JP6551129B2 - Circuit board - Google Patents

Description

  The present invention relates to a circuit board for a programmable logic controller.

  A programmable logic controller (hereinafter, referred to as a PLC (Programmable Logic Controller)) in which a power supply unit, an input / output unit, a control unit, and the like are housed in a single case is known (see, for example, Patent Document 1).

JP, 2014-190566, A

In such a PLC, although basic functions are common, some specifications may be different. For example, in a PLC having a function of performing processing according to an input signal, when a terminal portion having 16 terminals is provided, a signal is input to all 16 terminals (hereinafter referred to as convenience). In some cases, the input signal is less than the A type, and the order in which the signals are input is different from the A type (hereinafter referred to as the B type for convenience).
However, if the above-mentioned A type and B type are dedicated designs, the number of circuit boards to be stocked will increase, and the types and number of parts to be mounted will also differ, so the stocked parts will be managed separately. There is a problem that inventory management becomes complicated.

In addition, for example, when the A type is a mainstream product that is shipped regularly or in large quantities, and the B type is a sidestream product that is irregular or a product that is shipped in a smaller number than the A type, There are also circumstances that it is not very desirable from the viewpoint of management and cost to stock parts dedicated to B type and to separately manage parts separately for A type and B type.
The present invention has been made in view of the above circumstances, and an object thereof is to provide a circuit board capable of facilitating inventory management when there are programmable logic controllers having different specifications.

  In the first aspect of the present invention, the circuit board has a terminal portion in which N terminals are arranged adjacent to each other, a control portion having N input ports from No. 1 to N, and a terminal part And a switching circuit which is provided between the control unit and switches a signal path from the terminal unit to the control unit. The switching circuit is formed with a circuit pattern for mounting a plurality of jumper components, and by changing the mounting state of the jumper components, that is, depending on whether the jumper components are mounted or not mounted, A first path connecting the N terminals of the terminal section and the 1st to Nth input ports of the control section in the order of the numbers, or M at least a part of the terminals of the terminal section are not adjacent to each other The signal path is switched to one of the second paths that connects the terminals (where M <N) and the input ports from No. 1 to No. M of the control unit in the order of the numbers.

As a result, by switching the signal path by the switching circuit, even signals input to the same terminal can be connected to different input ports corresponding to the respective specifications. For this reason, even if it is PLC from which the specification of the signal connected to a terminal part differs, it will suffice if one kind of circuit board is prepared.
In addition, since the signal path can be switched in the mounted state of the jumper component, it is possible to suppress an inadvertent increase in the type and number of components. That is, since there is only one type of jumper component and it is a component commonly used even in PLCs with different specifications, the number of managed components does not increase. This makes it possible to reduce the types of parts to be managed.

Therefore, when there are programmable logic controllers with different specifications, inventory management of circuit boards and components can be facilitated. Further, since the main PLC, the circuit board, and the types of components to be mounted can be made common, it is also possible to reduce the time and effort for managing the PLC to be a side stream.
Further, the circuit board switches the signal path itself by a resistor depending on the mounting state of the jumper component. Therefore, compared with the case of performing the process of switching the correspondence between the terminal number and the input port number in software, the time required for outputting the processing result after the signal is input can be shortened.
In addition, since the signal path is switched due to the difference in the arrangement of the jumper parts, it can be easily confirmed which specification is used, and practical work such as visual inspection at the work site can be simplified. .

According to the second aspect of the present invention, the circuit board is provided with an insulating circuit having N individual insulating circuits which individually electrically insulate the signals inputted to the respective terminals of the terminal portions. The switching circuit is arranged between the insulating circuit and the control unit, and changes the mounting state of the jumper component, and the mounting state of the individual insulating circuit in which no signal is input among the N individual insulating circuits. Is changed to either the first route or the second route.
As described above, by dismounting the individual isolation circuit that is not required in the second path among the mountable individual isolation circuits, the output of the individual isolation circuit and other signals collide when the path is switched. Can be prevented. Moreover, since the individual insulation circuit which is not required is not mounted, the component cost can be reduced. In other words, even when using a common circuit board, it is possible to suppress an increase in cost when setting the second path. In addition, since the signal path is switched by not mounting the individual insulation circuit, it is not necessary to provide a jumper component for intermittent connection with the individual insulation circuit, and an increase in the number of jumper components can be suppressed.

  In addition, in the vicinity of a terminal portion to which an external signal line is connected, it may be regulated by product safety standards such as UL standards, for example, for the sake of safety, that components are densely arranged. Therefore, by providing the switching circuit on the rear stage side of the individual insulation circuit, that is, by providing the switching circuit between the insulation circuit and the control unit, it is possible to prevent components from being densely arranged near the terminal unit. Ru. Therefore, when providing the switching circuit, the product safety standard can be cleared.

  In the invention described in claim 3, the jumper component forming the second path is the 3 × i + 1-th (where i is an integer of 1 or more) terminal of the terminal portion and the i + 1-th input port of the control portion. It is provided between. Further, the jumper component forming the first path is provided between the 3 × i + 1-th (where i = 1) terminal of the terminal section and the 3i + 1-th input port of the control section. That is, the jumper parts are arranged so that signals can be input to all the terminals of the terminal part in the case of the first path, while the difference between the terminals of the terminal part is equal in the case of the second path. The arrangement is such that signals can be input to M terminals arranged in series.

When the number of input signals is less than the number of terminals and there are remaining terminals that do not input signals, the user desires to use the remaining terminals for other purposes such as power supply and grounding. It is possible to do. And from the manufacturer side of PLC, it is considered that there is a high possibility that the above-mentioned user's request will be taken in.
Therefore, by providing jumper parts so that the terminals for inputting signals are arranged in an arithmetic series, a terminal for use in other applications can be arranged next to the terminal for inputting signals. become. In other words, a terminal used as a set with the input signal can be provided in the vicinity of the signal terminal.

  As a result, for the user side, the terminal can be used for applications other than signal input, and since the terminal to be used is close, wiring can be facilitated and the possibility of wiring error can be reduced. Further, on the manufacturer side, not only the above-described management cost is reduced, but also the convenience on the user side is increased, so that a highly convenient PLC can be provided.

  In the invention described in claim 4, when the second path is set, N terminal portions are used as signal input terminals while the rest are used as power supply terminals. The circuit board is provided with a power supply circuit for supplying power to terminals used as a power supply terminal. Thereby, when connecting an external sensor etc. to a terminal part, it becomes unnecessary to provide a power supply device separately. Therefore, it is possible to provide a PLC that is highly convenient for the user.

The figure which shows typically the electric constitution of the circuit board by embodiment Diagram schematically showing the connection status of A-type signals and the mounting status of components Diagram schematically showing the connection state of B-type signals and the mounting state of components A diagram schematically showing another example of the arrangement of the jumper parts

Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 3.
As shown in FIG. 1, the circuit board 1 includes a control unit 2, a terminal unit 3, an input circuit 4, an insulating circuit 5, a switching circuit 6, a power supply circuit 7 and the like. The circuit board 1 is a so-called printed board supposing that for a programmable logic controller (hereinafter, referred to as PLC (Programmable Logic Controller)). Although not shown in FIG. 1, the circuit board 1 is provided between a power supply circuit for supplying power to the control unit 2 and an output unit for outputting the processing result of the control unit 2 and the outside. Of course, other required circuits such as a communication circuit for performing communication in the above are also mounted.

The control unit 2 includes a microcomputer having a CPU, a ROM, a RAM, and the like (not shown). The control unit 2 controls the entire PLC by executing a computer program stored in a ROM or the like, for example. The control unit 2 has N (No. 16 in this embodiment) input ports 1 to 16 shown as P1 to P16 in FIG.
The terminal part 3 is directly mounted on the circuit board 1. The terminal portion 3 includes N (N = 16 in this embodiment) terminals (T1 to T16) from the first to the sixteenth. Each terminal 3 has, for example, a screw structure or a connector structure, and is connected to an external signal line.

The input circuit 4 includes 16 individual input circuits (I1 to I16) corresponding to the terminals T1 to T16. The input circuit 4 includes a protection circuit, an input buffer circuit, and the like. However, the configuration of the input circuit 4 is not limited to this.
The insulating circuit 5 is provided between the input circuit 4 and the control unit 2. The insulating circuit 5 includes sixteen individual insulating circuits (Z1 to Z16) corresponding to the number of terminals (T1 to T16) of the terminal portion 3. The individual insulation circuits (Z1 to Z16) electrically insulate between the input side (terminal 3 side) and the output side (control 2 side).

  The switching circuit 6 is provided between the terminal unit 3 and the control unit 2, more specifically, between the insulating circuit 5 and the control unit 2 in the present embodiment. The switching circuit 6 is formed with a circuit pattern for mounting a plurality of resistors (AR1, BR1 to BR4, which correspond to jumper components). In each of the resistors (AR1 and BR1 to BR4), a so-called chip resistor of a surface mount type, which has an electrical resistance close to zero, which is also called a zero ohm resistor, is adopted so as to enable automatic mounting by a mounter.

  The resistor (AR1) of the switching circuit 6 is provided between the individual insulation circuit (Z4) and the input port (P4). The resistor (BR1) is provided between the individual insulation circuit (Z4) and the input port (P2). Therefore, when the resistor (AR1) is mounted and the resistor (BR1) is not mounted, a signal path is formed between the individual insulating circuit (Z4) and the input port (P4). On the other hand, when the resistor (AR1) is not mounted and the resistor (BR1) is mounted, a signal path is formed between the individual insulating circuit (Z4) and the input port (P2).

  The resistor (BR2) is provided between the individual insulation circuit (Z7) and the input port (P3). Therefore, when the resistor (BR2) is mounted, a signal path is formed between the individual insulating circuit (Z7) and the input port (P3). At this time, a signal path is also formed between it and the input port (P7), but in the case of B type described later, since the input port (P7) is not used, there is no practical problem. .

  The resistor (BR3) is provided between the individual insulation circuit (Z10) and the input port (P4). Therefore, when the resistor (BR3) is mounted, a signal path is formed between the individual insulation circuit (Z10) and the input port (P4). At this time, a signal path is also formed between it and the input port (P10), but in the case of B type described later, the input port (P10) is not used, so there is no problem in practical use. .

  The resistor (BR4) is provided between the individual insulation circuit (Z13) and the input port (P5). Therefore, when the resistor (BR4) is mounted, a signal path is formed between the individual insulation circuit (Z13) and the input port (P5). At this time, a signal path is also formed between it and the input port (P13), but in the case of B type to be described later, since the input port (P13) is not used, there is no practical problem. .

  Among these resistors, the path in which the resistor (AR1) is mounted and the resistors (BR1 to BR4) are not mounted corresponds to the first path. On the other hand, a path in which the resistor (AR1) is not mounted and the resistors (BR1 to BR4) are mounted corresponds to the second path. That is, the switching circuit 6 mounts or does not mount each resistor (ARxx, BRyy), thereby making the signal path from the terminal unit 3 to the control unit 2 either the first path or the second path. Switch to More specifically, the signal path between the output of the isolation circuit 5 and the input port of the control unit 2 is switched.

  In other words, the circuit board 1 is configured such that the signal path from the terminal unit 3 to the control unit 2 is switched according to the mounting state of each resistor. As described later, when the second path is set, the corresponding individual input circuit (I2, I3, I5, I6, I8, I9, I11, I12, I14, I15) and the individual insulating circuit ( Z2, Z3, Z5, Z6, Z8, Z9, Z11, Z12, Z14, Z15) are also unmounted.

  The power supply circuit 7 supplies power to a terminal to which an external signal is not input when the second path is set. Specifically, the power supply circuit 7 includes a plurality of resistors (RB10 to RB19). Among these, the resistors (BR10 to BR14) have one terminal connected to a positive power supply (V +) supplied from a power supply circuit (not shown). The resistors (BR15 to BR19) have one terminal connected to a negative power supply (V−) supplied from a power supply circuit (not shown). Although a positive power supply may be shared with the power supply potential (VCC) or a negative power supply may be shared with GND, in such a case, the power used internally should be isolated from the power supplied externally. Is desirable.

  In addition, each resistor has a terminal opposite to the terminal connected to the power supply connected to the terminal (T1 to T16) of the corresponding terminal portion 3. Specifically, the resistor (BR10) is connected to the terminal (T2), the resistor (BR11) is connected to the terminal (T5), and the resistor (BR12) is connected to the terminal (T8). BR13) is connected to the terminal (T11), and the resistor (BR14) is connected to the terminal (T14). The resistor (BR15) is connected to the terminal (T3), the resistor (BR16) is connected to the terminal (T6), the resistor (BR17) is connected to the terminal (T9), and the resistor (BR18) is The resistor (BR19) is connected to the terminal (T15).

Next, the operation of the above configuration will be described.
First, the reason why the first route and the second route are configured to be switchable will be described.
Although PLCs have the same basic functions, some specifications may be different. In the example of the present embodiment, the control unit 2 of the present embodiment has a function of performing processing according to each signal input to the terminal unit 3. However, even when 16 terminals are provided, a PLC of a type in which signals are input to all terminals (hereinafter referred to as A type for convenience) and the number of input signals is A. There is a type of PLC (hereinafter referred to as "B type" for convenience) that uses fewer types and uses some terminals for power supply. As shown in FIGS. 2 and 3 to be described later, the arrangement of terminals to which signals are input differs between the A type and the B type.

  In this case, if the A type and the B type are respectively designed specifically, the number of boards increases and the types and the number of parts to be mounted are different, so it becomes necessary to separately manage the parts to be stocked separately . As a result, there is a problem that inventory management becomes complicated. Also, for example, when the A type is a mainstream product to be shipped regularly or in large quantities, and the B type is an irregular or sidestream product to which only a small number is shipped compared to the A type, parts dedicated to the B type There is also a situation that it is not very desirable from the management aspect and the cost aspect to keep parts in stock and to manage parts separately for A type and B type.

In addition, when the order in which signals are input differs between A type and B type, the control unit 2 can perform processing to associate the terminal number with the input port number, but in that case, Since the change of the association is processed by software, it takes a long time to output the processing result after the signal is input.
Therefore, the circuit board 1 according to the present embodiment attempts to share parts in the A type and B type PLCs that use different terminals as described below, and outputs a processing result after a signal is input. It is preventing that the time required until it becomes long.

In the case of the above-mentioned A type, as shown in FIG. 2, 16 external signals of CH1 to CH16 are respectively input to the terminals (T1 to T16) of the terminal portion 3. That is, in the A type, all terminals of the terminal unit 3 are used as input terminals for inputting external signals. Note that CH1 to CH16 are assumed to be external sensor signals.
The first route is a route for supporting this A-type PLC, and the terminals 1 to 16 (T1 to T16) of the terminal unit 3 are connected to the first to 16th units of the control unit 2. The input ports (P1 to P16) are connected in the order of their numbers. That is, in the 21st route, the signals of CH1 to CH16 are input to the input ports (P1 to P16) in the order of their numbers.

Specifically, in the case of the first path, the resistor (AR1) is mounted, the resistors (BR1 to BR4) are not mounted, and the input circuit 4 and the insulating circuit 5 are mounted. In FIG. 2, parts to be unmounted are hatched to schematically show that the parts are not mounted.
Thereby, the 1st path | route through which the signal input into each terminal (T1-T16) of the terminal part 3 is transmitted to an input port (P1-P16) via the input circuit 4 and the insulation circuit 5 is formed. The

On the other hand, in the case of the B type described above, as shown in FIG. 3, the CH1 signal is input to the terminal (T1) of the terminal portion 3, the CH2 signal is input to the terminal (T4), and the terminal (T7 , The signal of CH3 is input to the terminal (T10), the signal of CH4 is input to the terminal (T10), and the signal of CH5 is input to the terminal (T13). In the case of the B type, the terminals (T2, T5, T8, T11, T14) are used for supplying positive power, and the terminals (T3, T6, T9, T12, T15) are used for supplying negative power. .
That is, in the B type, five predetermined terminals among the sixteen terminals are used as input terminals for inputting an external signal, and the remaining ten terminals supply power to the outside. It is a specification used as a terminal.

  The second path is a path for coping with this B type PLC, and M terminals where at least a part of the terminals of the terminal portion 3 are not adjacent to each other (where M <N, M in this embodiment is M). = 5) are connected to the input ports (P1 to P5) of No. 1 to No. 5 of the control unit 2 in the order of the numbers. That is, in the second route, the signals of CH1 to CH55 are input to the input ports (P1 to P5) in the order of their numbers.

  Specifically, the resistor (AR1) is not mounted, the resistors (BR1 to BR4) are mounted, and the individual input circuits (I2, I3, I5, I6, I8, I9, I11, I12) of the input circuit 4 are mounted. , I14 and I15) are not mounted, and individual insulating circuits (Z2, Z3, Z5, Z6, Z8, Z9, Z11, Z12, Z14 and Z15) not used among the insulating circuits 5 are not mounted. In FIG. 3, the parts that are not mounted are hatched to schematically show that they are not mounted.

  Thereby, the terminal (T1) of the terminal unit 3 and the input port (P1) are connected, the terminal (T4) of the terminal unit 3 and the input port (P2) are connected, and the terminal (T7) of the terminal unit 3 The input port (P3) is connected, the terminal (T10) of the terminal unit 3 and the input port (P4) are connected, and the terminal (T13) of the terminal unit 3 and the input port (P5) are connected. That is, a second path is formed for transmitting the signals of CH1 to CH5 input to the terminals of the terminal unit 3 to the input ports (P1 to P5) via the corresponding input circuit 4 and the insulating circuit 5. More specifically, the resistors (BR1 to BR4) forming the second path are the 3 × i + 1-th (where i is an integer of 1 or more) terminal 3 and the i + 1-th input of controller 2. It is provided between the ports (P2 to P5). The resistor (AR1) forming the first path is the 3 × i + 1-th (where i = 1, that is, the fourth) terminal of the terminal portion and the 3i + 1-th input port (P4) of the control portion. It is provided between.

  Further, since the individual insulation circuits (Z2, Z3, Z5, Z6, Z8, Z9, Z11, Z12, Z14, Z15) are not mounted, for example, the input port (P2) via the resistor (BR1) There is also no collision between the signal input to the signal and the output of the individual isolation circuit (Z2). Also, by mounting the resistors (BR10 to BR19) of the power supply circuit 7, positive power is supplied to the terminals (T2, T5, T8, T11, T14) of the terminal unit 3, and the terminals (T3, Negative power is supplied to T6, T9, T12, and T15).

Further, since the resistor (AR1) is not mounted, for example, when switching between the first path and the second path, the output of the individual insulation circuit (Z4) and the output of the individual insulation circuit (Z7), for example. And collision is prevented.
Thus, the circuit board 1 can switch between the first path and the second path in a hardware manner by selecting mounting / non-mounting of the resistor on one type of substrate.

According to the embodiment described above, the following effects can be obtained.
The circuit board 1 includes a terminal unit 3 in which N terminals from No. 1 to N are arranged adjacent to each other, a control unit 2 having N input ports from No. 1 to N, and terminals The switching circuit 6 is provided between the unit 3 and the control unit 2 and switches a signal path between the terminal unit 3 and the control unit 2.

  The switching circuit 6 is formed with a circuit pattern for mounting the jumper component, and by changing the mounting state of the jumper component, the first to Nth terminals of the terminal section 3 and the control section 2 are A first path connecting input ports from No. 1 to No. N in the order of numbers, or M terminals (where M <N) at least some of the terminals of the terminal unit 3 are not adjacent to each other And the signal path is switched to one of the second paths that connect the input ports from No. 1 to No. M of the control unit 2 in the order of the numbers. That is, the switching circuit 6 switches the signal path by mounting or not mounting the jumper component.

  Thus, for example, the terminal (T4) is connected to the input port (P4) in the case of A type PLC, and is connected to the input port (P2) in the case of B type, etc. Signals can be connected to different input ports. For this reason, PLCs with different specifications such as A type and B type exist, and even when the specifications for connecting external signals are different, one type of circuit board 1 can cope with them. In addition, since the signal path can be switched by selecting mounting / non-mounting of the jumper component, it is possible to suppress an unnecessary increase in the type and number of components. That is, the types of parts to be managed can be reduced.

Therefore, inventory control of the circuit board 1 and components can be facilitated in programmable logic controllers having different specifications.
In this case, since the signal path itself is switched by the resistor, the processing result after the signal is input is compared with the case where the control unit 2 performs the process of associating the terminal number with the input port number. The time required for output can be shortened, and the response speed can be increased. Further, since the types of the circuit board 1 and the components to be mounted can be made common between the mainstream PLC and the sidestream PLC, it is possible to reduce management effort for the sidestream PLC. In addition, by configuring the switching circuit 6 with a minimum number of resistors, an increase in cost due to the provision of the switching circuit 6 can be suppressed.

In addition, the circuit board 1 includes an insulating circuit 5 having N individual insulating circuits that electrically insulate the signals input to the respective terminals of the terminal portions 3 individually. The switching circuit 6 is provided between the insulating circuit 5 and the control unit 2.
Then, the switching circuit 6 switches the signal path to either the first path or the second path by changing the mounting state of the jumper component and the mounting state of the individual isolation circuit. In other words, the switching circuit 6 switches the signal path by mounting or unmounting the jumper component, and mounting or unmounting the individual insulation circuit to which no signal is input among the individual insulation circuits.

  At this time, if there is an individual insulation circuit that does not need to be mounted as in the B type, the individual insulation circuit is not mounted. Therefore, when the second path is set, the collision with the output of the individual isolation circuit is prevented. In addition, since the individual insulating circuit is not mounted, it is possible to reduce the component cost when setting the second path. In this case, since unnecessary inputs are not implemented, the cost can be reduced accordingly. In other words, it is possible to suppress an excessive increase in cost when the second route is set.

  In addition, in the vicinity of the terminal portion 3 to which the external signal line is connected, there is a case where it is regulated by product safety standards that parts are arranged densely for safety reasons. Therefore, by providing the switching circuit 6 on the rear side of the individual insulation circuit, that is, between the insulation circuit 5 and the control unit 2, it is possible to prevent parts from being densely arranged in the vicinity of the terminal unit 3 and to ensure product safety. The criteria can be cleared.

  In addition, in the circuit board 1, when the second path is set, M (5 in the embodiment) terminals out of N (16 in the embodiment) terminals are used as signal input terminals. The remaining terminals are used as power supply terminals. The circuit board 1 includes a power supply circuit 7 that supplies power to a terminal used as a power supply terminal. Thereby, when connecting an external sensor to the terminal part 3, for example, it is not necessary to separately provide a power supply device, and convenience for the user can be improved.

In addition, since the signal path is switched due to the difference in the arrangement of the resistors, it can be easily confirmed which specification is used, and since the number of jumper parts is small, the confirmation work itself can be simplified. . Therefore, it is possible to reduce the practical labor at the work site.
The resistors (BR1 to Br4) forming the second path are the 3 × i + 1-th terminal (where i is an integer of 1 or more) of the terminal unit 3 and the i + 1-th input port (P2) of the control unit 2. To P5). The jumper parts forming the first path are the 3 × i + 1-th terminal (where i = 1, the fourth in the present embodiment) and the 3i + 1-th input port (P4) of the control unit 2. It is provided between.

  As a result, a terminal not used for signal input can be used for other purposes such as power supply as in the present embodiment. Further, a terminal for inputting a signal and a terminal used as a set with the signal can be provided close to each other. Therefore, the usability on the user side is enhanced, and a highly convenient PLC can be provided.

The present invention is not limited to the embodiments described above and described in the drawings, and various modifications and expansions can be made without departing from the scope of the invention.
The numerical values shown in the embodiments are examples, and the present invention is not limited to these.
In the embodiment, an example in which a zero ohm resistor is adopted as a resistor as a jumper component constituting the switching circuit 6 is shown, but other types of components can be used as long as they can be connected or short-circuited without changing electrical characteristics. It may be adopted. In that case, it would be better if the mounter can be automatically mounted.

Although the configuration in which the input circuit 4 and the insulating circuit 5 are provided is shown in the embodiment, the insulating circuit 5 may be configured to also serve as the input circuit 4.
In the embodiment, in order to reduce the number of resistors, a signal is also input to input ports (P7, P10, and P13) that are not used in the B type PLC. However, as shown in FIG. For example, a resistor (AR2) that is not mounted in the B type may be provided between the input port (P7). In FIG. 4, parts to be unmounted are hatched to schematically show that the parts are not mounted. Thereby, in the case of the A type, the first path can be formed by mounting the resistors (AR2 to AR4), and in the case of the B type, the resistors (AR2 to AR4) are not mounted. A second path can be formed. Then, no signal is input to the input ports (P7, P10, P13) that are not used in the B type. This prevents a signal from being input to an unused input port and prevents an increase in software processing load.

  In the drawings, 1 is a circuit board, 2 is a control unit, 3 is a terminal unit, 4 is an input circuit, 5 is an insulating circuit, 6 is a switching circuit, 7 is a power supply circuit, AR1 is a resistor (jumper part), BR1 to BR1. BR4 is a resistor (jumper part), P1 to P16 are input ports, T1 to T16 are terminals, and Z1 to Z16 are individual insulation circuits.

Claims (4)

A circuit board for a programmable logic controller,
A terminal portion in which N terminals are arranged adjacent to each other;
A control unit having N input ports from No. 1 to No. N;
A switching circuit provided between the terminal unit and the control unit and switching a signal path between the terminal unit and the control unit;
The switching circuit is formed with a circuit pattern for mounting a plurality of jumper components. By changing the mounting state of each of the jumper components, the N terminals of the terminal unit and the control unit 1 A first path that connects input ports from number N to number N, or M (where M <N) terminals that are not adjacent to each other among the terminals of the terminal section The circuit board characterized in that the signal path is switched to any one of second paths connecting the first to Mth input ports of the control unit in the order of the numbers. N individual insulation circuits that individually electrically insulate signals input to the respective terminals of the terminal portion;
The switching circuit is disposed between the individual insulation circuit and the control unit, and changes the mounting state of the jumper component, and individual insulation in which no signal is input from among the N individual insulation circuits. The circuit board according to claim 1, wherein the signal path is switched to either the first path or the second path by changing the mounting state of the circuit. The jumper component forming the second path is provided between a 3 × i + 1th terminal (where i is an integer of 1 or more) of the terminal unit and an i + 1th input port of the control unit,
The jumper component forming the first path is provided between the 3 × i + 1th terminal (where i = 1) of the terminal unit and the 3i + 1th input port of the control unit. The circuit board according to claim 1, wherein the circuit board is characterized. When the second path is set, the terminal unit uses M terminals out of N terminals as signal input terminals, while the remaining terminals are used as power supply terminals.
The circuit board according to any one of claims 1 to 3, further comprising a power supply circuit for supplying power to a terminal used as the power supply terminal.

Images