JPH0720171B2 - Redundant signal supply device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] The present invention relates to a dual signal supply device that can continue to supply a signal when a signal supply system that has become a signal supply system has a temporary failure. For the purpose of increasing the reliability of the output of the own system, the inhibition output of the own system output switch circuit that connects the own system signal source to the load in response to the switch output of the own system output drive switch circuit In a duplicated signal supply device for prohibiting the operation of the other system output switch circuit for connecting the other system signal source by the output to the load, the other system output is output in response to the loss of the switch output of the own system output drive switch circuit. A holding switch circuit for supplying a switch drive output equivalent to the switch drive output of the drive switch circuit to the other system output switch circuit is provided.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dual signal supply device capable of continuing signal supply when a signal supply system that has become a signal supply system temporarily fails.

In a telephone exchange or the like, it is necessary to supply a signal (for example, a calling signal) to the load. For example, since the paging signal device is required to have reliability, the paging signal device has a dual structure.

[Conventional technology]

An example of a conventional dual signal supply device is configured as shown in FIG. At startup in this device configuration, the 0-system output drive relays RDY and iNT are turned on, the output relay OUT is turned on, and a signal is supplied from the signal source 8 to the load. At that time, output drive relay RD of 1 system
Since Y is also turned on and the relay iNT is turned on at the same time, the output relay OUT is not turned on and the signal supply from the signal source 14 of the 1-system to the load is not generated.

In this signal supply state, if a failure occurs in system 0,
Since the 0-system relay RDY is turned off, the relay OUT is turned off and the signal supply from the 0-system signal supply source 8 to the load is stopped. However, the switching of the relay OUT to the off state releases the prohibition of the switching of the relay OUT of the 1-system to the on state until then, so that the relay OUT is turned on. Thus, the signal is supplied from the 1-system to the load when the 0-system fails. That is, the signal supply system is duplicated.

[Problems to be solved by the invention]

However, as described above, the signal supply system changes from 0 system to 1 system.
If a failure occurs in the 1st system while the system is switched to the 1st system, the 1st system relay RDY will be turned off. This is relay O
The UT is turned off, and the signal supply from the 1st system to the load is stopped. Therefore, the function of the signal supply device is lost when a temporary failure occurs in the own system when the other system has a failure.

The present invention was created in view of the above problems, and an object thereof is to provide a dual signal supply device capable of improving reliability in a temporary failure of the own system in a failure condition of another system.

[Means for solving problems]

FIG. 1 shows a block diagram of the principle of the present invention. In the figure, reference numeral 6 denotes an own system output switch circuit which can be operated by the own system output drive switch circuit 4. The operated system output switch circuit 6 supplies the signal of the system signal source 8 to the load. In the state where the own system output switch circuit 6 is operated, even if the other system output drive switch circuit 10 is operated, the other system whose operation is prohibited by the prohibited output of the own system output switch circuit 6 that is in operation The present invention is configured by providing the holding switch circuit 16 which holds the drive of the output switch circuit 12 in response to the disconnection of the supply of the drive signal to the own system output switch circuit 6.

[Operation] When the signal supply device is started up and the own system (0 system) output drive switch circuit 4 is operated, the own system output switch circuit 6
Is activated. Thus, the signal is supplied from the signal source 8 of its own system (0 system) to the load. However, even if the other system output drive switch circuit 10 is activated, the own system output switch circuit 6
Is operated, the operation of the other system output switch circuit 12 is prohibited by the prohibition output.

When a failure occurs in the own system, the own system output drive switch circuit 4 is turned off, so the own system output switch circuit 6 is also turned off. Therefore, the prohibition of operation is released, the other system output switch circuit 12 is operated, and the signal is supplied from the other system signal source 14 to the load. Since the holding switch circuit 16 is activated at the same time as the release, even if a temporary failure occurs in the other system and the other system output drive switch circuit 10 is turned off,
The operated holding switch circuit 16 continues to turn on the other system output switch circuit 12, so that it is possible to prevent the signal to the load from being stopped.

〔Example〕

FIG. 2 shows an embodiment of the present invention. This embodiment assumes either of the output relay contacts out ₂ also bidirectional contact structure of the 0-system and 1-system of a conventional dual signal supply apparatus of FIG. 2, a photocoupler 10 ₀ to the normally open fixed contact side, 10 ₁ Photodiodes
10 ₀₁ and 10 ₁₁ are installed and the normally closed fixed contact is relay K
Connected to a -48 volt power supply via
0 _0, 10 ₁ of the phototransistor 10 _02, 10 ₁₂ and grounded through a normally closed relay contact k in addition those constituted by normally open relay contact rdy juxtaposed. The 0-system relay RDY and its relay contact rdy correspond to the self-system output drive switch circuit 4 in FIG. 1, and the 0-system relay iNT and its relay contact int and the relay OUT and its relay contacts out ₁ and out ₂ are the This corresponds to the own system output switch circuit 6 in FIG. Further, the 1-system relay RDY and its relay contact rdy correspond to the other-system output drive switch circuit 10 of FIG. 1, and the 1-system relay iNT and its relay contact int and relay OUT and its relay contacts out ₁ , ou
t ₂ corresponds to the other system output switch circuit 12 in FIG. 1, and the 1 system relay K and its relay contact k and the photocoupler 10 ₁ correspond to the holding switch circuit 16 in FIG.

With such a configuration, after the dual signal supply device is started up in the same manner as in the conventional case, the 0 system becomes an obstacle, and the signal supply to the load is switched from the 0 system to the 1 system. Even if a temporary failure occurs in the first system, the signal supply to the load is not stopped by it.

That is, when a failure occurs in the 0 system, the 0 system relay OUT is turned off, so the O system output relay contact out ₂ is switched,
The 0 system relay K is kept on and its relay contact k
The 1-system output relay OUT is turned on in the same manner as before, and the 1-system signal source 16 supplies the signal to the load via the 1-system output relay contact out ₁ that is closed. To be done.

The switching of the 1-system output relay OUT to ON also closes the relay contact out ₂ . This is a photo coupler 10 ₁
Does not operate, the 1-system relay K is turned off to close the relay contact k.

Therefore, even if a temporary failure occurs in the first system, the signal stop to the load is prevented because the relay contact k in parallel with the output relay contact rdy is closed.

In the above embodiment, the case of starting from the 0 system is shown, but if the circuit for the relays iNT and OUT is replaced by the plug replacement type, the system can be started from the 1 system. can do.

〔The invention's effect〕

As described above, according to the present invention, when a temporary failure occurs in the switched system, it is possible to prevent the signal supply from the signal supply device from being stopped and enhance the significance of the duplication. .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the principle of the present invention, FIG. 2 is a diagram showing an embodiment of the present invention, and FIG. 3 is a diagram showing a conventional dual signal supply device. In FIG. 1 and FIG. 2, 4 is the own system output drive switch circuit (0 system relay RDY and its relay contact rdy), and 6 is the own system output switch circuit (0
System relays iNT and OUT and their relay contacts int, ou
t ₁ , out ₂ ), 8 is a signal source of its own system (0 system), 10 is another system output drive switch circuit (1 system relay RDY and its relay contact rdy), 12 is another system output switch circuit (1 system of iNT and OUT and their relay contacts int, out ₁ , out ₂ ), 14 are other systems (1 system)
A signal source 16 is a holding switch circuit (a relay K of system 1 and its relay contact k and a photocoupler 10 ₁ ).

Claims (1)

[Claims] 1. A system output drive circuit (4) is connected to a load in response to a switch output of a system output drive switch circuit (4). A dual signal supply device for inhibiting the operation of the other system output switch circuit (12) for connecting the other system signal source (14) to the load by the switch output of the switch circuit (10), wherein the own system output drive switch A holding switch circuit (1) that supplies a switch drive output equivalent to the switch drive output of the other system output drive switch circuit (10) to the other system output switch circuit (12) in response to the loss of the switch output of the circuit (4).
6) A dual signal supply device characterized by being provided.