KR20050081469A - Digital surge protector - Google Patents

Abstract

Disclosed is a digital surge protector in the present invention.

According to the present invention, in the surge protector for preventing the surge voltage inherent to the commercial power supplied to the load, the surge voltage attenuator for attenuating the surge voltage invaded into the commercial power in each phase by parallel connection with the commercial power Wow; A surge detector for sensing the surge voltage for each phase through a nonlinear resistor (MOV); First and second optical couplers for converting the surge signal detected by the surge detector into an optical signal; A counter for counting and displaying the number of occurrences of the surge signal provided from the first optocoupler for each phase; A display driver for detecting a surge signal provided from the second optical coupler and displaying the surge signal for each phase; And a buzzer driver for providing a predetermined oscillation sound in synchronization with the display drive signals output from the respective display driver parts, wherein the surge voltage attenuation part comprises a pair of varistor groups composed of a plurality of varistors and a pair of varistor groups. The capacitors C are connected in parallel to each other and form a capacitor C connected in parallel with one of the varistor groups in one pair of varistor groups, and the varistor groups constituting each pair are each formed in phases of the commercial power source to be connected in parallel with each other. After connecting the commercial power supply to the load in parallel, the surge voltage is attenuated when the surge voltage is generated, and the number of occurrences of the surge voltage, the phase of occurrence and the state of the surge voltage are displayed, and the digital surge protector is Load error based on the surge voltage introduced to the load by connecting with the computer equipped with the program for surge analysis As the cause of the operation can be extracted, it can protect the major digital equipment or system sensitive to surge and analyze the cause of system error based on the input status of the surge in case of malfunction of the system to prevent damage to digital equipment. Provide the effect.

Description

Digital Surge Protector {DIGITAL SURGE PROTECTOR}

The present invention relates to a surge protector, and more particularly, to prevent input power due to wavelength distortion such as overvoltage, overcurrent, surge, lightning, noise, etc. flowing into the AC power supply of the electronic equipment. In addition, the present invention relates to a digital surge protector for determining a signal change of an input power source as a digitized signal to predict or diagnose an abnormality of an electronic device.

In general, as high technology occupies us, high-tech semiconductors are widely used in the fields of electricity and electronics. As a result, the damage caused by surge increases rapidly. As the degree of integration of semiconductors increases, the circuit line width of the semiconductor becomes narrower, and the short circuit phenomenon is lowered due to the use of a conductive material to operate at low voltage. The built-in system is weak to internal pressure and proportionally weak to surge.

In these circumstances, the problems related to the damage and burnout of information / communication facilities against lightning or surge are becoming more and more important as the miniaturization, popularization of electronic communication equipment, and the increase of facilities of computers and computer systems in buildings. . It is estimated that about 70% of unknown causes of computer and communication equipment are caused by power surges and transients induced from signal and power lines. In addition, repetition of small surges degrades the device and chronically destroys it, and strong surges destroy it in a non-regenerating state at once. This would result in paralysis of the entire system at one point, and in extreme cases the entire system would be serially broken.

Therefore, it is emerging as a general view of the industry that it is urgent to develop a surge protector capable of suppressing various types of surges such as switching surge, switching surge, nuclear electromagnetic pulse, and brain surge occurring in a low voltage system.

The present invention was created to solve the above problems, an object of the present invention is to prevent a large number of surges invading the electronic equipment, to minimize the damage of the equipment by predicting the damage of the electronic equipment through the analysis of the surge To provide a digital surge protector.

Digital surge protector according to an aspect of the present invention for achieving the above object, in the surge protector for preventing the surge voltage inherent to the commercial power supply supplied to the load, is connected in parallel with the commercial power source is invaded into the commercial power source A surge voltage attenuator for attenuating the surge voltage for each phase; A surge detector for detecting a surge voltage input for each phase through the nonlinear resistor MOV; First and second optical couplers for converting the surge signal detected by the surge detector into an optical signal; A counter for counting and displaying the number of occurrences of the surge signal provided from the first optocoupler for each phase; A display driver for detecting a surge signal provided from the second optical coupler and displaying the surge signal for each phase; And a buzzer driver for providing a predetermined oscillation sound in synchronization with the display drive signal output from each display driver.

Preferably, the surge voltage attenuating unit comprises a pair of varistor groups consisting of a plurality of varistors and a pair of varistor groups are connected in parallel to each other, a capacitor (C) connected in parallel with any one of the varistor group of the pair of varistor groups And the varistor groups constituting each pair are formed in phases of commercial power supplies, respectively, and connected in parallel.

In addition, the surge detection unit is characterized by consisting of each varistor connected in series for each phase, and a forward diode and a capacitor connected in series with each varistor.

In addition, in order to measure the reliability of the attenuation capability of the surge voltage damping unit, a burnout detection sensor is mounted on the PCB of adjacent positions of the varistors constituting the surge voltage damping unit, and the operating state of the burnout detecting sensor is provided. It characterized in that it comprises a burn-out detection unit for turning on the effective indicator lamp according to.

In addition, the burnout detection sensor is characterized in that made of carbon fuse.

Each of the display drivers may include a latch circuit unit for latching an input signal, a display unit for turning off the surge indicator in response to the latched signal, and a reset for initializing the system power when the power supply to the load is momentarily interrupted. It is characterized by consisting of a guarantee.

Preferred embodiments of the present invention having such features will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a digital surge protector according to the present invention. As shown, a predetermined shape of the housing 105, a power switch 107 mounted on the front panel of the housing 105 for controlling the system power, and a surge for counting the number of times of occurrence of the surge by phase The counter 103, the surge indicator 101 for indicating the occurrence of surge by phase, the effective indicator lamp 109, the surge counter and the system for judging the reliability of the surge attenuation capability of the digital surge protector are artificially It consists of a reset switching 111 for initializing. In addition, a power input cord for receiving commercial power and a power output outlet for supplying commercial power to electronic equipment are provided in a state not shown.

The digital surge protector 100 configured as described above supplies power to the system through the power switch 107. That is, the commercial power flowing into the power input code is decompressed through a transformer and converted into direct current power required for driving the digital surge protector 100 through a predetermined regulator and smoothing circuit. Accordingly, the digital surge protector 100 detects each surge invading from a hot line, a natural line, and a ground line of a commercial power source, and determines whether a surge for each phase is generated. The determination result is displayed for each phase through the surge indicator 101. The surge indicator 101 is composed of a pair of light emitting diodes. If there is no surge intrusion, the green light emitting diode is turned on. If a surge is invaded, the red light emitting diode is turned on to visualize the intrusion of the surge for each phase. You can check.

The surge counter 103 counts the number of surges generated for each phase and displays the number of surges on a predetermined display device such as FND, LCD, and the like. Therefore, the surge indicator 101 can confirm whether the surge is generated and at the same time the number of surge occurrences in the phase. The effective indicator lamp 109 is for diagnosing the validity of a device for detecting a surge, and determines the effectiveness of the surge protector by determining a heat generation or deterioration state of the surge detection device. Accordingly, the validity of the digital surge protector 100 may be recognized according to the lighting state of the effective indicator lamp 109, which may be achieved through a predetermined light emitting device, for example, an LED.

The reset switch 111 is for artificially initializing the digital surge protector 100 and switches the surge indicator 101 and the effective indicator lamp 109 to an initial state. This is used for the replacement of the electronic equipment for the test or the initialization when replacing the internal element of the digital surge protector 100. On the other hand, the surge counter 103 is not related to the operation of the reset switch 111, which is to cumulatively calculate the inflow of the surge voltage.

2 is a block diagram illustrating the main functions of the digital surge protector according to the present invention. As shown, a surge voltage attenuator 201 for attenuating the surge voltage penetrating into the AC input power AC for each phase, and a surge for sensing the surge voltage for each phase through a nonlinear resistor MOV. The first and second optocouplers 215 and 217 for converting the surge signal detected by the surge sensing unit 209 into an optical signal, and the first optocoupler 215. A counter 219 for counting the number of occurrences of a surge signal for each phase, a first display driver 221 for each phase for detecting and displaying a surge signal provided from the second optical coupler 217, Buzzer 239 and buzzer driver for providing a predetermined oscillation sound by synchronizing with the second display driver 223 and the third display driver 225 and the display drive signals output from the display drivers 221-225. 227.

As shown in FIG. 3, the surge voltage attenuator 201 is connected to a plurality of varistor groups 201a to 201g and capacitors each consisting of a plurality of varistors connected in parallel to each other, and the surge detection unit 209 ) Consists of each varistor connected in series for each phase and a forward diode and a capacitor connected in series with each varistor. Each of the display drivers 221 to 225 is supplied to a latch circuit unit 233 for latching an input signal, a display unit 237 for turning off the surge indicator 101 in response to the latched signal, and a load. The reset guarantee unit 235 is configured to initialize the system power supply of the surge protector when the power is momentarily interrupted. The reset guarantee unit 235 prevents a malfunction due to partial power cutoff of the surge protector when the power supplied to the load is cut off.

In addition, the driving power of each circuit is to reduce the input commercial power (AC) through the transformer 203, and then the power supply unit 205 and power switch 107 for providing a DC voltage through a predetermined DC circuit. Is provided through.

On the other hand, the burnout detection unit 229 is connected to a burnout detection sensor 213 set to a close position of each varistor group, in order to measure the reliability of the attenuation capability of the surge voltage, each of the varistors through the burnout detection unit 229 After detecting the burned out state due to the heat generation of the group, that is, the disconnection state of the car phone fuse due to the heat generated, the result according to the burned out state is displayed through the valid indicator lamp 109. That is, as shown in FIG. 4, the burnout detection sensor 213 has an insulating pattern 405 formed on a circuit board (PCB) 403 equipped with a varistor group, and carbon is formed on the insulating pattern 405. The pattern 407 is constructed. Such a pattern is formed in close proximity to the varistor group, and when the varistor group is destroyed due to excessive surge or frequent surge, or the overheating of the reference value or more occurs, the burnout detection sensor 213 of the PCB pattern made of carbon fuse is disconnected. Accordingly, the burnout detection unit 229 operates the effective indicator lamp 109 based on the burnout state of the burnout detection sensor 213 to secure stability of the system.

Hereinafter, the operation of the digital surge protector according to the present invention will be described.

The user supplies commercial power to the input terminal of the digital surge protector 100, connects the output terminal of the digital surge protector 100 to the load, and then turns on the power switch 107. The commercial power supply AC supplies a reduced pressure AC power to the power supply unit 205 via the transformer 203, and the power supply unit 205 switches the reduced pressure AC power to a predetermined level of DC power. The DC power is used as the driving voltage of each driving circuit, and the first display driver 221 to the third display driver 225 reset the surge indicator 101 to a normal state. For example, the surge indicator 101 lights up in green, and the surge counter 103 is set to zero ('0') to display an initial state.

On the other hand, commercial power (AC) supplied to the input terminal of the digital surge protector 100 is provided to the surge detection unit 209 via the surge voltage attenuation unit 201. The surge voltage attenuation unit 201 is a pair of varistor group 201 composed of a plurality of varistors are connected in parallel to form a capacitor (C) is connected in parallel with one of the varistor group 201, forming each pair The varistor group 201 is formed for each phase of a commercial power source and connected in parallel with each other. Therefore, when a surge voltage is generated for each phase of the commercial power supply, the surge voltage is attenuated by each varistor group 201 connected in phase and paired.

Such surge voltage represents the change of voltage generated in the low voltage system such as switching surge, switching surge, nuclear electromagnetic pulse, brain surge, etc., and has a voltage of several thousand volts (V) and an operation time of several tens of microsec (μsec). . The varistor turns on the device when the voltage is applied above the reference value to cancel the high voltage, and at the same time, the surge flowing through the fuse unit 207 is switched through the varistors for each phase of the surge detection unit 209. The switching signal of the varistor is introduced into the input terminals of the two optocouplers 215 and 217 through the diode and the capacitor to operate the light emitting diode of the optocoupler.

The lighting of the light emitting diodes of each of the optocouplers 215 and 217 turns on the light emitting diodes to provide a predetermined electrical signal to the output terminal of the first optocoupler 215, based on which the count of the counter 219 is performed. That is, the counter 219 counts the number of occurrences of the surge voltage provided for each phase and displays the number of occurrences of the surge voltage with the surge counter 103 composed of FNDs. In addition, the same output signal as the first optical coupler 215 is provided to the output terminal of the second optical coupler 217. Accordingly, the count signal provided for each phase is supplied to each display driver 221, 223, 225 for each phase.

The count circuit section 233 of each display driver section counts the surge voltage generated in the corresponding phase, latches the pulse signal at the count, and operates the respective surge indicators 101 through the display section 221. The surge indicator 101 may be composed of two light emitting diodes composed of a single color light emitting diode, and may be composed of three color light emitting diodes. From this, the operation of the surge indicator 101 is performed to turn on the LED of a red color to identify whether or not a surge is generated. For example, when a surge occurs in the A line, the LED of the red line is turned on through the display unit 237, and each display unit of the B and C lines that do not generate a surge maintains the LED of the green line. Thus, the user can visually identify that a surge occurs in the A line.

Since the display driver 221 is switched to an initial state (light emitting diode of a green system) when the reset switch (not shown) is operated, it is possible to determine whether a surge occurs after the system is started. In addition, the generation of the surge voltage allows the buzzer driver 227 to operate so that the buzzer 239 continuously oscillates, thereby indicating an audible surge generation state.

On the other hand, the burnout detection unit 229 indicates the reliability of the operation state of each display driver (221-225), which means the reliability of the attenuation ability of the surge. That is, the heat generation state of each varistor is recognized by the burnout detection sensor 213 of the carbon fuse mounted on the adjacent PCB ratio (PCB) pattern of each varistor group constituting the surge voltage attenuation part 201, and the heat generation state is detected. According to the reliability of the present invention, if one or more varistors generate heat due to the occurrence of excessive surge, frequent surge, or device failure, the attenuation capability of the input surge cannot be reliable. Therefore, as the carbon fuse is disconnected when the varistor is heated, the reliability of the attenuation ability of the surge is determined through the burned-out state of the car phone fuse.

In addition, when the at least one of the varistors provided for each phase exhibits heat generation over the reference value, the effective indicator lamp 109 of the red system is operated, and the varistor is under heat generation below the reference value. The effective indicator lamp 109 of the green system is operated to indicate the reliability of the surge reduction capability of the surge voltage reduction unit 201.

5 (a) is an experimental graph showing the surge voltage generated from the input power supply, Figure 5 (b) is an experimental graph to witness the attenuation of the surge voltage through the digital surge protector according to the present invention. The surge voltage of several thousand volts is reduced by the surge voltage attenuation unit 201 as shown in FIG. 5 (b), and the number of surges introduced into the load by indicating the number of surges generated through the counter 219. Can be accumulated and detected.

Therefore, the user detects the generation state, the number of occurrences, and the generation phase of the surge flowing into the load through the digital surge protector 100 as a digital signal, and predicts the damage of the load through such a system. That is, the digital surge protector 100 is connected to a computer, and the computer is loaded with a program that lists the influence of the load proportional to the surge occurrence so that the cause of the load abnormality can be inferred.

What has been described above is only one embodiment for the digital surge protector according to the present invention, and the present invention is not limited to the above-described embodiment, and the scope of the present invention is not limited to the claims. Without departing from the scope of the present invention, those skilled in the art will have the technical spirit of the present invention to the extent that various modifications can be made.

As described above, the digital surge protector according to the present invention prevents the surge voltage from flowing into the load when the surge voltage is generated in parallel, after connecting commercial power supplied to the load in parallel, and the occurrence frequency, phase and In addition to displaying the generation status of the surge voltage, it is possible to connect the digital surge protector with a computer equipped with a predetermined surge analysis program to extract the cause of the load malfunction based on the surge voltage introduced into the load. It protects major digital equipment or system that is sensitive to the system and analyzes the cause of system error based on the input status of surge when the system malfunctions, thus preventing the damage to digital equipment.

1 is a perspective view showing a digital surge protector according to the present invention.

2 is a block diagram illustrating a digital surge protector according to the present invention.

FIG. 3 is a circuit diagram illustrating the surge voltage damping unit of FIG. 2.

4 is a view for explaining the carbon fuse of the burn-out detection sensor of FIG.

5 (a) (b) is a graph showing the experimental results according to the present invention.

<Description of Symbols for Main Drawings>

100: digital surge protector 101: surge indicator

103: surge counter 105: housing

109: effective indicator lamp 201: surge voltage attenuation part

207: fuse unit 209: surge detection unit

215/217: Optocoupler 219: Counter

221-226: display driver 233: latch circuit

235: reset unit 237: display unit

Claims (9)

In the surge protector to prevent the surge voltage inherent to the commercial power supplied to the load, A surge voltage attenuating unit for attenuating the surge voltage invading into the commercial power in parallel with the commercial power for each phase; A surge detector for detecting a surge voltage input for each phase through the nonlinear resistor MOV; First and second optical couplers for converting the surge signal detected by the surge detector into an optical signal; A counter for counting and displaying the number of occurrences of the surge signal provided from the first optocoupler for each phase; A display driver for detecting a surge signal provided from the second optical coupler and displaying the surge signal for each phase; And And a buzzer driver configured to provide a predetermined oscillation sound by synchronizing with a display driver signal output from each display driver. The capacitor of claim 1, wherein the surge voltage attenuator comprises a pair of varistor groups composed of a plurality of varistors, a pair of varistor groups connected in parallel to each other, and a capacitor connected in parallel with any one of the pair of varistor groups. And C), and each pair of varistor groups are formed for each phase of a commercial power supply and connected in parallel to each other. 3. The digital surge protector of claim 2 wherein the plurality of varistors comprise eight elements. The digital surge protector of claim 1, wherein the surge detection unit comprises a varistor connected in series for each phase and a forward diode and a capacitor connected in series with each varistor. 5. The burnout detection sensor according to claim 4, further comprising a burnout detection sensor mounted on a PCB (PCB) at an adjacent position of each varistor constituting the surge voltage attenuator to measure the reliability of the surge attenuation capability of the surge voltage attenuator. And a burnout detector for turning off the effective indicator lamp according to the operation state of the detection sensor. 6. The digital surge protector of claim 5, wherein the burnout detection sensor is made of carbon fuse. 6. The digital surge protector of claim 5 wherein said effective indicator lamp is a light emitting diode having at least two colors. The display device of claim 1, wherein each of the display drivers comprises a latch circuit part for latching an input signal, a display part for turning off a surge indicator in response to the latched signal, and a system power supply when a power supply to a load is interrupted. Digital surge protector comprising a reset guarantee for initializing. 9. The digital surge protector of claim 8 wherein said surge indicator is comprised of a light emitting diode having at least two colors.