KR0146966B1 - Duplex method in the ring production - Google Patents

Abstract

The present invention relates to a duplexing method of a ring generator, and more particularly, to a mixed duplexing method of a ring generator that can be used by mixing a conventional duplexing method.

In the prior art, when the ring generator is redundant, the operation / standby method and the load division method are separately applied. Therefore, when the load fluctuates, the redundancy of the ring signal supply can be efficiently reduced due to the lack of duplication for the load. There was a problem of disappearing.

According to the present invention, it is possible to operate in the operation / standby mode by using the load division circuit so that the ring signal can be selectively operated in the load division mode and the operation / standby mode according to the capacity of the ring board and the load capacity. Redundancy can be efficiently performed.

Description

Mixed redundancy method of ring generator

1 and 2 are views for explaining a duplexing method of a conventional ring generator,

3 is a view for explaining a hybrid redundancy of the ring generator according to the present invention,

4 is an operation timing diagram for a ring generator and a mixed redundancy scheme according to the present invention.

* Explanation of symbols for main parts of the drawings

10, 20, 30, 40, 50, 60: ring board

RYA, RYA 'RYB, RYB': Relay

The present invention relates to a ring generator redundancy method, and more particularly, to a method of mixing redundancy of a ring generator that enables a mixture of conventional redundancy methods to be used.

Conventional ring generator redundancy includes an active / standby method and a load shring method.

In case of duplication by operation / standby method, as shown in FIG. 1, the first ring board 10 and the second ring board 20 are provided to supply ring signals to the same load 1, and the first ring board is provided. The first relay RYA is provided at 10 and the second ring board 20 is provided at second relay RYA.

In the case of the duplication by the operation / standby method provided as described above, it operates as follows.

When the first ring 10 is in a normal operating state, the first relay RYA is turned on to output the ring signal of the first ring board 10 to the load 1 side, and the second relay RRY is off. The ring signal of the ring board 20 is not output to the load 1 side. When a failure occurs in the first ring board 10 in this state, the first relay RYA is turned off and the second relay RYB is turned on, so that the second ring board 20 sends a ring signal to the load 1 side. Will print.

In the case of redundancy by the load division method, as shown in FIG. 2, the first ring board 30 and the second ring board 40 are provided, and the first ring board 30 has a first relay RYA. And a second relay RYA ', and the second ring board 40 includes a third relay RYB and a fourth relay RYB'.

In the case of the redundancy by the load division method provided as described above, it operates as follows.

When the first and second ring boards 30 and 40 operate normally, the first relay RYA and the third relay RYB are turned on to supply ring signals to the first and second loads 1,2. At this time, the second relay (RYA ') and the fourth relay (RYB') are turned off so that the ring signals are not supplied to the loads 1,2.

During operation in such a state, for example, when a failure occurs in the first ring board 30, the first relay RYA is turned off and the fourth relay RYB 'is turned on so that the second ring board 40 is turned on. Supply ring signal to the load 1,2 side.

As described above, the operation / standby method and the load division method are individually employed for redundancy, but each of them has different advantages and disadvantages according to the capacity of the ring board and the capacity of the load. In other words, if the capacity of the ring board is for 2K (for 2048 subscribers) and the load capacity is configured for 2048 subscribers, it is appropriate to use dual chemistry in the operation / standby mode. And if the load capacity is composed of 2048 subscribers, it is appropriate to duplicate by load division method.

As such, in the case of duplexing the ring generator, the operation / standby method and the load splitting method are applied separately. Therefore, when the load fluctuates, duplication of the ring signal supply can be efficiently performed due to the lack of duplication suitable for the load. There is a problem that can not be.

The present invention has been made to solve the problems described above, by using a load-dividing circuit can be operated in the operation / standby method selectively load-dividing mode according to the capacity of the ring board and load capacity It is an object of the present invention to provide a hybrid ring duplication method of ring generator that can be efficiently operated in the operation / standby mode.

A characteristic feature of the present invention for achieving the above object is a first ring having a first relay and a second relay for outputting a ring signal to a first load side and a second load side, respectively, in a mixed redundancy method of a ring generator. The supply of ring signals is provided by using a known load division redundancy circuit comprising a board and a second ring board having a third relay and a fourth relay for outputting ring signals to the first load side and the second load side, respectively. Redundancy; When operating in the operation / standby mode, the ring signal is output to the first load side by turning on the first and second relays of the first ring board or the third and fourth relays of the second ring board. Among the first and second ring boards, the ring board that does not output the ring signal to the first load side checks the state of the two relays of the opposite ring board that is outputting the ring signal, and if the two relays are off, after a predetermined time delay Operating two relays of a ring board that were not in a ring signal output to turn on and output a ring signal to the first load side; When operating in the load split mode, one of the two relays provided on the first and second ring boards is turned on during the normal operation of the first and second ring boards to reset the ring signal of the first ring board. If one of the first and second ring boards is faulted and the relay which is outputting to the ring is turned off while outputting the ring signal of the second ring board to the second load side while outputting to the first load side, the fault is not generated. Delay the relay that was not outputting the ring signal of the ring board for a predetermined time and turn it on to output the ring signal.If the failing ring board fails, the relay which outputs the ring signal is turned off and delayed for a predetermined time. After that, it operates to output a ring signal by turning on a single relay provided in the failing ring board.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

3 is a diagram illustrating a mixed duplication method of a ring generator according to the present invention, and FIG. 4 is an operation timing diagram of the mixed duplication method of a ring generator according to the present invention.

The redundancy apparatus applied to the present invention uses a known load splitting circuit as shown in FIG. 3, and includes a first ring board 50 and a second ring board 60, and includes a first ring board ( The first relay RYA and the second relay RYA 'are provided at 50, and the third ring RYB and the fourth relay RYA' are provided at the second ring board 60. In addition, the first ring board 50 is provided with a control circuit (not shown) for controlling on / off of the first relay RYA and the second relay RYA ', and the second ring board 60. ) Is provided with a control circuit (not shown) for turning on / off the third relay RYB and the fourth relay RYB ', and the control circuit operates / standby according to the selection of the operation mode. Control relay on / off in mode or load sharing mode. That is, the control circuits of the first and second ring boards 50 and 60 operate the relay at the timing as shown in FIG. 4A when the operation / standby mode is selected, and the load sharing mode is selected. In this case, the relay is operated at the timing as shown in (b) of FIG.

As described above, the redundancy apparatus according to the present invention is operated at the timing as shown in FIG. 4A only when the redundancy operation is performed in the operation / standby mode, and the timing as shown in FIG. In FIG. 4, a denotes an on time of the first relay RYA, and b denotes a delay time between turning off the first relay RYA and turning on the fourth relay RYB '. C represents the on time of the fourth relay RYB ', and d represents the delay time from the off of the fourth relay RYB' to the first relay RYA on. A 'is the on time of the first relay RYA, c' is the on time of the fourth relay RYB ', g' is the off time of the third relay RYB, and b ', d', e 'and f' are relay delay times.

First, the operation process in the case of operating in the operation / standby mode is as follows.

The second ring board 60 while the first relay RYA and the second relay RYA 'of the first ring board 50 are turned on to output the ring signal of the first ring board 50 to the load 1 side. Checks the states of the first relay (RYA) and the second relay (RYA '), and if a failure occurs in the first ring board (50), the first relay (RYA) and the second relay (RYA') are turned off. After the time delay of b of 4 degrees (a), the third relay RYB and the fourth relay RYB 'are turned on to output the ring signal of the second ring board 60 to the load 1 side.

In addition, the third ring RYB and the fourth relay RYB 'are turned on in the second ring board 60 to output the ring signal of the second ring board 60 to the load 1 side. 50 checks the states of the third relay RYB and the fourth relay RYB ', and a failure occurs in the second ring board 60 so that the third relay RYB and the fourth relay RYB' are turned off. When the time delay of d in FIG. 4 (a) is delayed, the first relay RYA and the second relay RYA 'are turned on to output the ring signal of the first ring board 50 to the load 1 side.

In the meantime, the operation process in the case of operating in the load split mode is as follows.

In the normal operation of the first and second ring boards 50 and 60, the first relay RYA and the third relay RYB are turned on to output the ring signal of the first ring board 50 to the load 1 side. At the same time, the ring signal of the second ring board 60 is output to the load 2 side.

If a failure occurs in the first ring board 50 while the first relay RYA is turned off while the operation is performed, the fourth relay RYB 'of the second ring board 60 becomes b in FIG. 4 (b). After the delay by time, the ring signal of the second ring board 60 is output to the load 1 side.

In this state, when the first ring board 50 fails over, after the fourth relay RYB 'is turned off, the first relay RYA is turned on after the fourth relay RYB' is turned off for the d 'time in FIG. The ring signal of the ring board 50 is supplied to the load 1 side.

In addition, during normal operation of the first and second ring boards 50 and 60, the first relay RYA and the third relay RYB are turned on to output the ring signal of the first reed 50 to the load 1 side. At the same time, while the ring signal of the second ring board 60 is output to the load 2 side, when the second ring board 60 is interrupted and the third relay RYB is turned off, the first ring board 50 is turned off. After the second relay RYA 'of FIG. 4B is delayed by e' time in FIG. 4B, the ring signal of the first ring board 50 is output to the load 2 side.

When the second ring board 60 fails in such a state, after the second relay RYA 'is turned off, the third relay RYB is turned on after being delayed by f' time in FIG. 2 Ring signal of the ring board 60 is supplied to the load 2 side.

As described above, the present invention enables operation in the operation / standby mode using a load division circuit so that it can be selectively operated in the load division mode and the operation / standby mode according to the capacity of the ring board and the load capacity. Therefore, the redundancy of the ring signal supply can be efficiently performed.

Claims (1)

1. A mixed redundancy method of a ring generator, comprising: a first ring board having a first relay and a second relay for outputting a ring signal to a first load side and a second load side, respectively, and a ring signal to a first load side and a second load side The supply of the ring signal is redundant by using a known load division redundancy circuit composed of a second ring board having a third relay and a fourth relay for respectively outputting a second relay; When operating in the operation / standby mode, the ring signal is output to the first load side by turning on the first and second relays of the first ring board or the third and fourth relays of the second ring board. Among the first and second ring boards, a ring board that does not output a ring signal to the first load side checks the state of two relays of the opposite ring board that is outputting the ring signal, and when the two relays are turned off, after a predetermined time delay Turn on two relays of the ring board that were not in the ring signal output to operate to output the ring signal to the first load side instead; When operating in the load split mode, one of the two relays provided on the first and second ring boards is turned on during the normal operation of the first and second ring boards to reset the ring signal of the first ring board. If one of the first and second ring boards is interrupted while the ring signal of the second ring board is output while the ring signal of the second ring board is output to the second load side while being output to the first load side, the fault is not generated. Delay the relay that was not outputting the ring signal of the ring board for a predetermined time and turn it on to output the ring signal.If the failing ring board fails, the relay which outputs the ring signal is turned off and delayed for a predetermined time. And then operating one relay provided on the failing ring board to output a ring signal.