KR101962238B1 - Sensor monitoring system to detect abnormalities in electronic equipment - Google Patents

Abstract

The present invention relates to a sensor monitoring system for sensing existence of abnormalities in electronic equipment and, more specifically, to a sensor monitoring system for sensing existence of abnormalities in electronic equipment which senses temperature or wind power of a cooling fan or an electronic element in electronic equipment in real time by a sensor module and analyzes the trend of acquired sensing data of the sensor module to sense abnormalities before partial or total damage to the electronic equipment to minimize harm caused by damage. The sensor monitoring system for sensing existence of abnormalities in electronic equipment comprises: a plurality of sensor modules to sense a driving status and existence of abnormalities of a cooling fan or an electronic element in electronic equipment; a relay controller to receive sensing data sensed by the plurality of sensor modules, and convert received analog data into digital data; and a monitoring terminal to receive digital sensing data measured from the plurality of sensor module from the relay controller to determine the driving status and the existence of abnormalities of the cooling fan or the electronic element in the electronic equipment.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sensor monitoring system for detecting abnormalities in electronic equipment,

The present invention relates to a sensor monitoring system for detecting an abnormality in an electronic equipment, and more particularly, to a sensor monitoring system for sensing the temperature or wind force of a cooling fan or an electronic device in an electronic equipment in real time through a sensor module, And more particularly, to a sensor monitoring system for detecting an abnormality in electronic equipment that can detect an abnormality before partial or total breakage of electronic equipment by analyzing a trend, thereby minimizing damage due to breakage.

In general, automation related electronic equipment, which is used for production of products in the industrial field, uses cooling fans to prevent overheating of electronic equipment.

If such a cooling fan fails, there is no problem in driving the electronic equipment right away. However, as time passes, the main part of the electronic equipment becomes hot, which adversely affects the IC part device, the power module or the capacitor, .

Usually, fans for cooling the electronic equipment are installed inside the equipment, so it is often necessary to confirm the removal by removing the case. During the operation, it is not even possible to confirm it. It is troublesome to turn off the equipment and detach and check the electronic equipment. There is a limit that can not be monitored.

As a result, the fan of the cooling function breaks down and various automation related electronic equipment that occurs afterwards breakdown occurs and the total production damage is very serious. Therefore, as a way to minimize the present damage, emergency repair, emergency purchase, .

In the case of large enterprises, spare parts should be provided so that the damage is minimized by emergency repairs and the like.

If emergency repairs and emergency purchases are possible, it is a good thing, but if the equipment is stopped because it is not solved, there will be an additional inconvenience such as delivery problems due to production loss and waste of manpower.

Therefore, it is necessary to develop a fault detection monitoring system that can prevent the failure of electronic equipment by confirming whether the fan of the cooling function inside the electronic equipment such as the automobile, the production facility or the electronic product is driven, Do.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method and apparatus for detecting the temperature or wind force of a cooling fan or an electronic device in an electronic equipment in real time through a sensor module, And an object of the present invention is to provide a sensor monitoring system that detects an abnormality in electronic equipment that can detect an abnormality before partial or total breakage and minimize damage due to breakage.

The present invention has the following features in order to achieve the above object.

A plurality of sensor modules installed on one side of a cooling fan or an electronic device in an electronic equipment to detect whether the target is driven or not; A relay controller for receiving sensing data sensed by the plurality of sensor modules and converting the received analog data into digital data; And a monitoring terminal for receiving the sensing data of the digital form measured from the plurality of sensor modules from the relay controller to determine whether the cooling fan or the electronic device in the electronic equipment is driven or not.

Here, the sensor module may include a temperature sensor module installed at one side of a cooling fan or an electronic device to sense the temperature of the sensing object, a cooling fan or a wind sensor module installed at one side of the electronic device for sensing wind speed or direction, And a current sensor provided on one side of the electronic device for measuring the amount of current, or a combination thereof.

In addition, the monitoring terminal calculates averaged data by averaging the sensing data received from the plurality of sensor modules over a plurality of times in units of a predetermined time period, and determines whether there is an abnormality based on the average data. When the average data has a value of 10% or more or 10% or less of the average data, the sensing data is configured to be excluded when calculating the average data.

In addition, the monitoring terminal provides output information including the position, real-time average data, and abnormality information of each sensor module through the display means. When the real-time average data exceeds the threshold value of the preset sensing data, And notifies the user through the alarm means.

The monitoring terminal receives sensing data for each sensor module from the monitoring terminal and is connected to the monitoring terminal so as to be able to communicate with the monitoring terminal. The sensing data and the anomaly information of each sensing object are used to determine a steady- An analysis server for generating preliminary alarm event information before generating the alarm event information of the monitoring terminal by predicting whether the current state is the normal driving state or the abnormal occurrence state through the sensed data distribution distribution for a predetermined period of time from the current monitoring terminal .

According to the present invention, by analyzing the trend of the sensing data of the sensor module, it is possible to detect the abnormality of the sensing object before partial or total destruction of the electronic equipment, thereby minimizing the damage caused by the damage.

1 is a schematic block diagram of a sensor monitoring system according to an embodiment of the present invention.
2 is a block diagram illustrating an internal configuration of a sensor monitoring system according to an embodiment of the present invention.
3 is a schematic block diagram of a sensor monitoring system according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

First, the terminology used in the present application is used only to describe a specific embodiment, and is not intended to limit the present invention, and the singular expressions may include plural expressions unless the context clearly indicates otherwise. Also, in this application, the terms "comprise", "having", and the like are intended to specify that there are stated features, integers, steps, operations, elements, parts or combinations thereof, But do not preclude the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a schematic configuration diagram of a sensor monitoring system according to an embodiment of the present invention, and FIG. 2 is a block diagram illustrating an internal configuration of a sensor monitoring system according to an embodiment of the present invention.

Referring to the drawings, a sensor monitoring system 100 according to the present invention includes a plurality of sensor modules 10 installed on one side of a cooling fan or an electronic device in an electronic equipment to detect whether the target object is driven or not, A relay controller 20 for receiving sensing data sensed by the plurality of sensor modules 10 and converting the received analog data into digital data and a plurality of sensor modules 10 from the relay controller 20, And a monitoring terminal 30 for determining whether the cooling fan or the electronic device in the electronic equipment is driven or not.

The sensor module 10 includes a temperature sensor module for sensing the temperature of the object to be sensed, a temperature sensor module for sensing the wind speed or direction of the object to be sensed, A current sensor module for measuring a current amount or a voltage amount, or a voltage sensor module, or a combination thereof.

At this time, thermocouple, RTD, thermistor, infrared temperature sensor, digital output temperature / humidity sensor can be applied as the temperature sensor module, and thermal type wind speed sensor (TA series) can be applied as the wind sensor module.

Of course, an analog optical sensor for measuring the light transmittance according to the rotation of the fan may be installed instead of the above-described wind sensor module so as to detect the operation and the rotation speed of the cooling fan, and a laser The measurement sensor module can replace the wind sensor module.

In addition, a magnetic sensor module that measures the magnetic force strength as needed to determine whether a cooling fan and an electronic device in an electronic device are driven or not, and a magnetic field sensing module for detecting the presence or absence of a magnetic field. And an ultraviolet sensor module may be installed.

The wind sensor module includes a wind direction sensor for sensing the wind direction, a wind speed sensor for sensing the wind amount, and an wind speed sensor for sensing the wind speed, and includes a sensor capable of simultaneously measuring two or more wind speed sensors.

The plurality of sensor modules 10 may be variously selected and combined according to performance and price factors in consideration of the installation environment and characteristics of the object to be sensed.

The plurality of sensor modules 10 includes a measurement unit 11 for measuring a sensing object and a communication unit 12 for transmitting the measured sensing data to a relay controller 20 to be described later. Or a processor unit 13 for analyzing the data.

At this time, the processor unit 13 may analyze the raw data collected every unit time, calculate an average value to remove noise, and transmit the average value to the relay controller 20 as a result value.

Meanwhile, the relay controller 20 receives the sensing data from the plurality of sensor modules 10, converts the received sensing data into digital sensing data if it is analog sensing data, and transmits the sensing data to the monitoring terminal 30 The relay controller 20 includes a first relay communication unit 21 for performing data communication with a plurality of the sensor modules 10 and a second relay communication unit 21 for transmitting the sensing data transmitted from the relay communication unit 21 in an analog form A second relay communication unit 23 for performing data communication between the A / D converter unit 22 and the monitoring terminal 30, which will be described later, And a memory unit 25 for storing the MCU 24 and log data.

The first relay communication unit 21 is provided to perform data communication with the communication unit 12 of the sensing module 10. The first relay communication unit 21 may be a Wi-Fi, a BLE, or a serial Communication can be applied.

In addition, the second relay communication unit 21 can be configured to be capable of data communication with the monitoring terminal 30 through an Ethernet network in the form of Wi-Fi, wired or wireless LAN, or the like.

Meanwhile, the monitoring terminal 30 receives sensing data of the digital form measured from the plurality of sensor modules 10 from the relay controller 20, and determines whether the cooling fan or the electronic device in the electronic equipment is driven or not The monitoring terminal 30 includes a terminal communication unit 31 for enabling data communication with the relay controller 20 and a sensor communication unit 31 for transmitting sensing data of each sensor module 10 received from the relay controller 20 to a corresponding sensor A status determination unit 33 for determining whether the real time sensing data exceeds a predetermined threshold value and generating alarm event information when the real time sensing data exceeds a predetermined threshold value, And generates alarm sound data or image data and generates a warning light driving signal when the alarm event information is generated by the situation determining unit 33 In the form it comprises an alarm generating unit 34 to inform the alarm condition with the alarm means.

Here, the situation determining unit 33 may calculate the average data by averaging the sensing data received from the plurality of sensor modules 10 every predetermined unit of time, and then determine the abnormality based on the average data. This is to filter data errors due to noise or momentary malfunction of the sensing data.

At this time, if any one of the sensing data has a value of 10% or more or 10% or less of the average data averaged by excluding the sensing data, the sensing data is configured to be excluded when the average data is calculated, The situation determination is performed based on the preset threshold value.

Of course, if a certain number of sensing data other than one of the sensing data has a value of 10% or more or 10% or less of the average data excluding the sensing data, it may be a momentary sensing error or an abnormal state in which alarm event information should be generated have.

Therefore, it is necessary to appropriately set the average data calculation exclusion to be performed with a specific number of sensed data by considering the characteristic of the sensing object and the characteristics of the sensor module 10 will be.

3 is a schematic block diagram of a sensor monitoring system according to another embodiment of the present invention.

The sensor monitoring system 100 according to the present embodiment includes the analysis server 40 and the manager portable terminal 50 in the sensor module 10, the relay controller 20 and the monitoring terminal 30 of the above- Wherein the analysis server 40 is connected to the monitoring terminal 30 so as to be able to communicate data and receives sensing data for each sensor module 10 from the monitoring terminal 30, And the abnormality occurrence distribution curve and the sensing data distribution distribution for a certain period of time from the current monitoring terminal 30 to generate a normal driving state distribution or an abnormal occurrence state And generates preliminary alarm event information before the alarm event information of the monitoring terminal 30 is generated.

The analysis server 40 predicts the state of the subboundary requiring attention or boundary from the manager before the predetermined threshold value reaches the state determiner 33 of the monitoring terminal 30, And coping is performed.

For this, the analysis server 40 collects all the sensing data of the previous sensor module 10 from the monitoring terminal 30 and constructs a learning based learning for optimizing the abnormal situation detection, The occurrence of an abnormal situation is predicted through a progression before a result is generated.

For example, the abnormality presence information is collected in the sensing data of the conventional sensing object by the big data type to generate and store a number of normal driving distribution distribution curves and anomalous development distribution distribution curves per sensing object, The trend distribution of the trend data is estimated by predicting the trend distribution curve that is similar to the trend distribution curve.

Accordingly, when an event is generated about whether or not an abnormality will occur after a predetermined time elapses in the future, the preliminary alarm event information is generated and transmitted to the monitoring terminal 30 or the manager portable terminal 50 together with specific information.

The manager portable terminal 50 is connected to the monitoring terminal 30 and the analysis server 40 so as to be able to communicate data, and outputs output information including the location of each sensor module 10, real-time average data, And receives the alarm event information and the preliminary alarm event information when generating the alarm event information and the preliminary alarm event information.

Even if the manager portable terminal 50 does not reside in the field, it is possible to remotely check the current state of the object to be sensed and to receive and respond to the information about the occurrence of the abnormality before or when the abnormality occurs.

In another embodiment of the present invention, in order for the sensor module 10 according to the present invention to obtain sensed data such as temperature, direction, current, or voltage on the sensing object, Or more.

Accordingly, the same sensor module 10 is provided as the first sensor module and the second sensor module, and the order of the second sensor module may be one or more.

Since the plurality of sensor modules 10 are provided to measure the same real-time environment of the object to be sensed, the relay controller 20 and the monitoring terminal 30 receive the sensing data from the first sensor module at normal times, The monitoring terminal 30 stops the operation of the first sensor module and drives the second sensor module.

Accordingly, when the sensing data of the second sensor module is received from the second sensor module and the sensed data of the second sensor module exceeds the threshold value like the first sensor module, the monitoring terminal 30 generates alarm event information.

This makes it possible to prepare for the case where the first sensor module generates distortion of the sensing data due to external noise or an internal failure even in the case where the sensing object does not cause an abnormality and in case of failure of the first sensor module, It is possible to prevent an increase in the number of airs.

In addition, when alarm event information is generated in response to a failure of the sensor module, an unnecessary follow-up process for the alarm event information can be omitted, thereby ensuring the stability of the entire system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Sensor module
20: Relay controller
30: Monitoring terminal
40: Analysis server
50: Manager portable terminal
100: Sensor monitoring system

Claims (5)

A plurality of sensor modules 10 installed on one side of a cooling fan or an electronic device in the electronic equipment to sense whether the target object is driven or not;
A relay controller (20) for receiving sensing data sensed by the plurality of sensor modules and converting the received analog data into digital data;
And a monitoring terminal 30 for receiving sensing data of the digital form measured from the plurality of sensor modules 10 from the relay controller 20 to determine whether the cooling fan or the electronic device in the electronic equipment is driven or not, Lt; / RTI >
The sensor module (10)
The sensor module 10 includes a temperature sensor module installed at one side of a cooling fan or an electronic device to sense the temperature of the sensing object, a wind sensor module installed at one side of the cooling fan or the electronic device to sense wind speed or direction, A fan, or a current sensor module or a voltage sensor module installed on one side of the electronic device for measuring a current amount or a voltage amount, or a combination thereof,
The sensor module (10)
The first sensor module and the second sensor module are provided, and the order of the second sensor module may be one or more,
When the relaying controller 20 and the monitoring terminal 30 receive the sensed data from the first sensor module and the sensed data exceeding a preset threshold value is sensed in the monitoring terminal 30, And stopping the operation of the sensor module and driving the second sensor module.
delete The method according to claim 1,
The monitoring terminal (30)
Averaging the sensing data received from the plurality of sensor modules (10) a plurality of times at a predetermined time unit to determine average data based on the average data,
Wherein the sensing data is configured to be excluded when calculating the average data when the sensing data has a value of 10% or more or 10% or less of the average data obtained by excluding any one of the sensing data. Sensor monitoring system.
The method of claim 3,
The monitoring terminal (30)
Provides output information including the position of each sensor module (10) and real-time average data and abnormality information through display means, and generates alarm event information when the real-time average data exceeds the threshold value of predetermined sensing data And an alarm means for informing the user of the abnormality in the electronic equipment.
5. The method of claim 4,
The sensing terminal 30 is connected to the monitoring terminal 30 so as to be able to communicate data and receives sensing data for each sensor module 10 from the monitoring terminal 30. The sensing data for each sensor module 10 and the abnormal presence / A distribution curve and an anomaly occurrence distribution curve are generated and it is predicted whether the current state is the current normal driving state or the abnormal state through the sensing data distribution distribution for a predetermined time period which is received from the current monitoring terminal 30, Further comprising an analysis server (40) for generating preliminary alarm event information before the generation of the information.

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