JP2013095288A - Switch display input circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a switch display input circuit that can secure a fail-safe property against an open failure of a resistor of a threshold voltage setting circuit, and reducing power consumption when an inspection signal is off-controlled.SOLUTION: In a switch display input circuit 10A, a first resistor R1, a third resistor R3, and a fourth resistor R4 are serially connected between a positive input terminal 11 and a negative input terminal 12 applied with a voltage of a polarity responding to a shift state (a normal position shifting state/a reverse position shifting state) of a switch. A first circuit part 21 is parallel-connected to the fourth resistor R4, and serially-connected second resistor R2 and second circuit part 22 are parallel-connected to the serially connected third resistor R3 and fourth resistor R4.

Description

  The present invention relates to a switch display input circuit that outputs a signal corresponding to an input signal indicating a switching state of a switch.

  An electronic interlocking device that ensures the safety of train operation within a station premises, etc., receives an input signal indicating its operating state (opening / closing state of a relay contact of the field device) from a remote field device such as a switch or a traffic light. , Logic processing for ensuring safety is performed based on the operation state of the field device indicated by the input signal. In such an electronic interlocking device, even if a failure occurs, a fail-safe measure is taken so that the passenger does not fall into a dangerous state due to the failure. Input is required.

  For example, in the fail-safe input circuit disclosed in Patent Document 1, in order to make it less susceptible to noise, an input signal from a field device is taken in via a threshold voltage setting circuit that does not sense a threshold voltage or less, A function is provided for checking whether or not the threshold voltage setting circuit is operating normally.

  However, in the circuit disclosed in Patent Document 1, no current flows through the input contact except when the fail-safe inspection signal is pulse-on-controlled. Therefore, when the input contact is closed, the contact wetting effect that prevents the contact contact resistance from increasing by destroying the oxide film on the contact surface by continuously flowing current can be expected, and the possibility of contact failure is reduced. Thus, there was a problem from the viewpoint of improving reliability.

  Therefore, as in the contact input circuit (a type of the switch display input circuit) for inputting a signal indicating the switching state of the switch machine disclosed in Patent Document 2, an open failure of the resistor of the threshold voltage setting circuit There has been known a configuration in which the contact reliability of the contact is improved while ensuring the fail-safe property against the contact.

JP-A-8-080851 JP 2008-126801 A

  However, in the contact input circuit disclosed in Patent Document 2, the control current that flows when the inspection signal is turned on in a pulsed manner is substantially equal to the contact wetting current that flows when the inspection signal is turned off. . Normally, a large value is set for the control current. Since the control current and the contact wetting current are substantially equal, there is a problem that the power consumption and the heat generation amount are large when the inspection signal is controlled to be off.

  The present invention has been made in view of the above circumstances, and an object thereof is to ensure fail-safety against an open-circuit failure of a resistor of a threshold voltage setting circuit and when an inspection signal is controlled to be off. It is to realize a switch display input circuit capable of reducing the power consumption.

The first form for solving the above problem is
A switch display input that outputs an output signal according to the input signal indicating the switching state of the switch depending on the polarity input between the positive input terminal and the negative input terminal when the inspection signal is input A circuit,
A first resistor, a third resistor and a fourth resistor connected in series between the positive input terminal and the negative input terminal;
A first circuit unit that is connected in parallel to the fourth resistor and bypasses the flow of the fourth resistor when the inspection signal is input;
A second circuit unit configured to add a second resistor in parallel to the third resistor and the fourth resistor connected in series according to the presence or absence of a bypass current by the first circuit unit;
With
A switch display input circuit that outputs the output signal according to the presence / absence of a current through the second resistor and the polarity of the current.

  According to the first embodiment, in the switch display input circuit, when the inspection signal is not input, the first resistor, the third resistor, and the second resistor connected in series between the positive input terminal and the negative input terminal. A current having a direction corresponding to the polarity of the input signal flows through the path through the four resistors. On the other hand, when the inspection signal is input, the flow of the fourth resistor is bypassed, and the second resistor is inserted in parallel with the third resistor and the fourth resistor connected in series. . As a result, when a test signal is input, a current having a direction corresponding to the polarity of the input signal flows through the second resistor. An output signal corresponding to the presence / absence of current through the second resistor and the polarity of the current, that is, an output signal corresponding to the polarity of the input signal is output.

  With the above circuit operation, a current always flows between the positive input terminal and the negative input terminal regardless of whether or not the inspection signal is input, and contact wetting is performed to maintain contact reliability. At this time, for example, by sufficiently increasing the resistance value of the fourth resistor, the current (wetting current) when no inspection signal is input can be reduced, and the power consumption can be reduced. it can. Further, for example, when the third resistor has an open failure, no current flows between the input terminals. That is, since the output signal is the same as when no input signal is input, fail-safe is realized.

As an example of a more specific circuit configuration, as a second form, the switch display input circuit of the first form, the inspection signal includes a localization inspection signal and an inversion inspection signal,
The first circuit unit includes:
A second photodiode of the second photocoupler and a third phototransistor of the third photocoupler that is turned on / off by the localization inspection signal are forward with respect to the polarities of the positive input terminal and the negative input terminal. A fifth circuit unit having a first diode connected in antiparallel to the second photodiode and the third phototransistor connected in series;
The fourth phototransistor of the fourth photocoupler that is turned on / off by the inversion inspection signal and the fifth photodiode of the fifth photocoupler are in reverse directions with respect to the polarities of the positive input terminal and the negative input terminal. A sixth circuit unit having a second diode connected in anti-parallel to the fourth phototransistor and the fifth photodiode connected in series;
In series,
The second circuit unit includes:
A first photodiode of a first photocoupler and a second phototransistor of the second photocoupler are connected in series in a forward direction with respect to the polarities of the positive input terminal and the negative input terminal, and the input A third circuit portion for injecting the second resistor in parallel when the signal has a polarity indicating a localization state;
A fifth phototransistor of the fifth photocoupler and a sixth photodiode of a sixth photocoupler connected in series in opposite directions with respect to the polarities of the positive input terminal and the negative input terminal; A fourth circuit unit for injecting the second resistor in parallel when the signal has a polarity indicating an inverted state;
In parallel,
When the first phototransistor of the first photocoupler is turned on / off, an output signal indicating a localization state is output, and when the sixth phototransistor of the sixth photocoupler is turned on / off, the output signal is output. Output an output signal indicating that
A switch display input circuit may be configured.

Further, as another specific circuit configuration example, as a third form, the switch display input circuit of the first form,
The first circuit unit directly connects the second bidirectional diode of the second photocoupler, the bidirectional MOSFET of the photoMOS relay that is turned on / off by the inspection signal, and the fourth bidirectional diode of the fourth photocoupler. Have connected,
The second circuit unit includes:
A first photodiode of a first photocoupler and a second phototransistor of the second photocoupler are connected in series in a forward direction with respect to the polarities of the positive input terminal and the negative input terminal, and the input A third circuit portion for injecting the second resistor in parallel when the signal has a polarity indicating a localization state;
A fourth phototransistor of the fourth photocoupler and a sixth phototransistor of the sixth photocoupler connected in series in opposite directions with respect to the polarities of the positive input terminal and the negative input terminal; A fourth circuit unit for injecting the second resistor in parallel when the signal has a polarity indicating an inverted state;
In parallel,
When the first phototransistor of the first photocoupler is turned on / off, an output signal indicating a localization state is output, and when the sixth phototransistor of the sixth photocoupler is turned on / off, the output signal is output. Output an output signal indicating that
A switch display input circuit may be configured.

Further, as a fourth form, the switch display input circuit of the second or third form,
Each of the first to sixth photocouplers may be configured as a switch display input circuit configured by replacing an optical semiconductor element such as a photo MOS relay.

Further, as a fifth form, the switch display input circuit according to any one of the first to fourth forms,
The second resistor and the third resistor have substantially the same resistance value.
A switch display input circuit may be configured.

According to the fifth embodiment, since the second resistor and the third resistor have substantially the same resistance value, when the inspection signal is input, the current flowing through the first resistor is The current is divided equally between the third resistor and the second resistor.
As a result, the operations of the first circuit unit and the second circuit unit can be stabilized.

The block diagram which shows the connection state of the switch display input circuit in 1st Embodiment. The circuit diagram of a switch display input circuit. Operation | movement explanatory drawing of a switch display input circuit. Operation | movement explanatory drawing of a switch display input circuit. Operation | movement explanatory drawing of a switch display input circuit. Operation | movement explanatory drawing of a switch display input circuit. The circuit diagram of the switch display input circuit in 2nd Embodiment. Operation | movement explanatory drawing of a switch display input circuit. Operation | movement explanatory drawing of a switch display input circuit.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the applicable embodiment of the present invention is not limited to this.

[First Embodiment]
First, the first embodiment will be described.

<Connection configuration>
FIG. 1 is a block diagram illustrating a connection state of the switch display input circuit 10A according to the first embodiment. According to FIG. 1, the switch display input circuit 10 </ b> A includes a positive input terminal 11, a negative input terminal 12, a localization output terminal 13, an inversion output terminal 14, a localization inspection signal input terminal 15, and an inversion. And an inspection signal input terminal 16.

  The positive input terminal 11 and the negative input terminal 12 are connected to a switch display contact configured by a relay contact included in the switch machine 20 via an input line, and correspond to the switching state of the switch machine 20. A polarity voltage is applied. Specifically, the forward voltage (positive polarity) greater than the specified voltage is applied in the localization transition state, and the reverse voltage (negative polarity) greater than the specified voltage is applied in the inversion state. Is done.

  The localization output terminal 13 and the inversion output terminal 14 are connected to the electronic interlocking device 30, output a localization output signal from the localization output terminal 13, and output an inversion output signal from the inversion output terminal 14.

  The localization inspection signal input terminal 15 and the inversion inspection signal input terminal 16 are connected to the electronic interlocking device 30, and the localization inspection signal input terminal 15 receives a localization inspection signal and the inversion inspection signal input terminal 16 An inversion inspection signal is input.

  The switch display input circuit 10A outputs a localization output signal from the localization output terminal 13 indicating whether or not the switch 20 is in the localization switching state when the localization inspection signal is input (ON). When the inversion inspection signal is input (turned on), an inversion output signal indicating whether or not the switch 20 is in the inversion change state is output from the inversion output terminal 14.

<Circuit configuration>
FIG. 2 is a circuit diagram of the switch display input circuit 10A in the first embodiment. According to FIG. 2, the switch display input circuit 10A includes a first resistor R1, a second resistor R2, a third resistor R3, a fourth resistor R4, a first circuit unit 21, And a second circuit unit 22. Specifically, a first resistor R1, a third resistor R3, and a fourth resistor R4 are connected in series between the positive input terminal 11 and the negative input terminal 12, and the fourth resistor R4 is connected to the fourth resistor R4. Thus, the first circuit unit 21 is connected in parallel, and the second resistor R2 and the second circuit unit 22 connected in series are connected in parallel to the third resistor R3 and the fourth resistor R4 connected in series. ing.

  The first circuit unit 21 is configured by connecting a fifth circuit unit 25 and a sixth circuit unit 26 in series. The fifth circuit unit 25 is configured such that the second photodiode Pd2 of the second photocoupler P2 and the third phototransistor Pt3 of the third photocoupler P3 are forward with respect to the polarity between the positive input terminal 11 and the negative input terminal 12. Are connected in series, and a first diode D1 for reverse voltage protection is connected in antiparallel to the second photodiode Pd2 and the third phototransistor Pt3 connected in series.

  In the sixth circuit unit 26, the fourth phototransistor Pt4 of the fourth photocoupler P4 and the fifth photodiode Pd5 of the fifth photocoupler P5 are in opposite directions with respect to the polarity between the positive input terminal 11 and the negative input terminal 12. Are connected in series, and a second diode D2 for reverse voltage protection is connected in antiparallel to the fourth phototransistor Pt4 and the fifth photodiode Pd5 connected in series.

  The second circuit unit 22 is configured by connecting a third circuit unit 23 and a fourth circuit unit 24 in parallel. The third circuit unit 23 is configured so that the first photodiode Pd1 of the first photocoupler P1 and the second phototransistor Pt2 of the second photocoupler P2 are forward with respect to the polarity between the positive input terminal 11 and the negative input terminal 12. Are connected in series. In the fourth circuit unit 24, the fifth phototransistor Pt5 of the fifth photocoupler P5 and the sixth photodiode Pd6 of the sixth photocoupler P6 are in opposite directions with respect to the polarity between the positive input terminal 11 and the negative input terminal 12. Are connected in series.

  In the localization output circuit unit 31, the collector of the first phototransistor Pt1 of the first photocoupler P1 is connected to the power supply (pull-up voltage) via the localization output terminal 13 and the fifth resistor R5, and the emitter is grounded. Has been configured. The inversion output circuit unit 32 is configured such that the collector of the sixth phototransistor Pt6 of the sixth photocoupler P6 is connected to the power supply (pull-up voltage) via the inversion output terminal 14 and the eighth resistor R8. Is grounded.

  In the localization input circuit unit 33, the anode of the third photodiode Pd3 of the third photocoupler P3 is connected to the power supply (pull-up voltage) via the sixth resistor R6, and the cathode is connected to the localization inspection signal input terminal 15. Configured. In the inversion input circuit 34, the anode of the fourth photodiode Pd4 of the fourth photocoupler P4 is connected to the power supply (pull-up voltage) via the seventh resistor R7, and the cathode is connected to the inversion inspection signal input terminal 16. Connected and configured.

  In the switch display input circuit 10A configured as described above, the first resistor R1 and the third resistor R3 form a threshold voltage setting circuit when an inspection signal is input (turned on). . That is, as will be described later, when a localization inspection signal or an inversion inspection signal is input, the first circuit unit 21 is activated to bypass the flow of the fourth resistor R4. Further, the second resistor R2 is configured by a resistor having substantially the same resistance value as that of the third resistor R3. As a result, since the input signal input between the positive input terminal 11 and the negative input terminal 12 generally acts to divide the voltage between the first resistor R1 and the third resistor R3, the first resistor R1 and The third resistor R3 functions as a threshold voltage setting circuit.

  Further, the first resistor R1 and the third resistor R3 divide the noise voltage generated between the positive input terminal 11 and the negative input terminal 12 by noise induced in the input line, and the noise voltage is obtained. The malfunction of the 3rd circuit part 23 or the 4th circuit part 24 which originates is prevented.

  In addition, the resistance values of the second resistor R2 and the third resistor R3 are substantially the same (“substantially the same” is because a resistor having the same resistance value is physically difficult to create). is there). As a result, the current flowing through the first resistor R1 is almost equally divided into the third resistor R3 and the second resistor R2.

<Operation>
Next, the operation of the switch display input circuit 10A will be described.

(A) When the turning machine 20 is in the position change state When the turning machine is turned and the display output contact is formed on the position side, the gap between the positive input terminal 11 and the negative input terminal 12 is established. A forward voltage is applied to.

(A-1) Localization inspection signal is off (high level)
In this state, as shown in FIG. 3, when the localization inspection signal is off (high level), no current flows through the third photodiode Pd3, and the third phototransistor Pt3 is turned off. For this reason, no current flows through the second photodiode Pd2, and the second phototransistor Pt2 is turned off. Then, no current flows through the first photodiode Pd1, and the first phototransistor Pt1 is turned off. As a result, the localization output signal output from the localization output terminal 13 becomes “high level”. At this time, a current corresponding to the applied voltage between the positive input terminal 11 and the negative input terminal 12 flows through the path of the first resistor R1, the third resistor R3, and the fourth resistor R4, and the reliability of the contact point In order to maintain the contact, wetting is performed.

(A-2) Localization inspection signal is on (low level)
As shown in FIG. 4, when the localization inspection signal is on (low level), a current flows through the third photodiode Pd3, and the third phototransistor Pt3 is turned on. For this reason, the flow of the fourth resistor R4 is bypassed, and the current flows in the path of the first resistor R1, the third resistor R3, the second photodiode Pd2, the third phototransistor Pt3, and the second diode D2. Flows, and the second phototransistor Pt2 is turned on. When the second phototransistor Pt2 is turned on, the second resistor R2 is connected in parallel to the third resistor R3. Then, a current flows through the path of the first resistor R1, the second resistor R2, the first photodiode Pd1, and the second phototransistor Pt2, and the first phototransistor Pt1 is turned on. As a result, the localization output signal output from the localization output terminal 13 becomes “low level”.

(A-3)
On the other hand, when the forward voltage is not applied or when the third resistor R3 has an open failure, the second phototransistor Pt2 is turned off because no current flows through the second photodiode Pd2. For this reason, regardless of the on / off control of the localization inspection signal, no current flows through the first photodiode Pd1, the first phototransistor Pt1 is turned off, and the localization output signal becomes “high level”.

(B) The switch 20 is in an inverted position When the switch is turned in an inverted position and the display output contact is configured on the inverted side, the positive input terminal 11 and the negative input terminal 12 A reverse voltage is applied between them.

(B-1) When the inversion inspection signal is off (high level) In this state, as shown in FIG. 5, when the inversion inspection signal is off (high level), a current flows through the fourth photodiode Pd4. Does not flow, and the fourth phototransistor Pt4 is turned off. For this reason, no current flows through the fifth photodiode Pd5, and the fifth phototransistor Pt5 is turned off. Then, no current flows through the sixth photodiode Pd6, and the sixth phototransistor Pt6 is turned off. As a result, the inverted output signal output from the inverted output terminal 14 becomes “high level”. At this time, a current corresponding to the applied voltage between the positive input terminal 11 and the negative input terminal 12 flows through the path of the fourth resistor R4, the third resistor R3, and the first resistor R1, and the reliability of the contacts In order to maintain the contact, wetting is performed.

(B-2) Inversion inspection signal is on (low level)
As shown in FIG. 6, when the inversion inspection signal is on (low level), a current flows through the fourth photodiode Pd4, and the fourth phototransistor Pt4 is turned on. For this reason, the flow of the fourth resistor R4 is bypassed, and the current flows in the path of the fifth photodiode Pd5, the fourth phototransistor Pt4, the first diode D1, the third resistor R3, and the first resistor R1. Flows, and the fifth phototransistor Pt5 is turned on. When the fifth phototransistor Pt5 is turned on, the second resistor R2 is connected in parallel to the third resistor R3. Then, a current flows through the path of the sixth photodiode Pd6, the fifth phototransistor Pt5, the second resistor R2, and the first resistor R1, and the sixth phototransistor Pt6 is turned on. As a result, the inverted output signal output from the inverted output terminal 14 becomes “low level”.

(B-3)
On the other hand, when no reverse voltage is applied or when the third resistor R3 has an open failure, the fifth phototransistor Pt5 is turned off because no current flows through the fifth photodiode Pd5. Therefore, regardless of the on / off control of the inversion inspection signal, no current flows through the sixth photodiode Pd6, the sixth phototransistor Pt6 is turned off, and the inversion output signal becomes “high level”.

<Action and effect>
Thus, according to the switch display input circuit 10A, when the localization inspection signal is controlled to be turned on / off, if the localization output signal changes to low level / high level correspondingly, the third resistor It can be determined that there is no open failure of R3 and that the display information indicating that the switch 20 is in the converted state is correctly transmitted. Even if the localization inspection signal is controlled to be turned on / off, if the localization output signal is fixed at a high level, it can be determined that there is a possibility that the third resistor R3 has an open failure.

  On the other hand, similarly, when the inversion inspection signal is controlled to be on / off, if the inversion output signal changes to low level / high level in response to the on / off control of the inversion inspection signal, the third resistor R3 It can be determined that there is no open failure and that the tip display information indicating that the tipper 20 is in the inverted change state is correctly transmitted. Even if the inversion inspection signal is controlled to be on / off, if the inversion output signal is fixed at a high level, it can be determined that there is a possibility that the third resistor R3 has an open failure.

  Further, in either case of the localization switching state / inversion switching state, when the relay contact of the switch 20 is configured, the positive input is performed regardless of the on / off control of the localization inspection signal / inversion inspection signal. A current always flows between the terminal 11 and the negative input terminal 12 to perform contact wetting.

  At this time, the magnitude of the current (wetting current) flowing between the positive input terminal 11 and the negative input terminal 12 when the localization inspection signal / inversion inspection signal is off-controlled is the resistance value of the fourth resistor R4. It depends on. Therefore, by increasing the resistance value of the fourth resistor R4, it is possible to reduce the current (wetting current) that flows when the localization inspection signal / inversion inspection signal is turned off and to reduce power consumption.

[Second Embodiment]
Next, a second embodiment will be described. In the second embodiment, in the switch display input circuit 10A of the first embodiment described above, the localization inspection signal input terminal 15 and the inversion inspection signal input terminal 16 are shared, and the localization inspection signal and the inversion inspection signal are set to 1. This is an embodiment realized as two inspection signals. In the following description, the same elements as those in the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted or simplified.

<Configuration>
FIG. 7 is a circuit diagram of the switch display input circuit 10B in the second embodiment. According to FIG. 7, the switch display input circuit 10B has a positive input terminal 11, a negative input terminal 12, a localization output terminal 13, an inversion output terminal 14, and a common inspection signal input terminal 17. ing.

  The common inspection signal input terminal 17 is connected to the electronic interlocking device 30 and receives a common inspection signal. When the inspection signal is input (turned on), the switch display input circuit 10B outputs a localization output signal indicating whether or not the switch 20 is in the localization switching state from the localization output terminal 13. At the same time, an inverted output signal indicating whether or not the switch 20 is in the inverted change state is output from the inverted output terminal 14.

  The switch display input circuit 10B includes a first resistor R1, a second resistor R2, a third resistor R3, a fourth resistor R4, a first circuit unit 41, and a second circuit unit 42. The localization output circuit unit 31, the inversion output circuit unit 32, and the common input circuit unit 35 are configured. Specifically, a first resistor R1, a third resistor R3, and a fourth resistor R4 are connected in series between the positive input terminal 11 and the negative input terminal 12, and the fourth resistor R4 is connected to the fourth resistor R4. The first circuit unit 41 is connected in parallel, and the second resistor R2 and the second circuit unit 42 connected in series are connected in parallel to the third resistor R3 and the fourth resistor R4 connected in series. Yes.

  The first circuit unit 41 includes a seventh bidirectional diode Pd7 of the seventh photocoupler P7, a bidirectional MOSFET Pt8 of the photoMOS relay P8, and a ninth bidirectional diode Pd9 of the ninth photocoupler P9 connected in series. Has been.

  The second circuit unit 42 is configured by connecting a third circuit unit 43 and a fourth circuit unit 44 in parallel. The third circuit unit 43 is configured by connecting the first photodiode Pd1 and the seventh phototransistor Pt7 of the seventh photocoupler P7 in series in the forward direction with respect to the polarities of the positive input terminal 11 and the negative input terminal 12. ing. The fourth circuit unit 44 is configured by connecting the ninth phototransistor Pt9 and the sixth photodiode Pd6 of the ninth photocoupler P9 in series in opposite directions with respect to the polarities of the positive input terminal 11 and the negative input terminal 12. ing.

  The common input circuit unit 35 is configured such that the anode of the photodiode Pd8 of the photoMOS relay P8 is connected to the power supply (pull-up voltage) via the sixth resistor R6, and the cathode is connected to the common inspection signal input terminal 17. ing.

<Operation>
Next, the operation of the switch display input circuit 10B will be described.

(A) When the turning machine 20 is in the position change state When the turning machine 20 is turned and the turning display output contact is configured on the localization side, the positive input terminal 11 and the negative input terminal 12 A forward voltage is applied between them.

(A-1) Common inspection signal is off (high level)
In this state, as shown in FIG. 8, when the common inspection signal is off (high level), no current flows through the eighth photodiode Pd8, and the bidirectional MOSFET Pt8 is turned off. Therefore, no current flows through the seventh bidirectional diode Pd7 and the ninth bidirectional diode Pd9, and both the seventh phototransistor Pt7 and the ninth phototransistor Pt9 are turned off. Then, no current flows through the first photodiode Pd1 and the sixth photodiode Pd6, and both the first phototransistor Pt1 and the sixth phototransistor Pt6 are turned off. As a result, the localization output signal output from the localization output terminal 13 and the inversion output signal output from the inversion output terminal 14 are both “high level”.

(A-2) Inspection signal is on (low level)
As shown in FIG. 9, when the common inspection signal is on (low level), a current flows through the eighth photodiode Pd8, and the bidirectional MOSFET Pt8 is turned on. For this reason, the flow of the fourth resistor R4 is bypassed, and the current flows in the path of the first resistor R1, the third resistor, the seventh bidirectional diode Pd7, the bidirectional MOSFET PTt8, and the ninth bidirectional diode Pd9. Flows. At this time, a current flows in the forward direction through the seventh bidirectional diode Pd7 and the ninth bidirectional diode Pd9. Since the current flows through the seventh bidirectional diode Pd7 and the ninth bidirectional diode Pd9, both the seventh phototransistor Pt7 and the ninth phototransistor Pt9 are turned on, and the second resistor R2 is connected in parallel. Since it is a current, no current flows through the ninth phototransistor Pt9, and a current flows only through the seventh phototransistor Pt7. For this reason, the localization output signal becomes “low level” and the inversion output signal becomes “high level”.

(B) When the switch 20 is in the inverted position When the switch 20 is inverted and the display output contact is configured on the inverted side, the positive input terminal 11 is negative. A reverse voltage is applied to the input terminal 12.

(B-1) Common inspection signal is off (high level)
Although not shown, when the common inspection signal is off (high level) in this state, the bidirectional MOSFET Pt8 is turned off in substantially the same manner as in the case of the localization switching state (see FIG. 8). Both the localization output signal output from the terminal 13 and the inversion output signal output from the inversion output terminal 14 are “high level”. The difference from the case of the localization switching state is that current flows between the positive input terminal 11 and the negative input terminal 12 through the path of the fourth resistor R4, the third resistor R3, and the first resistor R1. is there.

(B-2) Common inspection signal is on (low level)
On the other hand, when the common inspection signal is on (low level), the bidirectional MOSFET Pt8 is turned on, and the ninth bidirectional diode Pd9, the bidirectional MOSFET Pt8, Current flows in the order of the seventh bidirectional diode Pd7, the third resistor R3, and the first resistor R1. That is, since a reverse current flows through the seventh bidirectional diode Pd7 and the ninth bidirectional diode Pd9, no current flows through the seventh phototransistor Pt7, and current flows only through the ninth phototransistor Pt9. It will be. As a result, the localization output signal becomes “high level” and the inversion output signal becomes “low level”.

<Action and effect>
As described above, according to the switch display input circuit 10B, when the common inspection signal is controlled to be turned on / off, one of the localization output signal and the inverted output signal changes to low level / high level correspondingly. If it does so, it can be judged that there is no open failure of the third resistor R3, and that the switch display information indicating that the switch 20 is in the inverted change state is correctly transmitted. Further, even if the common inspection signal is turned on / off, if both the localization output signal and the inverted output signal are fixed at a high level, there is a possibility that the third resistor R3 has an open failure. Judgment can be made.

  Further, when the relay contact of the switch 20 is configured, a current always flows between the positive input terminal 11 and the negative input terminal 12 regardless of the on / off control of the common inspection signal, and contact wetting is performed. Made. Further, since the magnitude of the current (wetting current) flowing at this time is determined by the resistance value of the fourth resistor R4, by increasing the resistance value of the fourth resistor R4, the common inspection signal flows during the off control. The current (wetting current) can be reduced and power consumption can be reduced.

[Modification]
Note that embodiments to which the present invention can be applied are not limited to the two embodiments described above, and it is needless to say that the embodiments can be appropriately changed without departing from the spirit of the present invention.

(1)
For example, the localization output circuit 31 configured by the first phototransistor Pt1 or the inversion output circuit 32 configured by the sixth phototransistor Pt6 is a collector load type, but may be an emitter load type.

(2)
Further, instead of any one or more of the first photocoupler P1 to the sixth photocoupler P6, other types of optical semiconductor elements such as a photo moss relay may be used.

(3)
Further, the input signal is not limited to the switch display input from the switch 20 and may be any signal as long as it represents a different value depending on the polarity.

10A, 10B switch display input circuit 11 positive input terminal, 12 negative input terminal, 13 localization output terminal, 14 inversion output terminal 15 localization inspection signal input terminal, 16 inversion inspection signal input terminal,
17 Inspection signal input terminal R1 to R8 Resistor P1 to P7, P9 Photocoupler, P8 PhotoMOS relay Pd1 to Pd6, Pd8 Photodiode, Pd7, Pd9 Bidirectional diode Pt1 to Pt7, Pt9 Phototransistor, Pt8 Bidirectional MOSFET
D1, D2 Diode 20 Switching machine 30 Electronic interlocking device

Claims (5)

A switch display input that outputs an output signal according to the input signal indicating the switching state of the switch depending on the polarity input between the positive input terminal and the negative input terminal when the inspection signal is input A circuit,
A first resistor, a third resistor and a fourth resistor connected in series between the positive input terminal and the negative input terminal;
A first circuit unit that is connected in parallel to the fourth resistor and bypasses the flow of the fourth resistor when the inspection signal is input;
A second circuit unit configured to add a second resistor in parallel to the third resistor and the fourth resistor connected in series according to the presence or absence of a bypass current by the first circuit unit;
With
A flip-flop display input circuit that outputs the output signal in accordance with the presence / absence of current through the second resistor and the polarity of the current. The inspection signal includes a localization inspection signal and an inversion inspection signal,
The first circuit unit includes:
A second photodiode of the second photocoupler and a third phototransistor of the third photocoupler that is turned on / off by the localization inspection signal are forward with respect to the polarities of the positive input terminal and the negative input terminal. A fifth circuit unit having a first diode connected in antiparallel to the second photodiode and the third phototransistor connected in series;
The fourth phototransistor of the fourth photocoupler that is turned on / off by the inversion inspection signal and the fifth photodiode of the fifth photocoupler are in reverse directions with respect to the polarities of the positive input terminal and the negative input terminal. A sixth circuit unit having a second diode connected in anti-parallel to the fourth phototransistor and the fifth photodiode connected in series,
In series,
The second circuit unit includes:
A first photodiode of a first photocoupler and a second phototransistor of the second photocoupler are connected in series in a forward direction with respect to the polarities of the positive input terminal and the negative input terminal, and the input A third circuit portion for injecting the second resistor in parallel when the signal has a polarity indicating a localization state;
A fifth phototransistor of the fifth photocoupler and a sixth photodiode of a sixth photocoupler connected in series in opposite directions with respect to the polarities of the positive input terminal and the negative input terminal; A fourth circuit unit for injecting the second resistor in parallel when the signal has a polarity indicating an inverted state;
In parallel,
When the first phototransistor of the first photocoupler is turned on / off, an output signal indicating a localization state is output, and when the sixth phototransistor of the sixth photocoupler is turned on / off, the output signal is output. Output an output signal indicating that
The switch display input circuit according to claim 1. The first circuit unit directly connects the second bidirectional diode of the second photocoupler, the bidirectional MOSFET of the photoMOS relay that is turned on / off by the inspection signal, and the fourth bidirectional diode of the fourth photocoupler. Have connected,
The second circuit unit includes:
A first photodiode of a first photocoupler and a second phototransistor of the second photocoupler are connected in series in a forward direction with respect to the polarities of the positive input terminal and the negative input terminal, and the input A third circuit portion for injecting the second resistor in parallel when the signal has a polarity indicating a localization state;
A fourth phototransistor of the fourth photocoupler and a sixth phototransistor of the sixth photocoupler connected in series in opposite directions with respect to the polarities of the positive input terminal and the negative input terminal; A fourth circuit portion for injecting the two resistors in parallel when the signal has a polarity indicating an inverted state;
In parallel,
When the first phototransistor of the first photocoupler is turned on / off, an output signal indicating a localization state is output, and when the sixth phototransistor of the sixth photocoupler is turned on / off, the output signal is output. Output an output signal indicating that
The switch display input circuit according to claim 1.   4. The switch display input circuit according to claim 2, wherein each of the first to sixth photocouplers is configured by replacing an optical semiconductor element such as a photo moss relay. 5. The second resistor and the third resistor have substantially the same resistance value.
The switch display input circuit according to any one of claims 1 to 4.

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