KR20040092284A - DCVG measuring apparatus - Google Patents

Abstract

PURPOSE: A DCVG(DC Voltage Gradient) survey system is provided to identify easily a surveying result by detecting a DCVG electrode signal of a buried pipe and displaying the intensity of the DCVG electrode signal. CONSTITUTION: A signal detector(10) is used for detecting a DCVG electrode signal from a probe. A survey unit(20) is used for analyzing the DCVG electrode signal. The survey unit includes a controller(201) for receiving the DCVG electrode signal, an input part(202) for inputting a predetermined command, a storage part(203) for storing the received electrode signal, an analyzer(204) for analyzing the stored electrode signal, and a display(205) for displaying the received electrode signal and the analyzed result. The controller is used for controlling a receiving process, a storing process, an analyzing process, and a displaying process of the DCVG electrode signal according to the predetermined command the input part.

Description

DCVG measuring apparatus

The present invention relates to a DCVG detection device for analyzing and displaying an electrode signal detection result by DC Voltage Gradient (DCVG), which is a method of detecting cover damage of buried pipe without excavation.

DCVG, which is known to be the most accurate method to find buried damages in buried pipes, is used to detect potential damages in the soil around the covering damages in detecting buried damages that may be caused by mechanical defects or damages by other construction during construction of buried pipes. Detect deformation and find cover damage. On the other hand, when DCVG is carried out while interpolating (on, off) the anticorrosive rectifier to the buried pipe.

An electric pen recorder (EPR) has been mainly used as a device for measuring data by the DCVG method. An EPR is a device for recording continuously measured values on a sheet of paper in an analog form using a pen. Work has been carried out in the form of the operator to read the measurements by the naked eye to determine the correct value, to record using a writing tool, and to return to the office to organize the measured value.

Recently, in addition to the use of EPR, devices have been developed to digitize data to organize and display measured values in the field. These devices use a small LCD panel, which not only displays continuous measurement values but also measures previously. There was a problem in that the accumulated values could not be displayed in a stacked form.

The present invention has been made to overcome the above problems, an object of the present invention is to measure and display the DCVG electrode signal of the buried pipe to arrange and display the DCVG detection device that can measure and display the continuous potential distribution To provide.

It is also an object of the present invention to provide a portable detection device that can immediately check the detected results through a display or print output in the field.

BRIEF DESCRIPTION OF THE DRAWINGS The figure for demonstrating the detection of the piping coating damage part by the DCVG method.

2 is a block diagram of a detection device 1 according to an embodiment of the present invention.

3 is a screen example of a detection unit 20 according to an embodiment of the present invention.

4 is a screen example showing a current detection result detected by the DCVG method of the screen example of the detection unit 20.

5 is a screen example sequentially showing the detection results measured to date by the DCVG method of the screen example of the detection unit 30.

In order to achieve the above object, the present invention is a DCVG probe for analyzing the DCVG electrode signal detected through the probe while supplying the on-off current to the buried pipe at a predetermined time interval, the DCVG electrode A detection unit for detecting a signal through the probe and a detection unit for receiving and analyzing the electrode signal from the signal detection unit, wherein the detection unit comprises: a control unit receiving the DCVG electrode signal from the signal detection unit; An input unit for inputting a predetermined instruction for commanding an operation of the probe, a storage unit for storing the electrode signal received by the signal receiving unit, an analysis unit for analyzing the electrode signal stored in the storage unit, and the signal A display for displaying the electrode signal received by the receiver and an analysis result by the analyzer It includes a unit, wherein the control unit provides a DCVG detection device, characterized in that for controlling the reception, storage, analysis and display of the DCVG electrode signal according to the predetermined instruction input to the input unit.

In addition, the detection unit is a touch screen type PDA, characterized in that the signal detection unit and the detection unit is communicated through a serial or parallel interface.

In addition, the analysis of the electrode signal is performed by sequentially extracting the magnitude of the electrode signal stored in the storage unit, characterized in that the display unit displays the sequential electrode signal over time.

In addition, the detection unit further comprises a DCVG-CIPS combined pipe detection device characterized in that it further comprises an output unit for outputting the analysis results.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

First, the detection of the covering damage part of the embedded pipe by the DCVG method will be described with reference to FIG. 1 shows an example of the coating damage detection method by the DCVG method. The DCVG method is a method of detecting the coating damage by measuring the voltage gradient appearing around the pipe 301 when the anticorrosive current is applied to the buried pipe 301. The two saturated copper sulfate reference electrodes 302 are buried in the pipe 301. The voltage difference between the two reference electrodes, that is, the voltage gradient of the ground surface 306, is separated by about 1-2m along the upper portion of the voltmeter 303. At this time, the system current applied to the pipe 301 is periodically turned on and off, and the voltage difference is accurately measured by correcting the potential difference at the time of turning off from the potential difference at the time of turning on. As shown in Fig. 1 (b), the anticorrosive current is concentrated to the coating damage portion having the lowest resistance, so that a large potential gradient occurs around the coating damage portion. Therefore, when the potential is measured along the pipe in the longitudinal direction of the pipe at the ground surface 306 using the two reference electrodes 302, the sign of <on potential-off potential> is shown around the damaged part as shown in FIG. The phenomenon of reversal occurs, whereby the reversal point can be seen that the coating damage.

2 is a block diagram of a DCVG detection device according to the present embodiment. According to FIG. 2, the detection device 1 includes a signal detection unit 10 and a detection unit 20, and the detection unit 20 includes a control unit 201, an input unit 202, a storage unit 203, and an analysis unit. 204 and a display unit 205. Meanwhile, the signal detector 10 and the detector 20 communicate with each other via a serial or parallel interface.

The signal detector 10 detects the DCVG electrode signal through the probe, and the DCVG electrode signal is input to the controller 201 through amplification and A / D conversion. The input unit 202 inputs a predetermined instruction for commanding the operation of the probe 20, and the probe may select whether the signal detector 10 receives a DCVG electrode signal through the input unit 202, which will be described later. As described above, the input unit 202 may select a storage, analysis, and display operation of the DCVG electrode signal.

The storage unit 203 sequentially stores the DCVG electrode signals received by the controller 201 over time. The analysis unit 205 analyzes the DCVG electrode signals stored in the storage unit 204. For example, the DCVG electrode signals stored sequentially are extracted from the storage unit 204 according to time. By performing the analysis. The display unit 206 displays the DCVG electrode signal received by the signal receiver 202 and displays the DCVG electrode signal analyzed by the analyzer 205, and specifically displays the magnitude of the DCVG electrode signal sequentially.

In addition, the analysis result analyzed by the probe 20 may be transmitted to the output unit (not shown) and output. In this case, a normal small printer may be used as an output unit, and the probe has an advantage of directly outputting the result of the observation in the field and confirming the result.

3 shows an example of the screen of the detection unit 20. The detection unit 20 uses a personal digital assistant (PDA) of a touch screen input method, and the A area of the screen displays the detected result, and the result value is displayed after one detection is completed. By pressing an area, one detection point can be stored in the storage unit 203. Pressing the B area allows you to switch between the detection screen and the trend screen (sequential view of the stored data in time). Area C is an area for displaying the current pulse period, detection related message, and the like. Area D is an area for displaying a detection graph. When this area is pressed, detection is started. E area is an area for selecting a menu related to parameter setting.

More specifically, 'ON = 0.0000' in the A area means the on-potential value while the anticorrosive current flows in the pipe, and 'OF = 0.0000' means the off-potential value while the anticorrosive current does not flow in the pipe. 'DF = 0.0000' means the difference between the on potential and the off potential.

'DCVG Measure' in area B shows that the current pulse is being detected in the area D. 'DCVG Trend' shows that the detection data that has been completed until now is shown in the area D. Fig. 5 shows an example of the screen in the 'DCVG Measure' state, and Fig. 6 shows an example of the screen in the 'DCVG Trend' state.

'Pulse = 0.4 & 0.2' in the C area means the pulse period synchronized with the cycle to turn on / off the method current in the pipe, the first 0.4 represents the on cycle and the 0.2 represents the off cycle. In addition to 0.4 & 0.2, there are 1.0 & 0.5, 2.0 & 1.0, 3.0 & 1.5, and 4.0 & 2.0 pulse types. On the other hand, the on / off of the method current is performed using a device called a rectifier interrupter, and the pulse is synchronized with the on / off period set by the rectifier interrupter. 'Ready ...' indicates that the probe is ready to start. If you press the D area to start the probe, the message 'Wait ...' is displayed for a while and then 'Processing ...' is displayed. When the detection device 1 reads the data.

In other areas, 'DCVG [X]' means that if the DCVG method is performed, the probe is carried out in the direction of pipe progress.If a potential reversal point is found during the detection, press 'X ~ Y' on the menu. Change the direction to the Y axis (vertical direction of piping) and proceed with the detection. In addition, 'Saved [0000]' means the number of stored data, and 'Parallel with Pipe [X axis]' means that the detection is performed in the pipe direction when the measurement is performed by the DCVG method. If you change the direction perpendicular to the pipe, it changes to the message 'Across Pipe'.

Hereinafter, the operation of performing the detection and analysis by the detection device 1 of the present embodiment will be described. First, before conducting the detection by DCVG method, the anticorrosive current should be flowed into the buried pipe. If the wire is connected to the pipe by supplying the anticorrosive current from the rectifier to the buried pipe, then disconnect the wire from the rectifier to the pipe. Connect the rectifier interrupter and set the on / off time of the method current in the rectifier interrupter.

On the other hand, if the detection is to be performed in the section using the sacrificial anode method, it is necessary to supply cathode electricity to the pipe by using an external power supply and interrupter, and to turn on and off at regular intervals. As a temporary anode, copper rods, which are usually included in the product of the detection device, may be used, or, in case of no use, the surrounding features may be appropriately used for the train railroad or other steel structures. At this time, the distance between the temporary anode and the pipe becomes wider so that the detection can be widened, the distance between the pipe and the temporary anode should be at least 50 m or more, and preferably 100 m or more. In this case, set the on / off time of the method current in the external power supply and interrupter.

Next, the probe synchronizes the pulse period of the DCVG electrode signal input to the controller 201 through the 'Option' menu in the region E of FIG. 4 with the on-off period of the system current.

The probe presses the area D of FIG. 6 to start the measurement and presses the area A of FIG. 6 when the measurement is completed to store the measurement results.

As described above, according to the present invention, the detection result is clearly detected by detecting the DCVG electrode signal of the buried pipe, displaying the detected electrode signal or storing the detected electrode signal and sequentially displaying the magnitude of the electrode signal according to time. You can see the effect.

In addition, according to the present invention by providing a portable detection device using a PDA can be displayed or analyzed in the field on the detected results, there is an effect that can be immediately confirmed through the print output.

Claims (4)

In the DCVG detection device for analyzing the DCVG electrode signal detected through the probe while supplying the corrosion protection current to the buried pipe at a predetermined time interval, A signal detector for detecting the DCVG electrode signal through the probe; Including a probe for receiving and analyzing the electrode signal from the signal detector, The probe is: A controller which receives the DCVG electrode signal from the signal detector; An input unit for inputting a predetermined instruction for instructing an operation of the detection unit; A storage unit for storing the electrode signal received by the signal receiving unit; An analysis unit analyzing the electrode signal stored in the storage unit; A display unit for displaying the electrode signal received by the signal receiving unit and the analysis result by the analysis unit, And the control unit controls reception, storage, analysis, and display of the DCVG electrode signal according to the predetermined instruction input to the input unit. The DCVG detection device according to claim 1, wherein the detection unit is a touch screen PDA, and the signal detection unit and the detection unit communicate through a serial or parallel interface. The method of claim 1, wherein the analysis of the electrode signal is performed by sequentially extracting the magnitude of the electrode signal stored in the storage unit according to time, and the display unit displays the sequential electrode signal according to time. Probe. The DCVG detection device of claim 1, wherein the detection unit further comprises an output unit capable of outputting the analysis result.