KR101902286B1 - arc flash detection system using the IR and UVC censor - Google Patents

Abstract

An object of the present invention is to provide an ultraviolet (UV) light source for detecting an arc flash by detecting ultraviolet rays having a wavelength band of 280 to 400 nm by natural light or illumination, An infrared ray sensor for detecting a temperature from an arc flash generated in the apparatus and outputting a temperature detection signal; and an ultraviolet ray sensor for detecting an ultraviolet ray having a wavelength band of 280 to 400 nm A controller for receiving an ultraviolet ray detection signal of a specific band from the UVC sensor and detecting an arc flash with a temperature detection signal detected from the infrared sensor; The signal is input and the pulse width is converted to a constant value. A blocking unit for receiving an arc flash detection signal output from the digital signal processing unit with a predetermined pulse width and outputting a trip signal to the breaker; An alarm / on-off display unit for receiving an arc flash detection signal and generating an alarm sound through a speaker or emitting a lamp to transmit the occurrence of an arc flash to the outside, and a communication unit for transmitting the occurrence information of the arc flash to the outside .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an arc flash detection system using an ultraviolet (UV) and ultraviolet (UV)

The present invention relates to an arc flash detection system and, more particularly, to an arc flash detection system which is capable of detecting an arc flash more quickly by blocking ultraviolet rays having a wavelength band of 280 nm to 400 nm by natural light or an illumination light, To an arc flash detection system using a sensor.

In general, the switchgear is one of the electric power facilities, which consists of monitoring and control devices such as relays, instruments, and controllers, and main circuit devices such as circuit breakers and disconnecting devices. Each unit device is mounted on the supporting structure for easy maintenance and repair.

However, if a problem arises in insulation and circuit durability because a high voltage is formed in the switchgear and a current flows, there is a possibility of leading to a serious accident.

In order to detect the deterioration and fire in advance due to the characteristics of such a switchboard, measures have been taken to prevent it. Arc and corona discharges are the main causes of accidents, which can lead to fire or explosion.

In the case of arc fires, abnormal current flows due to grounding, over capacity, contact with other objects, and overheating of booth bars, cables, wires, and terminal contacts inside the high voltage and low voltage switchgear. As a result, contact with other objects can lead to interruption of the line at the fault site, resulting in continuous repetitive arcing with partial contact.

Since it is not easy to prevent the generation of an arc in this manner, it is very important to detect the arc quickly and accurately to prevent fire.

On the other hand, local insulation breakdown may occur in the insulation of a device such as a transformer, a switch, or a breaker. Such internal insulation breakdown causes an internal discharge phenomenon. The internal partial discharge causes deterioration of the apparatus and may seriously cause a fire, but it is not easy to detect it.

This internal partial discharge is mainly discharged through a gap or a joint of a metal clad, which is a housing of a switchgear, and a transient earth voltage (TEV) applied to the metal clad is discharged from the metal clad and ground The ground voltage will change immediately and temporarily. The time it takes is very instantaneous.

In the past, there was no means for detecting such internal partial discharge, and there was no example in which the excessive ground voltage applied to the metal clad was detected and used for the abnormality diagnosis.

However, the local insulation breakdown of the insulation can have serious consequences for the switchboard. On the other hand, in the switchboard, a lot of wiring, switches, breakers, relays, and other components are densely packed, and their functions are constantly operating, leading to frequent accidents leading to deterioration, aging, and fire.

In order to prevent such deterioration and fire from being detected in advance due to the characteristics of such a switchboard, measures have been taken.

One of them is to detect the heat which is particularly vulnerable to deterioration and cope with the heat. Numerous devices are built in the switchgear and the wiring is very complicated, so it is not easy to monitor everything.

In the conventional method of detecting the temperature of the switchboard panel, it is judged whether or not the target of deterioration exceeds a specific critical temperature by dichotomizing the risk. However, deterioration or temperature rise is not so simple as to continuously deteriorate the state and to simply judge deterioration based on the critical temperature.

In addition, there is a problem that the conventional method can not know the change of the deterioration such as the increase of the temperature rise or the deterioration of the deterioration. Therefore, there is a need for a more detailed and precise determination of the deteriorated state, and an automatic algorithm for the deterioration allowance is also required.

In addition, although the arc flash detection system according to the related art detects an arc flash using an ultraviolet sensor and a loop sensor, precise arc detection is difficult due to noise coming from various light sources.

An object of the present invention is to solve the above-mentioned problems, and an object of the present invention is to provide an infrared ray detector for detecting an arc flash more quickly by detecting ultraviolet rays of a specific wavelength band by intercepting ultraviolet rays having a wavelength band of 280 to 400 nm by natural light, The object of the present invention is to provide an arc flash detection system using a UVC sensor.

According to an aspect of the present invention, there is provided an arc flash detection system using an infrared (UV) and ultraviolet (UV) light sensor, including an infrared sensor for detecting a temperature from an arc flash generated in the apparatus and outputting a temperature detection signal, A UVC sensor for detecting an ultraviolet ray of a specific band by blocking ultraviolet rays having a wavelength band of 280 nm to 400 nm by natural light or illumination from a flash; and a temperature sensor for detecting a specific band of ultraviolet rays from the UVC sensor A controller for receiving an ultraviolet detection signal and detecting an arc flash; a digital signal processor for receiving the arc flash detection signal of the controller to convert the pulse width into a constant signal and outputting the signal as a digital signal; Receives the output arc flash detection signal An arc flash detection signal output from the digital signal processing unit at a predetermined pulse width to generate an alarm sound or a lamp to emit an arc flash to the outside, / Turn-on display unit, and a communication unit for transmitting the occurrence information of the arc flash to the outside.

The control unit includes a first amplifier for receiving a temperature detection signal detected from the infrared sensor, amplifying and outputting the detected temperature signal, a second amplifier for receiving and outputting an ultraviolet detection signal of a specific band from the UVC sensor, A first and a second signal converting unit for receiving a temperature detection signal and an ultraviolet detection signal amplified from the second amplifier and converting the received temperature detection signal into a digital signal and outputting the digital signal, And an arc detection unit for receiving the ultraviolet ray detection signal and comparing the received ultraviolet ray detection signal with a reference value to detect the occurrence of an arc flash.

The arc flash detection system using the infrared and ultraviolet (UV) sensor according to the embodiment of the present invention has the following effects.

First, the arc flash is detected more quickly by blocking ultraviolet rays having a wavelength band of 280 nm to 400 nm by natural light or an illumination lamp, and tripping of the breaker can minimize electric power equipment and human casualties.

Second, only ultraviolet rays in the wavelength band of 100 nm to 280 nm are detected, and ultraviolet rays of other wavelength bands generated by sunlight or illumination light are blocked. Thus, only ultraviolet rays generated by an arc other than sunlight or illumination are detected and detected Errors can be reduced.

Third, it is possible to prevent the occurrence of the secondary damage by detecting the occurrence of the arc flash at the initial stage and reducing the time for determining whether or not there is an accident.

1 is a block diagram schematically showing an arc flash detection system using an infrared (UV) and ultraviolet (UV) sensor according to the present invention
2 is a graph showing ultraviolet ray detection in a general arc flash
Fig. 3 is a graph showing response characteristics of a specific band by the UVC sensor in the ultraviolet rays of Fig. 2

Hereinafter, the present invention will be described in detail with reference to the drawings. It is to be noted that the same elements among the drawings are denoted by the same reference numerals whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

FIG. 1 is a block diagram schematically showing an arc flash detection system using an infrared ray and ultraviolet (UV) sensor according to the present invention.

Here, an arc flash detection system using an infrared (UV) and ultraviolet (UV) sensor according to the present invention is installed inside a low-voltage switchboard, a high-voltage switchboard, a distribution board, a motor control panel, a connection panel, and an inverter to detect an arc flash.

In the conventional method, the arc current waveform is distorted or distorted due to noise due to a high voltage inside the switchgear, so that the arc can not be accurately detected. However, in the present invention, the ultraviolet rays of a specific wavelength band And is not affected by internal noise.

In the switchboard, only the ultraviolet rays of a specific wavelength band using the UVC sensor 120 are detected in the wavelength band of the ultraviolet rays generated from sunlight or illumination lamps, so that the ultraviolet rays of the sunlight or the ultraviolet rays of the illumination lamps can be detected as arcs .

1, an arc flash detection system using an infrared (UV) and ultraviolet (UV) sensor according to the present invention includes an infrared sensor 110, a UVC sensor 120, a controller 130, a digital signal processor 140, a cut-off unit 150, an alarm / turn-on display unit 160, and a communication unit 170.

The infrared sensor 110 senses the surface temperature of the connection part of the device and outputs the connection part temperature signal. The infrared sensor 110 measures the surface temperature of the object using the characteristic that the infrared radiation energy emitted by the object changes with temperature. The infrared sensor 110 senses the temperature by reacting with infrared rays corresponding to a wavelength range of about 5 to 14 μm when an arc flash occurs.

The infrared sensor 110 converts the intensity of the infrared radiation energy into heat and measures the temperature of the object, converts the temperature change into an electronic signal, amplifies it, and then reads the temperature.

Since the infrared sensor 110 has an advantage of being able to measure the temperature of an object which is difficult to be in direct contact with the infrared sensor 110 in a non-contact state, the infrared sensor 110 has stability and does not need to wait until it becomes a thermal equilibrium state, Can speed up faster.

The infrared sensor 110 may be installed inside the control panel so that the sensing part of the infrared sensor 110 faces the connection part of the device. That is, the infrared sensor 110 is not directly attached to the connection portion of the device. For this purpose, the infrared sensor 110 is installed at a distance from the connecting portion of the infrared sensor 110 by an effective sensing distance of the infrared sensor 110.

The UVC sensor 120 detects ultraviolet rays in the 100 nm to 280 nm band by blocking ultraviolet light having a wavelength band of 280 nm to 400 nm by natural light or illumination light.

The UVC sensor 120 is preferably configured to block the ultraviolet wavelength band caused by natural light or illumination light.

For example, ultraviolet rays having a wavelength band of 280 nm to 400 nm are preferably blocked. Among natural light, ultraviolet rays generally in the band of 100 nm to 280 nm are generally absorbed in the ozone layer as ultraviolet rays in the UVC band. It can be considered that almost no ultraviolet ray in the range of 100 nm to 280 nm exists in the atmosphere.

When the control unit 130 is operated by the ultraviolet rays of natural light, it is possible to misjudge that an arc has occurred. Therefore, it is preferable that the natural light ultraviolet rays in the atmosphere are blocked from ultraviolet rays of 280 to 400 nm.

On the other hand, since the illumination lamp also emits ultraviolet rays of about 280 to 400 nm, the ultraviolet rays of the corresponding band are cut off, thereby reducing the number of false positives.

The control unit 130 detects the arc flash by receiving the ultraviolet ray detection signal of the 100 nm to 280 nm band specified by the UVC sensor 120 together with the temperature detection signal detected from the infrared ray sensor 110.

The control unit 130 includes a first amplifier 131 receiving a temperature detection signal detected from the infrared sensor 110 and amplifying and outputting the temperature detection signal, A second amplifier 132 receiving a detection signal and amplifying the amplified detection signal and outputting the amplified detection signal and a temperature detection signal and an ultraviolet detection signal amplified by the first and second amplifiers 131 and 132, The first and second signal converters 133 and 134 receive the temperature detection signal and the ultraviolet ray detection signal converted from the first and second signal converters 133 and 134, And an arc detection unit 135 for detecting the occurrence of the presence or absence of the occurrence of the abnormality.

The digital signal processor 140 receives the arc flash detection signal of the controller 130 and converts the pulse width into a constant pulse width to output the pulse signal as a digital signal.

The blocking unit 150 receives the arc flash detection signal output from the digital signal processing unit 140 with a predetermined pulse width, and outputs a trip signal to the breaker.

The alarm / on-off display unit 160 receives an arc flash detection signal output from the digital signal processing unit 140 with a predetermined pulse width, and generates an alarm sound or a lamp through the speaker to transmit the occurrence of the arc flash to the outside .

The communication unit 170 may be configured to transmit the occurrence information of the arc flash to the remote control terminal at a remote location by RS-485 method or RS-232 method. Other communication schemes may be used, but several different radio schemes for generating high frequencies may be unsuitable.

FIG. 2 is a graph showing ultraviolet ray detection in a general arc flash, and FIG. 3 is a graph showing response characteristics of a specific band by the UVC sensor in the ultraviolet ray of FIG.

As shown in FIG. 2, when an arc flash occurs, an ultraviolet ray region of the UVC region exists in the ultraviolet region, and ultraviolet rays having a wavelength band of 280 to 400 nm are blocked using a UVC sensor Ultraviolet rays in the wavelength band of nm to 280 nm are detected.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments or constructions. Can be carried out within a limited range. Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

110: Infrared sensor 120: UVC sensor
130: controller 140: digital signal processor
150: shutoff unit 160: alarm /
170:

Claims (3)

An infrared sensor for sensing a temperature from an arc flash generated inside the apparatus and outputting a temperature detection signal,
A UVC sensor for detecting an ultraviolet ray in a band of 100 nm to 280 nm by blocking ultraviolet rays having a wavelength band of 280 nm to 400 nm by natural light or illumination light from the arc flash,
A control unit for receiving an ultraviolet ray detection signal of a specific band from the UVC sensor together with a temperature detection signal detected by the infrared ray sensor and detecting an arc flash,
A digital signal processor for receiving the arc flash detection signal of the controller and converting the pulse width into a constant signal and outputting the signal as a digital signal;
A blocking unit for receiving an arc flash detection signal output from the digital signal processing unit with a predetermined pulse width and outputting a trip signal to the breaker;
An alarm / on-off display unit for receiving an arc flash detection signal output from the digital signal processing unit at a predetermined pulse width, generating an alarm sound through a speaker or emitting a lamp to transmit the occurrence of an arc flash to the outside,
And a communication unit for transmitting the occurrence information of the arc flash to the outside,
The control unit includes a first amplifier for receiving a temperature detection signal detected from the infrared sensor, amplifying and outputting the detected temperature signal, a second amplifier for receiving and outputting an ultraviolet detection signal of a specific band from the UVC sensor, A second signal converter for converting a temperature detected signal amplified from the first and second amplifiers and an ultraviolet ray detection signal into a digital signal and outputting the digital signal; And an arc detection unit for detecting the presence or absence of an arc flash by comparing the detected signal with a reference value, and detecting an arc flash by using an infrared ray and ultraviolet (UV) sensor. delete delete

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