JPH0880851A - Fail-safe input circuit - Google Patents

Abstract

PURPOSE: To exclude the false information of a remote device by connecting and cutting off the electric current which flows in the photodiode of the second photocoupler connected with the emitter of the first photocoupler, by using the first photocoupler. CONSTITUTION: The first resistor R1 is connected at one end of an input terminal 11, and the second resistor R2 is connected with the other end of the first resistor R1, and the third resistor R3 is connected with the connection point between the first and the second resistors R1 and R2. With the other end of the second resistor R2, the collector of the first photoocoupler P1 is connected, and a cathode is connected with an ON/OFF input terminal 13, and an anode is connected with an electric power source. With the ON/Off input terminal 13, a fail-safe inspection signal is applied, and the electric current which flows in the photodiode of the second photocoupler P2 connected with the emitter of the first photocoupler P1 is connected and cut off by using the first photocoupler P1. Accordingly, the false information of the remote device can be excluded.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fail-safe input circuit for inputting information of a remote device. More specifically, a fail-safe input for inputting information (a relay ON / OFF current signal) of a remote relay contact device, such as a railway, directly to an electronic interlocking device in an equipment room without using an interface relay. Circuit.

[0002]

2. Description of the Related Art An electronic interlocking device for ensuring the safety of train operation in a station premises is provided with fail-safe measures so that even if a failure occurs, passengers do not enter a dangerous situation due to the failure. However, it is premised that accurate operation information from a field device (for example, a remote relay contact device) is input to the electronic interlocking device as a condition for the fail-safe measure to have a sufficient effect.

In this type of conventional remote relay contact device, information on the relay contact (ON / OFF current signal of the relay) is transmitted to the electronic interlocking device via the interface relay, whether or not there is a current in the input line.

In order to reduce the size of the electronic interlocking device, there is an electronic interlocking device using an input circuit for the electronic interlocking device as shown in FIG. 3 instead of the interface relay. In the input circuit of FIG. 3, ON / OFF is applied to the ON / OFF input terminal 3.
When information of a relay contact (ON / OFF current signal of the relay) is input between the (+) input terminal 1 and the (-) input terminal 2 in a state where the control signal is applied and the photocoupler P1 is turned on, the photo The coupler P2 becomes operable, and information on the relay contact is output to the output terminal 4. The output signal was transmitted to the electronic interlocking device via the output terminal 4.

[0005]

However, the conventional fail-safe input circuit has a problem that it is difficult to reduce the size of the electronic interlocking device due to the presence of the interface relay.

Further, in the conventional fail-safe input circuit shown in FIG. 3, when the third resistor R3 that defines the operating voltage of the input circuit is opened and a failure occurs, the (+) input terminal of the input circuit is generated. The input impedance between 1 and the (-) input terminal 2 becomes very high, and it is easily affected by the high frequency noise induced in the input line connected between the (+) input terminal 1 and the (-) input terminal 2. There was a problem.

The present invention has been made in view of the above conventional problems. Even if a failure occurs in the third resistor R3, accurate operation information from a field device (remote relay contact device) is obtained. It is an object of the present invention to provide a small-sized fail-safe input circuit having a reliable fail-safe property, which can input a signal to an electronic interlocking device.

[0008]

The gist of the present invention is to provide a fail-safe input circuit (10) for inputting information on a remote device. (+) Input terminal (11)
And (-) an input terminal (12), an ON / OFF input terminal (13) for inputting a fail-safe check signal (20a), and an output terminal (14) for outputting information of the remote device. , One end of which is the (+) input terminal (11)
And a first resistor R1 connected to the first resistor R1.
, A third resistor R3 having one end connected to a connection point between the first resistor R1 and the second resistor R2, and a collector connected to the other end of the second resistor R2. , A cathode is connected to the ON / OFF input terminal (13), an anode is connected to a power supply, a collector is connected to the other end of the third resistor R3, and a cathode is (-) A second photocoupler P2 connected to the input terminal (12) and having an anode connected to the emitter of the first photocoupler P1; a cathode connected to the collector of the first photocoupler P1; The first photocoupler P1 and the second photocoupler P2 are connected to a cathode of a second photocoupler P2.
A first diode D1 for bypassing the reverse current to the collector, the collector is connected to the output terminal (14), the emitter is grounded, the cathode is connected to the (-) input terminal (12), and the anode is the Third photocoupler P3 connected to the emitter of second photocoupler P2
And a cathode connected to the collector of the second photocoupler P2, an anode connected to the (-) input terminal (12), and bypassing a reverse current to the second photocoupler P2 and the third photocoupler P3. And a second diode D2 for causing the fail-safe input circuit (10).

[0009]

The function of the fail safe input circuit (1
0) applies the fail-safe check signal (20a) to the ON / OFF input terminal (13) and causes a current to flow in the photodiode of the second photocoupler P2 connected to the emitter of the first photocoupler P1. Is connected or disconnected by using the first photocoupler P1 to perform fail-safe diagnosis for eliminating false information of the remote device, the main part of which is composed of electronic circuit parts.

Thus, accurate operation information from on-site equipment (remote relay contact device (24)) is transmitted to the electronic interlocking device (2).
It is possible to realize a small fail-safe input circuit (10) having a reliable fail-safe property that can be input to 0).

The operation of the fail-safe input circuit (10) inspection method of the present invention will be described in more detail.

When the information of the remote device is generated, the fail safe check signal (2) from the electronic interlocking device (20) is sent.
0a) controls the first photo coupler P1 to be ON, whereby the second photo coupler P2 is turned ON,
The information of the remote device is transmitted to the third photocoupler P3.

Since the emitter of the second photo coupler P2 is connected to the anode of the photodiode of the third photo coupler P3, the third photo coupler P3 is turned on by the input current of the second photo coupler P2.

Since the collector of the third photocoupler P3 is connected to the power source through the load resistance, the input current transmitted to the third photocoupler P3 (that is, information on the remote device).
Is output as a voltage to the output terminal (14) by the load resistance. The output terminal (14) is connected to an electronic interlocking device (20)
, The transmission of the information of the remote device to the electronic interlocking device (20) can be turned ON, and the information of the remote device can be transmitted to the electronic interlocking device (20).

Further, a fail safe check signal (20
By controlling a) to be turned off, the first photocoupler P1 is turned off and the second photocoupler P2 is turned off.
In the FF state, the information of the remote device is not transmitted to the output of the third photocoupler P3.

Since no input current flows through the anode of the photodiode of the third photocoupler P3, the output of the third photocoupler P3 is turned off.

Since the third photocoupler P3 is in the OFF state, transmission of information of the remote device to the electronic interlocking device (20) can be turned off.

Further, in the fail-safe input circuit (10) inspecting method according to the present invention, when the fail-safe inspecting signal (20a) is ON-controlled, the output of the third photocoupler P3 is turned ON, fail-safe inspecting. When the signal (20a) is turned off, the third photo coupler P
When the output of the third photocoupler 3 performs an OFF operation (that is, the ON / OFF control of the fail-safe inspection signal (20a) and the ON / OFF operation of the output of the third photocoupler P3 match one-on-one), the electronic interlocking device ( 20) determines that the information of the true remote device has been transmitted to the electronic interlocking device (20) (the input condition to the electronic interlocking device (20) is satisfied, that is, there is an input).

Fail fail check signal (20a)
When the N control is performed, the output of the third photocoupler P3 is turned off. When the fail-safe inspection signal (20a) is controlled to be turned off, the output of the third photocoupler P3 is turned off (that is, when the fail-safe inspection signal (20a) is turned off). ON, O
Output of third photocoupler P3 is OF regardless of FF control
When the electronic interlocking device (20) performs the F operation, the information of the fake remote device is transmitted to the electronic interlocking device (20) (the input condition to the electronic interlocking device (20) is not satisfied, that is, there is no input). Is determined.

Further, when a failure occurs due to the open state of the third resistor R3 in FIG. 1, the input current to the anode of the third photocoupler P3 is cut off, so that the third photocoupler P3
Output is fixed to OFF operation (that is, the output of the third photocoupler P3 is OFF operation regardless of ON / OFF control of the fail-safe inspection signal (20a)), so that false remote device information is electronically interlocked. It is determined that the information is transmitted to the device (20) (the input condition to the electronic interlocking device (20) is not satisfied, that is, no input is made).

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram of a fail-safe input circuit according to one embodiment of the present invention, and FIG. 2 is a block diagram showing connections of the fail-safe input circuit according to one embodiment of the present invention.

As shown in FIG.
The safe input circuit 10 has a (+) input terminal 11 and a (-) input terminal 12 for inputting information of a remote relay contact device 24 (remote device) so as to input information of a remote device.
ON / OFF for inputting a fail-safe inspection signal 20a, which is connected to the remote relay contact device 24 via
It is connected to an electronic interlocking device 20 via an OFF input terminal 13 and an output terminal 14 for outputting information of a remote device.

As shown in FIG.
The safe input circuit 10 has a (+) input terminal 11 and a (-) input terminal 12 for inputting information of a remote device, and an ON / O for inputting a fail-safe check signal 20a.
An FF input terminal 13, an output terminal 14 for outputting information from a remote device, a first resistor R1 having one end connected to the (+) input terminal 11, and one end connected to the other end of the first resistor R1. Second resistor R2, one end of which is first resistor R1 and second resistor R
A third resistor R3 connected to the connection point of the second resistor R2, a collector connected to the other end of the second resistor R2, and a cathode connected to ON / OF.
The first photocoupler P1 connected to the F input terminal 13 and the anode connected to the power supply, the collector connected to the other end of the third resistor R3, the cathode connected to the (−) input terminal 12, and the anode connected to the first A second photocoupler P2 connected to the emitter of one photocoupler P1, a cathode connected to the collector of the first photocoupler P1, an anode connected to the cathode of the second photocoupler P2, and a first photocoupler P1 and A first diode D1 for bypassing a reverse current to the two photo coupler P2, a collector is connected to the output terminal 14, an emitter is grounded, a cathode is connected to the (−) input terminal 12, and an anode is the second photo. A third photocoupler P3 connected to the emitter of the coupler P2, and a cathode connected to the collector of the second photocoupler P2, Node (-) is connected to the input terminal 12, a second photocoupler P2 and the third photocoupler P
And a second diode D2 for bypassing a reverse current with respect to No. 3 to form a circuit.

Next, the operation will be described.

When the remote relay contact device 24 operates,
Output current of remote relay contact device 24 (remote device information)
Fail-safe input circuit 10 via input line 22
Is transmitted between the (+) input terminal 11 and the (-) input terminal 12.

The fail-safe input circuit 10 in the present embodiment applies the fail-safe inspection signal 20a to the ON / OFF input terminal 13 and connects the second photo connected to the emitter of the first photo coupler P1. Fail-safe diagnosis for eliminating false information of the remote device is performed by connecting or disconnecting the current flowing through the photodiode of the coupler P2 by using the first photocoupler P1. The main part is electronic circuit parts. It is composed by.

Thus, accurate operation information from the on-site equipment (remote relay contact device 24) can be input to the electronic interlocking device 20, and even if a failure occurs, passengers will not fail or fail. It is possible to realize a small fail-safe input circuit 10 having a certain fail-safe property and capable of taking safety measures.

Referring to FIG. 1, the operation of the fail-safe input circuit 10 according to the present embodiment and the test method thereof will be described in further detail.

When the input condition is satisfied and the forward voltage is applied between the input terminals to generate the information of the remote device, the fail safe check signal 20a from the electronic interlock device 20 is generated.
Thus, when the first photocoupler P1 is ON-controlled, an input current flows through the route of the first resistance R1 → second resistance R2 → first photocoupler P1 → second photocoupler P2, and the second photocoupler P2 is turned ON. Then, the information of the remote device is transmitted to the third photo coupler P3.

As a result, the input current also flows through the path of the first resistor R1, the third resistor R3, the second photocoupler P2, and the third photocoupler P3, and the collector of the photocoupler is connected to the power supply via the load resistor. Therefore, the input current (that is, information on the remote device) transmitted to the third photocoupler P3 is output to the output terminal 14 as a voltage by the load resistance.

By connecting the output terminal 14 to the electronic interlocking device 20, transmission of information of the remote device to the electronic interlocking device 20 can be turned on, and the information of the remote device can be transmitted to the electronic interlocking device 20. Can be communicated.

Further, by controlling the fail-safe inspection signal 20a to be OFF, the first photocoupler P1 is turned off, the second photocoupler P2 is turned off, and the information of the remote device is transmitted to the third photocoupler P3. Since it is not transmitted to the output, no input current flows to the anode of the photodiode of the third photocoupler P3, and the output of the third photocoupler P3 is turned off.

Therefore, in the present embodiment, the failure
In the inspection method of the safe input circuit 10, a failure
When the safe inspection signal 20a is ON-controlled, the output of the third photocoupler P3 is turned ON, and when the fail-safe inspection signal 20a is OFF-controlled, the output of the third photocoupler P3 is turned OFF (that is, the fail-safe inspection signal 2).
When the ON / OFF control of 0a and the ON / OFF operation of the output of the third photocoupler P3 are in one-to-one correspondence), the electronic interlocking device 20 transmits the information of the true remote device to the electronic interlocking device 20. It is determined that (the input condition to the electronic interlocking device 20 is satisfied, that is, there is input).

As a result, accurate (true) operation information from the field device (remote relay contact device 24) can be input to the electronic interlocking device 20.

When the input condition is not satisfied and information on the remote device is not generated, or when a failure occurs due to the open state of the third resistor R3, the first resistor R1 → the third resistor R3 → the second photocoupler P2 → the third photo. Even if the input current does not flow through the path of the coupler P3 (that is, the input current to the anode of the third photocoupler P3 is cut off), the first photocoupler P1 is turned on and off by the fail-safe inspection signal. Since the output of the third photocoupler P3 is fixed to the OFF operation (that is, the output of the third photocoupler P3 is OFF regardless of the ON / OFF control of the fail-safe inspection signal 20a), the information of the fake remote device is not obtained. Transmitted to the electronic interlocking device 20 (unsatisfied input conditions to the electronic interlocking device 20,
That is, there is no input).

As described above, according to the fail-safe input circuit 10 of this embodiment, accurate (true) operation information from the field device (remote relay contact device 24) is input to the electronic interlock device 20. Therefore, it is possible to realize a small fail-safe input circuit having a reliable fail-safe property.

[0037]

According to the fail-safe input circuit of the present invention, by detecting the open state of the third resistor R3, accurate operation information from the field device (remote relay contact device) is transmitted to the electronic interlocking device. A small fail-safe input circuit capable of inputting and having a reliable fail-safe property can be realized.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a fail-safe input circuit according to one embodiment of the present invention.

FIG. 2 is a block diagram showing connection of a fail-safe input circuit according to one embodiment of the present invention.

FIG. 3 is a circuit diagram of a conventional input circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Fail safe input circuit 10a ... Output signal 11 ... (+) input terminal 12 ... (-) input terminal 13 ... ON / OFF input terminal 14 ... Output terminal 20 ... Electronic interlocking device 20a ... Fail safe test signal 22 ... Input line 24: Remote relay contact device

Claims (1)

[Claims] 1. A fail safe input circuit for inputting information of a remote device, comprising a (+) input terminal and a (−) input terminal for inputting information of the remote device, and a fail safe check signal. ON / OF to enter
F input terminal, an output terminal for outputting information of the remote device, and a first resistor R1 having one end connected to the (+) input terminal
And a second resistor R having one end connected to the other end of the first resistor R1.
2, a third resistor R3 having one end connected to a connection point between the first resistor R1 and the second resistor R2, a collector connected to the other end of the second resistor R2, and a cathode connected to the ON / OFF. A first photocoupler P1 connected to an input terminal and an anode connected to a power supply; a collector connected to the other end of the third resistor R3; a cathode connected to the (-) input terminal; A second photocoupler P2 connected to the emitter of one photocoupler P1, a cathode connected to the collector of the first photocoupler P1, an anode connected to the cathode of the second photocoupler P2, A first diode D1 for bypassing a reverse current to P1 and the second photocoupler P2; a collector connected to the output terminal; A third photocoupler P3 having a cathode connected to the (-) input terminal and an anode connected to the emitter of the second photocoupler P2; a cathode connected to the collector of the second photocoupler P2; Are connected to the (-) input terminal, and the second photocoupler P2 and the third photocoupler P3
And a second diode D2 for bypassing a reverse current to the fail-safe input circuit.