KR20100013028A - Sensor for detecting with surge current by no power supply - Google Patents

Abstract

PURPOSE: An abnormal current detecting sensor without power supply is provided to manage a thunderbolt or a surge current in the remote by driving a switch of an output end after converting a current signal to a time signal. CONSTITUTION: An abnormal current detecting sensor without power supply comprises the following: a noncontact detector(10) detecting surge input from a detected line; a micro capacitor(30) storing DC components outputted from an input forming part; an amplifier(40) amplifying surge signals stored on the micro capacitor; a delay signal(50) converting an output signal to switching signals; an output forming part(70) transmitting switching results of a switch unit with driving power.

Description

Sensor-less Detecting with Surge Current by No Power Supply

The present invention relates to an abnormal current detection sensor, and in particular, in detecting impulses induced on a track provided on the ground and transmitting the result to a remote location, the energy of the detection signal and the bias of the output line without a separate power supply ( The charging time is used as a power source for the whole sensor while the operation time of the delay circuit 50 operates as a non-power supply that provides a technology that is proportional to the amount of energy stored in the microcapacitor 30, that is, the magnitude of the input current. It relates to an abnormal current detection sensor.

As shown in FIG. 1, the abnormal current detection circuit according to the related art converts an analog signal into a digital signal in an A / D conversion unit with respect to a signal input from a limit unit by supplying a separate power source, and sensor lines T and R. The parallel-to-serial converter must convert the serial signal into a line before transmitting it.

Such a general abnormal current detection circuit can not only operate by supplying power, but also it is difficult to detect a lightning current in a device already in operation such as an environmental monitoring system, and it is difficult to commercialize it without changing the structure of an existing device. I have a problem.

Therefore, the present invention was made to solve the above-mentioned problems of the prior art, and utilizes a signal introduced from an input line and a bias signal introduced from an output line as a power source without a separate power supply, thereby monitoring the existing environment. The purpose of the present invention is to provide a technique for detecting a surge current by changing a program without changing a mechanical structure by detecting an amount of current proportional to the time of a signal input to a digital input terminal without changing a system H / W.

Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, which is a non-contact CT (current transformer) input, the brain surge (lightning surge) or switching surge with two output (T, R) line A sensor for detecting and outputting a switch surge,

A non-contact detection unit 10 for detecting a surge inflow non-contacted from the line to be detected L1;

An input shaping unit 20 for rectifying the output of the non-contact detecting unit 10;

A microcapacitor 30 for accumulating a DC component output from the input shaping unit 20;

An amplifier 40 for amplifying the detected surge detection signal stored in the microcapacitor 30;

A delay circuit 50 for converting the output signal of the amplifier 40 into a signal for switching;

It is characterized in that it comprises an output shaping unit 70 for transferring the switching results of the switch unit 60 to the output (T, R) while taking the driving power from the output line.

Here, the output shaping unit 70 converts a signal flowing from a digital input device connected to the output terminals T and R into a direct current, and converts the converted direct current component to the switch 60 as a power source and at the same time an amplification unit. The power supply 40 is supplied.

In addition, the non-contact detection unit 10 is normally there is no input signal, and thus the power supplied from the output shaping unit 70 is not consumed at all to maintain the stability of the output circuit of the present invention.

At this time, when the abnormal current is detected in the non-contact detection unit 10, the input shaping unit 20 rectifies (shaping) the detected current waveform, and the rectified current component is charged in the microcapacitor 30.

When the electric charge stored in the microcapacitor 30 becomes the base current of TR (TR1) constituting the amplifier 40, TR1 turns on and immediately supplies power supplied from the output shaping unit from the capacitor C1 of the delay circuit. Will charge.

At this time, the bias (Bias) flowing into the output lines (T, R) to which the present invention is applied is a very small current of about 10mA or less depending on the configuration, and becomes a short circuit when the delay circuit C1 starts charging. As the capacitor C1 charges, the TR2 of the switch 60 is operated again, so that the output shaping part 70 is diffused in a completely shorted state.

In addition, as long as the potential stored in the microcapacitor 30 is maintained, the amplifier 40 operates and the delay circuit 50 starts operation.

As a result, the delay circuit maintains the switch 60 in a short circuit state until the capacitor C1 of the microcapacitor 10 completes discharging. The charging energy of the microcapacitor 10 is proportional to the detected current. Therefore, the short time of output is proportional to the detected current.

In other words, the present invention, which has a basic configuration, implements a sensor function for driving a switch of an output by converting a magnitude of an input current into a change in an output time without having a separate power supply device.

As described above, the digital input terminal of the environmental monitoring system, which is already common, is provided with a sensor function that converts an input current signal into a signal of time to drive a switch of an output terminal without having a separate power supply device. By connecting the sensor of the present invention to it is a very convenient and useful invention that can remotely manage by detecting lightning or surge current.

(Example)

Hereinafter, with reference to the accompanying drawings, the configuration of the embodiment of the present invention and its operation will be described in detail.

1 is a block diagram showing an abnormal current detection sensor of the prior art, Figure 2 is a block diagram showing an abnormal current detection sensor operating with no power supply of the present invention, Figure 3 is a specific application circuit diagram for Figure 2, Figure 4 is the present invention Each shows a current-time conversion characteristic according to an example of.

3 is an example circuit for a preferred embodiment of the present invention, the non-contact detection unit 10 is provided as an electromagnetic coupling sensor of the CT type. When a surge current flows in the detection line L1, a current is induced on the secondary side, and the onion is rectified by the bridge diodes D1 to D4 of the waveform shaping unit 20 to charge the microcapacitor 30. At this time, since the capacitance of the capacitor C1 is highly related to the CT capacity of the detector, the capacitance can be applied corresponding to the standard impulse current waveform of IEC61000-4-5 in conjunction with the CT characteristics.

The surge energy stored in the microcapacitor 30 acts as the TR1 base current of the amplifier part via the resistor R1. In this case, TR1 has a characteristic that the discharge time of C1 can be obtained very long by adopting an emitter follower method whose input impedance is close to infinity.

While the discharge current via C1 and R1 acts as a bias of TR1, C2 charges via R2, and then turns on TR3 via R3. When TR2 is turned on, TR1 has a lower collector potential. TR2 and TR1 remain turned on while the discharge of C1 is continued. When TR2 reaches short-circuit condition, current of TR1 decreases, and TR2 will try to escape short-circuit condition. At this time, TR1 current increases and TR2 returns to short-circuit condition. It will continue until it is complete.

As a result, the collector potential of TR2 of the switch 60 is lowered until the surge energy charged in C1 is consumed, thereby switching the output lines T and R of the diodes D5 to D8 of the output shaping unit 70. The result is that the potential is short-circuited, resulting in a sensor function that drives the output switch by converting the magnitude of the input current into a change in output time.

The present invention provides a machine by detecting the amount of current in proportion to the time of the signal input to the existing digital input terminal without a structural change to the H / W for the digital input device of the environmental monitoring system that has been widely spread in the art It is possible to provide the technology to detect surge current by changing the program without any structural change, and remote control is possible by detecting the short-circuit / surge current (analog) within 8us ~ 20us to the digital input terminal of environmental monitoring system. To do it.

As a still further feature of the present invention, the non-contact detection unit 10 is provided as a CT connected to the line L1; The input shaping section 40 is connected as bridge diodes D1, D2, D3, D4; The micro charge unit 30 is characterized in that it is provided as a small capacitor (C1) of 10uF or less.

The output shaping section 70 is provided with bridge diodes D5, D6, D7, and D8 connected between both ends of the output lines T and R as inputs. Supplying the outputs of the bridge diodes D5, D6, D7, and D8 to the power supply of the switch 60 and the amplifier 40; The switch 60 is operated until the capacitor C2 of the delay circuit 50 is discharged according to the state of the amplifier 40 by the current of the microcharger 30, and at this time, the output lines T and R are short-circuited. Characterized in that.

In addition, the amplifying unit 40 is provided with an emitter follower method that loads one transistor TR1 and C2 and R3 to increase the input impedance of TR1 to provide a timer proportional to the input current. do.

       In addition, the amplifier 40 includes an amplifying TR (TR1), is provided with a resistor (R2) connected to the collector of TR1, the capacitor (C2) is connected to the emitter, the capacitor (C2) and TR1 The resistor R3 is connected at the emitter connection point to be connected to the base of the switching unit TR2, and the collector of TR2 is provided with a current limiting resistor R4.

On the other hand, as shown in Figure 4, the current-time conversion characteristics according to the present invention allows a sensor connected only two signal lines without a separate power supply is converted to a change in a long time proportional to the current flowing in a short time As a non-powered sensor circuit, a current change of about 1,000V / 500A of 1.2us to 50us can be detected and a time change of 12.4s can be obtained.

This is because by connecting the sensor of the present invention to the digital input terminal of the environmental monitoring system that is already common, it is possible to remotely manage by detecting lightning or surge current.

As mentioned above, although one preferred embodiment of the present invention has been described in detail with reference to the drawings and examples, the present invention is not limited to the above embodiment, and is common in the art within the spirit and scope of the present invention. Various forms of variation and modifications are possible to those skilled in the art.

1 is a block diagram showing an abnormal current detection sensor of the prior art

2 is a block diagram showing an abnormal current detection sensor operating with a no power supply of the present invention.

3 is a specific application circuit diagram of FIG.

4 is a current-time conversion characteristic graphic according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10-Non-contact detection part 20-Input shaping part

30-Microcapacitor 40-Amplifier

50-Delay Circuit 60-Switch

70-output shaping

Claims (7)

In the sensor that receives a non-contact current transformer (CT) as an input, and detects and outputs a lightning surge or a switch surge having two output (T, R) lines, A non-contact detection unit 10 for detecting a surge inflow non-contacted from the line to be detected L1; An input shaping unit 20 for rectifying the output of the non-contact detecting unit 10; A microcapacitor 30 for accumulating a DC component output from the input shaping unit 20; An amplifier 40 for amplifying the detected surge detection signal stored in the microcapacitor 30; Delay circuit 50 for converting the output signal of the amplifier 40 into a signal for switching, In addition, the abnormal current operated by the non-power supply, characterized in that it comprises an output shaping unit 70 for transferring the switching result of the switch unit 60 to the output (T, R) while taking the driving power from the output line. Detection sensor. The abnormal current detection sensor according to claim 1, wherein the non-contact detection unit (10) further comprises a CT connected to the line (L1). 2. The abnormal current detection sensor as claimed in claim 1, wherein the input shaping portion (20) further comprises being connected as a bridge diode (D1, D2, D3, D4). 2. The abnormal current detection sensor as claimed in claim 1, wherein the micro charge unit (30) is further configured to be connected as a small capacitor (C1) of 10 uF or less. 2. An output device (70) according to claim 1, wherein the output shaping section (70) is connected with bridge diodes (D5, D6, D7, D8) between the output lines (T, R) at both ends; Supplying the outputs of the bridge diodes D5, D6, D7, D8 to the power supply of the switch 60 and the amplifier 40; The switch 60 is operated until the capacitor C2 of the delay circuit 50 is discharged according to the state of the amplifying unit 40 by the current of the micro charging unit 30. At this time, the output lines T and R The abnormal current detection sensor operated by the no power supply, characterized in that it further comprises a short circuit. The method of claim 1, wherein the amplifying unit (40) uses an emitter follower system that loads one transistor (TR1), C2, and R3 as a load, and increases the input impedance of the TR1 to increase a timer proportional to the input current. Abnormal current detection sensor operating by a non-power supply, characterized in that it further comprises. The amplification unit 40 is provided with an amplifying TR (TR1), and a resistor (R2) is connected to a collector of TR1, and a capacitor (C2) is connected to an emitter. An abnormal current detection sensor operating with no power supply, characterized in that the resistor R3 is connected at the emitter connection point of TR1 to the base of TR2 of the switching section, and the collector of TR2 further includes a current limiting resistor R4.

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