 is connected to the transport direction signal Dir side, the transport direction signal Dir input through the terminal 16 is transmitted to the control means 10 and the terminals 17e and 18e through the photocoupler PC3.
The switch SW4 switches the interface of these in-stock signal, driving state signal, and conveyance direction signal.
That is, when the switch SW4 is opened, an interface of an NPN transistor that becomes an active input when the inputs of the photocouplers PC1 to PC3 are grounded is performed. Further, when the switch SW4 is closed, the interface of the PNP transistor that becomes an active input when the inputs of the photocouplers PC1 to PC3 are connected to the power supply voltage (connected to the open collector in this embodiment) is configured. .
[0087]
Further, the control means 10 of the zone controller 1 receives the above signals input to the zone controller 1, and generates and outputs a drive state signal (first signal) based on these input signals (parameters). It has a ZPA controller. In the illustrated embodiment, the ZPA controller includes an upstream drive state signal RUin, a downstream drive state signal RDin, a load signal Sout of the load sensor S in the own zone, and a load signal SUin of the upstream zone. The downstream zone presence signal SDin and the conveyance direction signal Dir are input, and the drive state signal S-RUN (first signal) is generated and output.
[0088]
This ZPA controller can be mainly configured by the logic circuit shown in FIG. 14, or can be configured by any other appropriate circuit equivalent to the illustrated logic circuit, or by a microcomputer and its software program. In FIG. 14, D-RUN is a drive signal for the zone controller on the downstream side in the transport direction, D-SNS is a stock signal on the downstream side in the transport direction, and S-SNS is a stock signal on the own zone. U-SNS is a stock signal upstream in the transport direction. Depending on the content of the transport direction signal Dir, one of the RUin and RDin signals is used as D-RUN. This signal switching can be performed by an appropriate switching circuit. Similarly, according to the content of the conveyance direction signal Dir, one of the SUin and SDin signals is used as the D-SNS, and the other signal is used as the U-SNS. Further, the stock signal S-SNS of the own zone may be the Sout signal itself. Below the logic circuit shown in FIG. 14, a logic value table of this circuit is shown. Here, the three presence signals indicate that there is a transported object when the signal is at the H level, and indicates that there is no object when the signal is at the L level. The two drive state signals indicate stop when the signal is at the H level, and indicate drive when the signal is at the L level. Further, when no cable is connected to the upstream and downstream connectors 17 and 18, the output S-RUN of the ZPA controller is configured to be at the H level.
[0089]
Further, the control means 10 of this embodiment includes a driving state signal S-RUN (first signal) output from the ZPA controller and a driving state signal transmitted / input from another zone controller to a signal input terminal 16 described later. A drive state signal generation circuit 20 that generates and outputs a control signal (third signal) that becomes an output signal of the control means 10 based on Syin (second signal) is provided. The circuit 20 is mainly composed of an AND circuit that inputs the signal S-RUN and an inverted signal of the signal Sin, and a NOT circuit that inverts the output of the AND circuit. The output signal of the NOT circuit is the control signal. Used as RUN and drive state signal Syout. As described above, the output signal S-RUN of the ZPA controller has a drive state of L level and a stop state of H level. Further, the control signal RUN and the drive state signal Syout (third signal) indicate the drive state at the H level and indicate the stop state at the L level.
[0090]
Therefore, when the zone controller 1 performs follow-up control, the upstream and downstream connectors 17 and 18 are not connected by wiring, and the jumper JP1 is connected between ca. Then, when the driving state signal Syin (second signal) is input from another zone controller, if the signal Sin is H level indicating the driving state, one input of the AND circuit becomes L level. Since the output becomes L level and the output of the NOT circuit becomes H level, the ZPA controller outputs the drive state signal Syout and the control signal RUN (third signal) finally generated and output by the control means 10. Regardless of the drive state signal S-RUN, the drive state is always indicated. On the other hand, if the signal Syin input from the other zone controller is L level indicating a stop state, one input of the AND circuit is H level and the output of the ZPA controller is also H level. Becomes H level, the output of the NOT circuit becomes L level, and the control signal RUN indicates a stopped state.
[0091]
In addition, when the controller 1 is controlled in the main, no wiring is connected to the terminal 16 and the a terminal of the jumper JP1 is at the L level, so that the photocoupler connected to the a terminal does not operate and the photo Since the transistor is OFF, the 5V power supply voltage is input to the AND circuit as an H level input signal, so that the control signal RUN is output according to the content of the output signal S-RUN of the ZPA controller. It has become.
[0092]
By using the control unit U including the zone controller 1 of this embodiment, the conveyor lines L1 to L4 shown in FIGS. 2 to 5 can be easily configured.
Further, in a configuration provided with a host controller (not shown) that controls the conveyor line, for example, the conveyor speed signal Vin output from the host controller is input to the terminal 15 of one of the zone controllers 1 to thereby convey the conveyor. The entire line speed can be controlled.
Similarly, by inputting the conveyance direction signal Dir output from the host controller to the terminal 16 of one of the zone controllers 1, the conveyance direction of the entire conveyor line can be instantaneously switched.
Furthermore, by transmitting the error signal Err output from the terminal 14 to the host control device, it is possible to perform error monitoring and avoidance control.
[0093]
The zone controller 1 shown in FIGS. 1 and 10 has a configuration in which only one signal input terminal 16 for inputting a driving state signal is provided, but two signal input terminals 16 connected to each other are provided. It is also possible to adopt a configuration. In this configuration, the driving state signal transmitted from the zone controller 1 that performs the main control to the signal input terminal 16 can be sequentially transmitted to another zone controller 1 through the other signal input terminal 16, and the main control can be performed. A plurality of zone controllers 1 can be controlled to be driven (linked control) with respect to one zone controller 1 to be performed.
[0094]
In addition to the configuration of the conveyor line described above, conveyor lines having various configurations can be constructed.
For example, although FIG. 3 shows the conveyor line L2 in which the control units U are arranged in two rows in parallel, it is also possible to form a conveyor line in which the control units U are arranged in three or more rows. 5 shows the conveyor line L4 in which a plurality of control units Ub and Ub ′ are arranged in the control zone B. However, two control units U are used in the control zones A and C, and three in the control zone B. It is also possible to adopt a configuration using a control unit.
[0095]
The zone controller and conveyor system of the present invention are provided to improve a conveyor system constituted by a roller conveyor of the prior art. However, the essence of the present invention is not limited to the roller conveyor system, but can be applied to a conveyor system including a belt conveyor and a zone controller of the conveyor system.
[0096]
The zone controller and the conveyor system of the present invention are effective for a conveyor line in which a plurality of control units U are arranged in series or in parallel with respect to the conveyance direction of the object to be conveyed, as exemplified in the above embodiment. This is effective when the unit U is short.
[0097]
【The invention's effect】
According to the zone controller of the present invention, it is possible to carry out transportation in which a plurality of control units are interlocked only by performing switching setting of switches and wirings, and the control zone can be expanded equivalently. Thereby, various conveyor lines can be constructed according to the shape and weight of the object to be conveyed, and versatility can be further improved.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram of a zone controller according to an embodiment of the present invention.
FIG. 2 is a plan view of an example of a conveyor line configured using a conveyor unit having the zone controller shown in FIG.
FIG. 3 is a plan view of another example of a conveyor line configured using a conveyor unit having the zone controller shown in FIG.
4 is a plan view of still another example of a conveyor line configured using a conveyor unit having the zone controller shown in FIG. 1. FIG.
FIG. 5 is a perspective view of still another example of a conveyor line configured using a conveyor unit having the zone controller shown in FIG. 1;
6 is a wiring connection diagram of a zone controller corresponding to the conveyor line shown in FIG. 2;
7 is a wiring connection diagram of a zone controller corresponding to the conveyor line shown in FIG. 3;
8 is a wiring connection diagram of a zone controller corresponding to the conveyor line shown in FIG. 4. FIG.
9 is a wiring connection diagram of a zone controller corresponding to the conveyor line shown in FIG.
FIG. 10 is a circuit configuration diagram of a zone controller according to an embodiment of the present invention.
FIG. 11 is a plan view showing a configuration example of a conveyor line using a conventional conveyor unit.
FIG. 12 is a plan view showing a configuration example of a conveyor line using a conventional conveyor unit.
FIG. 13 is a perspective view showing a configuration example of a conveyor line using a conventional conveyor unit.
14 is a logic circuit diagram of a ZPA controller included in the zone controller shown in FIG. 1. FIG.
[Explanation of symbols]
1 Zone controller
10 Control means
15 Signal output terminal
16 Signal input terminal

Claims (18)

A zone controller of a predetermined control zone of a roller conveyor line divided into a plurality of control zones arranged in the transport direction, which performs drive control of a transport drive roller provided in the predetermined control zone,
A signal output terminal for outputting a driving state signal indicating a driving state of the driving roller to another zone controller; a signal input terminal for inputting a driving state signal transmitted from the other zone controller; and for driving the driving roller Control means for generating a control signal,
The control means determines the necessity of driving the driving roller and generates a control signal, and outputs a driving state signal using the control signal to another zone controller via a signal output terminal; A drive state signal transmitted from another zone controller via a signal input terminal is used as a control signal, and the driven control for driving the drive roller in conjunction with the control by the transmission source zone controller can be switched. A zone controller characterized by that.   The control means determines whether or not it is necessary to drive the driving roller with reference to a loaded state or a driving state of the driving roller in at least one of the control zones including the predetermined control zone during the main control. The zone controller according to claim 1.   A controller that controls driving of a transport motor for a first conveyor unit that forms part of the conveyor line, and determines whether or not the motor of the first conveyor unit needs to be driven by calculating a predetermined parameter. An operation circuit for generating the first signal, a signal input terminal for inputting the second signal from the outside, and a driving state for generating the third signal based on the first signal and / or the second signal A controller, comprising: a signal generation circuit; and a signal output terminal for outputting the third signal to the outside.   4. The controller according to claim 3, further comprising a motor drive circuit that is electrically connected to a transport drive motor of the first conveyor unit and that inputs the third signal, the motor drive circuit comprising: A controller that generates a drive control signal for driving or stopping the conveyance drive motor of the first conveyor unit based on the signal and outputs the drive control signal to the motor.   4. The controller according to claim 3, wherein each of the first, second and third signals is a digital signal indicating one of a driving state and a stopped state, and the driving state signal generating circuit A controller that generates a third signal indicating the driving state when indicating the driving state.   4. The controller according to claim 3, wherein each of the first, second and third signals is a digital signal indicating one of a driving state and a stopped state, and the driving state signal generating circuit A controller that generates a third signal indicating the driving state regardless of the first signal when indicating the driving state.   4. The controller according to claim 3, wherein each of the first, second, and third signals is a digital signal indicating one of a driving state and a stopped state, and depends on a predetermined parameter used for calculation of an arithmetic circuit. A controller further comprising a setting device for forcibly setting the first signal to one of a drive state and a stop state. 4. The controller according to claim 3, wherein the first, second, and third signals are digital signals each indicating one of a drive state and a stop state, and are predetermined signals used for calculation of an arithmetic circuit. A plurality of external signal input terminals for inputting parameters from outside the controller;
When no external input is made to the terminal, the arithmetic circuit generates a first signal indicating either the driving state or the stopped state, and the driving state signal generation circuit is involved in the first signal. And a controller that generates a third signal that indicates a driving state when the second signal indicates a driving state and generates a third signal that indicates a stopping state when the second signal indicates a stopping state.   4. The controller according to claim 3, wherein a connector shape of the signal input terminal and a connector shape of the signal output terminal are the same. A conveyor system comprising a first conveyor unit that forms part of a conveyor line, and a first controller associated with the first conveyor unit,
The first conveyor unit includes a transport drive motor for transporting a transported object on the conveyor line,
The controller determines a necessity of driving the motor of the first conveyor unit by calculating a predetermined parameter and generates a first signal, and a signal for inputting the second signal from the outside An input terminal; a drive state signal generation circuit that generates a third signal based on the first signal and / or the second signal; and a signal output terminal for outputting the third signal to the outside. The conveyor system.   11. The conveyor system according to claim 10, wherein the first controller further includes a motor drive circuit that is electrically connected to the transport drive motor of the first conveyor unit and inputs the third signal, The motor drive circuit generates a drive control signal for driving or stopping the conveyance drive motor of the first conveyor unit based on the third signal, and outputs the drive control signal to the motor.   11. The conveyor system according to claim 10, wherein the first, second, and third signals are digital signals that indicate one of a driving state and a stopped state, respectively, and the driving state signal generation circuit includes a second signal. A conveyor system that generates a third signal indicative of a drive condition when indicates a drive condition.   11. The conveyor system according to claim 10, wherein the first, second, and third signals are digital signals that indicate one of a driving state and a stopped state, respectively, and the driving state signal generation circuit includes a second signal. A conveyor system that generates a third signal indicative of a drive state regardless of the first signal when indicates a drive state.   The conveyor system according to claim 10, wherein the first, second and third signals are digital signals indicating one of a driving state and a stopped state, respectively, and the first controller performs calculation of the arithmetic circuit. A conveyor system further comprising a setter that forcibly sets the first signal to either the drive state or the stop state regardless of the predetermined parameter used. 11. The conveyor system according to claim 10, wherein the first, second, and third signals are digital signals indicating one of a drive state and a stop state, respectively, and the first controller is an arithmetic circuit. It further comprises a plurality of external signal input terminals for inputting predetermined parameters used in the calculation of from the outside of the controller,
When no external input is made to the terminal, the arithmetic circuit generates a first signal indicating either the driving state or the stopped state, and the driving state signal generation circuit is involved in the first signal. The conveyor system generates a third signal indicating the driving state when the second signal indicates the driving state and generates a third signal indicating the stopping state when the second signal indicates the stopping state. .   The conveyor system according to claim 10, wherein the connector shape of the signal input terminal and the connector shape of the signal output terminal are the same.   The conveyor system according to claim 10, wherein the conveyor line includes: a second conveyor unit arranged in series in the transport direction on the first conveyor unit; a second controller associated with the second conveyor unit; A conveyor system further comprising: a signal output terminal of the second controller and a first wiring that electrically connects the signal input terminal of the first controller.   The conveyor system according to claim 10, wherein the conveyor line includes a third conveyor unit arranged in parallel to the first conveyor unit, a third controller associated with the third conveyor unit, and a third controller. A conveyor system further comprising a second wiring for electrically connecting a signal output terminal of the controller and a signal input terminal of the first controller.

Images