KR101199924B1 - Stack tele-monitoring system based on digital communication automated measuring instrument in flu gas - Google Patents

Abstract

PURPOSE: A chimney remote monitoring system of digital communication mode chimney automatic measurement instrument base is provided to immediately sense the change of a set value by collecting alarm data and setup state of a measurement instrument in real time. CONSTITUTION: A chimney remote monitoring system(100) using digital communications comprises a measurement instrument(110) and a data collector(120). The measurement instrument is installed in a chimney and measures pollutant materials included in gas which is discharged from the chimney. The measurement instrument outputs a value signal and a status signal which is measured through a first digital signal input and output terminal. The data collector receives, stores, and outputs the value signal and the status signal in rear time. The data collector transmits and receives a signal with the first digital input and output terminal through a second digital input and output terminal. [Reference numerals] (120) Data collector; (130) Management server

Description

Chimney remote monitoring system based on digital communication type chimney automatic measuring device {STACK TELE-MONITORING SYSTEM BASED ON DIGITAL COMMUNICATION AUTOMATED MEASURING INSTRUMENT IN FLU GAS}

The present invention relates to a chimney remote monitoring system, and more particularly to a system for monitoring the gas discharged from the chimney is applied communication.

The chimney is a structure for discharging the gas generated when the fuel is burned out, and the gas discharged through the chimney often contains various pollutants. Therefore, the Atmospheric Environment Conservation Act regulates the emission of gas from chimneys.

However, because the nature of the gas discharged from the chimney is dangerous for direct measurement by humans, a chimney remote monitoring system is installed to install a measuring device inside the chimney and transmit the data obtained from the measuring device to the central control station. The chimney remote monitoring system constantly monitors pollutant emissions by measuring air pollutant emission concentrations contained in the exhaust gas from the chimney and sending them online to the central control center.

The measuring device used in the chimney remote monitoring system is an analog or analog-digital combined method. At this time, the communication from the measuring device to the data collector is made in an analog manner, and the communication from the data collector to the central control station is made in a digital manner. Accordingly, only one-way communication is possible from the sensor to the data collector, and two-way communication is performed from the data collector to the central control station.

In general, chimneys are operated at various workplaces, and the central control center regulates the situation at which they operate. However, even if the measured value of the measuring device is abnormal or the measured value is manipulated at the workplace, there is no alternative except for visiting and inspecting the workplace directly. This is because the measured value measured by the sensor is transmitted to the central control center in one-way communication, there is a difficult problem of ensuring the reliability of the transmitted measured value in the central control center.

The present invention is to solve the above problems, the present invention is to secure the reliability of the measured value measured by the measuring device in the chimney remote monitoring system for monitoring the exhaust gas of the chimney remote chimney that can check the operating state of the measuring device The purpose is to provide a surveillance system.

In order to achieve the above object, the chimney remote monitoring system using the digital communication of the present invention is installed in the chimney and measures the pollutants contained in the gas discharged from the chimney, and outputs the measured value signal and the status signal. At least one measuring device having a signal input / output terminal; And a data collector having a second digital signal input / output terminal for receiving, storing, and outputting the measured value signal and the status signal in real time, and transmitting and receiving a signal with the first digital signal input / output terminal.

And a management server for receiving data output from the data collector, controlling the data collector, and transmitting a signal for monitoring or controlling the one or more measurement devices to the data collector.

At this time, the signal for monitoring or controlling the at least one measuring device in the management server is the measuring range of the measuring device, the pressure of the sample gas, the temperature of the sample gas, the flow rate of the sample gas, the set factor (factor) value and the set coefficient It is preferable that it is a signal for confirming any one or more of these.

In addition, the status signal output from the at least one measuring device preferably includes a notification signal for informing the management server when any one or more of the lamp intensity, lamp voltage, chamber temperature and chamber pressure.

In addition, the management server may transmit a signal for confirming the state of the at least one measuring device to the data collector, if there is an error in the measured value received from the at least one measuring device.

In this case, the criterion that the management server determines that the measured value is abnormal may include a momentary decrease of the measured value, exceeding a set measured value, maintaining a constant measured value, changing a measuring range of the measuring device, and a zero gas of the measuring device. Change of value, span value of the measuring device, change of calibration coefficient of the measuring device, offset change, change of standard deviation of the time before and after, alarm of sample gas, flow rate alarm of sample gas, temperature alarm of sample gas, measurement If the value is less than "0", the alarm exceeds the set value, the effective data of the measuring device is insufficient, the password of the measuring device is changed, the lamp voltage alarm occurs, the lamp intensity alarm occurs, the lamp temperature alarm occurs, and the lamp pressure alarm occurs. At least one of an alarm occurrence and a power supply disconnection alarm may occur during maintenance.

In addition, the communication between the at least one measuring device and the data collector is preferably serial communication or LAN communication.

According to the present invention, by changing the communication from the measuring device installed in the chimney to the data collector to digital communication capable of two-way communication, it is possible to collect a variety of status information from the measuring device, based on this to strengthen the management capabilities for the measuring device It is effective to provide a chimney remote monitoring system.

Furthermore, since the digital communication method is not affected by the current signal, the digital communication method is not affected by the converter for current conversion, so that an error such as a measurement value is changed in the data transmission process does not occur.

1 is a block diagram showing a chimney remote monitoring system using a digital communication of the present invention.
2 is a table showing state information in the measuring device of the present invention.

Preferred embodiments of the present invention will be described more specifically with reference to the accompanying drawings.

As illustrated in FIG. 1, the chimney remote monitoring system 100 using the digital communication of the present invention includes a measuring device 110, a data collector 120, and a management server 130.

The measuring device 110 is installed in the chimney to measure in real time the various contaminants discharged from the chimney and correction items such as oxygen, flow rate and temperature and the first digital signal input and output stage (not shown) for the measured value Through digital signal output. The first digital signal input / output terminal may be provided by mounting a digital communication card or the like for inputting / outputting a digital signal to the measuring device 110.

At this time, the pollutants measured by the measuring device 110 are dust, sulfur oxides, nitrogen oxides, carbon monoxide, hydrogen chloride, ammonia and hydrogen fluoride.

There are a plurality of chimneys in the workplace, and since the measuring device 110 is installed in each of the chimneys, a plurality of measuring devices 110 are used.

The measuring device 110 outputs the status and alarm information of the measuring device 110 as a digital signal in addition to the measured values of pollutants or correction items included in the discharged gas. The measuring device 110 state information is a factor value used to determine measured values such as sample gas temperature, pressure, and measurement range.

As shown in FIG. 2, the parameter values include measurement range values (maximum and minimum), set value exceeded alarms, calibration curve slope, calibration coefficients, span gas value, zero gas value, offset, and light transmission for each measurement method. Percentage, chamber temperature, chamber temperature alarm, chamber pressure, chamber pressure alarm, lamp intensity, lamp intensity alarm, lamp voltage, lamp voltage alarm, sample gas flow rate, sample gas flow rate alarm, sample gas pressure, sample gas pressure Alarms, the temperature of the sample gas, and the temperature alarm of the sample gas.

The measurement range values (maximum and minimum) mean the maximum and minimum values that the measuring device 110 can measure, and the alarm value exceeding the set value is an alarm generated when the concentration measurement value of the measuring device 110 is out of the measuring range. Information. The calibration curve slope is a slope for converting the indicator of the furnace analyzer used for quantitative analysis into a concentration, and the calibration coefficient value means a coefficient value for compensating for obstacles in the calibration and operation of the measuring device 110.

The value of the span gas means the value for accounting for the highest reading of the analyzer, and the value of zero gas means the value for accounting for the lowest reading of the analyzer. The offset refers to an error or a shifted value (a difference from a reference value or a difference value), and the light transmission percentage refers to a fraction of transmitted light incident on the gaseous sample.

In addition, the chamber temperature means a temperature value of the chamber provided in the measuring device 110, the chamber temperature alarm refers to an alarm that occurs when there is a temperature abnormality in the chamber inside the measuring device 110. The chamber pressure refers to the pressure value of the chamber inside the measuring device 110, and the chamber pressure alarm refers to an alarm generated when there is an abnormal pressure in the chamber inside the measuring device 110. The lamp intensity refers to an intensity value of a lamp provided in the measuring device 110, and the lamp intensity alarm refers to an alarm generated when there is an intensity abnormality in the lamp inside the measuring device 110. The lamp voltage refers to a voltage value of the lamp inside the measuring device 110, and the lamp voltage alarm refers to an alarm generated when there is a voltage abnormality in the lamp inside the measuring device 110.

The flow rate of the sample gas refers to the flow rate of the sample gas to be measured by the measuring device 110, and the flow rate alarm of the sample gas refers to an alarm generated when there is more than the flow rate of the sample gas to be measured. The pressure of the sample gas refers to the pressure of the sample gas to be measured, and the pressure alarm of the sample gas refers to an alarm generated when there is an abnormality in the pressure of the sample gas to be measured. The temperature of the sample gas means the temperature of the sample gas to be measured, and the temperature alarm of the sample gas is an alarm that occurs when there is an abnormal temperature of the sample gas to be measured.

The measuring device 110 of the present invention outputs an output value including the above-described factor value as a digital signal, and outputs a signal for a state and alarm information that was not output as an analog signal.

The data collector 120 receives, collects and documents the digital signal measured and output by the measuring device 110 in real time. The collected and documented data are stored as average data for 5 or 30 minutes, and the stored average data is transmitted to the management server. At this time, the data collector 120 is provided with a second digital signal input and output terminal (not shown) for transmitting and receiving signals with the first digital signal input and output terminal of the measuring device 110.

The second digital signal input / output terminal may be provided by mounting a digital communication card in the data collector 120. Therefore, if the existing data collector can be equipped with a digital communication card, the existing data collector can be used as it is.

In addition, the signal transmitted to control the measuring device 110 from the management server 130 transmits to the measuring device (110). And the data collector 120 of the present invention may collect at least once per five seconds the measured value received from the measuring unit 110, and may include a function to store or output the measuring unit 110 and its own state. have.

Since a plurality of measuring instruments 110 may be provided, one data collector 120 receives signals from a plurality of measuring instruments 110. And, if necessary, a plurality of data collectors 120 may be provided.

The management server 130 receives the average data from the data collector 120, analyzes and stores the collected average data. Here, the average data is data measured by each measuring unit 110, the management server 130 analyzes and stores using the average data. In addition, the management server 130 monitors whether the measurement is normally performed in each measuring unit 110 using the analyzed average data.

In addition, the management server 130 may control each measuring unit 110 through the data collector 120 as necessary, if it is confirmed that there is an error in the average data, the control command to confirm this data collector 120 ) Can be transmitted to each meter 110.

At this time, the criterion for determining that the average data is abnormal in the management server 130 is the instantaneous decrease of the measured value, exceeding the set measured value, maintaining a constant measured value, change the measuring range of the measuring instrument 110, the measuring instrument 110 Change of zero gas value, change of span gas value of measuring instrument 110, change of calibration coefficient of measuring instrument 110, change of offset, change of standard deviation of before and after time, pressure alarm of sample gas, flow rate alarm of sample gas, sample When the gas temperature alarm occurs, if the measured value is less than "0", the alarm exceeds the set value, the effective data of the measuring device 110 is insufficient, the password change of the measuring device 110, the lamp voltage alarm occurs, the lamp intensity alarm Occurrence, lamp temperature alarm, lamp pressure alarm, maintenance and power off alarm.

The management server 130 may determine whether the plurality of measuring devices 110 are operating normally according to the selection criteria as described above, and whether the data measured by the measuring device 110 is correct data. The control command may be transmitted to each measuring device 110 through the data collector 120.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It should be understood that the scope of the present invention is to be understood as the scope of the following claims and their equivalents.

100: chimney remote monitoring system
110: measuring instrument 120: data collector
130: management server

Claims (7)

At least one measuring device installed in the chimney and having a first digital signal input / output terminal for measuring a pollutant contained in the gas discharged from the chimney and outputting a measured value signal and a status signal; And
A chimney remote monitoring system using digital communication, including a data collector, having a data collector which receives, stores and outputs the measured value signal and the state signal in real time, and transmits and receives a signal with the first digital signal input / output terminal. . The method according to claim 1,
And a management server that receives data output from the data collector, controls the data collector, and transmits a signal for monitoring or controlling the one or more measurement devices to the data collector. Chimney remote monitoring system. The method according to claim 2,
The signal for monitoring or controlling the one or more measuring devices in the management server is any one of the measuring range of the measuring device, the pressure of the sample gas, the temperature of the sample gas, the flow rate of the sample gas, the set factor value and the set coefficient Chimney remote monitoring system using a digital communication, characterized in that the signal for identifying one or more. The method according to claim 2,
The status signal output from the at least one measuring device includes a notification signal for informing the management server if any one or more of the lamp intensity, lamp voltage, chamber temperature and chamber pressure is notified. Chimney remote monitoring system. The method according to claim 2,
The management server, if there is an error in the measurement value received from the at least one measuring device, chimney remote monitoring system using a digital communication, characterized in that for transmitting a signal for confirming the state of the at least one measuring device to the data collector . The method according to claim 5,
The criterion for determining that the management server is abnormal in the measured value,
Instantaneous decrease of the measured value, exceeding the set measurement value, maintaining a constant measured value, changing the measuring range of the measuring device, changing the zero gas value of the measuring device, changing the span value of the measuring device, calibration coefficient of the measuring device Change, offset change, standard deviation change in front and rear time, alarm of sample gas, flow alarm of sample gas, alarm of temperature of sample gas, alarm of set value exceeded when measured value is less than "0" Insufficient data of measuring device, password change of measuring device, lamp voltage alarm, lamp intensity alarm, lamp temperature alarm, lamp pressure alarm, alarm during maintenance and power off alarm. Chimney remote monitoring system using digital communication. The method according to claim 1,
The chimney remote monitoring system using digital communication, characterized in that the communication between the at least one measuring device and the data collector is serial communication or LAN communication.

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