KR102228349B1 - System for remote diagnosing fault of oxygen concentration analyzer and method thereof - Google Patents

Abstract

Disclosed is a system and method for remote failure diagnosis of an oxygen concentration analyzer. An oxygen concentration analyzer remote fault diagnosis system according to an embodiment includes an oxygen concentration analyzer that detects oxygen generation at an installed location, analyzes detailed oxygen information including the detected oxygen concentration, saturation, and generation time, and transmits it to a manager terminal; A manager terminal receiving the analyzed detailed oxygen information, outputting it to the display panel, and adjusting a communication period with the oxygen concentration analyzer and a measurement period of detailed oxygen information; Including, the oxygen concentration analyzer is characterized in that to grasp the failure state of the oxygen concentration analyzer by using the analysis period of the pressure, flow rate, temperature, and detailed oxygen information and the oxygen generation detection period.

Description

Remote fault diagnosis system and method of oxygen concentration analyzer {SYSTEM FOR REMOTE DIAGNOSING FAULT OF OXYGEN CONCENTRATION ANALYZER AND METHOD THEREOF}

The present invention relates to a system and method for remote failure diagnosis of an oxygen concentration analyzer, and more particularly, to a system and method for remotely diagnosing an operation state of an analyzer that analyzes the oxygen concentration of exhaust gas inside a chimney and a pipe.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application, and inclusion in this section is not admitted to be prior art.

The oxygen concentration analyzer is a device that measures the oxygen concentration of gas discharged from industrial incinerators and boilers to the chimney. The gas generated during the process in industry can affect the environment and the human body, so it must be discharged after combustion. However, if unburned gas or unburned gas is discharged into the atmosphere through the chimney for failure or cost reduction of the combustion device, serious environmental pollution may be caused.Therefore, various analyzers are installed in the chimney of the industry to prevent this. . The oxygen concentration analyzer functions to monitor the exhaust gas of the chimney by analyzing the oxygen concentration of the exhaust gas collected from the chimney and entering the analyzer through a pipe among these analysis equipment in real time.

It is normal that the concentration of oxygen in the exhaust gas after combustion is very low. If the oxygen concentration is high, it can be suspected as a failure of the analyzer, non-combustion due to a failure of the combustion equipment, or the company's arbitrary non-combustion emission.

If the oxygen concentration analyzer malfunctions, the oxygen concentration measurement is inaccurate and there is a high possibility of environmental pollution. Conventionally, in order to determine the failure state of the oxygen concentration analyzer, he went directly to the site where the analyzer was installed and compared the analyzer data with other analyzer data to determine the operating state of the oxygen concentration analyzer. Specifically, when there is a large difference between the data of the analyzer and the data of other analyzers in the vicinity, or when unstable data occurs, the oxygen concentration is measured using other equipment that can be verified and the measured oxygen concentration data. Compared with, the fault condition has been confirmed according to the comparison result.

If it is determined that it is a failure according to the comparison result, the faulty parts and the faulty parts of the analyzer should be identified. To find this, the engineer had to remove the analyzer and review all the parts inside the analyzer. In addition, there are cases in which the analyzer is separated from the field and an abnormal part or faulty part of the analyzer needs to be identified through special equipment.

The conventional oxygen concentration analyzer diagnosis method takes a considerable amount of time to read the failure of the analyzer and prevents the analyzer from operating for a long time. In addition, after reading the failure of the oxygen concentration analyzer, the operator must visit the site several times during the repair and installation of the analyzer. This is a major factor in reducing the utilization rate of the analyzer and the production system including the analyzer.

In addition, when the oxygen analyzer malfunctions, the user's status, the device status of the oxygen analyzer, and the oxygen supply status of the atmosphere cannot be checked, and there is a trouble of having to check regularly during use. In particular, it is difficult for managers in remote locations to know the status of the oxygen analyzer, making it difficult to manage them smoothly. In addition, in order to manage oxygen analyzers scattered and used in various places, it is necessary to visit and inspect regularly, which consumes a lot of cost.

1. Korean Patent Registration 10-0485114 (2005.04.14) 2. Korean Patent Registration 10-0496410 (2005.06.10)

The present disclosure provides a system and method for remote failure diagnosis of an oxygen concentration analyzer that monitors the device status of an oxygen analyzer installed in an oxygen concentration analysis system, converts the oxygen supply status to digital information, and transmits it remotely through a communication means.

In addition, the fault condition of the oxygen concentration analyzer is quickly determined, and the engineer responds to the faulted part or prepares replacement parts in advance, visits the site once to quickly repair the analyzer's fault, and immediately returns the analyzer to a normal state. By returning to the system, it provides a remote fault diagnosis system for oxygen analyzers that maximizes equipment utilization and minimizes maintenance costs.

In particular, the remote failure diagnosis system and method of the oxygen concentration analyzer according to the embodiment remotely quickly grasps the state and normal operation of the oxygen concentration analyzer that analyzes the oxygen concentration in the exhaust gas inside the chimney and pipe, It makes it possible to improve the utilization rate.

The remote fault diagnosis system of the oxygen concentration analyzer according to the embodiment includes an oxygen concentration analyzer that detects oxygen generation at an installed location, analyzes detailed oxygen information including the detected oxygen concentration, saturation, and generation time, and transmits it to a manager terminal; A manager terminal that receives the analyzed detailed oxygen information, outputs it to the display panel, and adjusts a communication period with an oxygen concentration analyzer and a measurement period of detailed oxygen information; Including, the oxygen concentration analyzer is characterized in that to grasp the failure state of the oxygen concentration analyzer by using the analysis period of the pressure, flow rate, temperature, and detailed oxygen information and the oxygen generation detection period.

In a preferred embodiment, the oxygen concentration analyzer includes: a sensing module for sensing environmental information including pressure, flow rate, and temperature; A gas detection sensor that detects oxygen generation cycle, oxygen generation, and detailed oxygen information; An analysis module that analyzes environmental information and detailed oxygen information to determine whether the oxygen concentration analyzer is abnormal; A communication module for transmitting the oxygen concentration analyzer's abnormality, environmental information and detailed oxygen information to the manager terminal, and receiving oxygen concentration analyzer control information from the manager terminal; And an output module for displaying the oxygen concentration analyzer control information received from the manager terminal and the environmental information and detailed oxygen information. Includes.

The remote fault diagnosis system and method of the oxygen concentration analyzer as described above makes it possible to quickly determine the fault condition of the oxygen concentration analyzer from a remote location, thereby maximizing the operation rate of the equipment. Maximizing the equipment utilization rate can improve the reliability and effectiveness of management of the atmospheric environment for technical purposes to be implemented through the oxygen concentration analyzer, and minimize the management and maintenance costs of the oxygen concentration analyzer.

In addition, it is possible to ensure the safety of workers and improve workplace safety management efficiency by minimizing the number of times of coming to and from the site where the oxygen concentration analyzer is installed or entering and leaving a hazardous area.

In addition, through the remote diagnosis of the oxygen concentration analyzer, the emission regulations based on the environmental law are thoroughly observed, so that pollutants are not discharged to ordinary citizens, and the judgment by monitoring agencies such as the Ministry of Environment does not result in legal violations. Accordingly, companies that have installed oxygen concentration analyzers may not pay fines for regulatory violations and regulatory violations. In addition, the emission of pollutants to citizens is thoroughly prevented, so that it can contribute to the improvement of the environment. In addition, companies that maintain and manage the oxygen concentration analyzer and the oxygen concentration analyzer remote diagnosis system can quickly identify and respond to malfunctions and failures of the oxygen concentration analyzer.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a view showing an oxygen concentration analyzer remote fault diagnosis system according to an embodiment
2 is a block diagram showing a data processing configuration of an oxygen concentration analyzer according to an embodiment;
3 is a view showing a data processing block of an analysis module configured in an oxygen concentration analyzer according to an embodiment
Figure 4 is a signal flow diagram of the oxygen concentration analyzer remote diagnosis system according to the embodiment

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and the general knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to the possessor, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

In describing embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present specification.

In the embodiment, in order to quickly determine the failure state of the oxygen concentration analyzer, the analyzer is equipped with an additional sensor and a communication function. Pressure gauges, flow meters, thermometers, and storage devices are installed to determine whether the oxygen concentration analyzer is broken, and the data of these sensors are displayed on the LCD along with the analyzer's data so that they can be checked in the field. In addition, in the embodiment, the displayed data is transmitted to a remote location using a broadband communication network so that the person in charge can check it at any time. The criterion for determining the malfunction and failure of the oxygen concentration analyzer is to accumulate the judgment information of the field engineer and convert the accumulated information into a software algorithm so that the data stored in the storage device can be analyzed and confirmed. In addition, in the embodiment, the accumulated data can be managed over a long period of time and used to predict whether the oxygen concentration analyzer has failed in connection with the big data analysis technology. In particular, in the embodiment, the state of the analyzer and the operation information of the analyzer for analyzing the oxygen concentration in the exhaust gas inside the factory chimney or the pipe can be remotely sensed and the state of the oxygen analyzer can be diagnosed, thereby improving the operation rate of the oxygen analyzer. In addition, it is to prevent pollutant gas emission due to malfunction of the analyzer and detection error.

1 is a view showing an oxygen concentration analyzer remote fault diagnosis system according to an embodiment.

Referring to FIG. 1, an oxygen concentration analyzer remote fault diagnosis system according to an embodiment may include an oxygen concentration analyzer 100, a manager terminal 200, and a manager server 300.

The oxygen concentration analyzer 100 detects oxygen generation and detects detailed oxygen information. In an embodiment, the oxygen detail information may include a concentration of sensed oxygen, a saturation degree, an occurrence time, and the like. The oxygen concentration analyzer 100 detects whether oxygen is generated and detailed oxygen information, and then transmits it to the manager terminal 200 or the manager server 300. In the embodiment, the oxygen concentration analyzer 100 identifies a failure state of the oxygen concentration analyzer by using the pressure, flow rate, temperature information, the analysis period of the detailed oxygen information, and the oxygen generation detection period.

The manager terminal 200 is a wireless communication terminal that receives the status and failure information of the oxygen concentration analyzer installed in various places, checks the status and failure information of the oxygen concentration analyzer, and controls a plurality of oxygen concentration analyzers in detail. In an embodiment, the manager terminal 200 may receive and output the analyzed detailed oxygen information, and adjust a communication period with an oxygen concentration analyzer and a measurement period of detailed oxygen information.

The manager server 300 is a management server that remotely controls and monitors both the manager terminal and the oxygen concentration analyzer. In an embodiment, the manager server 300 monitors both the oxygen concentration analyzer and the manager terminal, or receives detailed oxygen information, operation information, and whether or not oxygen is generated from the oxygen concentration analyzer, and details each oxygen concentration analyzer included in the remote fault diagnosis system. Can be controlled.

In the embodiment, the oxygen concentration analyzer is equipped with not only an oxygen sensor but also other sensors (flowmeter, thermometer, pressure gauge) for oxygen concentration analysis, so that it can be checked in the field through an LCD display. In addition, the displayed data can be transmitted to a remote smartphone through broadband wireless communication, or through a notification, the person in charge can quickly check the status of the oxygen concentration analyzer. This broadband communication can not only send data to a server computer, but also send real-time text messages to registered users. This makes it possible to stably transmit the status of the analyzer through a separate communication method called text message even when data communication is not smooth.

On the user screen, the values of various sensors of the oxygen concentration analyzer can be displayed, the analysis result and abnormality can be displayed, or notification can be performed, and the analyzer can communicate with the analyzer in both directions, such as determining the period of data transmission from the analyzer. You can do it.

In the embodiment, the manager terminal 200 is a tablet PC, a laptop, a personal computer, a smart phone, a personal digital assistant (PDA), and a mobile device. It may be any one of a mobile communication terminal or the like. That is, the terminal 200 refers to a terminal including a memory for storing a specific application for accessing a management device via a wired/wireless communication network, a microprocessor for calculating and controlling by executing a program, and the like. That is, the terminal is generally a personal PC, but any terminal can be used as long as communication with the oxygen concentration analyzer 100 is possible, and it is a broad concept including all communication computing devices such as notebook computers, mobile communication terminals, and PDAs. .

2 is a block diagram showing a data processing configuration of an oxygen concentration analyzer according to an embodiment.

Referring to FIG. 2, the oxygen concentration analyzer 100 according to the embodiment includes a detection module 110, a gas detection sensor 130, an analysis module 150, a communication module 170, and an output module 190. Can be configured. The term'module' used in the present specification should be interpreted as being able to include software, hardware, or a combination thereof, depending on the context in which the term is used. For example, the software may be machine language, firmware, embedded code, and application software. As another example, the hardware may be a circuit, a processor, a computer, an integrated circuit, an integrated circuit core, a sensor, a MEMS (Micro-Electro-Mechanical System), a passive device, or a combination thereof.

The detection module 110 senses environmental information. In the embodiment, the environmental information means detailed information indicating the environment of the place where the oxygen concentration analyzer is installed, such as pressure, flow rate, and temperature.

The gas detection sensor 130 detects the oxygen generation period, whether or not oxygen is generated, and detailed oxygen information.

The analysis module 150 determines whether the oxygen concentration analyzer is abnormal by analyzing environmental information and detailed oxygen information. In an embodiment, the analysis module 150 presets a range of change of a value detected by the detection module and the gas detection sensor, and when the set value does not exceed a certain range, the detection information is transmitted to the manager terminal. You may not report. In general, data monitoring periodically converts the values of corresponding sensors into message frames and transmits them through communication. Since it is sent every fixed time, cost is incurred depending on the capacity of the message to connect to the communication network and send. However, in an embodiment, in order to save this, the change range of the sensor or data value is determined, and the change of the value is not reported if it does not exceed a certain range, thereby improving message transmission efficiency.

In addition, the analysis module 150 according to the embodiment converts the message into a short message service (SMS) format and transmits/receives the message when the size of the message transmitted/received with the manager terminal is less than a preset value. For example, when the size of a transmission/reception message between the manager terminal and the oxygen concentration analyzer is less than 80 bytes, the analysis module converts the format of the message to a text message and transmits/receives it, thereby reducing the communication cost with the manager terminal.

In addition, the communication module 170 transmits the abnormality of the oxygen concentration analyzer, environmental information, and detailed oxygen information to the manager terminal, and receives the oxygen concentration analyzer control information from the manager terminal. The output module 190 displays oxygen concentration analyzer control information, environmental information, and detailed oxygen information received from the manager terminal.

In an embodiment, the communication module 170 converts a message frame transmitted to the manager terminal into a binary format, and applies a bit unit to each of data including the presence or absence of an oxygen value and the presence or absence of an oxygen value included in the message frame. In the embodiment, the length of a message frame is not sent in readable ASCII (ASCII) code format, but is basically converted into binary format, and data such as the presence or absence of a value and the presence or absence of a state are applied in bit units without using all 1 byte. In this way, for example, the state of 8 sensors can be transmitted as 8 bytes, allocated as 8 bits, and sent as 1 byte, thereby saving the data transmission amount up to 8 times.

In addition, in the embodiment, the communication module 170 communicates with the manager terminal through a Transmission Control Protocol (TCP) connection method. In general, there are many cases of sending data to the server and the manager terminal in the HTTP (HYPERTEXT TRANSFER PROTOCOL) method for convenience in terminal communication, which tends to consume a little bit of data when transmitting and receiving data. Accordingly, in the embodiment, data can be transmitted to the manager terminal and the manager server by using a TCP connection method that can save data to eliminate wasted data and improve communication efficiency, stability, and reliability.

In the embodiment, the communication module 170 sets an internal communication period between the internal sensor and the analysis module and an external communication period between the manager terminal and the oxygen concentration analyzer, and the time at which the internal communication occurs does not coincide with the unit of seconds of the set internal communication period. If not, it is judged as a modem error or system error. In addition, if the failure diagnosis report is not delivered to the manager terminal during the external communication period, it can be identified as a communication error.

In addition, the communication module 170 may determine whether the communication function of the oxygen concentration analyzer is abnormal. For example, the communication module sets an internal communication period and an external communication period, and through this, checks whether a communication function is abnormal. Specifically, the communication module can set the internal communication period in which data is transmitted and received between the oxygen concentration analyzer internal data processing terminals in units of 1 minute, and the external communication period, which is the communication period between the external management terminal and the oxygen concentration analyzer, in units of 1 hour. . In the embodiment, the 1-minute internal communication period report may not be reported when the amount of change in the sensor is small, but the 1-hour failure diagnosis report is set to be necessarily reported. If the failure diagnosis report is not performed during the external communication cycle, it can be judged as a communication error. In addition, since the 1-minute periodic report is accurately reported at 60 second intervals, the value should be reported in the same second unit. If the reporting point of the value is not constant, perform equipment inspection by suspicion of a modem abnormality or system reset. You can take action to do it.

Hereinafter, the appearance of the oxygen concentration analyzer according to the embodiment will be described. An LCD and a keypad are arranged on the front front panel of the oxygen concentration analyzer so that contents that cannot be displayed on one screen can be navigated through menus of various screens by key operation. In addition, it enables the function of adjusting the offset for the accuracy of the internal algorithm and the accuracy of the analyzer. Main power, communication terminals, output terminals, antenna terminals, etc. are arranged on the rear panel. In particular, the communication terminal can transmit or receive data directly to a remote server by applying wired Internet communication through Ethernet as well as broadband wireless communication. It provides protocols and standard interfaces that can be provided when needed. In addition, by re-printing the original data of the oxygen sensor as it is, other external devices can be used for oxygen concentration analysis.

3 is a diagram showing a data processing block of an analysis module configured in an oxygen concentration analyzer according to an embodiment.

Referring to FIG. 3, the analysis module 150 according to the embodiment may include a collection unit 151, an operation unit 153, and a determination unit 155. The collection unit 151 of the analysis module 150 collects detailed oxygen information and environmental information from various measurement sensors such as a gas detection sensor, a thermometer, a flow meter, and a pressure gauge. The operation unit 153 performs an operation comparing the collected information with a preset threshold value and a set value, and the determination unit 155 identifies abnormalities and abnormal parts of the oxygen concentration analyzer according to the comparison result.

In the embodiment, the detection module detects detailed oxygen information and environmental information in which an oxygen concentration analyzer is installed, including various sensors such as a flow meter, a pressure gauge, a thermometer, and an oxygen sensor.

In an embodiment, the determination unit 155 of the analysis module receives data sensed by the flow meter from the collection unit and determines whether a sample sample is normally introduced. In addition, it is possible to determine whether an abnormality in an external device flowing in the sample sample is detected through data detected by the pressure gauge.

In addition, when the oxygen concentration analyzer operates normally, the determination unit 155 of the analysis module maintains a constant temperature for accurate analysis. It can be determined that there is an abnormality in the heating part of the concentration analyzer.

In an embodiment, when the data value recently sensed by the oxygen sensor exceeds the normal range from the previously sensed value, the analysis module primarily determines that the sample sample is abnormal. If the value of the oxygen sensor is continuously out of the normal range of the sample sample value, the determination unit 155 infers the failure of the oxygen sensor, and compares the value of the additionally installed oxygen sensor with the measured value of the pre-installed oxygen sensor. Secondary diagnosis can be made as either an abnormality in the sensor or an abnormality in an existing oxygen sensor or a malfunction of the equipment.

Hereinafter, a method for remote failure diagnosis of an oxygen concentration analyzer according to an embodiment will be sequentially described. Since the function (function) of the remote failure diagnosis method of the oxygen concentration analyzer is essentially the same as the function of the remote failure diagnosis system of the oxygen concentration analyzer, the overlapping description of FIGS. 1 to 3 will be omitted.

4 is a signal flow diagram of an oxygen concentration analyzer remote diagnosis system according to an embodiment.

In step S410, the oxygen concentration analyzer 100 collects detailed oxygen information and environmental information measured by various sensors such as a gas detection sensor, a thermometer, a flow meter, and a pressure gauge. In step S420, the oxygen concentration analyzer 100 transmits the collected information to the manager terminal 200 or the server. In step S430, the manager terminal 200 outputs environmental information and detailed oxygen information of each oxygen concentration analyzer to inform the manager.

In step S440, the oxygen concentration analyzer 100 determines whether an abnormal operation occurs in each technical configuration included in the analyzer. In step S450, when an abnormal operation occurs in the oxygen concentration analyzer 100, a part in which the abnormal operation occurs is identified. In step S460, the oxygen concentration analyzer 100 transmits the abnormal operation status and abnormal operation part information of the oxygen concentration analyzer 100 to the manager terminal. In step S470, the manager terminal 200 outputs information about abnormal operation and abnormal operation parts received from the manager terminal.

In step S480, the manager terminal generates detailed control commands of the analyzer, such as a communication cycle with the oxygen concentration analyzer and a sensor operation cycle of the oxygen concentration analyzer. In step S490, the manager terminal transmits a detailed operation control command of the oxygen concentration analyzer including the communication cycle and the sensor operation cycle control command to the oxygen concentration analyzer, and in step S500, the analyzer according to the control command received from the oxygen concentration analyzer 100 Controls detailed operation information such as communication period and sensor operation period.

The remote fault diagnosis system and method of the oxygen concentration analyzer as described above is equipped with a broadband communication device in the oxygen concentration analyzer, so that a user can analyze the data received and stored from a remote device to solve the failure of the oxygen concentration analyzer. In addition, by attaching various sensors such as flow meter, pressure gauge, thermometer, oxygen sensor, etc., it is possible to determine whether the sample sample is properly received using the data obtained from the flow meter, and through the data obtained from the pressure gauge, through a constant pressure. It is possible to judge whether there is an abnormality in the equipment sending the sample sample from the outside. In addition, through the data acquired through the thermometer, when the oxygen concentration analyzer operates normally, a certain temperature is maintained for the accuracy of the analysis.If the temperature is higher or lower than the normal range, the heating part of the analyzer is abnormal. Allows you to judge that there is this. In addition, in an embodiment, when the recently received data exceeds the range of a typical value previously received, the oxygen sensor first determines an abnormality in the sample sample. However, if the value of the sensor is continuously out of the range of the sample sample, the failure of the sensor can be inferred, and by comparing the value of the additionally installed sensor, the abnormality of the sample or the abnormality of the sensor or equipment failure can be advanced. .

Through the remote diagnosis system and method of the oxygen concentration analyzer according to the embodiment, it is possible to quickly determine the failure state of the oxygen concentration analyzer from a remote location, thereby maximizing the operation rate of the equipment. Maximizing the utilization rate enables the reliability and effectiveness of management of the atmospheric environment for the technical purpose to be realized through the oxygen concentration analyzer to be improved, and minimizes the management and maintenance costs of the oxygen concentration analyzer. In addition, it is possible to ensure the safety of workers and improve workplace safety management efficiency by minimizing the number of times of coming to and from the site where the oxygen concentration analyzer is installed or entering and leaving a hazardous area.

In addition, through remote diagnosis of the oxygen concentration analyzer, it is necessary to thoroughly comply with emission regulations based on environmental laws, to prevent pollutants from being discharged to ordinary citizens, and to prevent legal violations from being judged by an audit by a monitoring agency such as the Ministry of Environment. Accordingly, companies that have installed oxygen concentration analyzers may not pay fines for regulatory violations and regulatory violations. In addition, the emission of pollutants to citizens is thoroughly prevented so that it can contribute to environmental improvement. In addition, companies that maintain and manage the oxygen concentration analyzer and the oxygen concentration analyzer remote diagnosis system can quickly identify and respond to malfunctions and failures of the oxygen concentration analyzer.

The disclosed contents are only examples, and various changes may be made by those of ordinary skill in the art without departing from the gist of the claims claimed in the claims, so the scope of protection of the disclosed contents is limited to the above-described specific It is not limited to the examples.

Claims (11)

In the remote fault diagnosis system of the oxygen concentration analyzer,
An oxygen concentration analyzer that senses oxygen generation at the installed location, analyzes detailed oxygen information including the detected oxygen concentration, saturation, and generation time, and transmits it to a manager terminal;
A manager terminal receiving the analyzed detailed oxygen information, outputting it to a display panel, and adjusting a communication period with the oxygen concentration analyzer and a measurement period of detailed oxygen information; Including,
The oxygen concentration analyzer
By using the analysis cycle of pressure, flow rate, temperature and oxygen detail information and the oxygen generation detection cycle, the failure status of the oxygen concentration analyzer is identified
The oxygen concentration analyzer
A sensing module for sensing environmental information including pressure, flow rate, and temperature;
A gas detection sensor that senses the oxygen generation period, whether or not oxygen is generated, and the detailed oxygen information;
An analysis module that analyzes the environmental information and detailed oxygen information to determine whether an oxygen concentration analyzer is abnormal;
A communication module for transmitting an abnormality of the oxygen concentration analyzer, environmental information, and detailed oxygen information to a manager terminal, and receiving oxygen concentration analyzer control information from the manager terminal; And
An output module for displaying the oxygen concentration analyzer control information received from the manager terminal and the environmental information and detailed oxygen information; Including
The detection module
Including a flow meter, a pressure meter, a thermometer, an oxygen sensor,
The analysis module
Based on the data sensed by the flow meter, it is determined whether the sample sample flows normally,
An oxygen concentration analyzer remote failure diagnosis system, characterized in that it determines whether or not an abnormality in an external device that introduces a sample sample is abnormal through the data sensed by the pressure gauge.
delete The method of claim 1, wherein the oxygen concentration analyzer
Oxygen, characterized in that the range of change of the value detected by the detection module and the gas detection sensor is set in advance, and the detection information is not reported to the manager terminal when the set value does not exceed a certain range. Concentration analyzer remote fault diagnosis system.
The method of claim 1, wherein the oxygen concentration analyzer
An oxygen concentration analyzer remote failure diagnosis system, characterized in that a message frame transmitted to the manager terminal is converted into a binary format, and a bit unit is applied to each data including the presence or absence of an oxygen value and the presence or absence of an oxygen value included in the message frame. .
The method of claim 4, wherein the oxygen concentration analyzer
An oxygen concentration analyzer remote fault diagnosis system, characterized in that communication with a manager terminal through a Transmission Control Protocol (TCP) connection method.
The method of claim 5, wherein the oxygen concentration analyzer
When the size of a message transmitted and received with the manager terminal is less than a preset value, the message is converted to SMS (Short Message Service) in the form of a text message and transmitted/received, thereby reducing communication cost with the manager terminal. Oxygen concentration analyzer remote fault diagnosis system.
delete The method of claim 1, wherein the analysis module
When the oxygen concentration analyzer operates normally, it maintains a constant temperature for accurate analysis.If the real-time measurement temperature detected by the thermometer is outside the normal range of the constant temperature, it is determined that there is an abnormality in the heating part of the oxygen concentration analyzer. Oxygen concentration analyzer remote fault diagnosis system, characterized in that to determine.
The method of claim 1, wherein in the oxygen sensor
When the recently detected data value exceeds the normal range from the previously detected value, the analysis module first determines that the sample sample is abnormal.
The method of claim 8, wherein the analysis module
If the value of the oxygen sensor is continuously out of the normal range of the sample sample value, it is determined as a failure of the oxygen sensor, and the value of the additionally installed oxygen sensor and the measured value of the previously installed oxygen sensor are compared, and the sample is abnormal or already installed. An oxygen concentration analyzer remote failure diagnosis system, characterized in that diagnosing as either an abnormality of an oxygen sensor or a failure of an equipment.
The method of claim 1, wherein the communication module
Set the internal communication cycle between the oxygen concentration analyzer internal sensor and the analysis module and the external communication cycle between the manager terminal and the oxygen concentration analyzer,
If the time point at which internal communication occurs does not coincide with the unit of seconds of the set internal communication period, it is judged as a modem error or system error,
When the failure diagnosis report is not transmitted to the manager terminal during the external communication period, the oxygen concentration analyzer remote failure diagnosis system is identified as a communication error of the oxygen concentration analyzer.

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