JP6225417B2 - Programmable control unit wiring converter - Google Patents

Description

  The present invention relates to a wiring conversion device for a programmable control unit including an interface module for inputting and outputting signals to and from a controlled device.

  Conventionally, a programmable control unit in which a power supply module, a CPU module, and an interface module are unitized by being fixed to a base board is known. In such a programmable control unit, a wiring connector in which a plurality of wiring cables are aggregated is connected to an external connection connector provided in the interface module. Each sensor and actuator of the controlled device is connected to the wiring cable, and when an input detection signal from each sensor is input to the interface module, arithmetic processing according to the input detection signal is executed in the CPU module, A control signal is output to each actuator via the interface module.

  In this way, the controlled device is controlled by the programmable control unit. However, when more sophisticated and complicated control is required in the controlled device, or when a failure occurs, more power saving is achieved. The programmable control unit may be updated to a new one when it is desired to plan. Here, there is also a demand for downsizing, weight reduction, and power saving, and a programmable control unit that is downsized with respect to an existing (conventional) programmable control unit has been developed. Thus, when the programmable control unit to be updated is downsized with respect to the existing programmable control unit, the shape of the external connection connector of the interface module in the programmable control unit to be updated is May not be compatible with wiring connectors.

  In this case, it is necessary to perform wiring again for the programmable control unit to be updated. However, in general, there are many wiring cables for connecting the programmable control unit and the controlled device, and the wiring is complicated. It is. Since the operation of the controlled device must be stopped during the wiring work, there is a demand for a wiring conversion device capable of realizing accurate wiring in a short time when updating the programmable control unit.

  Therefore, as shown in Patent Document 1, a wiring conversion device including a main body portion to which a programmable control unit to be updated is fixed and a connector conversion panel to which an external connection connector that is fitted to an existing wiring connector is fixed. Has been proposed. According to the wiring conversion device disclosed in Patent Document 1, the external connection connector of the new interface module fixed to the main body and the conventional external connection connector fixed to the connector conversion panel are connected by the conversion cable. The Therefore, wiring work at the time of updating the programmable control unit is simplified, and accurate wiring can be realized in a short time.

JP 2007-42064 A

  However, in the wiring conversion device disclosed in Patent Document 1, since the connector conversion panel is provided in the main body so as to be rotatable or slidable, the exclusive area of the wiring conversion device is nearly twice that of the programmable control unit. It gets bigger. Therefore, when this wiring conversion device is used, there is a problem that a large installation space has to be ensured even though the programmable control unit to be updated is downsized. In particular, when the programmable control unit is efficiently placed in the control panel together with other electrical equipment, the wiring conversion device cannot be used in the first place when the installation space is restricted.

  Therefore, when the installation space is restricted, one end of the relay connector is fitted to the external connection connector of each interface module to be updated, and the other end of this relay connector is fitted to the existing wiring connector. Can be considered. However, in this case, the mass of the relay connector, wiring connector, etc. will all act on the interface module, and stress will occur in the part that supports the interface module and the fitting part of each connector, etc., due to long-term use. Each component may be damaged or an electrical connection failure may occur. Such a problem becomes more prominent as the relative mass of the programmable control unit to be updated becomes smaller with respect to the relay connector and the wiring connector as a result of promoting the downsizing of the programmable control unit to be updated.

  Therefore, an object of the present invention is to provide a wiring conversion device for a programmable control unit that can reduce damage to each component due to long-term use, and can realize space saving and simplification of wiring work.

In order to solve the above-described problem, a wiring conversion device used in the programmable control unit of the present invention includes an interface module provided with an external connection connector that is electrically connected to a wiring connector. A wiring conversion device for use in a programmable control unit that performs either or both of signal input and output to / from a controlled device via a wiring connector, the rear surface being opposite to the front surface of the interface module A base body that is positioned on the side and that supports the programmable control unit, and is opposed to the front surface of the interface module in a state of being attached to the base body, with both ends projecting in a plane direction from the front surface of the interface module. Front part, both of the front part A pair of extending portions extending toward the base body side from the part, the pair of extending portions one of the locking claw provided at the distal end, and to fix the wiring connector provided on the positive surface have a fixed part, is provided a signal conversion adapter detachably provided in the base body, the wiring connector fixed to said signal conversion adapter, and, in front of the interface module fixed to the base body wherein with an external connector relay connector for electrically conducting, and the said base body, the locking pawl provided on one of the pair of the extending portions is engaged, a pair of the extending portions The other is fixed with a screw .

  In addition, the signal conversion adapter includes a wiring conversion printed board on which a circuit that fits both the wiring connector fixed to the fixing portion and the relay connector and converts the arrangement order of the wiring between the two connectors is formed. It should be provided.

  Moreover, it is good for the front part to be provided with an opening facing the front of the interface module.

  In addition, in the extending portion provided with the locking claw, a portion facing the outer surface of the interface module is provided with an inclination that is separated from the outer surface of the interface module as it goes from the front side toward the locking claw side. It is good to be.

  According to the present invention, it is possible to realize space saving and simplification of wiring work while reducing damage to each component due to long-term use.

It is a perspective view of the existing programmable control unit. It is a three-view figure of the existing programmable control unit. It is an expanded view of a base board. It is a perspective view which shows the programmable control unit and wiring converter which are updated. It is a three-plane figure which shows the attachment state to the wiring converter of the programmable control unit to update. It is a three-view figure of a base body. It is a figure which shows the base main body of the state in which the attachment rail was screwed. It is a perspective view of a signal conversion adapter. It is a figure explaining a wiring conversion method. It is a figure explaining the attachment method of the signal conversion adapter to a base board.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in the embodiment are merely examples for facilitating understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present invention are not illustrated. To do.

  In the present embodiment, first, the configuration of the existing programmable control unit and the (new) programmable control unit to be updated will be described, respectively, and then the configuration of the wiring conversion device and the wiring conversion method will be described.

(Programmable control unit 1)
FIG. 1 is a perspective view of an existing programmable control unit, and FIG. 2 is a three-view diagram of the existing programmable control unit. In FIG. 2, (a) shows a front view, (b) shows a bottom view, and (c) shows a side view, but in (c) the side view, some modules are shown. The removed state is shown. Here, although the programmable control unit 1 provided with the base board 10, the power supply module 20, the CPU module 30, and the four interface modules 40 is demonstrated, the number of each module etc. are designed suitably according to a use. .

  The programmable control unit 1 includes a power module 20, a CPU module 30, and an interface module 40 fixed to the base board 10 as a unit. Hereinafter, the direction of the arrow W shown in FIG. 1, that is, the direction in which the power supply module 20, the CPU module 30, and the interface module 40 are adjacent will be described as the width direction of the programmable control unit 1. In the programmable control unit 1, the TH direction shown in FIG. 1 will be described as the upper surface side or the upper side, the TL direction as the lower surface side or the lower side, the F direction as the front side, and the B direction as the back side.

  FIG. 3 is a development view of the base board 10. As shown in FIG. 3, the base board 10 is configured by a member having a substantially rectangular cross section that extends with the width direction of the programmable control unit 1 as a longitudinal direction. A plurality of connectors 11 are provided on the front surface of the base board 10. The plurality of connectors 11 are arranged at a predetermined interval in the longitudinal direction of the base board 10. A plurality of module mounting pieces 12 are provided on the upper surface side of the base board 10, and a plurality of module locking portions 13 are provided on the lower surface side of the base board 10. A plurality of these module mounting pieces 12 and module locking portions 13 are arranged in the longitudinal direction of the base board 10 while maintaining a predetermined interval.

  Although detailed explanation is omitted, on the back side of the power supply module 20, the CPU module 30, and the interface module 40, locking claws that are locked to the module mounting piece 12 and the module locking portion 13 of the base board 10 are respectively provided. It has been. Then, by locking each locking claw to the module mounting piece 12 and the module locking portion 13, as shown in FIGS. 1 and 2, the power supply module 20, the CPU module 30, and the interface module 40 are connected to the base board 10. It will be fixed and supported by.

  Further, on the back surface of the power supply module 20, the CPU module 30, and the interface module 40, a connector (not shown) that fits into the connector 11 is provided. This connector is formed so as to be fitted to the connector 11 in a state where the power supply module 20, the CPU module 30 and the interface module 40 are fixed and supported on the base board 10. Inside the base board 10, there is provided a bus that allows signals to be exchanged between the modules.

  Thereby, in the programmable control unit 1 shown in FIGS. 1 and 2, the CPU module 30 and the interface module 40 are connected via the base board 10 so as to be able to transmit information. In addition, an external connection connector 40a composed of card edge connectors having different shapes is provided on the front face of each interface module 40, and a plurality of wiring cables are screwed to these external connection connectors 40a and aggregated. The card edge terminal of the wired connector can be connected.

  When each wiring cable is connected to a sensor or actuator of the controlled device, a detection signal is input from the sensor to the interface module 40 via the wiring cable, the wiring connector, and the external connection connector 40a. The detection signal input to the interface module 40 is transmitted to the CPU module 30 via the base board 10, and the CPU module 30 executes arithmetic processing based on the detection signal. Then, the CPU module 30 outputs a control signal for controlling the actuator according to the result of the arithmetic processing. This control signal is transmitted to the interface module 40 via the base board 10, and is output to the actuator of the controlled device via the external connection connector 40a, the wiring connector and the wiring cable, and the actuator is controlled according to this control signal. Is movable and controlled.

  A rail fitting groove 14 is provided on the back surface of the base board 10. An attachment rail R for fixing the programmable control unit 1 to a wall surface or the like can be fitted into the rail fitting groove 14. The mounting rail R is screwed to a metal base plate, and the programmable control unit 1 is installed at a desired position by fixing the base plate to, for example, a wall surface of a control panel in which other electrical equipment is accommodated. The Rukoto.

  By the way, although the controlled device is controlled by the programmable control unit 1 as described above, in the controlled device, when more sophisticated and complicated control is required, or when a failure occurs, The programmable control unit 1 may be updated to a new one in order to further save power. Here, as a result of downsizing the programmable control unit to be updated with respect to the existing (conventional) programmable control unit 1, the existing wiring connector may not correspond to the external connection connector of the programmable control unit to be updated.

  In the following description, it is assumed that the programmable control unit to be updated is smaller than the existing (conventional) programmable control unit 1 and the shape of the external connection connector does not correspond to the shape of the existing wiring connector.

(Programmable control unit 100)
FIG. 4 is a perspective view showing the programmable control unit 100 and the wiring conversion device to be updated, and FIG. 5 is a three-view diagram showing an attachment state of the programmable control unit 100 to be updated to the wiring conversion device. In FIG. 5, (a) shows a front view, (b) shows a bottom view, and (c) shows a side view, but in (c), some modules are removed. Indicates the state. Here, the programmable control unit 100 including the base board 110, the power supply module 120, the CPU module 130, and the three interface modules 140 will be described.

  The programmable control unit 100 to be updated includes a base board 110, a power supply module 120, a CPU module 130, and an interface module 140. In the programmable control unit 100 to be updated, the power supply module 120, the CPU module 130, and the interface module 140 are fixed to the base board 110 adjacent to each other in the width direction, like the conventional programmable control unit 1. However, in FIG. 4 and FIG. 5, a wiring conversion device 200 described later is shown at the same time, and the interface module 140 is not visible from the outside.

  The programmable control unit 100 is different from the programmable control unit 1 in the number of modules and the shape of each module, but the functions of the base board 110, the power supply module 120, the CPU module 130, and the interface module 140, and the base board 110 are different. The mounting structure of the power supply module 120, the CPU module 130, and the interface module 140 is the same as that of the programmable control unit 1 described above. Therefore, detailed description of the configuration of the programmable control unit 100 is omitted here.

  Here, the base board 110, the power supply module 120, the CPU module 130, and the interface module 140 are smaller than the base board 10, the power supply module 20, the CPU module 30, and the interface module 40 that constitute the existing (conventional) programmable control unit 1. It is assumed that weight reduction is achieved. Further, the interface module 140 is provided with an external connection connector 140a (not shown in FIG. 4) including a card edge connector connected to the wiring connector, similarly to the external connection connector 40a of the existing (conventional) interface module 40. However, the external connection connector 140a is also smaller than the external connection connector 40a.

  Therefore, when updating the programmable control unit 1 to the programmable control unit 100, the wiring connector that has been fitted to the external connection connector 40a of the existing interface module 40 is directly fitted to the external connection connector 140a of the new interface module 140. I can't let you. In such a case, first, the wiring connector connected to the controlled device is removed from the existing programmable control unit 1, and the existing programmable control unit 1 is removed. At this time, the base plate that fixes the existing programmable control unit 1 to the wall surface is also removed. And the programmable control unit 100 to update is installed through the wiring converter 200 in the place where the existing programmable control unit 1 was installed. This wiring conversion device 200 simultaneously supports both the programmable control unit 100 and the connection between the existing wiring connector and the interface module 140. Below, the structure of the wiring converter 200 is demonstrated in detail.

(Wiring converter 200)
The wiring conversion device 200 includes a base body 210, a signal conversion adapter 220, and a relay connector 230 described later. The base body 210 is a flat plate member formed by processing a metal plate, and includes a fixing surface 210a that fixes and supports the programmable control unit 100. Here, a rail fitting groove 114 is provided on the back surface of the base board 110 in the programmable control unit 100. The rail fitting groove 114 maintains a dimensional relationship in which the mounting rail R (see FIG. 5C) used for mounting the existing (conventional) programmable control unit 1 can be fitted. Therefore, when the existing programmable control unit 1 is removed, if the mounting rail R is removed from the programmable control unit 1, the same mounting rail R can be attached to the base board 110 of the programmable control unit 100 to be updated.

  FIG. 6 is a trihedral view of the base body 210, and FIG. 7 is a view showing the base body 210 in a state where the mounting rail R is screwed. As shown in FIG. 6, a pair of bosses 211 projecting to the front side are provided on the fixed surface 210 a of the base body 210 so as to be separated in the width direction. A screw hole 211a is formed at the tip of the boss 211. By screwing a screw inserted through a screw insertion hole provided in the mounting rail R into the screw hole 211a, as shown in FIG. The mounting rail R is fixed and supported on the base body 210. Therefore, the programmable control unit 100 is attached to the mounting rail R by screwing the mounting rail R to the base body 210 in a state where the mounting rail R is fitted in the rail fitting groove 114 provided on the back surface of the base board 110. It is fixed and supported by the base body 210 via

  Here, a boss 211 protruding to the front side is provided on the fixed surface 210 a of the base body 210, and a screw hole 211 a is provided at the tip of the boss 211. As described above, by providing the boss 211, in the state where the programmable control unit 100 is fixed to the base body 210, a gap is maintained between the fixed surface 210a and the back surface of the base board 110, but the boss 211 is essential. Instead, the screw hole 211a may be formed in the fixed surface 210a.

  Further, the base body 210 has a top surface portion 210b that is bent at a right angle from the upper end (upper surface side) in the height direction of the fixed surface 210a, and a front surface from the lower end (lower surface side) in the height direction of the fixed surface 210a. And a lower surface portion 210c bent at a right angle toward the side. Further, the base body 210 is bent at a right angle upward from a front end portion of the upper surface portion 210b and a detachable portion 212 that is bent at a right angle downward from the front end portion and from the front end portion of the lower surface portion 210c. A detachable portion 213. Note that the detachable portion 213 located on the lower surface portion 210c side of the base main body 210 is formed to have a larger protruding amount to the front side than the detachable portion 212 located on the upper surface portion 210b side of the base main body 210. Moreover, the fixed surface 210a has a dimension in the height direction larger than that of the programmable control unit 100, and the detachable portions 212 and 213 are designed not to interfere with the programmable control unit 100 fixed and supported on the fixed surface 210a. .

  Further, a plurality of the detachable portions 212 are provided at a predetermined interval in the width direction of the base main body 210, whereas the detachable portions 213 extend from one end to the other end of the base main body 210 in the width direction. doing. Each detachable portion 212 is provided with a screw hole 212a into which a screw is screwed. In the detachable portion 213, a plurality of claw receiving portions 214 have a predetermined interval in the width direction of the base body 210. Maintained. The claw receiving part 214 is located in each locking hole 214a that penetrates from the front side to the back side of the attachment / detachment part 213, and protrudes upward from the front side end of the lower surface part 210c. And a locking piece 214b. A gap is maintained between the protruding end of the locking piece 214b and the inner periphery of the locking hole 214a.

  The same number of the screw holes 212a provided in the detachable portion 212 and the claw receiving portions 214 provided in the detachable portion 213 are provided, and one screw hole 212a opposed in the height direction and one claw receiving portion. Part 214 is paired. Then, the signal conversion adapter 220 is detachably attached to the screw hole 212a and the claw receiving portion 214 that form a pair.

  FIG. 8 is a perspective view of the signal conversion adapter 220. The signal conversion adapter 220 shown in this figure mainly connects an existing wiring connector and the interface module 140 by converting the wiring. As can be understood with reference to FIGS. 4 and 5, the signal conversion adapter 220 is attached to the base body 210 so as to surround the interface module 140. In the present embodiment, since the outer shapes of the three interface modules 140 are the same shape, the outer shapes of the signal conversion adapters 220 corresponding to the interface modules 140 are also the same shape.

  However, in this embodiment, the shape of the external connection connector 140a in each interface module 140 is different. Therefore, each signal conversion adapter 220 also has a different shape corresponding to the external connector 140a. Hereinafter, as an example of the signal conversion adapter 220, the signal conversion adapter 220 corresponding to the leftmost interface module 140 in FIG. 5 among the three interface modules 140 will be described.

  The signal conversion adapter 220 has a front portion 220 a that is mounted on the base main body 210 and is opposed to the front surface of the interface module 140. The front portion 220a is provided with fixing portions 221a and 221b for fixing an existing wiring connector to the front side of the front portion 220a with screws. Further, an opening 222a and a connector insertion hole 222b penetrating in the thickness direction are formed in the front portion 220a.

  The opening 222a faces the front of the interface module 140, and enables confirmation of various lamps provided on the front of the interface module 140. The connector insertion hole 222b is for inserting the wiring connector fixed to the fixing portions 221a and 221b to the back side. As will be described in detail later, the signal conversion adapter 220 is fixed with a wiring conversion printed circuit board 223 that fits into an existing wiring connector, and when the existing wiring connector is fixed to the fixing portions 221a and 221b, the wiring The connector is designed to be fitted to the wiring conversion printed board 223.

  Further, the front portion 220 a maintains a dimensional relationship in which both end portions in the height direction protrude from the interface module 140. Then, a pair of extending portions 220b and 220c are extended from both ends in the height direction of the front portion 220a toward the back side, that is, the base body 210 side. A screw insertion portion 224 through which a screw is inserted is provided at the distal end in the extending direction of the extending portion 220b, and a locking claw 225 in which a through hole 225a is formed at the distal end in the extending direction of the extending portion 220c. Is provided.

In a state where the signal conversion adapter 220 is attached to the base body 210, the screw insertion part 224 faces the screw hole 212 a provided in the attachment / detachment part 212 of the base body 210, and the locking claw 225 is attached / detached to / from the base body 210. It is inserted through the locking hole 214a of the claw receiving portion 214 provided in the portion 213 (see FIGS. 5 to 7). Note that the extending portion 220b, in order to improve the strength, the reinforcing portion 220b ₁ is formed which is bent toward the both ends in the width direction downward. Similarly, the extending portion 220c, in order to improve the strength, reinforcing portion 220c ₁ are formed is bent toward the both ends in the width direction upwards.

Then, engagement of the reinforcing portion 220c ₁ of the extending portion 220c, a portion facing the outer surface (lower surface) of the interface module 140, i.e., the surface facing the interface module 140 in the reinforcing portion 220c ₁ from the front portion 220a side An inclination s is provided that is separated from the outer surface (lower surface) of the interface module 140 toward the stop claw 225 side. The extending portions 220b and 220c are provided with a number of lightening holes in order to reduce the weight and heat dissipation while ensuring the necessary strength.

(Wiring conversion method)
FIG. 9 is a diagram for explaining a wiring conversion method. When connecting an existing wiring connector to the interface module 140 of the programmable control unit 100 to be updated, first, the programmable control unit 100 is fixed to the base body 210 via the mounting rail R. At this time, the external connection connector 140a faces the front of the interface module 140, and the relay connector 230 that electrically connects the existing wiring connector 300 is fitted to the external connection connector 140a.

  More specifically, the relay connector 230 is provided with a card edge terminal 230a fitted on the card edge contact of the external connection connector 140a on the back side, and provided on the back side on the front side. A card edge terminal 230b having the same shape as the card edge terminal 230a is provided. Therefore, here, the card edge terminal 230a of the relay connector 230 is fitted into the external connection connector 140a (card edge contact) of the interface module 140.

  Further, the wiring conversion printed circuit board 223 fixed to the signal conversion adapter 220 is provided with a card edge contact 223a fitted to the card edge terminal 230b of the relay connector 230 on the back side, and the existing wiring connector 300 on the front side. A card edge contact 223b that fits into the card edge terminal 300a is provided. The wiring conversion printed circuit board 223 is formed with a printed circuit (etching) for converting the arrangement order of the wirings between the card edge contacts 223a and 223b.

FIG. 10 is a diagram for explaining a method of attaching the signal conversion adapter to the base board. As described above, after the relay connector 230 is fitted to the interface module 140, the signal conversion adapter 220 is then attached to the base body 210. Here, the signal conversion adapter 220 is attached to the base body 210 as follows. That is, as shown in FIG. 10 (a), the extending portion 220c of the signal adapter 220 is provided with a reinforcing portion 220c ₁ facing the bottom surface of the interface module 140, the inclination s of this reinforcing portion 220c ₁ is Is formed. The signal conversion adapter 220 is brought closer to the base body 210 as shown in FIG. 10B while the signal conversion adapter 220 is inclined so that the inclination s is substantially parallel to the lower surface of the interface module 140. .

  Then, as shown in FIG. 10C, the locking claw 225 provided at the tip of the extending portion 220 c of the signal conversion adapter 220 passes through the locking hole 214 a formed in the detachable portion 213 of the base body 210. To do. At the same time, as shown in FIG. 10B, the card edge contact 223a of the wiring conversion printed board 223 enters the card edge terminal 230b of the relay connector 230.

  Then, as shown in FIG. 10D, the signal conversion adapter 220 is rotated in a direction in which the front part 220 a of the signal conversion adapter 220 is parallel to the front of the interface module 140. Then, the card edge contact 223a of the wiring conversion printed board 223 is completely fitted to the card edge terminal 230b of the relay connector 230. At this time, the locking piece 214b provided in the base main body 210 passes through the through hole 225a formed in the locking claw 225, and the extending portion 220c is locked to the detachable portion 213. Further, at this time, the screw insertion portion 224 provided at the distal end of the extending portion 220 b of the signal conversion adapter 220 is disposed opposite to the screw hole 212 a provided in the detachable portion 212 of the base body 210. And the extension part 220b is screw-fixed to the attachment / detachment part 212 by screwing the screw inserted in the screw insertion part 224 into the screw hole 212a.

  As described above, according to the mounting structure of the base body 210 and the signal conversion adapter 220, the work of attaching and detaching the signal conversion adapter 220 to the base body 210 can be simplified. When the signal conversion adapter 220 is attached to the base body 210, the relay connector 230 is sandwiched between the front portion 220a of the signal conversion adapter 220 and the base body 210 (fixed surface 210a). Thereby, the electrical continuity among the wiring conversion printed circuit board 223, the relay connector 230, and the interface module 140 (external connection connector 140a) is reliably maintained.

  As described above, when the signal conversion adapter 220 is attached to the base body 210 and the external connection connector 140a, the relay connector 230, and the wiring conversion printed circuit board 223 are respectively fitted, the wiring is connected to the fixing portions 221a and 221b of the signal conversion adapter 220. The connector 300 is fixed by screwing. At this time, the card edge terminal 300a of the wiring connector 300 passes through the connector insertion hole 222b (see FIG. 8) formed in the front portion 220a of the signal conversion adapter 220 and enters the back side of the front portion 220a. It fits into the card edge contact 223b of the conversion printed circuit board 223. As a result, the existing wiring connector 300 is connected to the external connection connector 140a via the relay connector 230 after being converted in the wiring conversion printed board 223.

  As described above, according to the wiring conversion device 200 of this embodiment including the base main body 210, the signal conversion adapter 220, and the relay connector 230, the programmable control unit 100 to be updated can be installed without requiring a large installation space. Can do. Therefore, it becomes possible to install the programmable control unit 100 to be updated in the same place as the space where the existing (conventional) programmable control unit 1 is installed.

  In addition, according to the above-described wiring conversion device 200, the signal conversion adapter 220 supports the existing wiring connector 300, and the base main body 210 supports the signal conversion adapter 220. That is, the existing wiring connector 300 is supported by the base body 210. If the wiring connector 300 is directly fitted to the relay connector 230 without using the signal conversion adapter 220, the total mass of the relay connector 230 and the wiring connector 300 acts on the interface module 140. As a result, a fitting portion between the external connection connector 140a and the relay connector 230, a fitting portion between the relay connector 230 and the wiring connector 300, and a locking portion between the interface module 140 and the base board 110 (module mounting piece). In addition, stress is generated in the module locking portion), and each component may be damaged by long-term use.

  As in the wiring conversion device 200 of the present embodiment, the wiring connector 300 is supported on the base body 210 via the signal conversion adapter 220, thereby causing stress generated in the fitting portion between the external connection connector 140a and the relay connector 230, and the like. Can be reduced, and the risk of damage to each part can be reduced.

  As mentioned above, although preferred embodiment of this invention was described referring an accompanying drawing, it cannot be overemphasized that this invention is not limited to this embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Is done.

  For example, in the above embodiment, the base body 210 is provided with the detachable portions 212 and 213, the extension portion 220 b of the signal conversion adapter 220 is screwed to the detachable portion 212, and the signal conversion adapter 220 is extended to the detachable portion 213. The part 220c is locked. However, the mounting structure between the base main body 210 and the signal conversion adapter 220 is not limited to the above embodiment, and the specific structure can be used as long as the tips of the extending portions 220b and 220c can be locked or fixed. Can be designed as appropriate.

  Moreover, in the said embodiment, the structure of the existing (conventional) programmable control unit 1 and the programmable control unit 100 to update is only an example. In any case, the above-described wiring conversion device 200 has an interface module provided with an external connection connector that is electrically connected to the wiring connector, and is connected to the controlled device via the external connection connector and the wiring connector. The present invention can be widely applied to programmable control units that perform either or both of signal input and output.

  In the above embodiment, the electrical connection between the external connection connector 140a of the interface module 140 and the existing wiring connector 300 is performed via the wiring conversion printed circuit board 223 and the relay connector 230 provided separately. I decided to plan. However, for example, the wiring conversion printed circuit board 223 and the relay connector 230 may be integrally formed, and the wiring conversion printed circuit board 223 is not an essential configuration as long as the relay connector 230 has a wiring conversion function. .

  INDUSTRIAL APPLICABILITY The present invention can be used for a programmable control unit including an interface module that inputs and outputs signals to and from a controlled device.

DESCRIPTION OF SYMBOLS 100 ... Programmable control unit 140 ... Interface module 140a ... External connection connector 200 ... Wiring converter 210 ... Base main body 212, 213 ... Desorption part 214 ... Claw receiving part 214a ... Locking hole 214b ... Locking piece 220 ... Signal conversion adapter 220a ... Front parts 220b, 220c ... Extension parts 221a, 221b ... Fixing part 222a ... Opening 223 ... Wiring conversion printed circuit board 223a, 223b ... Card edge contact 225 ... Locking claw 230 ... Relay connector 230a, 230b ... Card edge terminal

Claims (4)

An interface module provided with an external connection connector that is electrically connected to the wiring connector, and either one of signal input and output with the controlled device via the external connection connector and the wiring connector Or a wiring conversion device used in a programmable control unit that performs both,
A base body that is located on the back side opposite to the front side of the interface module and supports the programmable control unit;
The front surface of the interface module is arranged opposite to the front surface of the interface module in a state of being attached to the base body, and both end portions protrude in the surface direction from the front surface of the interface module. a pair of extending portions extending Te, the pair of extending portions one of the locking claw provided at the distal end of, and have a fixing portion for fixing the wiring connector provided on the positive surface, said base A signal conversion adapter detachably provided on the main body ,
A relay connector that electrically connects the wiring connector fixed to the signal conversion adapter, and the external connection connector provided in front of the interface module fixed to the base body;
With
The wiring conversion device according to claim 1, wherein the locking claw provided on one of the pair of extending portions is locked to the base body, and the other of the pair of extending portions is screwed . In the signal conversion adapter,
There is provided a wiring conversion printed circuit board in which a circuit that fits both the wiring connector fixed to the fixing portion and the relay connector and converts the arrangement order of the wiring between the two connectors is formed. The wiring conversion device according to claim 1. Wherein the front portion, the wiring conversion device according to claim 1 or 2, characterized in that the opening facing the front of the interface module is provided. Of the extended portion provided with the locking claw, the portion facing the outer surface of the interface module has an inclination that is separated from the outer surface of the interface module as it goes from the front portion side to the locking claw side. The wiring conversion device according to claim 1 , wherein the wiring conversion device is provided.

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