KR20220161621A - Ict . - Google Patents

Abstract

In a smart farm which remotely turns on and off an LED light source, gives water, and operates a fan with a terminal such as a smartphone and a PC through LTE or a broadband communication network, failure diagnosis of individual sensors and non-operation due to defective operation of a driving unit impair the fundamental operational safety of a remote-control system. In order to solve the above-mentioned problem, the present invention provides an ICT device monitoring and recording device of a system comprising an ICT device such as the smart farm, remotely checking an input value of a sensor, and driving the driving unit according to an input sensor value, the ICT device monitoring and recording device comprising a data black box storing the input value of the sensor and an operating state of the driving unit as a digital or analog input for each channel. The system for measuring an environment with the sensor and driving the driving unit based on measured information according to configurations as described above has an effect of preventing an entire system from being stopped due to a failure of the sensor and the driving unit, and guaranteeing a stable operation of the system.

Description

ICT monitoring and recording devices {.}

The invention of the present application relates to an apparatus for collecting sensor information from a system composed of a sensor and a driving unit through the Internet and controlling the driving system according to a signal from the sensor. More specifically, it relates to a device for diagnosing failures of the sensors and devices and transmitting them to users through the Internet.

A next-generation smart farm operation system has been disclosed as a prior art prior to the filing of the present invention. Provides various services related to smart farm operation for the plurality of smart farm terminals through a communication network with a plurality of smart farm terminals in multiple regions, which are intelligent farm terminals made by grafting agricultural technology with information and communication technology (ICT) However, a weather observation / prediction server for observing and predicting the weather in the region, a logistics management server for logistics management of each region, that is, delivery or warehouse logistics, provided and operated in each smart farm A smart farm equipment operation server that manages the operation of equipment, a price management / prediction server that manages and predicts the prices of products produced or scheduled to be produced in each of the smart farms and various agricultural and marine products, and each of the smart farms A product management server that manages the production of agricultural and livestock products being produced in the farm, an operation performance management server that manages the performance of each smart farm operation, and the weather observation/prediction server, a logistics management server, a smart farm equipment operation server, Price management/prediction server, product management server, operational performance management server, data collected through smart farm manager’s PC or smart device, various data and data collected from Internet portals connected to the communication network, and input through input/output devices Through various types of data, smart farm operation information, smart farm equipment purchase/rental information, product information, and information according to the current location of the smart farm manager can be converted into big data, and smart farms across the country can be efficiently operated according to the data converted into big data. It is composed of a big data mining server that enables the purchase or rental of equipment necessary for the smart farm, and the purchase fee or rent is paid through a financial company server that provides financial transaction services between the smart farm integration server and the smart farm terminal when purchasing or renting equipment necessary for the smart farm. farm integration server; A configuration including a is disclosed.

As another prior art, a method and apparatus for diagnosing errors in smart farm operating equipment are disclosed. The error diagnosis method performed by the error diagnosis device of the smart farm operating equipment includes receiving a control message that triggers error diagnosis, and when the control message is received, data collected from the smart farm is diagnosed in advance. By analyzing based on the rule, a technique is disclosed that includes determining an error of operating equipment installed in the smart farm and providing a user with a result of the determination through a user interface.

Registered Patent Publication No. 10-2131037 Registered Patent Publication No. 10-2174466

In the invention of the present application, there is a case where the technology for remotely controlling the smart farm is incapacitated due to malfunction of the sensor due to aging of the sensor used in the smart farm or long-term exposure to poor environments and malfunction of driving units such as side windows and pumps. There are many.

In a smart farm that remotely turns on and off the LED light source, waters, and operates the fan through terminals such as smartphones and PCs through LTE or broadband communication networks, fault diagnosis of individual sensors and non-operation due to poor operation of the drive unit It harms the fundamental operation safety of the remote control system.

In order to solve the above problems, the invention of the present application is an ICT device monitoring and recording device of a system composed of ICT devices such as smart farms, remotely checking the input values of sensors, and driving the drive unit according to the input sensor values. in

Provided is an ICT device monitoring and recording device comprising a data black box for storing the input value of the sensor and the operating state of the driving unit for each channel as a digital or analog input.

In addition, the data black box further comprises a detachable data storage device, and stores the input value of the sensor and the operating state of the drive unit as digital or analog inputs for each channel in the detachable data storage device. Device monitoring and recording devices are provided.

In addition, the data black box provides an ICT device monitoring and recording device characterized in that a real-time clock capable of knowing the date and time is provided.

In addition, the data black box provides an ICT device monitoring and recording device, characterized in that a GPS for confirming the current location is further built-in.

In addition, an ICT device monitoring and recording device characterized by further comprising a failure prediction unit for reading data from the data black box and detecting a change in the data capable of predicting failure before failure of the sensor or drive unit. .

In addition, in the case of the temperature and humidity sensor, the failure prediction unit receives the measurement location from GPS, receives the measured data of the sensor and the time at that time, reads the climate at that time from the Internet climate DB, and affects the temperature and humidity. Provided is an ICT device monitoring and recording device characterized in that the operation health of the temperature and humidity sensor is measured by inputting the operation of the fan and the sprinkler.

In addition, the failure prediction unit is provided with a sensor operation curve DB for each sensor, and when the operation curves of the sensors are separated from the operation curve DB stored, it is determined as a failure. Provides an ICT device monitoring and recording device .

According to the present invention, in a system that measures the environment with a sensor and drives a driving unit with the measured information, the system prevents the entire system from being stopped due to a failure of the sensor and the driving unit, and ensures stable system operation. has the effect of

1 shows a configuration in which the input of the sensor and the operating state of the driving unit of the present invention are received digitally, stored in a data black box, and stored in a DB.
Figure 2 shows a neural network controller predicting the remaining life of the ICT device of the present invention.
3 illustrates a means for predicting a failure of the driving unit by additionally installing a sensor in the driving unit or a device interlocked with the driving unit for each type of driving unit.
4 illustrates types of failures by time.

The operation and effect of the present invention will be described using drawings as follows.

1 shows a configuration in which the input of the sensor and the operating state of the driving unit of the present invention are received digitally, stored in a data black box, and stored in a DB.

SW1 ~ SWn may be inputs of the same switch or sensors (signal input).

It may be an input signal that controls the driving unit, such as Act1 to Actn, or may be data measuring the power consumption of the driving unit to monitor the driving unit, and a vibration sensor or sound sensor capable of diagnosing the state of the driving unit according to the type of the driving unit. It may be data (signal output) such as

Depending on the type of the input signal, a digital signal is directly used, but an analog signal is converted into a digital signal and used.

In the case of the black box shown in FIG. 1, all of these signal inputs and signal outputs are stored and used to predict failure of the sensor and drive unit. To this end, the black box is provided with a real-time clock to store the date and time by combining the signal input and signal output, and a GPS may be embedded in the black box to use other information connected to the future location. .

Figure 2 shows a neural network controller predicting the remaining life of the ICT device of the present invention. This is a diagram explaining the overall operation concept of the present invention. In addition, by combining the data stored in the black box and the failure signal, failure is predicted using an artificial neural network or deep learning, and the remaining usable life of the sensor and drive unit is notified. shows the concept.

3 illustrates a means for predicting a failure of the driving unit by additionally installing a sensor in the driving unit or a device interlocked with the driving unit for each type of driving unit.

Failure of parts that transmit power, such as gears and motors, can be predicted by monitoring vibration or sound. In the case of a device that rotates at high speed for a long time, such as a rotating motor, failure can be diagnosed by monitoring at least one of temperature change and power consumption of the main surface caused by change in rotation speed or rotation.

In addition, in the case of an air circulation fan, a pressure sensor may be installed to monitor the operation stability of the fan based on a change in wind pressure generated by the operation of the fan. On the other hand, in the case of a fan, power consumption and vibration can also be measured and used.

In the case of a support part and a long power transmission shaft, displacement or the like can be measured to diagnose faults or check durability. A power meter can measure the change in power consumption, and a thermometer can measure the temperature change of the device. In particular, by monitoring the occurrence of a peak in the power meter, it is possible to remotely monitor the failure of a high-power consumable such as a motor that uses a lot of coils.

The above sensors are only used as examples, and sensors and thermal imaging cameras that can use electronic measurement methods can also be used for failure prediction.

In particular, in summer, devices have difficulties in sensing and driving due to high temperature and high humidity.

4 illustrates types of failures by time. shows the timing and causes of common failures. The types of failures can be divided into initial, accidental, and wear failures. There is an initial failure that occurs between 1 and 7 days after installation, and an accidental failure period in which a failure occurs due to a special event after normal operation after this period. In most cases, physical and electrical shocks such as shock, drop, and short circuit are applied as accidental failures. Wear failure refers to the case where the device fails using the normal sleep period.

The present invention is intended to provide a technique for predicting failure of a sensor and a driving unit by collecting characteristic data appearing in initial, accidental, and wear failures, respectively.

For example, in the case of a sensor, a reference sensor is provided at a location where the whole can be averaged and measured, and other sensors are configured as a network to store the difference and change according to the position of the measured value of each sensor so that the measured value of a specific sensor can be obtained. If it is different from the usual measurement result, it is checked to predict failure. It is assumed that all of the reference sensors are installed at a location where the average can be measured, but this is only an example and any specific sensor of the sensor network can be used.

As another example, in the case of the driving unit, the power consumption pattern according to the operation of the driving unit is stored by monitoring the power consumption of the driving unit itself, and the operation stability of the driving unit can be measured using this, but the vibration sensor, temperature sensor, and rotation speed sensor in the driving unit , pressure sensor, microphone sensor (sound sensor), displacement sensor, etc. can be attached to constantly monitor the operation of the drive unit.

The invention of the present application provides the following problem solving means in order to exhibit the above operational effects.

In the ICT device monitoring and recording device of a system that is composed of ICT devices such as smart farms, remotely checks the input value of the sensor, and drives the drive unit according to the input sensor value,

Provided is an ICT device monitoring and recording device comprising a data black box for storing the input value of the sensor and the operating state of the driving unit for each channel as a digital or analog input.

In addition, the data black box further comprises a detachable data storage device, and stores the input value of the sensor and the operating state of the drive unit as digital or analog inputs for each channel in the detachable data storage device. Device monitoring and recording devices are provided.

In addition, the data black box provides an ICT device monitoring and recording device characterized in that a real-time clock capable of knowing the date and time is provided.

In addition, the data black box provides an ICT device monitoring and recording device, characterized in that a GPS for confirming the current location is further built-in.

In addition, an ICT device monitoring and recording device characterized by further comprising a failure prediction unit for reading data from the data black box and detecting a change in the data capable of predicting failure before failure of the sensor or drive unit. .

In addition, in the case of the temperature and humidity sensor, the failure prediction unit receives the measurement location from GPS, receives the measured data of the sensor and the time at that time, reads the climate at that time from the Internet climate DB, and affects the temperature and humidity. Provided is an ICT device monitoring and recording device characterized in that the operation health of the temperature and humidity sensor is measured by inputting the operation of the fan and the sprinkler.

In addition, the failure prediction unit is provided with a sensor operation curve DB for each sensor, and when the operation curves of the sensors are separated from the operation curve DB stored, it is determined as a failure. Provides an ICT device monitoring and recording device .

Claims (4)

In the ICT device monitoring and recording device of a smart farm system that is composed of an ICT device and remotely checks the input value of the sensor and drives the drive unit according to the input sensor value,
An ICT device monitoring and recording device comprising a data black box that stores the input value of the sensor and the operating state of the drive unit as digital or analog inputs for each channel. According to claim 1,
The data black box further includes a detachable data storage device, and the input value of the sensor and the operating state of the drive unit are stored as digital or analog inputs for each channel in the detachable data storage device. and recorder. According to claim 2,
An ICT device monitoring and recording device, characterized in that the data black box is provided with a real-time clock capable of knowing the date and time. According to claim 3,
An ICT device monitoring and recording device, characterized in that the data black box further has a built-in GPS for confirming the current location.

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