KR100333522B1 - Site scope system for ADSL optical terminating equipment - Google Patents

Abstract

The present invention is distributed in a plurality of local system (S), each of the system for separately and integrally managing the state of the KEPCO power supply: a power monitoring device 20 for recognizing the alarm state from the high pressure pad 50 and the low pressure pad; A signal converter (30) for applying a voltage and a current for operating the instrument of the power monitoring device (20); And a central monitoring device 40 connected to the plurality of power monitoring devices 20 through a communication network and capable of searching, storing, and outputting received data using a computer.

Accordingly, there is an effect that can contribute to securing the reliability of the high-speed communication network by improving the management efficiency of a plurality of equipment at a relatively low cost.

Description

Power monitoring system for high speed communication network optical station equipment {Site scope system for ADSL optical terminating equipment}

The present invention relates to a power monitoring system for a high speed communication network optical station device, and more particularly, to a high speed communication network optical station device that can contribute to secure reliability of a high speed communication network by improving management efficiency of a plurality of equipments at a relatively low cost. The present invention relates to a power monitoring system.

Optical terminating equipment is an end device installed in an optical transmission system, which is composed of optical fiber cables and connected to a digital multiple conversion device in a lower layer. According to the type of each station equipment, necessary information data is converted into code conversion and digital multiplexing using stuffing, multiplexing, and scrambler circuits, and then optical pulses are transmitted to the transmission path using light emitting devices such as LD and LED. The transmitting and receiving station apparatus performs the reverse function of the transmitting unit.

The optical station equipment in operation in Korea is 6Mb / s optical station equipment (FT-2), 45Mb / s optical station equipment (FT-3), 90Mb / s optical station equipment (standard FT3C), 155Mbps optical station equipment, 565Mbps optical Station equipment, 2.5Gbps optical station equipment, optical video transmission equipment (OVID, DTLS, DVOS) and the like.

Recently, with the increase in the installation of ADSL optical end station devices, up to 2 to 4 power facility rectifiers (25A) are being installed. However, there is an urgent need for a countermeasure that can cope quickly with a power failure or failure due to the lack of an appropriate device for monitoring the power supply status of rectifier operation or KEPCO.

The power monitoring system currently used by KT is limited in its widespread use because there is a problem in the installation budget due to excessive initial installation and maintenance costs.

Accordingly, the present invention is to solve the above-mentioned disadvantages, to provide a power monitoring system for a high speed communication network optical end station device that can contribute to secure the reliability of a high speed communication network by improving the management efficiency of a plurality of equipment at a relatively low cost. It is for that purpose.

1 is a block diagram showing the overall configuration of a system according to the present invention;

2 is a block diagram showing the configuration of a power monitoring apparatus according to the present invention;

3 is a block diagram showing the configuration of a signal converter applied to the present invention;

Figure 4 is a block diagram showing the flow of operating software in the central monitoring unit according to the present invention.

Explanation of symbols on the main parts of the drawings

10: rectifier 20: power monitor

21: digital input 22: multiplexer

23: A / D converter 24: keypad

25: display 26: modem

29: microprocessor unit 30: signal converter

31, 33, 34, 36: signal amplifier 40: central monitoring unit

50: high pressure pad

In order to achieve the above object, the present invention is distributed to a plurality of local systems (S), each of which separately and integrally manages the state of the KEPCO power supply: the KEPCO power input to receive an alarm from the high pressure pad 50 and the low pressure pad A power monitoring device 20 recognizing a state; A signal converter (30) for applying a voltage and a current for operating the instrument of the power monitoring device (20); And a central monitoring device 40 connected to the plurality of power monitoring devices 20 through a communication network and capable of searching, storing, and outputting received data using a computer.

In this case, the power monitoring device 20 includes a digital input unit 21 for receiving an alarm signal, a multiplexer 22 for receiving an instrument signal from the signal converter 30, a keypad 24 for command input, and a status display. And a display 25 for control, a microprocessor unit 29 for control, and the like.

The central monitoring device 40 includes an information receiving module, a manual monitoring module, an automatic circulation module, a data retrieval module, a data printing module, and the like, receiving data through a communication processing unit, displaying results through a graphic interface, and inputting and outputting to a database. , Printer output, etc.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating the overall configuration of a system according to the present invention.

In the system distributed to a plurality of local system (S) of the present invention to individually and integrally manage the state of the KEPCO power supply, the power monitoring device 20, the signal converter 30, the central monitoring device 40 is provided. . The power monitoring device 20 and the signal converter 30 are local systems S, and the plurality of local systems S are connected to one central monitoring device 40.

At this time, the rectifier 10 is directly connected to the KEPCO power supply to convert to DC power, the power generated is preferably about DC48V. Terminals labeled A1 and A2 in the figure are parts for outputting signals related to alarms.

In addition, the power monitor 20 according to the present invention receives the operating power from the rectifier 10, and recognizes the alarm state from the high pressure pad 50 and the low pressure pad. The high pressure pad 50 is connected to the KEPCO power supply as shown on the outside of the rectifier 10, and the low pressure pad (not shown) is installed inside the rectifier 10 and connected to the rectified power supply. The high pressure pad 50 and the low pressure pad may use a low voltage relay, a low current relay, or the like.

In the city, it can be seen that the state alarm part is composed of three terminals such as A1, A2, KEPCO, and the measurement part is composed of two terminals such as voltage and current. The power supply terminal is connected to the DC 48V terminal of the rectifier 10.

In addition, the signal converter 30 applied to the present invention receives the operating power from the rectifier 10, and applies a voltage and a current for operating the instrument of the power monitoring device 20. As shown, the power terminal is connected to the power terminal of the rectifier 10, the current terminal is connected to the current terminal of the rectifier 10. Terminals denoted by A and V are for outputting a signal converted to the power monitoring device 20 side.

In addition, the central monitoring device 40 according to the present invention is connected to the plurality of power monitoring device 20 via a communication network, it is possible to search, store, and output the received data using a computer. The central monitoring unit 40 performs a sufficient function with one computer having a two-line modem 26.

On the other hand, as a suitable specification of a computer, a Pentium CPU of 400 MHz or more, 64 M bytes or more of RAM, a hard disk drive of 2 G bytes or more, and a modem of 33000 bps or more are preferable. The operating system is suitable for Windows 98, and secures two general public network lines for communication connections.

2 is a block diagram showing a configuration of a power monitoring apparatus according to the present invention.

The power monitoring device 20 includes a digital input unit 21 for receiving an alarm signal from the rectifier 10, a multiplexer 22 for receiving an instrument signal from the signal converter 30, and a keypad 24 for command input. ), A display 25 for status display, a microprocessor unit 29 for control, and the like. In the digital input unit 21, A1 and A2 terminals are connected to receive a signal from a low voltage pad of DC 48V, and the KEPCO terminal is connected to receive a signal from a high voltage pad of AC 220V. The multiplexer 22 alternately inputs the voltage and current signals from the power supply monitoring device 20 using a two-channel, analog method and is digitally signaled by a subsequent A / D converter 23. The voltage input through the multiplexer 22 is maintained at 0-10V and the current is maintained at 4-20mA. The display 25 is good if the 16-channel two-line LCD method is applied. The microprocessor unit 29 uses 68HC11F1CFN4 or more, and the memory 29 uses 32 bytes or more of EEPROM.

Reference numeral 27 denotes a DC-DC converter which converts a DC 48V voltage input from the rectifier 10 into a DC + 5V, DC + 12V, and DC-12V power source for driving the respective units.

3 is a block diagram showing the configuration of a signal converter applied to the present invention.

The signal converter 30 has the signal amplifiers 31, 33, 34, 36 and the zeros fan of 32 and 35 as main components, and the voltage and current signals from the rectifier 10 are 0 to 10V. And a current signal of 4 to 20 mA and converted to a power monitoring device 20. A signal converter 30 generates DC + 12V and DC -12V voltages to drive the signal amplifiers 31, 33, 34, 36, and zero fan 32, 35. (37) (38) are incorporated.

4 is a block diagram showing the flow of operating software in the central monitoring unit according to the present invention.

The central monitoring device 40 includes an information receiving module, a manual monitoring module, an automatic circulation module, a data retrieval module, a data printing module, and the like, receiving data through a communication processing unit, displaying results through a graphic interface, and inputting and outputting to a database. , Printer output, etc.

The graphic interface is connected with the information receiving module, manual monitoring module, data printing module and data retrieval module to display the information graphically on the monitor. The communication processing unit processes data transmission and reception through a modem in connection with an information receiving module, a manual monitoring module, and a data printing module. The database stores various data in association with the data retrieval module and the data print module. The printer driver is connected only to the data printing module so that the information is output to the printer.

Additional zones can be entered and saved on the monitor in conjunction with the graphical interface and database.

Accordingly, the power monitoring device 20 installed in each part of the optical end station device detects each KEPCO power state individually and reports them to the central monitoring device 40 so as to be integrated and managed. Operation reliability is high because a plurality of inputs for measurement and alarm status are configured.

Thus, in the configuration of the present invention, the central monitoring device 40 can use a PC class rather than a server-class medium and large computer, and it is an expensive component to the rectifier 10, the power monitoring device 20, and the signal converter 30. This does not take

According to the above configuration and operation, the present invention has an effect that can contribute to securing the reliability of the high speed communication network by improving the management efficiency of a plurality of equipment at a relatively low cost.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

Claims (3)

In a system distributed to a plurality of local systems (S) to manage the status of KEPCO individually and collectively: A power monitoring device 20 for recognizing an alarm state from the high pressure pad 50 and the low pressure pad; A signal converter (30) for applying a voltage and a current for operating the instrument of the power monitoring device (20); And Connected to the plurality of power monitoring devices 20 through a communication network, the power monitoring for the high-speed communication network optical end station device, characterized in that it comprises a central monitoring device 40 capable of searching, storing, and outputting received data using a computer. system. The method of claim 1, The power monitoring device 20 includes a digital input unit 21 for receiving an alarm signal, a multiplexer 22 for receiving an instrument signal from the signal converter 30, a keypad 24 for inputting a command, and a status display. And a display (25) for control, a microprocessor unit (29) for control, and the like. The method of claim 1, The central monitoring device 40 includes an information receiving module, a manual monitoring module, an automatic circulation module, a data retrieval module, a data printing module, and the like, receiving data through a communication processing unit, displaying results through a graphic interface, and inputting and outputting to a database. , A power monitoring system for a high speed communication network optical end device, characterized in that to perform a printer output.