KR101996028B1 - Power outage monitoring system and method of operating the same - Google Patents

Abstract

The power failure monitoring system according to an embodiment of the present invention includes an electric sensor connected to a configuration module of the facility, a humidity sensor connected to the configuration module, a temperature sensor connected to the configuration module, and a power failure message corresponding to the power failure level A humidity sensor, and a temperature measurement value through the electrical sensor, the humidity sensor, and the temperature sensor, and acquires the electrical characteristic measurement value, the humidity measurement value, and the temperature And a processor for determining the power failure level of the configuration module based on the comparison of the measured value with the electrical characteristic reference range, the humidity reference range, and the temperature reference range.

Description

[0001] POWER OUTAGE MONITORING SYSTEM AND METHOD OF OPERATING THE SAME [0002]

The present invention relates to an electrostatic monitoring system and an operation method thereof, and more particularly, to an electrostatic monitoring system which determines an electrostatic level based on sensed data acquired through a sensor and provides electrostatic data corresponding to the electrostatic level, .

The integrated management system of buildings is aimed at security, safety, etc. As the technology develops, the objects and monitoring items are being expanded.

Conventional building integrated management system not only reports the power failure through monitor, but also restricts access to information related to power outage, and has a problem that it is easy to miss the time to take appropriate measures related to power outage.

In particular, there is an increasing need to more efficiently and appropriately monitor the power failures of each of the facilities installed in a building to reduce data loss or catastrophic risks.

An object of the present invention is to provide an electrostatic surveillance technique for generating different electrostatic data according to an electrostatic level.

The power failure monitoring system according to an embodiment of the present invention includes an electric sensor connected to a configuration module of the facility, a humidity sensor connected to the configuration module, a temperature sensor connected to the configuration module, and a power failure message corresponding to the power failure level A humidity sensor, and a temperature measurement value through the electrical sensor, the humidity sensor, and the temperature sensor, and acquires the electrical characteristic measurement value, the humidity measurement value, and the temperature And a processor for determining the power failure level of the configuration module based on the comparison of the measured value with the electrical characteristic reference range, the humidity reference range, and the temperature reference range.

In this embodiment, the processor sets priorities of the electric sensor, the humidity sensor, and the temperature sensor, and when the measured value obtained through the first rank sensor is out of the reference range, And determines the power failure level as a middle water level when the measured value obtained through the second rank sensor is out of the reference range, and if the measured value obtained through the third rank sensor is out of the reference range, The level can be determined as the lowest level.

In this embodiment, the communication module receives a user input from the user terminal, and the processor can set priorities of the electric sensor, the humidity sensor, and the temperature sensor based on the user input.

In this embodiment, the processor is configured to obtain a humidity measurement value and a temperature measurement value through the humidity sensor and the temperature sensor for a predetermined period of time, calculate the number of measurement values out of the reference range, The priority of the humidity sensor and the temperature sensor can be set based on the number of times of the value.

In this embodiment, the processor includes a power failure notification in the power failure message corresponding to the highest power failure level, includes an power failure warning in the power failure message corresponding to the intermediate power failure level, You can include caution notifications.

In the present embodiment, it further comprises an alarm module for outputting at least one of a light and a sound warning a power failure, and a control module for determining whether the configuration module is operating, Wherein the control module drives at least one of the alarm module and the control module, the processor drives the communication module at the lowest interruption level, drives the alarm module at the intermediate interruption level, and drives the control module at the highest interruption level .

A method of operating an electrostatic-surveillance system according to an embodiment of the present invention includes the steps of obtaining an electrical characteristic measurement value by an electrical sensor connected to a component module of the facility, measuring a humidity measurement value by a humidity sensor connected to the component module Acquiring a temperature measurement value by a temperature sensor connected to the configuration module; determining, by the processor, the electrical characteristic measurement value, the humidity measurement value, and the temperature measurement value as an electrical characteristic reference range, Range, and temperature reference range, determining, by the processor, the power failure level of the configuration module based on the comparison result, and determining, by the communication module, the power failure level corresponding to the power failure level To the mobile station.

In the present embodiment, setting the priorities of the electric sensor, the humidity sensor and the temperature sensor by the processor allows the processor to determine whether the measured value obtained through the first rank sensor is within the reference range Determining, by the processor, the power failure level to be a medium water level if the measured value obtained via the second order sensor is out of the reference range; Determining the lowest level of the power failure level when the measured value obtained through the third rank sensor is out of the reference range.

In the present embodiment, the step of setting the priority comprises: receiving, by the communication module, a user input from the user terminal; and, by the processor, determining, based on the user input, And setting the priority of the temperature sensor.

In the present embodiment, the step of setting the priority includes: acquiring a humidity measurement value for a predetermined period by the humidity sensor; acquiring a temperature measurement value for the predetermined period by the temperature sensor; Calculating a number of measurements out of the reference range by the processor and setting a priority of the humidity sensor and the temperature sensor based on the number of measurements out of the reference range by the processor .

In the present embodiment, the power failure message corresponding to the highest power failure level includes the power failure occurrence notification, the power failure message corresponding to the intermediate power failure level includes the power failure warning notice, and the power failure message corresponding to the lowest power failure level, .

In this embodiment, the method further comprises, by the processor, driving at least one of the communication module, the alert module, and the control module based on the power failure level, wherein the step of transmitting the power failure message comprises: Outputting at least one of a light and a sound warning the power failure by the alarm module corresponding to the intermediate power interruption level, And stopping the operation of the configuration module by the control module.

In addition, other systems for implementing the invention, other methods, and computer programs for carrying out the methods may be further provided.

Other aspects, features, and advantages will become apparent from the following drawings, claims, and detailed description of the invention.

According to the embodiments of the present invention, it is possible to provide a more effective electrostatic surveillance technique by providing different electrostatic data according to the electrostatic level.

Further, by setting a reference range or priority based on user input, it is possible to provide an electrostatic surveillance technique more suitable for user needs.

In addition, by setting the reference range or priority based on the measured value, it is possible to provide an electrostatic surveillance technique more suitable for the environment.

In addition, since the access to the power failure data is relaxed, it is possible to take an action related to the power failure at an appropriate time, thereby providing an economical and stable power failure monitoring technique.

1 is a block diagram of a power failure monitoring system according to an embodiment.
2 is a flowchart illustrating an operation method of the power failure monitoring system according to an embodiment.
3 is a flow diagram illustrating a method for providing power failure data corresponding to a power failure level according to one embodiment.
Figures 4 and 5 are flow charts illustrating a method of setting priorities between sensors according to an embodiment, respectively.

Brief Description of the Drawings The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described in conjunction with the accompanying drawings. It should be understood, however, that the present invention is not limited to the embodiments set forth herein, but may be embodied in many different forms and includes all conversions, equivalents, and alternatives falling within the spirit and scope of the present invention . BRIEF DESCRIPTION OF THE DRAWINGS The above and other aspects of the present invention will become more apparent by describing in detail preferred embodiments thereof with reference to the attached drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

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. The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

In this specification, "communication", "communication network", "Internet network" and "network" may be used in the same sense. The terms refer to wired and wireless local and wide area data transmission and reception networks capable of transmitting and receiving a file between a user terminal, a terminal of other users, and a download server.

In the present specification, when one component 'transmits' data to another component, the component may transmit the data directly to the other component, or may transmit the data through at least one other component To the other component.

In this specification, the term 'module' may mean a functional and structural combination of hardware for carrying out the technical idea of the present invention and software for driving the hardware. For example, the 'module' may mean a logical unit of a predetermined code and a hardware resource for the predetermined code to be executed, and may be a code physically connected to the module, or a kind of hardware Or may be easily deduced to the average expert in the field of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. .

1 is a block diagram of an electrostatic surveillance system 100 according to an embodiment.

Referring to FIG. 1, the electrostatic surveillance system 100 includes a sensing module 110, a processor 120, a communication module 130, an alarm module 140, and a control module 150.

The electrostatic-surveillance monitoring system 100 may be connected to the facility 10 installed in the building to determine whether the facility 10 is in a power failure state, and to transmit information on the power-failure risk to the user in various manners.

The power failure monitoring system 100 can determine whether or not the configuration module 11 included in the facility 10 has failed. At this time, the electrostatic-surveillance system 100 may acquire sensed data through the sensing module 110 connected to the configuration module 11, and determine the electrostatic level based on the sensed data.

The power outage level can be divided according to the degree of power outage risk. The greater the degree of risk of blackout, the greater the level of blackout. The information about the power failure risk provided to the user by the power failure monitoring system 100 may be changed or added according to the power failure level.

The degree of the blackout risk can be determined according to the type and / or the number of the sensors that detect the blackout risk.

The power failure monitoring system 100 can generate different power failure messages according to the power failure level. The power failure message may include building identification information, facility identification information, configuration module identification information, power failure risk notification, and the like. The building identification information is information indicating a building where the facility 10 is installed, the facility identification information is information indicating the facility 10, and the configuration module identification information is information indicating the configuration module 11 included in the facility 10 . The power outage risk alert may include information indicating the degree of power outage risk, information describing countermeasures to protect the configuration module from power outage risk, and the like.

The power failure monitoring system 100 may transmit a power failure message to the user terminal 20 according to the power failure level, output a light and / or a sound warning the power failure, or stop the operation of the configuration module 11. [

The sensing module 110 is connected to the configuration module 11 of the facility 10. The sensing module 110 may generate monitoring data for the connected configuration module 11 and may transmit the monitoring data to the processor 120. [

The sensing module 110 may include an electrical sensor 111, a humidity sensor 112, and a temperature sensor 113. The electrical sensor 111 may sense the electrical characteristics of the configuration module 11 to produce an electrical characteristic measurement. The electric sensor 111 may mean a current sensor, a voltage sensor, or the like. The humidity sensor 112 may sense the humidity of the space in which the configuration module 11 resides to generate humidity measurements. The temperature sensor 113 may sense the temperature of the space where the configuration module 11 is present to generate a temperature measurement value.

The processor 120 obtains the measured value through the sensing module 110 and determines the power failure level of the configuration module 11 based on the result of comparing the measured value with the reference range.

For example, the processor 120 may obtain electrical characteristic measurements, humidity measurements, and temperature measurements via the electrical sensor 111, the humidity sensor 112, and the temperature sensor 113, The humidity measurement value, and the temperature measurement value with the electrical characteristic reference range, the humidity reference range, and the temperature reference range.

Electrical characteristics refer to the characteristics of electric charges such as current, voltage, resistance, and capacitance. Hereinafter, the electric current and voltage will be described in detail. The following description of current and voltage can also be applied to other electrical characteristics.

The electric characteristic measurement value may be a current measurement value, a voltage measurement value, and the like.

The electrical characteristic reference range may be a current reference range, a voltage reference range, or the like.

The electrical characteristic reference range may be any range except 0. At this time, the processor 120 may determine that the electrical characteristic measurement value of 0 is out of the electrical characteristic reference range, and that the non-zero electrical characteristic measurement value is included in the electrical characteristic reference range.

For example, the current reference range may be an amount of current other than zero. At this time, the processor 120 may determine that the current measurement value of 0 is out of the current reference range, and that the non-zero current measurement value is included in the current reference range.

For example, the voltage reference range may be a voltage magnitude other than zero. At this time, the processor 120 may determine that the voltage measurement value of 0 is outside the voltage reference range, and that the non-zero voltage measurement value is included in the voltage reference range.

The electrical characteristic reference range may be more than the minimum value. At this time, the processor 120 may determine that the electrical characteristic measurement value that is less than the minimum value is out of the electrical characteristic reference range, and that the electrical characteristic measurement value that is the minimum value or more is included in the electrical characteristic reference range.

For example, the current reference range may be greater than the minimum current. At this time, the processor 120 may determine that the current measurement value less than the minimum current amount is out of the current reference range, and that the current measurement value of the minimum current amount or more is included in the current reference range.

For example, the voltage reference range may be greater than the minimum voltage magnitude. At this time, the processor 120 may determine that the voltage measurement value that is less than the minimum voltage level is out of the voltage reference range, and that the voltage measurement value that is the minimum voltage level is included in the voltage reference range.

The humidity reference range may include a minimum humidity and a maximum humidity. At this time, the processor 120 may determine that the humidity measurement value that is less than the minimum humidity or the maximum humidity exceeds the humidity reference range, and that the humidity measurement value between the minimum humidity and the maximum humidity is included in the humidity reference range .

The temperature reference range may include a minimum temperature and a maximum temperature. At this time, the processor 120 may determine that the temperature measurement value below the minimum temperature or the maximum temperature exceeds the temperature reference range, and that the temperature measurement value between the minimum temperature and the maximum temperature is included in the temperature reference range .

The processor 120 is configured to determine a current reference range, a voltage reference range, a humidity reference range, and a temperature reference based on a user input that selects at least one of a minimum current magnitude, a minimum voltage magnitude, a minimum humidity and a maximum humidity, The range can be determined.

The processor 120 obtains the electrical characteristic measurement value, the humidity measurement value, and the temperature measurement value through the electrical sensor 111, the humidity sensor 112, and the temperature sensor 113, And an electrical characteristic reference range, a humidity reference range, and a temperature reference range based on a user input that selects normal or blackout for the temperature measurement value.

For example, the processor 120 may be configured to obtain a current measurement through the electrical sensor 111 for a predetermined period of time and to determine a current reference based on a user input that selects normal or blackout for the current measurement, Range can be learned.

For example, the processor 120 may be configured to obtain a voltage measurement via the electrical sensor 111 for a predetermined period of time, and to determine a voltage The reference range can be learned.

For example, the processor 120 may include a minimum humidity and a maximum humidity based on a user input to obtain a humidity measurement through the humidity sensor 112 for a predetermined period of time and to select a normal or a blackout for the humidity measurement value The humidity reference range can be learned.

For example, the processor 120 may obtain a temperature measurement via the temperature sensor 113 for a predetermined period of time and may include a minimum temperature and a maximum temperature based on a user input that selects normal or blackout for the temperature measurement value. Can be learned.

The processor 120 sets priorities of the electrical sensor 111, the humidity sensor 112 and the temperature sensor 113 and sets the power failure level when the measured value obtained through the first rank sensor is out of the reference range And determines the level of the power failure as a middle level when the measured value obtained through the second rank sensor is out of the reference range, and if the measured value obtained through the third rank sensor is out of the reference range, The level can be determined as the lowest level.

For example, the processor 120 may set the electrical sensor 111 in a first order, the humidity sensor 112 in a second order, and the temperature sensor 113 in a third order. At this time, the processor 120 can determine the electrostatic level as the maximum water level when the measured current value obtained through the electric sensor 111 is out of the current reference range. The processor 120 determines that the current measurement value obtained through the electric sensor 111 is included in the current reference range and the humidity measurement value obtained through the humidity sensor 112 is out of the humidity reference range, You can decide. The processor 120 determines that the current measurement value obtained through the electric sensor 111 is included in the current reference range and the humidity measurement value obtained through the humidity sensor 112 is included in the humidity reference range, It is possible to determine the power failure level as the minimum water level when the temperature measurement value obtained through the temperature measurement range is out of the temperature reference range.

For example, the processor 120 may set the electrical sensor 111 in a first order, the humidity sensor 112 in a second order, and the temperature sensor 113 in a third order. At this time, the processor 120 may determine the electrostatic level as the highest level when the voltage measurement value obtained through the electrical sensor 111 is out of the voltage reference range. The processor 120 determines that the voltage measurement value obtained through the electric sensor 111 is included in the voltage reference range and the humidity measurement value obtained through the humidity sensor 112 is out of the humidity reference range, You can decide. The processor 120 determines that the voltage measurement value obtained through the electrical sensor 111 is included in the voltage reference range and the humidity measurement value obtained through the humidity sensor 112 is included in the humidity reference range, It is possible to determine the power failure level as the minimum water level when the temperature measurement value obtained through the temperature measurement range is out of the temperature reference range.

The processor 120 may set the priorities of the electric sensor 111, the humidity sensor 112, and the temperature sensor 113 based on the user input received from the user terminal 20. [

For example, if the user terminal 20 receives a user input that selects the electrical sensor 111 as the first order, the humidity sensor 112 as the second order, and the temperature sensor 113 as the third order, Upon transmission to the surveillance system 100, the processor 120 sets the electric sensor 111 to the first rank, the humidity sensor 112 to the second rank, and the temperature sensor 113 to the third rank based on the user input .

On the other hand, the processor 120 obtains the humidity measurement value and the temperature measurement value through the humidity sensor 112 and the temperature sensor 113 for a predetermined period, calculates the number of measurement values out of the reference range, The priorities of the humidity sensor 112 and the temperature sensor 113 can be set based on the number of times of the measurement values deviating from each other.

For example, the processor 120 may obtain a humidity measurement value and a temperature measurement value via the humidity sensor 112 and the temperature sensor 113 for a predetermined period of time, and determine whether the number of humidity measurement values that deviate from the humidity reference range exceeds a temperature reference It is possible to set the order of the humidity sensor 112 to be higher than the order of the temperature sensor 113. In this case,

The processor 120 may periodically reset the priorities of the electrical sensor 111, the humidity sensor 112, and the temperature sensor 113. The processor 120 can learn the priorities of the electric sensor 111, the humidity sensor 112, and the temperature sensor 113 through a priority reset for a predetermined period.

The processor 120 may generate different power failure messages according to the power failure level. At this time, the power failure message corresponding to the highest power failure level includes the power failure notification, the power failure message corresponding to the intermediate power failure level includes the power failure alert, and the power failure message corresponding to the lowest power failure level have.

The power failure alert message may be a power failure message including a power failure notification, the power failure alert message may be a power failure message including an power failure alert message, and the power failure warning message may be a power failure message including a power failure warning.

The power failure alert message, the power failure alert message, and the power failure alert message may be transmitted in a push form, but are not limited thereto.

Power failure alert messages can be sent more than once. The power failure alert message may be transmitted every predetermined cycle.

The power failure alert message can be transmitted more than once. The power failure alert message may be transmitted every predetermined cycle. Power outage alert messages can be sent more often than power outage alert messages.

The outage alert message can be transmitted more than once. The power failure notification message may be transmitted every predetermined cycle. The outage alert message can be transmitted more frequently than the outage alert message and / or the outage alert message. The power failure notification message can be periodically transmitted until the power failure state is corrected to a normal state.

The power failure message may be determined according to the user input received through the user terminal 20. The power failure message may be limited in transmission depending on the user input, or may be transmitted irrespective of user input, depending on the type of notification. For example, the power failure alert message and the power failure alert message may be limited in transmission according to user input, but the power failure alert message may be transmitted regardless of user input, but is not limited thereto.

The processor 120 may drive at least one of the communication module 130, the alert module 140, and the control module 150 based on the power failure level. For example, the processor 120 may drive the communication module 130 at the lowest power interruption level, drive the alert module 140 at the intermediate power interruption level, and drive the control module 150 at the highest power interruption level. That is, the processor 120 transmits a power failure message including a power failure warning to the user terminal 20 in response to the lowest power failure level, and outputs at least one of a light and a sound warning the power failure in response to the intermediate power failure level , The operation of the configuration module 11 can be stopped in response to the highest power failure level.

The communication module 130 and the alarm module 140 operate together at the lowest power interruption level while the communication module 130 and the alarm module 140 operate at the highest power interruption level. And the control module 150 may all operate.

The communication module 130 performs communication with the user terminal 20. The communication module 130 may send a power failure message corresponding to the power failure level to the user terminal 20 and receive user input from the user terminal 20. [

The communication module 130 may determine whether to transmit the power failure message according to the user input received through the user terminal 20. [ At this time, the communication module 130 may transmit the power failure message regardless of the user input or restrict the transmission of the power failure message according to the user input according to the type of the notification, but the present invention is not limited thereto.

The alarm module 140 may output at least one of light and sound. It is possible to notify the users who do not have the user terminal 20 through the output of the alarm module 140 of the risk of power failure.

The alarm module 140 may determine whether to output at least one of light and sound according to the user input received through the user terminal 20. [

The control module 150 may determine whether the configuration module 11 is operating. The control module 150 can protect the facility 10 from a fire hazard or the like by stopping the operation of the configuration module 11 at the highest power failure level.

The control module 150 may determine whether the configuration module 11 operates according to a user input received through the user terminal 20. [

2 is a flowchart illustrating an operation method of the electrostatic-surveillance monitoring system 100 according to an embodiment.

Referring to FIG. 2, the electrostatic surveillance system 100 obtains a measurement value for the facility 10 (S200).

For example, an electrical sensor 111 connected to the configuration module 11 of the facility 10 obtains an electrical property measurement, a humidity sensor 112 connected to the configuration module 11 obtains a humidity measurement, The temperature sensor 113 connected to the configuration module 11 may obtain a temperature measurement value.

Here, the electric sensor 111 may acquire at least one of a current measurement value and a voltage measurement value.

Subsequently, the electrostatic-surcharging monitoring system 100 compares the measured value with the reference range (S300).

For example, the processor 120 may compare an electrical characteristic measurement, a humidity measurement, and a temperature measurement to an electrical characteristic reference range, a humidity reference range, and a temperature reference range, respectively.

The processor 120 may compare the current measurement to the current reference range. Processor 120 may compare the voltage measurement to a voltage reference range.

Subsequently, the electrostatic-discharge surveillance system 100 determines the electrostatic level of the facility 10 based on the comparison result of the operation of S300 (S400).

That is, the processor 120 may determine the power failure level of the configuration module 11 of the facility 10 based on the comparison result of the measured value and the reference range.

For example, the processor 120 can determine the power failure level as the highest water level when the electrical sensor 111 detects a power failure.

The processor 120 may determine the power failure level as a middle level when a risk of power failure is detected by the humidity sensor 112 and may determine the power failure level as a minimum water level when a risk of power failure is detected by the temperature sensor 113. [

The processor 120 determines the power failure level as a middle level when a risk of power failure is detected by the humidity sensor 112 and the temperature sensor 113 and when the risk of power failure is detected by the humidity sensor 112 or the temperature sensor 113 The power failure level may be determined as the minimum water level.

3 is a flow diagram illustrating a method for providing power failure data corresponding to a power failure level according to one embodiment.

Figures 4 and 5 are flow charts illustrating a method of setting priorities between sensors according to an embodiment, respectively.

Referring to FIG. 3, the processor 120 sets priorities between the sensors (S100).

For example, the processor 120 sets the priorities of the electrical sensor 111, the humidity sensor 112, and the temperature sensor 113. [ Hereinafter, a method of setting priorities between sensors will be described in detail with reference to FIGS. 4 and 5. FIG.

Referring to FIG. 4, the communication module 130 receives a user input from the user terminal 20 (S111).

For example, the user input may include information for selecting the electrical sensor 111 as the first order, the humidity sensor 112 as the second order, and the temperature sensor 113 as the third order.

Subsequently, the processor 120 sets the priority among the sensors based on the user input (S113).

For example, the processor 120 may set the electrical sensor 111 in a first order, the humidity sensor 112 in a second order, and the temperature sensor 113 in a third order based on user input.

As described above, by setting the priority among the sensors based on the user input, the electrostatic-surveillance monitoring system 100 more suitable for the user's needs can be provided.

Referring to FIG. 5, the sensing module 110 acquires a measurement value for a predetermined period of time (S121).

For example, for a period of time, the humidity sensor 112 may obtain a humidity measurement and the temperature sensor 113 may obtain a temperature measurement.

Subsequently, the processor 120 calculates the number of measurement values out of the reference range (S123).

For example, the processor 120 may count the number of times of the humidity measurement values out of the humidity reference range and the number of the temperature measurement values that deviate from the temperature reference range, respectively, of the measurement values obtained during the predetermined period.

Then, the processor 120 sets the priority among the sensors based on the number of measurement values out of the reference range (S125).

For example, the processor 120 may set the priorities of the humidity sensor 112 and the temperature sensor 113 based on the number of measurements out of the reference range. Specifically, the processor 120 may set the humidity sensor 112 to a higher priority than the temperature sensor 113 when the number of humidity measurement values outside the humidity reference range is greater than the number of temperature measurement values out of the temperature reference range .

As described above, by setting the priority order among the sensors based on the measured values, it is possible to provide the electrostatic surveillance system 100 more suitable for the environment in which the facility 10 is installed.

Referring again to FIG. 3, the electrical sensor 111, the humidity sensor 112, and the temperature sensor 113 acquire the electrical characteristic measurement value, the humidity measurement value, and the temperature measurement value, respectively (S210).

Subsequently, the processor 120 compares the electrical characteristic measurement value with the electrical characteristic reference range (S310), compares the humidity measurement value with the humidity reference range (S320), and compares the temperature measurement value with the temperature reference range (S330) .

When the electrical characteristic measurement value is out of the electrical characteristic reference range, the processor 120 determines the power failure level as the maximum water level (S410).

For example, if the current measurement value is zero, the processor 120 may determine the power failure level to the highest water level.

For example, if the voltage measurement value is zero, the processor 120 may determine the power failure level to the highest water level.

Next, the processor 120 includes a power failure occurrence notification in the power failure message corresponding to the highest power failure level, and the communication module 130 transmits a power failure occurrence notification message to the user terminal 20 (S511).

The outage alert message may include building identification information, facility identification information, configuration module identification information, and information indicating that the current status is current. The outage occurrence notification message may include information related to an action such as replacing the configuration module 11. [

When the processor 120 drives the control module 150 at the highest power interruption level, the control module 150 stops the operation of the configuration module 11 (S512).

Here, steps S511 and / or S512 may be performed corresponding to the highest power failure level.

When the electrical characteristic measurement value is included in the electrical characteristic reference range and the humidity measurement value is out of the humidity reference range, the processor 120 determines the power failure level as the intermediate water level (S420).

For example, if the current measurement value is not zero, and the humidity measurement value is below the minimum humidity or exceeds the maximum humidity, the processor 120 may determine the power interruption level to a medium water level.

For example, if the voltage measurement is not zero, and the humidity measurement is below the minimum humidity or exceeds the maximum humidity, the processor 120 may determine the power interruption level to a medium water level.

Then, the processor 120 includes the power failure alarm notification in the power failure message corresponding to the intermediate power failure level, and the communication module 130 transmits the power failure warning notification message to the user terminal 20 (S521).

The power failure alert message may include building identification information, facility identification information, configuration module identification information, and information indicative of high likelihood of power failure. The power failure alert message may include information related to measures such as adjusting the humidity of the space where the facility 10 is installed.

When the processor 120 drives the alarm module 140 at an intermediate power interruption level, the alarm module 140 outputs light and / or sound warning the power failure (S522).

Here, steps S521 and / or S522 may be performed corresponding to the intermediate power failure level.

When the electrical characteristic measurement value is included in the electrical characteristic reference range, the humidity measurement value is included in the humidity reference range, and the temperature measurement value is out of the temperature reference range, the processor 120 determines the power interruption level as the minimum water level (S430 ).

For example, if the current measurement value is not zero, the humidity measurement value is between a minimum humidity and a maximum humidity, and the temperature measurement value is between a minimum temperature and a maximum temperature, the processor 120 may determine the lowest level have.

For example, if the voltage measurement is not zero, the humidity measurement is between a minimum humidity and a maximum humidity, and the temperature measurement is between a minimum temperature and a maximum temperature, the processor 120 may determine the lowest level have.

Next, the processor 120 includes a power failure warning in the power failure message corresponding to the lowest power failure level, and the communication module 130 transmits a power failure warning message to the user terminal 20 (S530).

The power failure alert message may include building identification information, facility identification information, configuration module identification information, and information indicating that there is a possibility of power failure. The power failure alert message may include information related to measures such as adjusting the temperature of the space in which the facility 10 is installed.

On the other hand, if the electrical characteristic measurement value is included in the electrical characteristic reference range, the humidity measurement value is included in the humidity reference range, and the temperature measurement value is included in the temperature reference range, the processor 120 determines the power failure level as the normal water level (S440).

For example, if the current measurement value is included in the current reference range, the humidity measurement value is included in the humidity reference range, and the temperature measurement value is included in the temperature reference range, the processor 120 can determine the power failure level to be a normal water level have.

For example, if a voltage measurement is included in the voltage reference range, a humidity measurement is included in the humidity reference range, and the temperature measurement is in the temperature reference range, the processor 120 can determine the power interruption level to be a normal water level have.

Next, the processor 120 periodically notifies the power failure notification to the power failure message, and the communication module 130 transmits a power failure notification message to the user terminal 20 (S540).

As described above, the higher the power failure level, the more powerful and various the user is informed of the risk of the power failure, and the more effective the power failure monitoring system 100 can be provided.

The operation method of the electrostatic surveillance system 100 according to the embodiment of the present invention can be implemented as a computer-readable code on a computer-readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like. Also, the computer-readable recording medium may be distributed over a network-connected computer system so that the computer-readable code is stored in a distributed fashion and may be executed by at least one process. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers of the technical field to which the present invention belongs.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Facility 11: Configuration module
100: power failure monitoring system 110: sensing module
111: electric sensor 112: humidity sensor
113: Temperature sensor 120: Processor
130: communication module 140: alarm module
150: control module 20: user terminal

Claims (13)

An electrical sensor connected to the configuration module of the facility;
A humidity sensor connected to the configuration module;
A temperature sensor connected to said configuration module;
A communication module for transmitting a power failure message corresponding to the power failure level to the user terminal; And
Wherein the electrical characteristic measurement value, the humidity measurement value, and the temperature measurement value are acquired through the electrical sensor, the humidity sensor, and the temperature sensor, and the electrical characteristic measurement value, the humidity measurement value, And a processor for determining an interruption level of the configuration module based on a comparison result with a reference range, a humidity reference range, and a temperature reference range,
The processor sets priorities of the electric sensor, the humidity sensor, and the temperature sensor, and when the measured value obtained through the first rank sensor is out of the reference range, When the measured value obtained through the second rank sensor is out of the reference range, the power level is determined as the intermediate level, and when the measured value obtained through the third rank sensor is out of the reference range, And,
Wherein the processor is configured to obtain a humidity measurement value and a temperature measurement value via the humidity sensor and the temperature sensor for a predetermined period of time, calculate the number of measurement values that deviate from the reference range, and based on the number of measurement values out of the reference range And sets the priority of the humidity sensor and the temperature sensor. delete The method according to claim 1,
Wherein the communication module receives a user input from the user terminal,
Wherein the processor sets priorities of the electrical sensor, the humidity sensor, and the temperature sensor based on the user input. delete The method according to claim 1,
The processor includes a power failure notification in the power failure message corresponding to the highest power failure level, includes an power failure warning in the power failure message corresponding to the intermediate power failure level, and includes a power failure warning in the power failure message corresponding to the lowest power failure level , Power failure monitoring system. The method according to claim 1,
An alarm module for outputting at least one of a light and a sound warning the power failure; And
And a control module for determining whether the configuration module is operating,
Wherein the processor drives at least one of the communication module, the alert module, and the control module based on the power failure level,
Wherein the processor drives the communication module at a lowest power interruption level, drives the alert module at an intermediate power interruption level, and drives the control module at a highest power interruption level. Obtaining an electrical characteristic measurement value by an electrical sensor connected to the configuration module of the facility;
Obtaining a humidity measurement value by a humidity sensor connected to the configuration module;
Obtaining a temperature measurement value by a temperature sensor connected to the configuration module;
Comparing, by the processor, the electrical characteristic measurement value, the humidity measurement value, and the temperature measurement value to an electrical characteristic reference range, a humidity reference range, and a temperature reference range;
Determining, by the processor, an interruption level of the configuration module based on the comparison result; And
And transmitting, by the communication module, a power failure message corresponding to the power failure level to the user terminal,
Setting a priority of the electric sensor, the humidity sensor, and the temperature sensor by the processor;
Determining, by the processor, the power failure level to be a maximum water level if the measured value obtained through the first rank sensor is out of the reference range;
Determining, by the processor, the power failure level as a medium water level if the measured value obtained through the second rank sensor is out of the reference range; And
Further comprising: determining, by the processor, the power failure level to a minimum water level if the measured value obtained through the third order sensor is out of the reference range,
Wherein the setting of the priority comprises:
Obtaining, by the humidity sensor, a humidity measurement value for a predetermined period of time;
Acquiring a temperature measurement value for the predetermined period by the temperature sensor;
Calculating, by the processor, the number of measurements out of the reference range; And
And setting, by the processor, a priority of the humidity sensor and the temperature sensor based on the number of times of measurement values out of the reference range. delete The method of claim 7,
Wherein the setting of the priority comprises:
Receiving, by the communication module, a user input from the user terminal; And
Setting a priority of the electric sensor, the humidity sensor, and the temperature sensor based on the user input by the processor. delete The method of claim 7,
Wherein the power failure message corresponding to the highest power failure level includes a power failure alert, the power failure message corresponding to the intermediate power failure level includes an power failure alert, and the power failure message corresponding to the lowest power failure level includes a power failure alert Method of operation of the system. The method of claim 7,
Driving, by the processor, at least one of the communication module, the alert module, and the control module based on the power failure level,
Wherein the step of transmitting the power failure message comprises:
Transmitting, by the communication module, a power failure message corresponding to the lowest power failure level,
Outputting at least one of light and sound warning the power failure by the alarm module corresponding to the intermediate power failure level; And
Further comprising: stopping the operation of the configuration module by the control module in response to a highest power failure level. A computer program stored in a computer-readable recording medium for executing the method of any one of claims 7, 9, 11, and 12 using a computer.

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