KR100906305B1 - Device for preventing the surge voltage for a bidirectional suppression - Google Patents

Abstract

A device for preventing a surge voltage for bidirectional suppression is provided to protect an electronic apparatus and a serge voltage device by removing the serge voltage with a serge voltage protection circuit. In a device for preventing a surge voltage for bidirectional suppression, resistors(3A-3F) pass a normal signal flowed along the input line(1). The surge voltage is blocked with the resistor, and lightning arresters(5A-5C) are connected between the input terminal of the input line and an electronic or a communication system in parallel. The lightning arrester emits the surge voltage passing through the input line to the second through the GND.

Description

Device for preventing the surge voltage for a bidirectional suppression}

The present invention relates to a bidirectional suppression surge voltage suppressor, and more particularly, a surge voltage suppression circuit part is provided at a rear end of an external inflow surge voltage suppressor circuit connected to an inlet end of an electronic device. The present invention relates to a bidirectional suppression surge voltage suppressor that eliminates surge even when the voltage and input and output are changed and connected.

In general, surge voltages are generally classified into open / close surge, accident surge, and lightning surge. Among these surge voltages, open / close surge is a surge generated when opening / closing a breaker of a high voltage device installed on a transmission line. It refers to surge caused by overvoltage generated when ground is grounded by physical force, and thunder surge voltage (lightning thunder or lightning) refers to the lightning voltage when the thunderstorm charged in the thunderstorm in the upper part of the atmosphere is discharged to the ground. A surge surge is a type of surge surge that enters a communications or electrical device and damages the device.

However, in order to prevent damage to the device from the surge voltage (surge voltage) as described above, electronic or communication systems usually use surge voltage protection devices connected to the inlet or transmission line of the device. Voltage protection devices are mainly applied to various signals, communications, data, video transmission lines, or communication parts of communication devices such as telephones, fax machines, modems, or electric shocks due to surge voltages such as lightning surges and static electricity, such as CRT driving circuits. It is installed in the part which is easy to receive and it prevents the communication or electronic device from being damaged by abnormal voltage by consuming surge energy by gas discharge and discharge when surge voltage is inflowed.

Then, referring to FIG. 1, one example of the conventional surge voltage preventing device as described above is provided on an input line 70, for example, on input terminals IN A and IN B of various signals, communications, data, and image transmission lines. Surge flowing into the inlet (IN A, IN B) side of this line by installing in parallel

A first GDT (gas discharge tube) 71 for discharging the voltage primarily;

Resistors 72A and 72B connected in series on the input line 70 to pass normal signals flowing along the input line 70 and block only the surge voltage;

An arrester 74A connected in parallel between the input line 70 and the input terminal of the electronic or communication system 73 to discharge the surge voltage input via the input line 70 in a second manner through the ground terminal GND; 74B).

On the other hand, referring to the operation of the conventional surge voltage prevention device as described above, when a normal state in which lightning or other high voltage or overvoltage does not flow into the input line 70, an input signal normally input from the outside, for example, an image signal or a communication signal Alternatively, since the data signal is transmitted to the electronic or communication system 73 via the input line 70, the electronic or communication system 73 is normally operated. Here, the first GDT 71 or the arresters 74A and 74B connected on the input line 70 do not operate.

     However, if a lightning strike or high voltage is generated around the input line 70 to flow into the electronic or communication system 73 along the input line 70, the surge voltage is resistors 72A and 72B. Are blocked by the two holes and flow to the first GDT 71 side. At this time, the first GDT 71 is operated by a surge voltage of more than a threshold voltage flowing into the input terminals IN A and IN B of the input line 70 so that the corresponding surge voltage is primarily input and ground terminals GND. Release through. Here, when the surge voltage passes through the resistors 71A and 71B for several reasons, for example, primary discharged surge residual voltage, the surge voltage is between the input line 70 and the input terminal of the electronic or communication system 73. The lightning arresters 74A and 74B connected in parallel prevent the surge voltage from flowing into the electronic or communication system 73 by preventing the surge voltage from entering the electronic or communication system 73. To protect.

However, the conventional surge voltage suppressor as described above prevents only surge voltage flowing into the inlet end of the surge voltage suppressor, for example, lightning or overvoltage, but there is no protection element against surge voltage flowing into the electronic or communication system. When a voltage flows into the electronic or communication system, the surge voltage protection device and the expensive electronic or communication system are frequently damaged.

In addition, since the components of the surge voltage suppressor generally have characteristics of resistance, inductance, and capacitor, when the surge voltage does not flow, it acts as a factor to increase noise in the transmission signal input through the line, thereby improving the transmission efficiency of the line. Significantly reduced,

Furthermore, since the surge voltage preventing device is not provided with the transmission status notification means, the administrator cannot accurately determine whether the signal is normally supplied through the line. Therefore, the convenience of the surge voltage preventing device is also considerably degraded. .

Accordingly, the present invention has been invented to solve the above-mentioned problems of the prior art, and removes the surge voltage flowing into not only the inlet side of the surge voltage suppression circuit but also the rear end connected to the electronic equipment in multiple stages. It is an object of the present invention to provide a bidirectional suppression surge voltage suppressor that can reliably protect electronic equipment.

It is still another object of the present invention to provide a bridge circuit at a stop of the surge voltage preventing circuit to remove noise components included in a communication signal flowing along a line, thereby significantly improving the transmission characteristics of signals passing through the surge voltage device. It is to provide a surge voltage suppressor for bidirectional suppression.

The present invention for achieving the above object is provided with a first GDT installed in parallel on the inlet end of the input line to discharge the surge voltage introduced to the inlet end (IN A, IN B) side of the input line primarily;

A resistor connected in series on the input line and passing the normal signals flowing along the input line as it is and blocking only the surge voltage;

A lightning arrester connected in parallel between the input line and an input terminal of an electronic or communication system to discharge a surge voltage input via a second input line through a ground terminal (GND);

      A surge voltage canceller connected in parallel between the input line and an input terminal of an electronic or communication system to discharge a surge voltage flowing back from the input line or the electronic or communication system through a ground terminal (GND);

      A reverse surge removal GDT connected in parallel to an output line connected to an input terminal of the electronic or communication system to discharge a surge voltage flowing back from the electronic or communication system through a ground terminal (GND);

      A second GDT device connected between a ground terminal to which one side terminal of the first GDT is connected and a common connection point of the arrester to block inflow of overvoltage (surge voltage) and noise introduced through an input line;

      A bidirectional suppression transient voltage configured to include a noise removing unit connected to a line between the surge voltage canceller and the reverse surge suppression GDT to remove noise included in a transmission signal transmitted to an electronic or communication system through an input line and an output line. Provide prevention device.

As described above, the present invention includes a surge voltage suppression circuit unit at a rear end of an external inflow surge voltage prevention circuit connected to an inlet of the electronic equipment, thereby removing surge voltages accidentally flowing in the reverse direction from the electronic equipment in multiple stages. It has the advantage that it can protect electronic equipment from reliably and also protect expensive surge voltage device against western voltage.

In addition, according to the present invention, by providing a bridge circuit at the interruption of the surge voltage protection circuit to remove noise components contained in the communication signal flowing along the line, thereby significantly improving the transmission characteristics of the signals passing through the surge voltage device. There is also an advantage.

Furthermore, the present invention connects the transmission status display section for indicating the state of signal transmission of the line to the one side of the surge voltage circuit section, and the surge voltage display section for displaying the surge voltage numerically so that the administrator can monitor the operation state of the surge voltage device. In addition to this, it is possible to obtain numerical information on the surge voltage that flows in immediately, thus maximizing the function of the surge voltage suppressor.

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

As shown in FIG. 2, the apparatus of the present invention is installed in parallel on the input lines 1, for example, the input terminals IN A and IN B of various signals, communications, data, and video transmission lines such as a modem or a PLC. A first GDT 2 for discharging the surge voltage flowing into the input terminals IN A and IN B of the input line 1 primarily;

Resistors (3A-F) connected in series on the input line (1) to pass normal signals flowing along the input line (1) as they are and to block only the surge voltage;

The surge voltage input via the input line 1 is connected in parallel between the input line 1 and the input terminal of the electronic or communication system 4 to prevent the surge voltage through the ground terminal GND.

Lightning arresters 5A-C to be ejected;

      Each in parallel between the input line 1 and the input of an electronic or communication system 4

A surge voltage canceller 6A-C connected to discharge the surge voltage flowing from the input line 1 or the electronic or communication system 4 back through the ground terminal GND;

      Reverse surge removal GDT connected in parallel to the output line 7 connected to the input terminal of the electronic or communication system 4 to discharge the surge voltage flowing back from the electronic or communication system 4 through the ground terminal GND. (8);

      One side of the first GDT 2 is connected between the ground terminal GND connected to the common connection point of the lightning arresters 5A and 5B to detect an overvoltage (surge voltage) and noise flowing through the input line 1. A second GDT 13 for blocking;

      Noise included in the transmission signal connected to the line between the surge voltage remover 6C and the reverse surge suppression GDT 8 and transmitted to the electronic or communication system 4 through the input line 1 and the output line 7. It comprises a noise removing unit 9 for removing the.

      Here, the noise removing unit 9 may use a noise removing filter or a bridge circuit to improve transmission characteristics.

On the other hand, the line between the rear end of the reverse surge suppression GDT 8 and the input end of the electronic or communication system 4 is connected with a transmission state display unit 11 for displaying the transmission state of the surge voltage suppressor 10 to the outside. .

Here, a light emitting diode may be used for the transmission state display unit 11. In addition, the first GDT 2 and the reverse surge suppression GDT 8 are three-pole lightning arresters, and at least 800 V and 50/60 Hz of commercial frequency AC voltage based on a standard brain impulse voltage (1.2 / 50 μs). In this control circuit, a protective device that starts discharge at least 130 V in the event of a ground fault or adjacent ground fault can be used.

In addition, a line between the rear end of the reverse surge suppression GDT 8 and the input end of the electronic or communication system 4 is connected with a numeric display unit 12 which converts the incoming surge voltage into digital numerical information and displays it externally.

Here, the numerical display unit 12 is respectively installed at one terminal of the first GDT (2) connected to the ground terminal and one terminal of the reverse surge removing GDT (8) and the first GDT (2) and reverse surge removing GDT ( Detection sensors 14A and 14B which detect the surge voltage (detection of light, current, electric field, voltage included) when 8) is operated;

A control converter (15) for converting the surge voltage detected by the detection sensors (14A, 14B) into digital numerical information for display on a display;

And a battery power supply unit 16 for supplying operating power to the numerical display unit 12.

Next, the operation and effects of the present invention having the above configuration will be described.

The apparatus of the present invention first inputs an input signal, for example, an image signal or communication, normally input through the input line 1 from the outside when a surge voltage, for example, a lightning strike or other high voltage or overvoltage does not flow through the input line 1. Since the signal or data signal is transmitted to an input terminal of an electronic or communication system 4 such as a communication modem or a PLC, for example, the electronic or communication system 4 processes the input signal in a predetermined manner.

Here, when the surge voltage does not flow in the forward or reverse direction as described above, the first GDT (2), lightning arrester (5A-C), surge connected to the input line (1) or output line (7) The voltage remover 6A-C, the reverse surge suppression GDT 8 and the second GDT 13 do not operate.

At this time, in the normal state as described above, the input signal is passed through the noise removing unit 9 before being transmitted to the input terminal of the electronic or communication system 4, and the noise removing unit 9 is, for example, a noise removing filter. Alternatively, the bridge circuit filters the noise components included in the input signal to improve transmission characteristics and transmits the noise components to the input terminal of the electronic or communication system 4.

In addition, when the input signal is normally transmitted to the electronic or communication system without the surge voltage as described above, the transmission status display unit connected to the line between the rear end of the reverse surge suppression GDT 8 and the input terminal of the electronic or communication system 4 ( 11) lights up a red or green lamp indicating the current normal signal transmission to externally indicate the normal transmission state of the surge voltage preventing device 10. Of course, the transmission state display unit 11 is turned on without emitting light or flashing when the signal is not normally transmitted.

However, if an unexpected surge voltage, for example, a lightning strike or a high voltage is generated around the input line 1 during the normal operation as described above, and attempts to flow into the electronic or communication system 4 along the input line 1, The surge voltage is blocked by the resistors 3A and 3B and flows to the first GDT 2 side.

At this time, the first GDT 2 starts discharge at a minimum of 130 V when a commercial frequency AC voltage of at least 800 V and 50/60 hz is mixed in a control circuit or adjacent ground fault based on a standard brain impulse voltage (1.2 / 50 μs). Since the device is operated by a surge voltage higher than the reference voltage flowing into the input terminals IN A and IN B of the input line 1, the surge voltage is first emitted through the ground terminal GND.

Here, when the surge voltage passes through the resistors 3A and 3B for several reasons, for example, the primary discharged surge residual voltage, the surge voltage is blocked by the resistors 3C and 3D, and then the input line 1 The surge voltage flows to the arrester 5A-5C connected in parallel between the input terminals of the electronic or communication system 4, and this surge voltage is the minimum insulation breakdown voltage of the arrester 5A-5C and the second GDT 13, for example, 100 V. Or it is discharged through the ground terminal GND by the lightning arrester 5A-5C and the 2nd GDT 13 because it is more than a reference voltage.

At this time, since the resistors 3C and 3D connected to the rear ends of the arresters 5A-5C are connected in series on the input line 1, the overcurrent flows to the rear end of the line to maximize the operation of the arrester. In addition, the zener diodes of the surge voltage eliminators 6A-C and the bridge diodes of the noise canceling unit 9 are prevented from shorting.

However, if there is a surge voltage that is not removed through the above process, the remaining surge voltage will be higher than the avalanche breakdown voltage of the zener diode, for example, the zener diode. Since both the C) and the second GDT 13 are discharged to the ground terminal GND, the surge voltage is prevented from entering the electronic or communication system 4 to protect the electronic or communication system 4 from damage.

On the other hand, when such a sudden surge voltage flows in the reverse direction of the electronic or communication system 4 rather than the input side of the surge voltage suppressor 10, the surge voltage is convexed by the resistors 3E and 3F. The reverse surge suppression GDT 8 is controlled by a commercial frequency AC voltage of at least 800 V and 50/60 Hz based on a standard brain impulse voltage (1.2 / 50 μs). Since the device starts to discharge at least 130 V when mixed in the circuit or near ground fault, the reverse surge removal first GDT 8 is operated by the surge voltage to discharge the surge voltage flowing in the reverse direction through the ground terminal GND. Let's do it.

At this time, since the resistors 3E and 3F connected to the rear end of the noise removing unit 9 are connected in series to the line, the overcurrent flowing from the output line 7 side is suppressed, and the surge voltage remover 6A- The zener diode of C) and the bridge diodes of the noise removing unit 9 are prevented from shorting.

      On the other hand, when the surge voltage is input to the input terminal of the surge voltage protection circuit 10 or the output terminal of the reverse direction as described above, the control conversion unit 15 of the numerical display unit 12 is the first through the detection sensors 14A, 14B. The surge voltage is detected from the periphery of the GDT (2) and the reverse surge removal GDT (8), and then converted into digital numerical information. Display.

Here, the same method as described above also operates when the resistors 3A-F are replaced with inductors.

 As described above, the present invention can reliably protect the electronic equipment from the surge voltage by removing the surge voltage suddenly introduced from the electronic device in the reverse direction, as well as effectively remove the noise component included in the communication signal flowing along the line. Because it can be eliminated, it can be very useful if connected to all electronic and communication systems where surge voltage is a concern.

1 is an explanatory diagram illustrating an example of a conventional surge voltage prevention circuit.

       2 is an explanatory diagram for explaining an example of the surge voltage preventing device of the present invention.

     <Detailed Description of Codes>

    1: input line 2: first GDT

    3A-F: Resistor 4: Electronic or Communication System

    5A-C: Surge Arrester 6A-C: Surge Arrester

    7: output line 8: reverse surge removal first GDT

    9: noise removing unit 10: surge voltage suppressor

   11: Transmission status display section 12: Numerical display section

   13: second GDT 14A, 14B: detection sensor

   15: control conversion section 16: battery power supply

Claims (8)

A first GDT installed in parallel on the inlet end of the input line and discharging the surge voltage flowing into the inlet end (IN A, IN B) side of the input line primarily; A resistor connected in series on the input line and passing the normal signals flowing along the input line as it is and blocking only the surge voltage; An arrester connected in parallel between the input line and an input terminal of an electronic or communication system to discharge a surge voltage input via a second input line through a ground terminal (GND); A surge voltage canceller connected in parallel between the input line and an input terminal of an electronic or communication system to discharge a surge voltage flowing back from the input line or the electronic or communication system through a ground terminal (GND); A reverse surge removal GDT connected in parallel to an output line connected to an input terminal of the electronic or communication system to discharge a surge voltage flowing back from the electronic or communication system through a ground terminal (GND); A bidirectional suppression transient voltage configured to include a noise removing unit connected to a line between the surge voltage canceller and the reverse surge suppression GDT to remove noise included in a transmission signal transmitted to an electronic or communication system through an input line and an output line. Prevention device. The apparatus of claim 1, wherein the noise removing unit uses a noise removing filter. The apparatus of claim 1, wherein the noise canceling unit uses a bridge circuit. 2. The bidirectional suppression transient according to claim 1, wherein a transmission status indicator is connected to a line between the rear end of the reverse surge suppression GDT and an input terminal of an electronic or communication system to externally display the transmission state of the surge voltage suppressor. Voltage protection device. The line between the rear end of the reverse surge suppression GDT and an input terminal of an electronic or communication system is connected to a numerical display unit for converting a surge voltage flowing into a bidirectional line into digital numerical information and displaying it externally. Bidirectional suppression transient protection device. 6. The digital display of claim 5, wherein the numeric display unit is installed at one side of the first GDT connected to the ground terminal and one side of the reverse surge suppression GDT, and detects the surge voltage when the first GDT and the reverse surge suppression GDT are operated. A detection sensor; A control converter converting the surge voltage detected by the detection sensor into digital numerical information and displaying the same on a display; And a battery power supply unit for supplying operation power to the numerical display unit. The device of claim 1, wherein the resistor is replaced with an inductor. The method of claim 1, wherein a second GDT is connected between the ground terminal to which one terminal of the first GDT is connected and the common connection point of the arrester to block overvoltage, surge voltage, and noise flowing through an input line. Overvoltage protection device for bidirectional suppression.

Images