KR20240011312A - Distribution board for abnormal sign monitoring using reference values - Google Patents

Abstract

The present invention includes an enclosure, a sensor unit installed in the enclosure, and a control unit that monitors abnormal signs by comparing the sensor value of the sensor unit with a reference value, wherein the sensor unit compares a first sensor and a relative reference value for comparison with an absolute reference value. A second sensor is provided for comparison, and the control unit discloses a distribution board for monitoring abnormal signs using a reference value, characterized in that it monitors abnormal signs using both absolute and relative reference values.

Description

Distribution board for monitoring abnormal signs using reference values {DISTRIBUTION BOARD FOR ABNORMAL SIGN MONITORING USING REFERENCE VALUES}

The present invention relates to a switchboard for monitoring abnormal signs using reference values. More specifically, it relates to a switchboard that monitors abnormal signs using both absolute and relative reference values.

In the past, sensors may operate inaccurately due to the influence of temperature and humidity, and signals emitted from the sensor may be affected by temperature and humidity, resulting in sensor data errors. Therefore, calibration technology is needed through error correction or initial value change.

In the past, as in patent documents described as prior art, changes in temperature and humidity may occur due to the operation of the air conditioner, so the initial value was frequently reset and calibrated. However, in the past, there is a problem in that only facilities with air conditioners are considered, and electrical facilities that are less related to the operation of air conditioners are not considered. In addition, in the past, calibration was performed through frequent changes to initial values, causing a problem in that the efficiency of the system was reduced.

Electrical facilities, such as switchboards, may experience gradual temperature changes due to seasonal effects compared to air conditioners. Therefore, in the past, there is a lack of monitoring technology through relative reference values that can reduce frequent calibration and adapt to seasonal influences. Additionally, in the past, there is a lack of technology to improve monitoring accuracy by combining sensors capable of applying relative reference values and sensors capable of applying absolute reference values.

Korean Patent Publication No. 10-2013-0074437

In order to solve the above problem, the present invention provides a switchboard for monitoring abnormal signs using a reference value that monitors abnormal signs using both absolute and relative reference values.

A switchboard for monitoring abnormal symptoms using a reference value according to an embodiment of the present invention for the above problem to be solved includes an enclosure (100); It includes a sensor unit 600 installed in the enclosure and a control unit 900 that monitors abnormal signs by comparing the sensor value of the sensor unit with a reference value, and the sensor unit includes a first sensor and a relative reference value for comparison with an absolute reference value. A second sensor is provided for comparison, and the control unit monitors abnormalities using both absolute and relative reference values.

A switchboard for monitoring abnormal signs using a reference value according to another embodiment of the present invention includes an enclosure; It includes a sensor unit installed in the enclosure and a control unit that monitors abnormal signs by comparing sensor data of the sensor unit with a reference value, wherein the control unit compares the sensor value at a specific point in time with an absolute reference value, and compares the fluctuation range and relative value of the sensor value over time. It is characterized by comparing reference values and monitoring abnormal signs by using both absolute and relative reference values.

A switchboard for monitoring abnormal signs using a reference value according to another embodiment of the present invention includes an enclosure; A sensor unit installed in the enclosure and a control unit that monitors abnormal signs by comparing sensor data of the sensor unit with a standard value, wherein the sensor unit includes a sound field sensor 700, and the control unit includes a sound field value for each time detected by the sound field sensor. It is characterized by monitoring abnormal signs by comparing the fluctuation range and relative standard value.

The present invention monitors abnormal signs using both absolute and relative reference values, thereby minimizing calibration through changing the initial value, and monitoring accuracy by combining a sensor capable of applying a relative reference value and a sensor capable of applying an absolute reference value. can be improved.

Figure 1 shows a switchboard according to an embodiment of the present invention.
FIG. 2 is a block diagram showing the sensor unit of FIG. 1 in detail.
Figure 3 is a block diagram showing the sound field sensor of Figure 2 in detail.
Figure 4 is a block diagram showing the sound wave generating means of Figure 3 in detail.
Figure 5 shows a switchboard according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present invention is not limited or limited by the embodiments.

Figure 1 shows a switchboard according to an embodiment of the present invention. The switchboard 10 has the function of receiving high-voltage electricity, converting it to low voltage, and distributing the electricity to where it is needed.

The switchboard 10 may include a high-voltage panel, a low-voltage panel, a motor control panel, and a distribution board. The present invention can apply the switchboard 10 to various electrical facilities that process electricity, but is not limited to this.

The switchboard 10 includes at least one of an enclosure 100, a partition wall 200, an opening and closing means 300, an operation panel 400, an equipment 500, a sensor unit 600, and a control unit 900.

The enclosure 100 is composed of a first compartment 110 and a second compartment 120, and the partition wall 200 is used to separate the first compartment 110 and the second compartment 120. The opening and closing means 300 is formed for each compartment.

The operation panel 400 may include parts related to receiving and distributing electricity, and the equipment 500 may include various power equipment such as a busbar (busbar) such as a conductor or a circuit breaker. The switchboard 10 may include a plurality of enclosures 100, and equipment 500 installed in each enclosure may be different.

The operation panel 400 or the facility 500 may include insulators such as wires, tubes, terminal blocks, PCBs, and electronic components such as diodes.

FIG. 2 is a block diagram illustrating the sensor unit of FIG. 1 in detail. The sensor unit 600 detects the state inside the enclosure. The sensor unit 600 may include a gas sensor 800 that detects gas generated during thermal decomposition of an insulator or display material, and may include various sensors that detect temperature and humidity or current. The sensor unit 600 may further include a sound field sensor 700 for monitoring intrusions, abnormal signs of equipment, or fire. Here, abnormal signs may mean an intrusion, an abnormality in equipment, a fire sign, or a fire.

Figure 3 is a block diagram showing the sound field sensor of Figure 2 in detail. The sound field sensor 700 includes a sound wave generating means 710 for generating sound waves in response to the first compartment 110 and the second compartment 120, and It may include sound wave receiving means 720 for receiving sound waves diffracted or reflected inside the enclosure 100.

Figure 4 is a block diagram showing the sound wave generating means of Figure 3 in detail, and the sound wave generating means 710 is provided in a sound wave generating unit 711 that generates sound waves, and a first compartment 110 and a second compartment 120. Correspondingly, it may include a sound wave output unit 712 that provides multiple output paths for sound waves.

The sensor unit 600 may include a first sensor for comparison with an absolute reference value and a second sensor for comparison with a relative reference value. The first sensor may typically be a gas sensor 800, and the second sensor may typically be a sound field sensor 700. The first sensor or the second sensor may be a gas sensor 800 or a sound field sensor 700 depending on the purpose such as intrusion, abnormality sign, fire sign, or fire monitoring.

Figure 5 shows a switchboard according to another embodiment of the present invention. The enclosure 100 may be comprised of a plurality, and the sensor unit 600 may be installed in each enclosure. Among the plurality of enclosures, some of the enclosures are main enclosures in which the sensor unit 600 and the control unit 900 are installed together, and in some other enclosures, only the sensor unit 600 is installed.

The control unit 900 may receive sensor data for each enclosure through a communication means (not shown) or a sensor network between the sensor units 600. The control unit 900 can determine abnormal signs in a specific enclosure by comparing sensor data for each enclosure.

The control unit 900 can set an absolute standard value or a relative standard value for each enclosure to monitor abnormal signs by considering the equipment 500 installed inside each enclosure, the environment in which the enclosure is located, and seasonal influences.

An absolute standard value refers to an absolute amount or level without a relative concept, and a relative standard value refers to a ratio or change between relative values, such as the maximum and minimum.

The switchboard 10 may have different equipment 500 installed for each enclosure, and a specific enclosure in which specific equipment such as a transformer or circuit breaker is installed may have a higher internal temperature than other enclosures. However, in the related art, the internal characteristics of each enclosure are not considered, the same absolute standard value is applied, and sensor data is compared to monitor multiple enclosures, which causes a problem in that detection or monitoring reliability is reduced.

Therefore, the present invention can set an absolute standard value or a relative standard value for each enclosure by considering the internal characteristics of each enclosure. For example, the present invention sets absolute reference values for temperature and humidity or sets relative reference values for sound fields. Gas concentration can be applied as an absolute standard value or a relative standard value.

Conventionally, the average temperature of the surveillance area was detected using the sound field spectrum, but the reliability was very low because the absolute standard value for the average temperature was applied without reflecting the internal characteristics of each enclosure, and calibration by changing the initial value was required to take reliability into account. It was carried out. However, the present invention can set a relative reference value by considering the internal characteristics of each enclosure, and does not require calibration by comparing the variation range of the sound field spectrum and the relative reference value.

The present invention can further improve the monitoring accuracy for abnormal signs by comparing the sensor value at a specific point in time with the absolute reference value, and by comparing the fluctuation range of the sensor value by time and the relative reference value. At this time, the sensor value of a specific sensor can be used together to compare absolute and relative reference values.

The control unit 900 can monitor abnormal signs by comparing the fluctuation range of the sound field value over time detected by the sound field sensor 700 with a relative reference value. The control unit 900 can determine abnormal signs in a specific enclosure by comparing sound waves received for each enclosure.

10: switchboard 100: enclosure
110: first compartment 120: second compartment
200: Bulkhead 300: Opening and closing means
310: first opening and closing means 320: second opening and closing means
400: Control panel 500: Equipment
600: Sensor unit 700: Sound field sensor
710: Sound wave generating means 711: Sound wave generating unit
712: Sound wave output unit 720: Sound wave receiving means
800: Gas sensor 900: Control unit

Claims (3)

enclosure (100);
A sensor unit 600 installed in the enclosure and
It includes a control unit 900 that monitors abnormal signs by comparing the sensor value of the sensor unit with a reference value,
The sensor unit is provided with a first sensor for comparison with an absolute reference value and a second sensor for comparison with a relative reference value,
A switchboard for monitoring abnormal signs using reference values, wherein the control unit monitors abnormal symptoms using both absolute and relative reference values. enclosure;
A sensor unit installed in the enclosure and
It includes a control unit that monitors abnormal signs by comparing the sensor data of the sensor unit with a reference value,
The control unit compares the sensor value at a specific point in time with the absolute reference value, compares the fluctuation range of the sensor value over time and the relative reference value, and monitors abnormal signs by using both the absolute reference value and the relative reference value. Switchboard for monitoring signs. enclosure;
A sensor unit installed in the enclosure and
It includes a control unit that monitors abnormal signs by comparing the sensor data of the sensor unit with a reference value,
The sensor unit includes a sound field sensor 700,
A distribution board for monitoring abnormal signs using a reference value, wherein the control unit monitors abnormal signs by comparing the fluctuation range of the sound field value over time detected by the sound field sensor with a relative reference value.