KR100496142B1 - Data logger for use in telemetry system - Google Patents

Abstract

An improved data logger device is disclosed that can transmit meter reading data wirelessly while being installed at a site while remaining in a fixed state for a while. The data logger device for monitoring the corrosion degree of the pipe is a data logger device for monitoring the corrosion degree of the pipe, the signal outputting the magnitude of the potential difference generated between the pipe and the reference electrode installed around the pipe as a measurement signal value converter; After converting the measured signal value output from the signal converter into digital data and calculating the arithmetic measurement data using the converted digital data, generate the data for wireless transmission and store it in the storage area. And a main controller unit having a real time clock (RTC); A wireless transmitter configured to wirelessly transmit wirelessly transmitted data to the ground under the control of the main controller unit, wherein the wireless transmitter comprises a CDMA module; A power management unit connected to the main controller unit for managing power saving of the signal converter and the wireless transmitter; And an RS-232C driver connected to the main controller to communicate with the hand terminal.

Description

Data logger device with data transmission function for remote meter reading system {DATA LOGGER FOR USE IN TELEMETRY SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote meter reading system for remotely monitoring the degree of corrosion of gas pipes and the like, and more particularly to a data logger device having a data radio transmission function.

Typically, most of the high pressure gas piping used to supply gas to the destination useful for life and industry is buried underground in a complex form. In order to prevent such a gas pipe from corrosion, the outside of the pipe is mainly coated with a polyethylene resin. If there is a corrosion, there is a risk of an accident. I've installed and run a data logger.

Such data loggers have long been recognized as important tools for method management and are sold in various types by various companies. Currently, energy supply companies such as KOGAS are carrying out the procedure of analyzing the collected data logger after collecting the collected data logger for a certain period of time.

Such conventional data loggers have the following problems.

First, there was a problem that the method management was cumbersome and expensive. For example, if you collect one methodic potential every 10 seconds, you can collect data for about one month. You can retrieve 200-300 data loggers for each region, read the measured data from the recovered data loggers, Re-filling and discharging the data logger, analyzing the read data, printing for output, and organizing the data, all of which led to tremendous hassle, real-time monitoring was difficult, and It was expensive because people were involved.

Second, there is a problem that the life of the battery employed in the data logger is shortened so that the data accumulation operation of the data logger can be performed. The reason for this is that the use of Ni-MH series 1,000mA / H battery has limited the usage time, and the power consumption of electronic circuit and memory in the data logger occurs, so it charges before discharge using expensive automatic charger / discharger. There was a hassle to do. As the frequency of charging increases, the battery life is drastically shortened.

Third, there was a problem that is vulnerable to high-current AC current. That is, the electrical circuit of the data logger has often been burned by the high voltage current induced by the high voltage transmission line or the transformer around the pipe.

Fourth, even if the data logger is damaged due to traffic or civil engineering of the roadside, there is a problem that is found at the time of collection after a certain time.

Accordingly, there is a need for an improved data logger device that can wirelessly transmit method potential data collected at a remote site to a server by solving the problems of the conventional data logger.

It is therefore an object of the present invention to provide an improved data logger device which can solve the above-mentioned problems.

Another object of the present invention is to provide a data logger device that can transmit meter reading data wirelessly in a state in which it is kept in a fixed state for a period of time and then removed from the collected method.

Another object of the present invention is to wirelessly transmit the information indicating the corrosion state of the pipe installed in the field in real time, performs a high power saving mode operation, is not significantly affected by the surrounding environment, quickly found in case of damage to the device To provide a data logger device and a remote meter reading system for pipe monitoring.

According to an aspect of the present invention for achieving some of the above objects, a data logger device for monitoring the degree of corrosion of a pipe is generated between the pipe and a reference electrode installed around the pipe. A signal converter for outputting the magnitude of the potential difference as a measured signal value; A main controller unit for converting a measurement signal value output from the signal converter into digital data, obtaining arithmetic measurement data using the converted digital data, and generating wireless transmission data and storing the data in a storage area; And a wireless transmitting unit for wirelessly transmitting the wireless transmitting data to the ground under the control of the main controller unit.

Hereinafter, a data logger device having a data radio transmission function for a remote meter reading system according to an embodiment of the present invention will be described with reference to the accompanying drawings. Although shown in different drawings, components having the same or similar functions are represented by the same or similar reference numerals.

1 is a view showing an installation example of a data logger device according to an embodiment of the present invention. The data logger device 100 is installed in the protective metal case 2 and monitors the corrosion level of the pipe by measuring the potential difference generated between the gas pipe 6 installed at the site and the reference electrode 4 installed around the pipe. It functions to make measurement data necessary to transmit wirelessly. Since the data logger device 100 is mainly installed in the manhole, the data logger device 100 is finished in a completely waterproof case in consideration of infiltration by rainwater or the surrounding environment.

The data logger device is measured twice a day to continuously measure the corrosion state of the high-pressure gas pipe, the measurement period can be measured for 10-20 minutes to 1 second. The measured data is stored in the internal memory area and the final data processed by the CPU is transmitted wirelessly to the central monitoring center where the server is located. Here, the measurement period and the data transmission period of the data can be reset by the operator, of course.

2 is a conceptual diagram of a remote meter reading system in which a plurality of data logger devices 100 of FIG. 1 are installed. The CDMA measurement data emitted from the data logger devices 102-105 performing the same function as the data logger device 100 is transmitted to the base station 200 closest to the installed location through the wireless TCP / IP transmission method. It is sent to the server 300 in the central control station through the communication network.

3 is an electronic hardware block diagram of the data logger device of FIG. 1. Referring to the drawings, the signal converter 110, the main controller unit 120, the CDMA module 130, the RS232C driver 150, the power management unit 140, and the battery unit 160 that is the primary battery is the data logger The elements that make up the device. Here, the main controller unit 120 is composed of an A / D converter 121, a CPU 122, a memory 124, and a real time clock (RTC) 126.

The signal converter 110 filters the potential input signal measured at a maximum of -10V to + 10V, inductive current or noise filtering, and then converts the buffering and the signal size through an internal operational amplifier to convert the A / D converter 121. It is provided to be suitable as an input signal. The signal converter 110 uses a single power source and receives an input signal and converts the input of -10V to + 10V into an output having an amplitude of 2.5-0V. Also, to minimize the current consumption, power is consumed only during operation.

The analog measurement signal obtained by the signal converter 110 is amplified and anti-aliased filtered, and then converted into 8-bit, 10-bit or 16-bit digital data by the A / D converter 121. The digital data is converted into measurement data by correction by the main controller unit 120, and the average, maximum and minimum values of the data are processed in real time at the same time as the measurement. When the measurement is completed, the standard deviation is obtained based on the measurement data and stored in the internal memory. The stored data is automatically transmitted through the CDMA module 130 when the data transmission time reaches a certain time. Here, the sampling time, measurement time, number of sample data, and transmission time for measurement can be set by the operator.

That is, it measures 10-20 minutes at 1 second measurement cycle and stores 2000 data in memory in order. Arithmetic operation is performed to find the arithmetic mean, maximum, minimum, and standard deviation. Transmit over wireless TCP / IP. After the transmission to the server is completed, the memory data stored in a certain period of time is deleted. Here, the CPU 122 used "Aduc816BS".

Antenna 135 is a manhole embedded antenna, which is installed outside the metal case protecting the data logger to function to transmit CDMA signals wirelessly (approximately to the height of the lid of the manhole), and protects against durability and external impact It is fully epoxy sealed to allow for waterproof watertightness.

RS232C driver 150 is provided for standard serial interface functionality. In other words, since the communication port of the CPU is TTL level, it is necessary to convert it to a standard serial interface signal in order to connect to an external device such as a notebook or a hand terminal. It is the driver that plays this role. If transmission and reception do not occur, it is also desirable to implement power switching using FETs to minimize power consumption.

Since the data logger device uses a lithium ion battery and has a power saving function, it is designed to be used for more than one year without changing the battery. To minimize power consumption, the device is in power-down mode when it is waiting for measurement and wakes up only at set times. Even during data measurement, each internal module can be powered on and off separately and power is not supplied to unused peripheral I / O modules.

4 through 7 are fuller charts related to the operation of the data logger device of FIG. 1.

First, Figure 4 shows the control flow of the main loop, it is implemented in steps S40-S59. Here, the data logger device in the sleep mode is restarted after a certain time, and performs the measurement or transmission operation. In the case of the measurement operation, the measurement is started at the set measurement time and measurement interval, the analog measurement value received through the signal converter is A / D converted, and the converted digital data is stored in the memory. When the measurement is finished, the arithmetic operation is performed to store the processed measurement data as data for transmission. On the other hand, in the case of transmission, power is supplied to the CDMA module and initialization is performed. If a connection is established, a TCP / IP connection is made and a login is performed. Then, the transmission data stored in the memory is wirelessly transmitted. When the radio transmission of the transmission data is completed, the CDMA module is turned off.

5 shows a control flow for calculating an average value, standard deviation, maximum value, and minimum value by performing arithmetic operation after A / D conversion, and includes steps S500-S512. Here, the data converted into digital data is stored, and then the average value, standard deviation, maximum value, and minimum value are obtained. The above functions are achieved by the control and arithmetic operation of the CPU. When the potential difference between the line drawn from the pipe and the reference electrode is measured at a certain time and an analog measurement signal is output, digital data obtained by A / D conversion is obtained. From this, the average value, standard deviation, maximum value, and minimum value are obtained. To the server. Once transmitted in CDMA, the data is transmitted from the first base station to the server via the communication network. Collected data is used for control, analysis, inquiry and storage in the control center which is a server.

6 shows a control flow related to CDMA transmission, which consists of steps S600-S611. Here, the operation of checking the reception sensitivity until the CDMA power is turned on and off is performed, performing network connection and server connection, and then performing data transmission.

7 shows a control flow performed when performing communication with a hand terminal, which is comprised of steps S700-S714. Here, parameters are transmitted for various settings (date, time, 1 measurement, 2 measurements, transmission, viewing measurement data, sleep mode, etc.) until the RS232C driver is turned off and then powered off. Are updated. The module then enters sleep mode.

The wireless data logger manufactured according to the embodiment of the present invention measures the potential difference between the reference electrode and the pipe installed in the field twice a day. At this time, the measurement is performed for 10 minutes per one time (measurement of data once per second), in which case the measurement time unit can be arbitrarily set by the control of the server or the hand terminal. The measured values are stored by the storage device such as memory, and the average value, standard deviation, maximum value and minimum value of the stored data are calculated by the CPU. In one measurement, four data are calculated. After two measurements and calculations per day, the raw data (4200 raw data) is stored for seven days and then deleted, and the calculations are sent to the central monitoring center once a day. If the data transmission is not smooth, the transmission is retried and the data is transmitted smoothly. The central monitoring center collects, aggregates and stores the data transmitted from each data logger every day and outputs the method potential value in response to the administrator's output command. Therefore, it is possible to promote the convenience of the method potential management work in the field, and will provide a great help in the management and operation of various gas pipelines and other pipelines based on this.

In the above description, the embodiments of the present invention have been described with reference to the drawings, for example. However, it will be apparent to those skilled in the art that the present invention may be variously modified or changed within the scope of the technical idea of the present invention. . For example, if the matter is different, the detailed connection configuration in the data logger device can be changed in various forms.

As described above, according to the data logger device of the present invention, since the meter data is transmitted wirelessly while being installed in the field, remote meter reading provides an easy effect. In addition, according to the present invention, the condition of the pipe corrosion can be analyzed in real time, and the battery life of recharging and maintenance is prolonged according to the operation of the high power saving mode, and is not greatly influenced by the surrounding environment so that Can be collected.

1 is a view showing an installation example of a data logger device according to an embodiment of the present invention.

2 is a conceptual diagram of a remote meter reading system installed with a plurality of data logger device of FIG.

3 is an electronic hardware block diagram of the data logger device of FIG.

4 through 7 are flowcharts related to the operation of the data logger device of FIG.

Claims (8)

In the data logger unit for monitoring the corrosion of the pipe: A signal converter for outputting a magnitude of a potential difference generated between the pipe and a reference electrode provided around the pipe as a measured signal value; Convert the measured signal value output from the signal converter into digital data, obtain the arithmetic measurement data using the converted digital data, generate the data for wireless transmission, and store the data in the storage area. A main controller unit having a memory and a real time clock (RTC); A wireless transmitter configured to wirelessly transmit the wireless transmission data to the ground under the control of the main controller, and comprising a CDMA module; A power manager connected to the main controller to manage power saving of the signal converter and the wireless transmitter; And RS-232C driver connected to the main controller to communicate with the hand terminal is sealed in a waterproof metal case installed in the manhole except for the embedded antenna for data transmission, The arithmetic measurement data is obtained by calculating the average value, the maximum value, the minimum value, and the standard deviation using the digital data. The digital data is measured for 10 to 20 minutes at a sampling rate of 1 second. Data logger is stored in sequence in the memory area. delete delete delete delete delete delete delete