KR20140050947A - Management system of surge voltage having surge protector - Google Patents

Abstract

Disclosed is a surge voltage management system capable of preventing equipment failure in advance by collecting information on occurrence of surge voltage caused by lightning or over-voltage. To prevent equipment failure, the surge voltage management system comprises at least one surge protector which includes a surge voltage sensing module installed in electrical equipment and collecting information on occurrence of surge voltage resulting from lighting or over-voltage and a communication module transmitting the information on occurrence of surge voltage to the outside via a communications network; and a DB server which receives and stores the information on occurrence of surge voltage from a transceiver. According to the present invention, it is possible to detect an occurrence of surge voltage caused by lighting or over-voltage and to take follow-up measures such as replacing a surge protecting device or a surge protector, thereby preventing malfunction of electrical equipment. [Reference numerals] (100) Surge protector; (200) Communications network; (300) DB server

Description

TECHNICAL FIELD [0001] The present invention relates to a surge voltage management system using a surge protector,

The present invention relates to a surge voltage management system for collecting and managing data related to a surge voltage, and more particularly, to a surge voltage management system for collecting surge voltage generated by a lightning stroke or an overvoltage, Surge voltage management system.

Most of the recently used electric apparatuses, electronic circuits, communication apparatuses, and the like use low-power high-density integrated circuits, which can cause fatal damage to low surge voltages.

Here, the surge voltage can be generated by current coupling based on opening / closing operation of a power device or a lightning discharge, and may be caused by inductive or capacitive coupling with other elements. In electronic equipment, this surge voltage is known to be a transient anomaly.

The rise time of such a surge voltage is extremely fast in several microseconds (μs) and relatively decreases over a period of tens to several hundred microseconds (μs) after reaching the maximum value. To prevent sensitive electronic equipment from being damaged by this surge voltage, the surge-generating conductor should be short-circuited to the equipotential bonding ground quickly.

Thus, semiconductors typified by ICs and LSIs embedded in electronic equipment are extremely sensitive to transient surge voltages such as voltage impulses and voltage spikes that occur during lightning, lightning, electrical heavy equipment start-up, and main power switch operation There is a problem of malfunction or destruction of the device.

In addition, this problem caused by the combination of the system and the function of the electronic equipment or the combination of the devices becomes more prominent, and the reliability requirement for the processing of the high-level data of the multimedia device is very high. .

Such problems due to the complexity of the electronic equipment system functions or the combination of the devices are gradually increasing, and the reliability of the multimedia data processing device for the high-level data is very high, so that the device failure due to the surge voltage becomes an important problem .

Accordingly, in recent years, there have been many products equipped with a surge protector capable of effectively protecting an internal circuit from a surge voltage.

Such a surge protector is a device for preventing damage due to a surge voltage caused by a lightning strike or the like, and is divided into three types of discharge type, suppression type, and combination type depending on its function.

Specifically, the discharge type surge protector is in the open state below the discharge start voltage, and when a surge exceeding the discharge start voltage is input, the discharge state is instantaneously turned on, the current flows to the surge protector and the voltage drops. When it is removed, it returns to the original open state. As the surge protection element, gas enclosed gas tube, air gap, thyristor, triac are used.

Suppression surge protectors have very high impedance when the voltage is below the operating voltage, but very low impedance for surges that exceed the operating voltage. Surge is suppressed by the relationship between the line impedance and the impedance of the surge protector.

These suppression surge protectors are fast and have excellent surge absorption capability and are suitable for protection of precision equipment and are generally used most frequently.

However, the suppression surge protector constitutes a surge protection element called MOV (Metal Oxide Varistor). This surge protection element smoothly performs the voltage suppression function for abnormal overvoltage such as surge. However, The transient overvoltage is deteriorated without performing its function. Also, deterioration may proceed even by frequent operation for a large surge current. The deteriorated surge protection element has a characteristic that its characteristic is changed in a state of a very low impedance, and there is a problem that it is highly likely to lead to a secondary accident such as a short circuit or a fire.

In addition, a combined surge protector is a combination of a discharge surge protector and a suppression surge protector.

The surge protector protects the equipment and equipment connected to the next stage by discharging the overvoltage through the ground line when a voltage higher than the allowable range voltage is applied. However, Location, frequency of occurrence, etc., can not be known. Accordingly, the manager only coped with a judgment based on a guess when a device or equipment used due to a lightning stroke or an overvoltage is broken.

In addition, the conventional surge protector has a problem that its application is limited to a power supply (AC / DC) of a commercial power supply.

Therefore, it is required to develop a surge protector to solve such inconveniences.

Korean Patent No. 10-0925342 (2009.11.09) Korean Patent No. 10-0930552 (Announced on December 9, 2009) Korean Patent No. 10-1182596 (announced on September 18, 2012)

Accordingly, it is an object of the present invention to provide a surge voltage management system that records and manages data such as a time, an occurrence frequency, and a place where a lightning stroke and an overvoltage are introduced, thereby eliminating or solving the cause of the occurrence in advance.

In order to accomplish the object of the present invention, in one embodiment of the present invention, a surge voltage detection module installed in an electric device and collecting surge voltage generation information by a lightning stroke or an overvoltage, There is provided a surge voltage management system including at least one surge protector having a communication module for transmitting surge voltage generation information to the outside through a communication network and a DB server receiving and storing surge voltage generation information transmitted from the transceiver .

The use of the surge voltage management system according to the present invention can detect occurrence of a surge voltage due to lightning stroke and overvoltage, thereby performing subsequent processing such as replacement of a surge protection element or replacement of a surge protector. .

In addition, the present invention accumulates the location of the lightning and overvoltage, the occurrence time, and the frequency of occurrence in the DB, so that it is possible to quickly analyze the cause in the event of a failure.

In addition, the present invention can automatically calculate the place of occurrence of lightning and overvoltage, thereby enhancing the advance management of electronic devices.

In addition, the present invention can secure stable electronic devices by protecting all the input / output signals of the apparatus and the power supply unit, which are intended to be used as an extension of the application field.

1 is a block diagram for explaining a surge voltage management system according to an embodiment of the present invention.
2 is a block diagram illustrating a surge protector in accordance with an embodiment of the present invention.
3 is a configuration diagram illustrating a surge voltage management system according to another embodiment of the present invention.

Hereinafter, a surge voltage management system using a surge protector (hereinafter abbreviated as a surge voltage management system) to which an individual communication function according to preferred embodiments of the present invention is applied will be described in detail with reference to the accompanying drawings.

1 is a block diagram for explaining a surge voltage management system according to an embodiment of the present invention.

1, the surge voltage management system according to the present invention includes at least one surge protector 100 (100) connected to a wired / wireless communication network (hereinafter, referred to as 'communication network') for transmitting surge voltage generation information collected from an electronic device And a DB server 300 receiving the surge voltage generation information transmitted from each surge protector 100 and storing the received surge voltage generation information.

The communication network 200 may be a LAN network, a wireless communication network including a plurality of base stations, a base station controller, a mobile communication exchange and a WAP gateway, and a wired communication network such as the Internet.

Hereinafter, each component will be described in more detail with reference to the drawings.

2 is a block diagram illustrating a surge protector 100 according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, the surge voltage management system according to the present invention includes a surge protector 100.

The surge protector 100 is installed in an electronic device to be operated or used. The surge protector 100 discharges an overvoltage through an earth terminal in the form of an electric discharge by using a surge protection element against abnormal overvoltage such as a surge.

The surge protector 100 senses the occurrence of an overvoltage exceeding a predetermined voltage and transmits surge voltage generation information to the DB server 300 installed at a remote location via the communication network 200 when the occurrence of the overvoltage is sensed.

To this end, the surge protector 100 according to the present invention includes a surge voltage detection module 110 for collecting surge voltage generation information by a lightning stroke or an overvoltage, and surge voltage generation information collected by the surge voltage detection module 110 And a communication module 120 for transmitting the data to the DB server 300 through the communication network 200.

2, the surge protector 100 includes a surge voltage sensing module 110, a communication module 120, a surge protection module 130, a controller 140, a storage module 150, And a power supply unit 160.

More specifically, the surge voltage sensing module 110 generates surge voltage generation information by sensing generation of a surge voltage, and may be configured as an overvoltage detection circuit.

 At this time, the surge voltage generation information includes at least one of the time, the frequency, the place, and the surge frequency of the surge protector 100, and may further include a leakage current, a ground state, a surge capacity, have.

The communication module 120 transmits surge voltage generation information to a remote DB server 300 via LAN (Tcp / ip) communication.

The control unit 140 includes a microprocessor, an oscillation unit, and a detection unit, and receives signals and data to control other components.

The surge protection module 130 includes a surge protection element such as a gas discharge tube (GDT), a metal oxide varistor (MOV), a zener diode, an SCR, a varistor, a TRIAC and an arrester, By absorbing the overvoltage or the overcurrent due to the surge under the control of the controller 140, thereby preventing the electronic device from being damaged by the surge. In addition, the surge protection module 130 may bypass the abnormal overvoltage on the power supply line to the ground line through the surge protection element connected between the power supply line and the ground line.

The storage module 150 stores an event caused by the surge voltage in the surge protector 100 and may be a memory provided in the controller 140 or may be a separate memory. For example, the storage module 150 may be a hard disk drive, a flash memory, an EEPROM (Electrically Erasable Programmable Read-Only Memory), an SRAM (Static RAM), a Ferro- (Magnetic RAM), volatile memories such as RAM (Random Access Memory) and DRAM (Dynamic Random Access Memory) may be used.

The power supply unit 160 provides a power source for driving the surge protector 100, and uses an isolated DC supply and a power oscillator.

If necessary, the surge protector 100 according to the present invention may be configured to receive an external protected direct current power source without having its own power source unit. This is because the power supply unit 160 incorporated in the surge protector 100 is a component that is a major cause of failure because the amount of heat generated is always higher than other circuits in the vicinity in order to supply power to the surge protector. That is, if the power supply unit 160 built in the surge protector 100 is removed, the life of the surge protector 100 can be extended and downsized.

To this end, the surge protector 100 may include a power regulation module for shutting off the external protected direct current power applied to the electronic device by the switching operation of the surge protector when a surge voltage is applied to the electronic device.

Meanwhile, at least one of the surge protector 100 of the present invention may be installed in an electronic apparatus. For example, as one or more surge protector 100, a surge protector 100 'for power, a surge protector 100' 'for signal and a surge protector 100' 'for video may be used.

If necessary, the power surge protector 100 'may incorporate a power shutoff unit. This is to control the power supply to cut off the power or surge when a load current of more than the rated capacity or a leakage current of more than the rated capacity occurs or a surge occurs.

In addition, the power surge protector 100 'can supply fault information of the surge interrupter to a remote site so that a fault condition of the surge interrupter can be grasped at a remote site.

The surge protector 100 generates an alarm warning when there is an abnormality such as when the leakage current is significantly out of the steady state, when the number of times of the surge intrusion exceeds the designed capacity, or when the internal temperature exceeds the normal operation range Or operate the circuit breaker to prevent deterioration of the surge protection element.

Referring to FIG. 1, the surge voltage management system according to the present invention includes a DB server 300.

The DB server 300 remotely monitors at least one surge protector 100 and is connected to the communication network 200 to generate surge voltage generated from at least one surge protector 100 through the communication network 200 Receives the signal, stores it, and analyzes it.

Also, the DB server 300 stores the surge voltage generating signal in the surge voltage DB.

In this way, when the DB server 300 manages a plurality of surge protector 100, the DB server 300 assigns an identification number such as an ID address to each surge protector, The surge voltage generation information is divided into ID addresses and stored in the surge voltage DB. This is to analyze the surge voltage generation information by ID address to clearly distinguish the surge protector connected to any equipment from the surge voltage.

At this time, the surge voltage DB is stored in the DB server 300 or in the external storage means. Such a storage means may be configured to include an HDD or a solid state drive (SSD).

If necessary, the DB server 300 may be provided with a monitor for outputting the analyzed data of the surge voltage generation signal as an image. When the status of the surge protector 100 is displayed through such a monitor, the surge protector 100 can be quickly maintained and maintained by the administrator, so that the system can be operated in an optimum condition.

For example, the DB server 300 analyzes the surge voltage generation signal to analyze data such as the time when a lightning or an overvoltage is introduced into the electronic device in which the surge protector 100 is installed, frequency of occurrence of the overvoltage, So that the cause of the occurrence can be eliminated or solved in advance.

3 is a configuration diagram illustrating a surge voltage management system according to another embodiment of the present invention.

Referring to FIG. 3, the surge voltage management system according to the present invention may further include a power supply unit 400 of an Ethernet switching apparatus.

The Power over Ethernet (PoE) of the Ethernet switching device provides power to the surge protector 100 through an Ethernet cable, and includes a switch hub and an Ethernet cable.

The switching hub is connected to the communication network 200. The Ethernet cable has one end connected to the switching hub and the other end corresponding to the one end connected to the surge protector 100. [

The surge protector 100 configured to receive the AC commercial power and convert the AC / DC current into AC / DC to use the power source, the surge voltage detection module 110 and the communication module 120 are destroyed when an excessive overvoltage is inputted, The surge protector 100 supplied with power from the power supply 400 of the Ethernet switching device does not destroy the surge voltage sensing module 110 and the communication module 120 even when an excessive overvoltage is inputted.

Also, when the power supply unit 400 of the Ethernet switching device is used, the communication speed through the communication network becomes 10/100/1000 Mbps, so that the waiting time for data transmission is shortened and communication is possible in real time.

The PoE technology applied to the power supply unit 400 of such an Ethernet switching device is a technology for supplying a maximum of 12.95 W of power through an Ethernet cable for transmitting general LAN data to a device connected to a 10/100/1000 Mbps LAN. Since it is a technology already known in the art, a more detailed description will be omitted.

As described above, the conventional surge protector 100 is configured to connect a plurality of surge protectors 100 in a single controller and communication unit, while the surge voltage management system according to the present invention is configured to connect one surge protector 100 And a communication module (120).

Such conventional surge protector 100 is accompanied by a restriction condition that the electrical signal distortion of the connection signal (when the TTL is connected) occurs due to the loss characteristic and must be used in the adjacent place, while the individual sensing module and the communication module 120 The surge protector 100 of the present invention can be stably used without limitation of the distortion of the signal or the installation place and distance.

In addition, since each surge protector 100 of the present invention can transmit status information to the DB server 300 at a remote location via the control unit 140 and the communication network 200, The state of each surge protector 100 can be checked and checked.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It can be understood that it is possible.

100: surge protector 110: surge voltage detection module
120: Communication module 130: Surge protection module
140: control unit 150: storage module
160: power supply unit 200: communication network
300: DB server 400: Power supply of Ethernet switching device

Claims (4)

A surge voltage detection module installed in the electric device for collecting surge voltage generation information caused by a lightning stroke or an overvoltage and a communication module for transmitting surge voltage generation information collected by the surge voltage detection module to the outside through a communication network At least one surge protector; And
And a DB server receiving and storing the surge voltage generation information transmitted from the transceiver. The method of claim 1, wherein the at least one surge protector
A surge protector for power supply, a surge protector for signal, and a surge protector for image. The method according to claim 1,
Further comprising a power supply of an Ethernet switching device that provides power to the surge protector via an Ethernet cable. The method of claim 1, wherein the surge protector
Further comprising a power supply of an Ethernet switching device that provides power to the surge protector via an Ethernet cable.

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