KR20160090534A - Portable partial discharge simulation generator - Google Patents

Abstract

The present invention relates to a portable partial discharge simulation generating device. The device includes: a power switch part supplying or blocking power depending on a push signal input time, and changing characteristics of an output pulse; a level switch part selecting a level of a voltage depending on the number of pushes; a frequency switch part selecting a frequency; a pulse number switch part selecting whether to generate a pulse generation phase is generated only at a positive peak or also at a negative peak based on a sine wave of the frequency; a central processing part sensing signals, outputted from the power switch part, the level switch part, the frequency switch part, and the pulse number switch part, and progressing with processes including the control of a voltage doubler for display output, power, and pulse generation; a voltage doubler part generating a voltage at a corresponding level based on a pulse width, controlled through the central processing part, and supplying the generated voltage to a reed switch of a pulse generating part connected with an output terminal; and the pulse generating part generating a broadband pulse based on the voltage, supplied through the voltage doubler part, and including an FET, operated at a higher voltage than a predetermined voltage by the control of the central processing part in order to operate the reed switch by operating a coil as an electromagnet for a predetermined time, and the reed switch outputting the pulse of the applied voltage only when switching operation is performed.

Description

[0001] PORTABLE PARTIAL DISCHARGE SIMULATION GENERATOR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable partial discharge simulation generator, and more particularly, to a portable partial discharge simulation generator capable of verifying diagnostic equipment for diagnosing various electrical facilities.

Modern society is increasingly consuming electricity, and the importance of electric facilities is also highlighted. Accordingly, diagnostic equipment of various electrical equipments is being used, and there is not clearly specified a method of verifying in the field whether they are operating normally, so that it is often determined that the equipment is abnormal after the occurrence of an accident It is true.

Regarding the partial discharge simulation generation device, there are a large number of registered and disclosed in addition to Korean Patent Laid-Open No. 10-2014-0035122 (hereinafter referred to as 'prior art').

The foregoing prior art document discloses a plasma display panel comprising a discharge generating electrode which is located inside a chamber and which is disposed on both sides of an insulator which forms a bonding surface by overlapping two insulators and generates a partial discharge upon receiving a voltage, An interfacial pressure regulator for regulating the pressure of the bonding surface of the two insulators by pressurizing the two insulators, and a gas pressure regulator for regulating the gas pressure in the chamber .

At present, the verification method used in Korea is to conduct a partial discharge by using a discharge power to an expensive high voltage generator.

However, the conventional high-voltage generator including the above-described prior art is difficult to use when it is not an expert, is expensive, and has a great difficulty in field verification due to its weight. In addition, since the high pressure of the high-pressure generator itself is dangerous to a person, there is a risk of accidents when used incorrectly.

The reason why such a high-voltage generator has to be used is closely related to the characteristics of the generated pulses.

In case of partial discharge (PD), a very wide band (0Hz ~ 1.5GHz or more) pulse is generated, and it should be a nearly right angle pulse, not a rising curve like a sine wave.

However, when this is implemented in a circuit, a signal having a specified frequency and a curve like a sine wave at the time of enlargement are formed, and the intensity of the generated pulse can not be fixed.

Korean Patent Publication No. 10-2014-0035122.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is an object of the present invention to provide a partial discharge simulation generation device which can be portable and can control the intensity of a generated pulse.

According to an aspect of the present invention, there is provided a portable partial discharge simulator including: a power switch unit for performing power on / off according to a push signal input time and changing characteristics of an output pulse; A level switch unit for selecting a voltage level according to the number of times of pressing; A frequency switch section for selecting a frequency; A pulse number switch section for selecting whether a pulse generation phase occurs only at a positive vertex or a negative vertex based on a sine wave of a frequency; A central processing unit for detecting signals output from the power switch unit, the level switch unit, the frequency switch unit, and the pulse number switch unit and performing a process including display output, power supply, and double voltage circuit control for pulse generation; A voltage doubler circuit for generating a voltage of a corresponding level based on the pulse width adjusted through the central processing unit and supplying the generated voltage to a reed switch of a pulse generator connected to an output terminal; And a FET for generating a pulse of a wide band based on the voltage supplied through the voltage doubler circuit portion and operating the reed switch by operating the coil at an electromagnet for a predetermined time by operating under a control of the central processing unit, A pulse generating unit including a reed switch for outputting a pulse of a voltage applied only at a switching operation time; .

The power switch unit includes a timer and includes a power management module for turning on or off the power according to the power-on state and the push-in signal input time; And a pulse management module for changing a characteristic of the pulse when a push signal is inputted in a state in which the power is turned on less than a predetermined time; And a control unit.

In addition, the power management module turns on the power when the push signal is inputted in a state where the power is cut off for more than a predetermined time, and when the push signal is inputted more than the predetermined time in the state that the power is turned on, .

In addition, the power management module may cut off power when a push signal is not input within a predetermined time in a state that the power is turned on.

Further, the frequency switch unit is characterized by selecting a frequency of 50 Hz to 60 Hz.

Also, the reed switch is an apparatus in which the coil is surrounded and performs an electromagnet, wherein one side of the coil is connected to the battery + terminal and the other side is connected to the FET.

Further, the reed switch is characterized in that it generates a wide-band pulse in which an unstable tremble operation is performed when a magnetic field is formed, but the rising curve of the tremble operation is vertical.

A display unit for displaying at least one driving state information among a power state, a level value of a current output voltage, a phase of a pulse, a number of pulses, a frequency, a voltage value of a corresponding level generated according to pulse width control, and a battery state; And further comprising:

An output terminal connected to the pulse generator and outputting the generated wideband pulse; And further comprising:

A power supply unit including a battery and supplying power to the apparatus; And further comprising:

According to the present invention as described above, it is easy to carry, and a waveform such as an actual discharge is estimated.

According to the present invention, the intensity of a desired pulse can be adjusted, and the risk of accident can be reduced by generating the corresponding pulse only for a very short time.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a general configuration diagram of a portable partial discharge simulation apparatus according to the present invention; Fig.
2 is a circuit diagram of a voltage multiplier circuit and a pulse generator according to the present invention;
3 is a view showing an example of a reed switch and a coil according to the present invention.
FIG. 4 is an exemplary view showing a coil surrounded by a reed switch according to the present invention. FIG.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

The portable partial discharge simulation apparatus according to the present invention will be described with reference to FIGS. 1 to 4. FIG.

FIG. 1 is an overall configuration diagram of a portable partial discharge simulation apparatus according to the present invention. As shown in FIG. 1, the power supply switch unit 100, the level switch unit 200, the frequency switch unit 300, A central processing unit 500, a display unit 600, a voltage multiplication circuit unit 700, a pulse generation unit 800, an output terminal unit 900, and a power supply unit 1000.

The power switch unit 100 performs power on and off according to a push signal input time and changes the characteristics of output pulses. As shown in FIG. 1, (110) and a pulse management module (120).

Specifically, the power management module 110 includes a timer 111, and turns on or off the power of the power source unit 1000 according to the power-on state and the push-in signal input time.

At this time, the power management module 110 turns on the power when a push signal is inputted at a predetermined time (first preset time) or more in a state where the power is off, and when the power is turned on, The second set time), the power is cut off when a push signal is inputted.

Also, the power management module 110 can shut off the power when the push signal is not inputted within the predetermined time (third preset time) in the state that the power is turned on. The battery of the power source unit 1000 can be saved through the power-off.

The pulse management module 120 changes the characteristic of the pulse when the push signal is inputted at a time less than a preset time (fourth preset time) in the state that the power is turned on, that is, To change the characteristics of the pulse.

In the present embodiment, the first preset time, the second preset time, and the fourth preset time may be set to several seconds, preferably one second to three seconds, and the third preset time may be several minutes, 1 minute to 10 minutes. Here, the first preset time, the second preset time, and the fourth preset time may be the same time.

The level switch unit 200 selects the level of the voltage according to the number of times of pressing.

The frequency switch unit 300 selects a frequency (pulse generation cycle) of 50 Hz to 60 Hz.

The pulse number switch unit 400 selects whether a pulse generation phase occurs only at a positive vertex or a negative vertex based on a sine wave of a frequency. This shows the generation effect of 100 Hz and 120 Hz depending on the frequency.

The central processing unit 500 senses signals output from the power switch unit 100, the level switch unit 200, the frequency switch unit 300 and the pulse number switch unit 400 using a CPU or a CPLD, A power supply, and a voltage doubler circuit control for generating a pulse. More specifically, the voltage level is adjusted by the level of the voltage selected through the level switch unit 200, and the voltage is supplied to the voltage multiplier circuit unit 700 .

The display unit 600 includes an LCD, an LED, and the like. The display unit 600 includes a display unit 600, a display unit 600, And displays driving status information such as a voltage value and a battery status of the corresponding level.

The multiplication voltage circuit unit 700 generates a voltage of a corresponding level using the diode 710 and the capacitor 720 based on the pulse width adjusted through the central processing unit 500 and outputs the generated voltage to the output terminal unit 900. [ To the reed switch 810 of the pulse generator 800 connected to the reed switch 810 (see FIG. 2).

The pulse generator 800 generates a wide-band pulse based on the voltage supplied through the voltage multiplier circuit 700. The reed switch 810 and the FET 820, as shown in FIG. 2, .

3 and 4, the reed switch 810 is surrounded by the coil 811 to serve as an electromagnet. One side of the coil 811 is connected to the battery + terminal of the power source 1000 And the other side is connected to the FET 820.

At this time, the reed switch 810 operates unstably when the magnetic field is formed.

The unstable shaking motion of the reed switch 810 is generated according to the instantaneous operation and the gradually returning characteristic, and the reed switch 810 is operated to shake the other terminal based on the voltage supplied through the voltage doubling circuit portion 700 Of the rising curve is vertical.

Here, the generated wide band pulse generates a pulse having a characteristic of a pulse of 0 Hz to 1.5 GHz or more, a vertical waveform by an instantaneous contact, and a pulse whose peak is an applied voltage.

The FET 820 is connected to the coil 811 and operates the reed switch 810 at a time designated by the control of the central processing unit 500. [

That is, the FET 820 operates at a predetermined voltage or higher under the control of the central processing unit 500, and operates the reed switch 810 by operating the coil 811 as an electromagnet for a very short time, Outputs a pulse of an applied voltage only at the time of switching operation.

The output terminal unit 900 is connected to the pulse generator 800 and outputs the generated wideband pulse. At this time, if the output terminal unit 900 is connected to the reed switch 810 of the pulse generating unit 800 due to a high frequency, it may generate a large frequency loss and connect as short as possible.

The power supply unit 1000 includes a battery and supplies power to the apparatus.

Generally, a partial discharge signal is detected through a sensor attached to an electric facility, a partial discharge is detected based on the detected signal, and an administrator manages the facility by monitoring the partial discharge.

However, sometimes, during construction or aging, sensor failure, cable failure, and faulty measuring device occur. However, there is no way to check the electrical equipment before abnormality occurs and check it. It is possible to judge the abnormality of each stage. In this case, in the case of a simulated generator using a commercial power supply, noise is often introduced into a measuring instrument by riding on a power supply line, and malfunction is occasionally generated.

Therefore, the portable partial discharge simulation apparatus according to the present invention can be used as the following application.

1. Sensor check: The portable partial discharge simulation generator according to the present invention is connected to another sensor, and a high-level signal is applied to confirm that it is detected by a sensor to be inspected.

2. Cable check: The sensor is removed and the portable partial discharge simulation generator according to the present invention is connected to check whether a signal is detected after applying an intermediate level signal.

3. Partial Discharge Measurement Device Check: The cable connected to the sensor is removed and connected to the portable partial discharge simulation generator according to the present invention to check whether a signal due to application of a low level signal is detected.

It is difficult to check an arbitrary part of the signal of the conventional partial discharge generator. However, the portable partial discharge simulator according to the present invention can directly check the relevant part by adjusting the level of the signal for each part and applying it to a desired part Has a distinctive advantage.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. Accordingly, all such appropriate modifications and changes, and equivalents thereof, should be regarded as within the scope of the present invention.

100: power switch unit 200: level switch unit
300: frequency switch part 400: pulse number switch part
500: central processing unit 600: display unit
700: double voltage circuit part 800: pulse generating part
900: output terminal part 1000: power source part
110: power management module 120: pulse management module
111: Timer 710: Diode
720: Capacitor 810: Reed switch
820: FET 811: Coil

Claims (10)

A power switch unit for performing power on and off according to a push signal input time and changing a characteristic of an output pulse;
A level switch unit for selecting a voltage level according to the number of times of pressing;
A frequency switch section for selecting a frequency;
A pulse number switch section for selecting whether a pulse generation phase occurs only at a positive vertex or a negative vertex based on a sine wave of a frequency;
A central processing unit for detecting signals output from the power switch unit, the level switch unit, the frequency switch unit, and the pulse number switch unit and performing a process including display output, power supply, and double voltage circuit control for pulse generation;
A voltage doubler circuit for generating a voltage of a corresponding level based on the pulse width adjusted through the central processing unit and supplying the generated voltage to a reed switch of a pulse generator connected to an output terminal; And
An FET for generating a pulse of a wide band based on the voltage supplied through the voltage doubler circuit and operating the reed switch by operating the coil at an electromagnet for a predetermined time by operating under a control of the central processing unit, A pulse generating unit including a reed switch for outputting a pulse of an applied voltage only at a switching operation time; Wherein the portable partial discharge simulation apparatus comprises:
The method according to claim 1,
The power switch unit includes:
A power management module including a timer for turning on / off the power according to the power-on state and the push-in signal input time; And
A pulse management module for changing a characteristic of a pulse when a push signal is inputted in a state in which the power is turned on less than a predetermined time; Wherein the portable partial discharge simulation apparatus comprises:
3. The method of claim 2,
The power management module includes:
The power supply is turned on when a push signal is input at a time longer than a predetermined time in a state where the power supply is cut off and the power supply is cut off when a push signal is inputted at a time longer than a predetermined time in a state that the power supply is turned on. A partial discharge simulation generator.
3. The method of claim 2,
The power management module includes:
And when the push signal is not inputted within a predetermined time in the state that the power source is turned on, the power source is cut off.
The method according to claim 1,
Wherein the frequency switch unit comprises:
Wherein a frequency of 50 Hz to 60 Hz is selected.
The method according to claim 1,
The reed switch,
Wherein the coil is surrounded by an electromagnet, wherein one side of the coil is connected to the battery + terminal and the other side is connected to the FET.
7. The method according to claim 1 or 6,
The reed switch,
And generates a pulse of a wide band in which an unstable tremble operation is performed when the magnetic field is formed, but the rising curve of the tremor operation is vertical.
The method according to claim 1,
A display unit for displaying at least one driving state information among a power state, a level value of a current output voltage, a phase of a pulse, a pulse number, a frequency, a voltage value of a corresponding level generated according to pulse width control, and a battery state; Further comprising a plurality of microcomputers.
The method according to claim 1,
An output terminal connected to the pulse generator and outputting the generated wideband pulse; Further comprising a plurality of microcomputers.
The method according to claim 1,
A power supply unit including a battery and supplying power to the apparatus; Further comprising a plurality of microcomputers.

Images