KR102008472B1 - Real Time Remote Management and Alarm Call out System of Electrical Consumers Type based on IoT - Google Patents

Abstract

According to the present invention, a real-time remote management and alarm dispatch system for each electricity consumer based on IoT monitors, in real-time, a resistance leakage current, an overcurrent, an overvoltage, and the like, which are the main cause of an electrical accident through a sensor installed in a distribution panel board of each floor of a building, an electrical room distribution panel board and the like, and transmits electrical hazard element information to an integrated management center. The integrated management center converts the transmitted electrical hazard element information into big data so as to be shared with an on-site management center and analyzes a change trend of big data-formed electrical hazard element information so as to allow the on-site management center to instruct the terminal of the electrical safety manager to dispatch to the venue in which the electrical abnormality is found when the electrical abnormality is found. The present invention allows the electrical safety manager to rapidly take a diagnosis and recovery action for the electrical abnormality, thereby providing an effect capable of preventing an electrical accident in advance.

Description

Real Time Remote Management and Alarm Call out System of Electrical Consumers Type based on IoT}

The present invention relates to a real-time remote management and alarm dispatch system based on IoT consumer, more specifically resistive leakage current, overcurrent, overvoltage which is the main cause of the electric accident through sensors installed in the floor distribution panel and electrical room distribution panel of the building. Analyze the change trend by monitoring the lamp in real time, and predict the occurrence of an electric accident in advance if an electrical abnormality occurs, and visit the place where the electrical abnormality occurred through the electrical safety manager to diagnose and repair the electrical abnormality. It is about IoT-based real-time remote management and alarm dispatch system based on IoT consumer, which can prevent action by proactively taking action.

If power equipment such as cable, ground equipment, pole, manhole, junction box, handhole, standing shop, distribution box, transformer, switchgear, etc. is installed, it is necessary to check and manage the status of power equipment.

For example, determine how long each power plant can live in different environments, such as in salty coastal areas, corrosive gaseous and urban areas, and typhoon invasion areas where typhoons land each year. Power facility traceability systems are being used to research and manufacture longer lasting power plants.

At this time, the manager who manages the power equipment prepares the manufacturer, production date, installation date, demolition date, construction company, installation pole number, demolition pole number, etc. of each power facility and submits it to the supervisor of the construction department. The supervisor checks this and enters it directly into the utility's history management system to manage the life of each utility.

Power facilities such as distribution boards, distribution boards, motor control panels, emergency generators, etc., which are installed in building units such as schools or group residential facilities, or sub-region units, are scattered independently of each other in necessary areas. It requires a lot of manpower and money.

In particular, these power facilities are hazardous facilities that handle high or special high pressures, but they are not facilities that can be placed with regular managers. Therefore, they are generally used in narrow spaces in the basement to prevent safety accidents and improve efficiency of building spaces. Because of the installation, maintenance and management of most individual switchboard facilities is also very inconvenient.

In addition, since the generation and recording of a series of management information related to facility maintenance inspection, troubleshooting, and maintenance of current electric power facilities are collected at the central management center through individual managers, statistics on the overall management information and on-site situation Since the recognition requires a considerable time or due date, there is a disadvantage in that real-time management check is impossible.

In addition, the government currently regulates monthly inspection, quarterly inspection, and semi-annual inspection in accordance with the job notification of electrical safety managers, and provides safety management education and guidance training for employees.

In most cases, the distribution boards installed on site are visually checked and managed by the manager of the site.

Home appliances that are closely related to the general consumer with the development of IoT technology are converged with cloud-based ICT technology, but monitoring, diagnosis, and monitoring of power facilities such as distribution boards related to electrical safety management are not commercialized as cloud-based smart systems. I'm not doing it.

Republic of Korea Patent Registration No. 10-1601605

The present invention has been made to solve the above-mentioned problems, through the sensors installed in the floor distribution panel and electrical room distribution panel of the building to monitor in real time the resistance leakage current, overcurrent, overvoltage, etc. which are the main causes of the electrical accident, the electrical hazard information Is transmitted to the integrated management center, and the integrated management center converts the transmitted electrical risk information into big data so that it can be shared with the site management center. If signs are found, the site management center instructs the electrical safety manager's terminal to be dispatched to the site where the electrical abnormality has been found, so that the electrical safety manager can promptly diagnose and recover from the electrical failure. IoT-based electricity acceptance to prevent proactive Stars that will provide real-time remote management and alarm dispatch system.

IoT-based real-time remote management and alarm dispatch system according to the present invention for achieving the above object, the various sensors installed inside the electrical hazard information including resistive leakage current, overcurrent and overvoltage that causes an electrical accident Intelligent distribution panel for measuring in real time through the, and delivering the measured electrical risk information to the integrated management center; Accumulate big data while monitoring electrical risk information transmitted from intelligent distribution boards, analyze accumulated big data to determine whether an electrical abnormality occurs, and if an electrical abnormality is found, send an alarm signal to the field management center. When the alarm signal for the electrical abnormality signal is transmitted from the integrated management center and the integrated management center to deliver, it is configured to include a site management center instructing the terminal of the electrical safety manager to be dispatched to the place where the electrical abnormality occurred.

Big data accumulated in the integrated management center includes monitoring data including full monitoring information, detailed monitoring information, chart monitoring information, and status monitoring information, daily trend analysis information, 15 minute peak trend analysis information, monthly power trend analysis information, and alarms. Statistical data including signal generation history analysis information may be included.

If there is a safety guide for each control element according to the management guidelines of the intelligent distribution panel, the integrated management center judges whether there is an electrical abnormality indication based on the value according to the safety guideline, and if there is no safety guide for each control element. Based on the allowable range set by the user, the reference value may be corrected according to the cumulative analysis of the big data to determine whether an electrical abnormality is indicated.

The electrical safety manager may go to the place where the electrical abnormality occurs, diagnose and recover the cause of the electrical abnormality, and report the result to the integrated management center through the administrator terminal.

The integrated control center can communicate the results of the treatment of electrical abnormalities delivered to the electrical safety manager to the site control center for sharing.

According to the IoT-based real-time remote management and alarm dispatch system according to the present invention as described above, the resistance leakage current, overcurrent, overvoltage which is the main cause of the electrical accident through sensors installed in the floor distribution panel and electrical room distribution panel of the building Monitor real-time, etc. to transmit electrical risk information to the integrated management center, and the integrated management center converts the transmitted electrical risk information into big data so that it can be shared with the on-site management center. After analyzing the change of element information, if an electrical abnormality is found, the site management center instructs the terminal of the electrical safety manager to go to the place where the electrical abnormality is found, and diagnoses and recovers from the electrical abnormality through the electrical safety manager. Electrical accidents by allowing action to be taken quickly It is effective to prevent the.

1 is a block diagram showing a real-time remote management and alarm dispatch system for each IoT-based electricity consumer according to an embodiment of the present invention,
FIG. 2 is a block diagram illustrating an intelligent distribution board configuring an IoT-based real-time remote management and alarm dispatch system according to an embodiment of the present invention.
3 is a block diagram showing an analysis prediction board constituting an intelligent distribution board according to an embodiment of the present invention.
4 to 12 is an exemplary view showing a monitoring progress in the integrated management center constituting the intelligent distribution panel according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

IoT based real-time remote management and alarm dispatch system according to an embodiment of the present invention, as shown in Figure 1, intelligent distribution panel 100, integrated management center 300, field management center 500 and manager It is configured to include a terminal 700.

First, the intelligent distribution panel 100 may be installed in an industrial site including a fire fragile zone and a factory including a building, a temple, a market, a cultural property, and a hanok including a building, a shopping mall, a school, a public building and a lodging facility.

The intelligent distribution panel 100 installed in buildings such as buildings, apartments, schools, etc. can be monitored by installing intelligent distribution panels by floor, and the configuration of the intelligent distribution panel 100 in factories, such as plant facilities, by installing intelligent distribution panels by buildings. Surveillance can be made, the configuration of the intelligent distribution panel 100 in the traditional market can be monitored by installing a small intelligent distribution panel for each store, the intelligent distribution panel 100 of the camping site, camping ground, recreation forest, tourism farm, etc. The configuration can be monitored by installing individual intelligent distribution panels.

Through the intelligent distribution panel 100 according to the present invention, arc detection, overload protection, overcurrent blocking, electricity usage and trend monitoring, and electricity use status alerts, and the like, to monitor the intelligent distribution panel 100 in the integrated management center 300. When an abnormality is detected, an on-site management center (500) can be dispatched to the electric safety manager's manager terminal (700), and the electric safety manager visits the site where the intelligent distribution panel (100) is installed and checks the site. You can proceed with any abnormality.

Intelligent distribution board 100 is to separate power from load on RST and supply power to load individually. It monitors electricity usage status in real time, and information on electrical risk factors including resistive leakage current, overcurrent and overvoltage that causes electric accidents. When the fire risk is detected by the operation of the breaker, according to the monitoring result and the operation state of the breaker to transmit to the integrated management center 300 to prevent the disaster caused by electricity.

As shown in FIG. 2, the intelligent distribution panel 100 may be provided in an enclosure form, and may include a sensor circuit breaker 110 and an analysis prediction board 150.

The sensor circuit breaker 110 is connected to the input RST to detect in real time at least one abnormality such as arc, overvoltage, overcurrent, short circuit, temperature change of the wire, etc. in order to detect the occurrence of an electrical fire sign of various electrical equipment. The circuit includes a circuit for operating the ground fault detection and breaker, a circuit breaker state monitoring circuit, an arc detection sensor, an overcurrent detection sensor, a leakage current detection sensor, and the like.

Analysis prediction board 150 is a trend analysis through the prevention of electric fire by the arc, short circuit, over current and real-time electricity consumption monitoring, and by analyzing the collected current signal at high frequency, harmonics, effective value, zero delay and duration The arc detection is determined through the complex monitoring, and the operation of the circuit breaker built in the sensor circuit breaker 110 is controlled according to the determination result.

For reference, the overvoltage detection can detect the occurrence of overvoltage by comparing the difference between the input voltage and the output voltage of the transformers connected on the RST and the set voltage value, and the arc detection can detect the CT (Current) connected to the RST. Transformer) It is possible to detect whether an arc is generated by comparing the current flowing through the current sensor with the set arc current value.

The overcurrent detection compares the current flowing through the current sensor connected to the RST phase with the set overcurrent detection value to detect whether overcurrent has occurred, and the earth leakage detection is connected to the RST phase and branch circuit of the distribution panel. The occurrence of a short circuit may be detected by comparing a current flowing through the TransFormer sensor with a set short circuit detection value.

Temperature change detection uses thermistor element or temperature sensor IC to detect the temperature of the magnetic, earth leakage breaker (ELB) or busbar on the RST and compares the detected temperature with the temperature table of the thermistor element or temperature sensor IC. Can be detected.

As shown in FIG. 3, the analysis prediction board 150 includes a sensor input unit 151, an analysis prediction control unit 153, a display 155, a voice output unit 157, and a communication module unit 159. .

The sensor input unit 151 receives sensing values of the arc detection sensor, the overcurrent detection sensor, and the leakage current detection sensor provided in the sensor circuit breaker 110.

The display 155 may be provided in an LCD form, and includes a voltage, current, or power according to a sensing value input through the sensor input unit 151, and monitors alarm elements according to leakage current, arc, and overcurrent. Is displayed.

The voice output unit 157 may be provided in the form of a speaker, and the alarm element according to the leakage current, the arc, and the overcurrent according to the sensing value input through the sensor input unit 151 is displayed acoustically.

The communication module unit 159 may be provided as a wired / wireless communication means such as Zigbee, Lan, Wlan, 3G, 4G, RS485, and the like, and the voltage, current, or power according to the sensing value input through the sensor input unit 151. Including, the monitoring data according to the leakage current, arc and overcurrent is transmitted to the integrated management center (300).

The analysis prediction controller 153 includes a voltage, current, or power according to a sensing value input through the sensor input unit 151 so that an alarm element according to leakage current, arc, and overcurrent is visually displayed on the display 155. Control to be displayed or audibly displayed through the voice output unit 157, and monitoring according to leakage current, arc and overcurrent, including voltage, current or power according to a sensing value input through the sensor input unit 151. The data is controlled to be transmitted to the integrated management center 300 through the communication module unit 159.

The integrated management center 300 accumulates the big data while monitoring the electrical risk information transmitted from the intelligent distribution panel 100, and analyzes the accumulated big data to determine the occurrence of the electrical abnormality sign and discover the electrical abnormality sign. When the alarm signal is transmitted to the site management center (500).

The information for accumulating as big data in the integrated management center 300 includes monitoring data, detailed monitoring information, chart monitoring information, and status management monitoring information. As a statistical graph, trend analysis information, 15 minute peak trend information, Includes monthly electricity trend information.

Detailed monitoring information is as shown in Figure 4, integrated power amount, power capacity, contract power, target peak power, expected maximum peak power, power factor and R, S, T phase voltage, current, apparent power, active power, reactive power, Intelligent distribution panels include power factor, ITHD, VTHE, frequency, total power factor, aggregated power, today's (previous) power, current month's power, phase unbalance, and cumulative uptime.

Chart monitoring information includes a real-time power graph, a real-time phase current graph, a real-time phase voltage graph, a real-time power factor graph, as shown in FIG. 5.

As shown in FIG. 6, the state management monitoring information includes facility management monitoring information including an unbalance rate, an R.S.T phase input voltage, an R.S.T phase overcurrent, a leakage current, and an accumulated operating time.

As shown in FIGS. 7 to 10, a graph displaying daily power statistics information, daily power factor statistics information, daily imbalance statistics information, frequency statistics information, ITHD statistics information, and VTHD statistics information of the entire intelligent distribution panel is shown. Included.

As shown in FIG. 11, the 15 minute peak trend information includes a graph displaying peak and power factor trend information in units of 15 minutes on a specific day.

Monthly power amount trend information, as shown in Figure 12, includes a graph indicating the monthly power amount trend.

The integrated management center 300 determines whether there is an electrical abnormality indication based on the value according to the safety guideline when there is a safety guide for each control element according to the management guideline of the intelligent distribution panel 100.

However, if there is no safety guide for each management element, the reference value is corrected according to the cumulative analysis of the big data based on the allowable range set by the user to determine whether there are any electrical abnormalities.

The integrated management center 300 displays (not shown) information on whether or not an electrical abnormality occurs in the monitoring through the intelligent distribution panel 100 (not shown), and the site that manages the intelligent distribution panel 100 when the abnormality is detected. The control center 500 transmits an alarm signal indicating whether an electrical abnormality occurs.

Subsequently, when the control agent of the field management center 500 receives an alarm signal indicating whether an electrical abnormality occurs from the integrated management center 300, the control agent of the electrical safety manager located near the intelligent distribution panel 100 in which the electrical abnormality occurred. Immediately instructs the dispatcher to the manager terminal 700 to request to handle the electrical abnormality according to the site visit.

Subsequently, the electrical safety manager is dispatched to the intelligent distribution panel 100 where the electrical abnormality sign is generated, diagnoses and recovers the cause of the electrical abnormality sign, and then transfers the processing result to the integrated management center 300 through the manager terminal 700. report.

The integrated management center 300 transmits and shares the processing result of the electrical abnormality signal delivered to the electrical safety manager to the site management center 500.

Meanwhile, the intelligent distribution panel 100 analyzes the collected current signal to determine arc detection through complex monitoring of high frequency, harmonics, effective value, zero delay, and duration, and determines the detection of the arc in the sensor circuit breaker 110 according to the determination result. Control the operation of the built-in breaker.

That is, when the high pass filter is used, it detects a high frequency generation rate of a specific band, detects harmonic generation in the arc state occurring under the same condition as the normal state of supplying power to the load, and monitors the amount of change in the current effective value, Delays at zero crossings in the event of an arc accident are detected and the duration of the arc or spark is measured.

In addition, in order to determine the arc detection, the current waveform of the output current of the circuit can be acquired, and the waveform characteristic peculiar to the abnormality occurrence due to the arc detection can be extracted and analyzed.

Subsequently, when an electrical abnormal signal is detected by these detection elements, the analysis prediction board 150 processes the signal sent from the sensor circuit breaker 110 and compares it with a normal value previously stored in the memory unit. The judgment of the possibility is made.

At this time, an electrical abnormal signal must be detected at all of high frequency, harmonics, effective value, zero delay, and durations to determine the possibility of fire by arc detection.

Thus, if it is determined that there is a possible arc signal, the analysis prediction board 150 controls the alarm element to be displayed visually through the display 155 or to be displayed acoustically through the voice output unit 157, The arc detection signal is transmitted to the integrated management center 300 and at the same time by operating a breaker that can be controlled by itself to immediately cut off the electricity supply to the electric line to take active fire prevention measures.

In addition, the arc detection signal using the communication module unit 159 transmits the alarm signal to the integrated management center (300).

Subsequently, in the integrated management center 300 that received the arc detection signal from the analysis prediction board 150, the electric safety manager having the manager terminal 700 immediately through the field management center 500 to the intelligent distribution panel 100. Emergency dispatch can be instructed to direct the diagnosis and recovery of the track on which an arc has been detected.

Subsequently, the electric safety manager who receives the dispatch instruction from the field management center 500 closely diagnoses the electrical abnormality sign on the electric line and the intelligent distribution panel 100 where the arc signal is detected, and diagnoses and recovers the arc occurrence position. By reporting the result to the integrated management center 300 as a wired / wireless communication means, it is possible to prevent the risk of fire due to the arc generation, the integrated management center 300 to the field management center 500 the results of the treatment of the electrical safety manager. By reporting again, it is possible to prevent the occurrence of a fire due to the arc since the fire risk area according to the arc occurrence is detected in real time and active measures are taken to prevent the fire.

In addition, in the present invention, the overcurrent alarm can be performed step by step.

For example, one hour or two hours at 80% or more of the breaker capacity, or one minute longer than 10 mA or more, will give a primary alarm, 15 minutes to 30 minutes or more at 100% or more of the breaker capacity, or more than 15 mA. A 1 minute duration will trigger a secondary alarm, 10 minutes to 20 minutes above 120% of the breaker capacity, or a 1 minute duration above 20 mA to give a 3rd alarm, which will shut off the electrical By making the prediction that it is expected, it can be cut off from the less important load.

According to the IoT-based real-time remote management and alarm dispatch system according to the present invention as described above, the resistance leakage current, overcurrent, overvoltage which is the main cause of the electrical accident through sensors installed in the floor distribution panel and electrical room distribution panel of the building It monitors the lamp in real time and transmits electric risk information to the integrated management center.

Subsequently, the integrated management center converts the transmitted electrical risk information into big data so that it can be shared with the site management center.Self-diagnosis by real-time electrical quality analysis, electric fire prediction and real-time alarm by real-time monitoring, big Pre-fire ignition factors can be analyzed and predicted using data-processed information, and if an electrical abnormality is detected by analyzing the change of big data-formed electrical hazard information, the site management center is connected to the terminal of the electrical safety manager. By directing the dispatch to the place where the signs are found, it is possible to prevent the electrical accident in advance by enabling the electrical safety manager to promptly diagnose and repair the electrical abnormality.

In the above description, the present invention has been described with reference to preferred embodiments, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains does not depart from the technical spirit of the present invention. It will be readily appreciated that various substitutions, modifications and variations can be made.

100: intelligent distribution board 110: sensor circuit breaker
150: analysis prediction board 153: analysis prediction control unit
300: central management server 500: administrator terminal
700: remote integrated server

Claims (5)

Intelligent distribution boards that measure electrical risk information including resistive leakage current, overcurrent and overvoltage that cause electric accidents in real time through various sensors installed therein, and transmit the measured electrical risk information to the integrated management center; Accumulate big data while monitoring electrical risk information transmitted from intelligent distribution boards, analyze accumulated big data to determine whether an electrical abnormality occurs, and if an electrical abnormality is found, send an alarm signal to the field management center. Integrated management center to deliver; And a field management center instructing the terminal of the electrical safety manager to go to the place where the electrical abnormality occurred when an alarm signal for the electrical abnormality is transmitted from the integrated management center.
Big data accumulated in the integrated management center includes monitoring data including full monitoring information, detailed monitoring information, chart monitoring information, and status monitoring information, daily trend analysis information, 15 minute peak trend analysis information, monthly power trend analysis information, and alarms. Statistical data including signal generation history analysis information is included;
Detailed monitoring information includes integrated power, power capacity, contracted power, target peak power, expected maximum peak power, power factor and R, S, T phase voltage, current, apparent power, active power, reactive power, power factor, ITHD, VTHE, frequency Total power factor, total power, current (previous) power, current monthly power, phase imbalance, cumulative operating time; The chart monitoring information includes a real time power graph, a real time phase current graph, a real time phase voltage graph, a real time power factor graph; The status management monitoring information includes facility management monitoring information including an unbalance rate, an RST phase input voltage, an RST phase overcurrent, a leakage current, and a cumulative operating time; The trend analysis information includes graphs displaying daily power statistics information, daily power factor statistics information, daily phase imbalance statistics information, frequency statistics information, ITHD statistics information, and VTHD statistics information of the entire intelligent distribution panel; 15 minute peak trend information includes a graph displaying peak and power factor trend information in units of 15 minutes on a specific day; Monthly power amount trend information includes a graph indicating the monthly power amount trend;
If there is a safety guide for each control element according to the management guidelines of the intelligent distribution panel, the integrated management center judges whether there is an electrical abnormality indication based on the value according to the safety guideline, and if there is no safety guide for each control element. Correcting the reference value according to the cumulative analysis of the big data on the basis of the allowable range set by the processor to determine whether there is an electrical abnormality sign; The integrated management center displays information on the occurrence or absence of electrical abnormalities in the monitoring through the intelligent distribution panel, and when an abnormality is detected, it sends an alarm signal on the occurrence of electrical abnormalities to the on-site management center in charge of the intelligent distribution panel. IoT based electric customer real-time remote management and alarm dispatch system, characterized in that. delete delete The IoT according to claim 1, wherein the electrical safety manager dispatches to the place where the electrical abnormality sign occurs, diagnoses and recovers the cause of the electrical abnormality sign, and reports the processing result to the integrated management center through the manager terminal. Real-time remote management and alarm dispatch system based on electricity consumer. delete

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