JP2007071712A - Soundness evaluation device, soundness remote evaluation system, soundness evaluation method and soundness evaluation program for anticorrosion-objective pipeline - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To get an omen of jeopardizing soundness of an anticorrosion-objective pipeline, in an early stage, based on a change of an operation state in a cathodic anticorrosion facility. <P>SOLUTION: This soundness evaluation device 30 for the anticorrosion-objective pipeline for evaluating the soundness of the anticorrosion-objective pipeline by getting situations of proper operations in the plurality of cathodic anticorrosion facilities installed in the anticorrosion-objective pipeline is provided with an output value acquiring means 32A for acquiring time-serially an output voltage value and an output current value from the cathodic anticorrosion facility, a circuit resistance value computing means 32B for finding time-serially a circuit resistance value that is a value provided by dividing the acquired output voltage value with the output current value at the same timing, and an anticorrosion facility renewal judging means 32C for judging the necessity of renewal of the cathodic anticorrosion facility, based on a long term change tendency of the circuit resistance value. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a soundness evaluation apparatus for an anticorrosion target pipeline that evaluates the soundness of the anticorrosion target by grasping a situation in which a plurality of cathode anticorrosion facilities installed in the pipeline as the anticorrosion target are operating properly. , Soundness remote evaluation system, soundness evaluation method, soundness evaluation program.

  Pipelines laid in the ground as fuel transportation pipes for gas, oil, etc., water pipes, communication pipes, or power cables, etc., have been laid out with the expansion of living areas, and each pipeline is laid The length is also increased. Such pipelines are exposed to the risk of DC stray current corrosion or natural corrosion due to DC stray currents such as rail leakage current of DC electric railways. The coating applied to the outer surface of the material and the cathodic protection are used together.

  Cathodic protection methods include an external power supply method, a galvanic anode method, and a forced exhaust method. Among these, for the cathodic protection facility of the external power source method and the forced drainage method, it is possible to evaluate the soundness of the anticorrosion object by grasping the operating state of the facility.

  In the external power supply system, a DC voltage is applied to the external electrode and the anticorrosion pipeline installed in the soil from the DC power supply (consisting of an AC power supply, rectifier, transformer, etc.) through the wire, and the external electrode passes through the soil. Thus, a direct current is allowed to flow into the anticorrosion target pipeline to prevent corrosion.

  In addition, the forced drainage system promotes the drainage of the current flowing into the anticorrosion target pipeline by inserting a DC power supply (also called a forced drainer) between the buried anticorrosion target pipeline and the rail of the DC electric railway. The rail here plays the role of the external electrode of the external power supply system described above.

  Such a cathodic protection facility (external electrodes in external power supply systems, DC power supply devices, etc. (hereinafter referred to as external power supply facilities), DC power supply devices in the forced drainage method, etc.) A plurality of cathodic protection facilities are installed in one anticorrosion target pipeline, which is installed for each anticorrosion target section divided into a plurality of sections by insulating joints.

  Also, when dealing with rail leakage current from DC electric railways, there are places with low ground leakage resistance such as railroad crossings and vehicle bases, and due to the popularization of regenerative control vehicles in recent years, Since it is difficult to identify the minimum point of rail ground potential (the maximum point of pipe tube ground potential), install an external power supply facility with small electric capacity in a local area with low rail leakage resistance. Even under such circumstances, the number of cathodic protection facilities installed in one anticorrosion target pipeline is increasing.

  And if the cathodic protection facility has a malfunction in its operating state, if there is a coating defect in the anticorrosion target section, there is a concern about natural corrosion from there, and in other anticorrosion target sections DC current stray current corrosion due to the current flowing into the pipeline flowing into the anticorrosion target section due to the jumping action and out of the coating defect will be a concern. Normal operation is a major premise.

  In this way, in the situation where a plurality of cathodic protection facilities are installed in the anticorrosion target pipeline, in order to monitor the proper operation of the plurality of cathodic protection facilities and the normal anticorrosion status of the anticorrosion target pipeline, It has been proposed to introduce an anticorrosion remote monitoring system (see Patent Document 1 below).

  In this prior art, a monitoring device that employs a monitoring device that monitors a cathodic protection facility that performs cathodic protection on a pipeline subject to anticorrosion, and a monitoring data collection device that collects data of the monitoring device at a remote location, is employed. Comprises a data measuring means for measuring data representing the state of cathodic protection of the cathodic protection facility, and a transmitting means for transmitting the data measured by the data measuring means to the monitoring data collecting apparatus. A system configuration including a receiving unit that receives data transmitted by the transmitting unit and a storage unit that stores data received by the receiving unit is shown.

  Then, according to this cathodic protection facility remote monitoring system, the output voltage and output current from the DC power supply, and further the control pipe ground potential are measured, and the average value, maximum value, minimum value, maximum value and minimum value of these measurement data are measured. Whether the cathodic protection facilities are operating properly at the present time based on the data stored in the monitoring data collection device, which are obtained from the respective measurement times and sent to the remote monitoring data collection device In addition, it is possible to remotely determine whether or not the cathodic protection status is normal in cathodic protection management at the present time.

JP 2004-28795 A

  According to such a conventional cathodic protection facility remote monitoring system, at present, it is possible to remotely determine whether the cathodic protection facility is operating without failure or malfunction and whether the cathodic protection status is normal. It becomes possible. However, in order to maintain the soundness of the pipelines that are subject to corrosion prevention in the future, it is not sufficient to know the current operating status of the cathodic protection facilities and the state of corrosion prevention of the corrosion protection target. It is important to detect signs of threatening health and to eliminate factors that threaten health.

  The life of the cathodic protection facility (external power supply facility) consisting of external electrodes, DC power supply devices, etc. is shorter than the life of the pipeline that is subject to corrosion prevention. It will be necessary to upgrade the cathodic protection facility.

  In order to renew the cathodic protection facility, for example, when the external electrode of the external power source facility is re-installed, it usually involves excavation work of hundreds of meters, so a long construction period and a large amount of construction cost are required. Therefore, immediate response is extremely difficult. Therefore, even if the above-described remote monitoring system can monitor the malfunction of the cathodic protection facility, it takes a predetermined time to update the defective facility. The state of high corrosion risk will continue.

  In addition, although it is possible to grasp the number of years of installation from the installation information of the cathodic protection facility, it is extremely difficult to grasp changes in the surrounding environment of the anticorrosion target pipeline and the cathodic protection facility as time passes. Accordingly, the cathodic protection facility is operated in a situation different from the originally planned operating state due to changes in the surrounding environment, and it may be necessary to renew the facility at a different time from the original plan due to the deterioration state of the facility. As described above, there is a problem in that it is not possible to perform systematic updating on a large number of cathodic protection facilities only by installing information on the cathodic protection facilities.

  In addition, the output method of the external power facility is the “constant potential control method” that controls the output of the DC power supply so that the tube-to-ground potential at the control point becomes a negative set potential from the anti-corrosion potential. "Constant voltage (no control) method", in which a constant voltage is always applied by a DC power supply device between the external electrode and the anticorrosion target pipeline, and a probe for controlling the inflow DC current density at the control point. And a probe for probe DC current density measurement evaluation, and control the output of the DC power supply device so that the probe inflow DC current density at the control point becomes a setting value that passes the cathodic protection standard. There is a “density control method”.

  In external power supply facilities that operate using these various output control methods, changes in the corrosion factor of the pipeline subject to anticorrosion itself (occurrence of coating defects, contact with other metal bodies (metal touch), etc.) and the surrounding area Due to environmental changes, the operating state of the cathodic protection facilities operating in each anticorrosion target section will change.

  However, in the conventional cathodic protection facility remote monitoring system, it is determined whether or not the corrosion protection target is in an appropriate state for corrosion protection management at present based on the pipe-to-ground potential and the probe direct current density of the corrosion protection target pipeline obtained as remote monitoring data. Cathode that can be grasped, but changes in the operating status (output voltage and output current) of the cathodic protection facility are not utilized effectively to detect signs that threaten the health of the object to be protected. There was a problem that the operational status data of the anti-corrosion facility was not effectively used for the assessment of the soundness of the anti-corrosion pipeline.

  This invention makes it a subject to cope with such a situation. In other words, when assessing the soundness of the pipelines that are subject to corrosion protection by grasping the situation in which multiple cathode corrosion prevention facilities installed in the pipelines that are subject to corrosion prevention are operating properly, the Ascertain early signs of threatening the soundness of the target pipeline, detect cathode cathodic protection facility malfunctions and malfunctions based on changes in the operating status of the cathodic protection facilities, and spend time and money on renewals. It is an object of the present invention to enable planned renewal of necessary cathodic protection facilities.

  In order to achieve such an object, the present invention has the following features.

  For one thing, evaluating the soundness of the anticorrosion target pipeline by assessing the state of proper operation of the multiple cathodic protection facilities installed in the anticorrosion target pipeline. In the apparatus, output value acquisition means for acquiring the output voltage value and the output current value of the cathodic protection facility in time series, and a circuit that is a value obtained by dividing the acquired output voltage value by the output current value of the same period Circuit resistance value calculating means for obtaining a resistance value in time series, and anticorrosion facility update determining means for determining the necessity of updating the cathodic protection facility from a long-term change tendency of the circuit resistance value, To do.

  Moreover, in the soundness evaluation apparatus for an anticorrosion target pipeline described above, the output value acquisition means includes an average value calculation means for obtaining an average value within a predetermined measurement period from measurement data, and the output voltage value And the output current value is an average value obtained from measurement data of the output voltage and output current.

  Further, in the above-described pipeline health assessment apparatus, the anticorrosion facility update determination means obtains a difference between the circuit resistance values before and after a set elapsed time, and the cathodic anticorrosion according to an increasing tendency of the difference. It is characterized by judging the necessity of renewal of facilities.

  In addition, in the apparatus for evaluating the health of an anticorrosion target pipeline described above, the anticorrosion facility renewal determination means is an allowable value obtained by dividing the rated output voltage of the cathodic protection facility by the required anticorrosion current of the anticorrosion target. The necessity of renewal of the cathodic protection facility is determined according to a situation in which the circuit resistance value approaches the maximum circuit resistance.

  In addition, in the above-described apparatus for evaluating the health of a pipeline to be protected against corrosion, based on the output current value, an operating state evaluation unit that evaluates the operating state of the cathodic protection facility within an evaluation period; and the output current Load state evaluation means for evaluating the load state of the cathodic protection facility during the evaluation period based on the comparison between the value and the rated current of the cathodic protection facility, and the determination result of the anticorrosion facility update determining means needs to be updated. In this case, an update priority setting unit is provided for setting an update priority of the cathodic protection facility based on the evaluation results of the operating state evaluation unit and the load state evaluation unit.

  Moreover, in the soundness evaluation apparatus for the anticorrosion target pipeline described above, the operating state evaluation unit may determine whether the output current value is generated for a predetermined time or more with respect to the total number of days in the evaluation period. The operation state is calculated by obtaining a calculated operation rate and comparing the operation rate with a reference value.

  Moreover, in the soundness evaluation apparatus for an anticorrosion target pipeline as described above, the load state evaluation unit is configured such that a daily average output current value is equal to a rated current in the cathodic protection facility for the operating days within an evaluation period. A load factor calculated by a ratio of days approached is obtained, and the load state is evaluated by comparing the load factor with a reference value.

  In addition, in the above-described apparatus for evaluating the health of the anticorrosion target pipeline, the anticorrosion target defect detection means for detecting the occurrence of a sudden failure of the anticorrosion target based on a short-term fluctuation state of the output current value. It is characterized by providing.

  In addition, in the soundness evaluation apparatus for the anticorrosion target pipeline described above, the anticorrosion target defect detection means has a difference between the output current values before and after the set short-term elapsed time is more than an allowable range, and The occurrence of the malfunction is detected by detecting that the difference between the subsequent short-term elapsed times is within an allowable range.

  Furthermore, a monitoring unit that is installed in each of the plurality of cathode protection facilities installed in the pipeline to be protected against corrosion, monitors the cathode protection facility, and a measurement data collection unit that collects measurement data from the monitoring unit; And a soundness remote evaluation system for an anticorrosion target pipeline comprising a soundness evaluation unit that evaluates the soundness of the pipeline based on the measurement data collected by the measurement data collection unit, wherein the monitoring unit includes: , An operation state measurement control means for measuring at least an output voltage and an output current indicating an operation state of the cathode anticorrosion facility, and data transmission for transmitting the measurement data measured by the operation state measurement control means to the measurement data collection unit And the measurement data collection unit receives the measurement data transmitted by the data transmission unit. And a data storage means for storing the measurement data received by the data reception means, and the soundness evaluation unit chronologically outputs an output voltage value and an output current value from the stored measurement data. Output value acquisition means for acquiring the circuit resistance value, which is a value obtained by dividing the acquired output voltage value by the output current value at the same time in a time series, and the circuit resistance value Corrosion protection facility renewal determination means for determining the necessity of renewal of the cathodic protection facility from a long-term change trend is provided.

  Further, in the above-described pipeline health remote evaluation system for corrosion protection, the health evaluation unit detects a sudden failure of the corrosion protection target based on a short-term fluctuation state of the output current value. A defect detection means is provided.

  In addition, in the method for evaluating the health of the anticorrosion target pipeline for evaluating the health of the anticorrosion target by grasping the situation in which a plurality of cathodic protection facilities installed in the pipeline to be protected against corrosion are operating properly, An operation state acquisition process for acquiring the output voltage value and the output current value of the cathodic protection facility in time series, and a circuit resistance value that is a value obtained by dividing the acquired output voltage value by the output current value at the same time period. A circuit resistance value calculation process obtained in a time series, and an anticorrosion facility update determination process for determining necessity of updating the cathode anticorrosion facility from a long-term change tendency of the circuit resistance value are performed.

  Further, in the above-described method for evaluating the soundness of an anticorrosion target pipeline, prior to the anticorrosion facility update determination process, a sudden failure occurrence of the anticorrosion target is detected based on a short-term fluctuation state of the output current value. It is characterized by performing anticorrosion target defect detection processing.

  In addition, the anticorrosion target pipeline health assessment program evaluates the health of the anticorrosion target by grasping the situation in which a plurality of cathodic protection facilities installed in the target pipeline are operating properly. A computer having at least a storage unit that stores measurement data obtained by measuring the operating state of the cathodic protection facility and an arithmetic processing unit that performs an operation process on the measurement data stored in the storage unit. Output value acquisition means for acquiring the output voltage value and output current value of the cathodic protection facility from time series, circuit resistance value that is a value obtained by dividing the acquired output voltage value by the output current value of the same period Circuit resistance value calculation means for obtaining in a time series, anticorrosion facility update determination means for determining the necessity of updating the cathodic protection facility from a long-term change tendency of the circuit resistance value, It characterized thereby to function.

  Further, in the above-described pipeline health assessment program for corrosion protection, the computer is used as a corrosion protection target malfunction detection means for detecting a sudden malfunction of the corrosion protection target based on a short-term fluctuation state of the output current value. Furthermore, it is made to function.

  According to the soundness evaluation apparatus, the soundness remote evaluation system, the soundness evaluation method, and the soundness evaluation program for the anticorrosion target pipeline having such characteristics, the following actions can be obtained.

  First, the output voltage value and output current value of the cathodic protection facility are acquired in time series, and the circuit resistance value is obtained in time series from the acquired output voltage value and output current value. The circuit resistance, which is the value obtained by dividing the output voltage of the cathodic protection facility by the output current, is the ground resistance of the anode of the cathodic protection facility (external electrode in the external power supply facility), the ground resistance of the cathode (corrosion protection object), and between the anode and cathode It can be considered that it is the total of the electrical resistance of the electrolyte and the electrical resistance of cables and screws. In an external power supply facility, the time-series fluctuation of the circuit resistance value obtained as described above is mainly due to an increase in the grounding resistance of the anode due to deterioration of external electrode wear and the addition of corrosion factors to the pipeline to be protected against corrosion (coating). This can be attributed to a decrease in the ground resistance of the cathode due to the occurrence of a defective part or the occurrence of a metal touch.

  Here, the increase in the former anode ground resistance is a phenomenon that gradually changes over a long period of time, and the latter decrease in the cathode ground resistance can be regarded as a phenomenon that changes suddenly, so that the circuit gradually increases. It becomes possible to grasp the consumption deterioration state of the external electrode from the long-term change tendency of the resistance value, and thereby it is possible to determine the necessity of renewing the external power supply facility.

  At this time, an average value within a predetermined measurement period is obtained from the measurement data of the output voltage and output current measured when the cathodic protection facility is operated, and each average value is set to the output voltage value and the output current value described above. By dividing the output voltage value by the output current value to obtain the above-described circuit resistance value, it is possible to appropriately grasp the long-term change tendency that excludes time-series fluctuations in a short time.

  Then, the determination as to whether or not to update the cathodic protection facility can be made by determining the difference in circuit resistance values before and after the set elapsed time and determining the increasing tendency of the difference. In other words, when the above-mentioned difference is continuously increasing, it can be grasped that the circuit resistance value gradually increases and the deterioration of the external electrode of the external power supply facility is progressing. Thus, it is possible to determine whether or not the external electrode needs to be updated.

  In addition, the determination as to whether or not to update the external power supply facility should be made based on whether or not the DC power supply can supply the required anticorrosion current to the anticorrosion object. More preferably, the judgment is made based on the situation where the aforementioned circuit resistance value, which tends to increase, increases to the maximum allowable circuit resistance obtained by dividing by the required anticorrosion current of the anticorrosion target. At this time, instead of making a determination when the circuit resistance value exceeds the allowable maximum circuit resistance, a value lower than the allowable maximum circuit resistance (for example, allowable maximum circuit resistance × 0.8 (safety factor)). ) Is set as a threshold value, it becomes possible to detect a failure or malfunction of the cathodic protection facility.

  Then, when the result of the judgment on the update of the cathodic protection facility needs to be renewed, the update priority ordering of the plurality of cathodic protection facilities is performed according to the evaluation of the operating state and the load state of the cathodic protection facility. Here, after confirming that the operating state of the cathodic protection facility is always operating, priority is given to those having a high load state. For high loads, the increase rate of the circuit resistance value is high, and it is predicted that the period from reaching the above threshold to reaching the maximum allowable circuit resistance is short. It is possible to prevent the cathodic protection facility from malfunctioning and malfunctioning, and to shorten the period during which the anticorrosion target is in the anticorrosion state by stopping the operation of the cathodic protection facility. Moreover, by considering the evaluation of the load state, it becomes possible to level the load of the cathodic protection facility installed in one anticorrosion target pipeline.

  At this time, the operating state is evaluated by obtaining an operating rate calculated by a ratio of operating days in which the output current value with respect to the total number of days in the evaluation period has occurred for a predetermined time or longer (not zero). Evaluate by comparing with the reference value. By confirming that this operation rate is 100%, it can be confirmed that the cathodic protection facility is always operating.

  The load condition is evaluated by obtaining a load factor calculated by a ratio of the number of days in which the output current value of the daily average approaches the rated current in the cathodic protection facility with respect to the operating days in the evaluation period, and calculating the load factor. Evaluate by comparing with the reference value. In other words, the load factor increases when operating while maintaining an output current close to the rated current.

  On the other hand, the latter decrease in the cathode ground resistance described above occurs suddenly when a metal touch occurs or the coating of the anticorrosion target pipeline is damaged, and the output current value suddenly increases. Therefore, it is possible to detect a sudden failure with respect to the anticorrosion target such as a metal touch based on a short-term fluctuation state of the output current value. If such a malfunction is detected based on the short-term fluctuation of the output current value, the anticorrosion status (tube-to-ground potential or probe DC current density) of the anticorrosion target satisfies the cathodic protection standard at that time. In many cases, it is important to take this detection as a sign that threatens the health of the anticorrosion target and take appropriate measures.

  In addition, since the increased output current value at this time does not decrease unless the cause of metal touch or the like is eliminated, the above-described failure detection of the anticorrosion target is the difference between the output current values before and after the set short-term elapsed time. It is possible to detect the occurrence of a malfunction by detecting that the difference between before and after the short-term elapsed time is within the allowable range. As a result, it is possible to distinguish between fluctuations in the output current due to disturbance and fluctuations due to the occurrence of a problem.

  The present invention adopts the system configuration of the remote monitoring system shown in the prior art, so that it is possible to perform appropriate soundness evaluation on the anticorrosion target pipeline in which a plurality of cathodic protection facilities are installed. An evaluation system can be constructed.

  Further, the above-described operation or function can be realized by executing a program incorporated in a general-purpose computer. As a result, it becomes possible to add the function of the above-described anti-corrosion pipeline health assessment device to a terminal configured by connecting a general-purpose computer to an existing network line such as the Internet, regardless of the installation location, Remote monitoring of anticorrosion objects is possible from anywhere.

  The present invention has the above-described features, and evaluates the soundness of the anticorrosion target pipeline by grasping the situation in which a plurality of cathodic protection facilities installed in the anticorrosion target pipeline are operating properly. From the change in the operating condition of the cathodic protection facility, it is possible to detect a sign that threatens the soundness of the pipeline to be protected. Moreover, it is possible to detect a failure / failure of the cathodic protection facility from a change in the operating state of the cathodic protection facility. Furthermore, it is possible to make a planned renewal of the cathodic protection facility that takes time and money to renew. In addition, it is possible to remotely monitor the decrease in grounding resistance of the anticorrosion target pipeline from changes in the operating state of the cathodic protection facility, and to quickly grasp the factors that threaten the health of the anticorrosion target.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory diagram showing a configuration of a corrosion remote evaluation system for a corrosion protection target pipeline including a soundness evaluation apparatus for a pipeline 1 that is a corrosion protection target. Here, the remote evaluation system will be described as an example. However, the soundness evaluation apparatus is separated from such a remote evaluation system for the data obtained by measuring the operating state of the recorded cathodic protection facilities. A single device may be used.

  In FIG. 1, the cathodic protection facility 10 exemplifies a facility using an external power supply system (external power supply facility), and is externally embedded in the ground in the vicinity of the coated pipeline 1. The electrode 11 is connected to the pipeline 1 via the DC power supply device 12. Further, in order to grasp the anticorrosion status of the pipeline 1 due to the operation of the cathodic protection facility 10, the probe 13 and the reference electrode 14 embedded in the vicinity of the pipeline 1 are piped via an ammeter 15 or a voltmeter 16, respectively. It is electrically connected to line 1.

Here, the external electrodes 11 is filled with graphite powder 11b to a depth _{D 1} depth drilled vertical hole in 11a (usually 120 m) _{D 2} (typically 90m), it is embedded therein, the external A PVC pipe 11c for passing a conductive wire electrically connecting the electrode 11 and the DC power supply device 12 is disposed in the vertical hole 11a, and gravel 11d for fixing the PVC pipe 11c is packed around the PVC pipe 11c. Yes. The DC power supply device 12 includes, for example, a rectifier that converts an AC voltage supplied from a commercial AC power source into a DC voltage, and an adjustable internal resistance. A DC voltage can be supplied with the line 1 side set as a negative pole.

  According to such a cathodic protection facility, the external electrode 11 has a positive potential with respect to the pipeline 1 by the applied DC voltage (output voltage) V, and conversely, the pipeline 1 has a negative potential. become. Therefore, the external electrode 11 becomes the anode and the pipeline 1 becomes the cathode, and the anticorrosion current corresponding to the output current I of the DC power supply device 12 is supplied to the pipeline 1.

At this time, the cathodic protection state of the pipeline 1 by the cathodic protection facility 10 includes the potential V _{P / S} (“tube-to-ground potential”) between the pipeline 1 and the reference electrode 14 and the direct current flowing into the probe 13 ( It can be evaluated by the probe DC current density obtained from the probe DC current I _P ). Normally, when the verification electrode 14 is composed of a saturated copper sulfate electrode, the probe DC current density is within a range where the tube-to-ground potential VP _{/ S} is −0.85 V or less and over-corrosion does not occur. The output voltage V is adjusted so that is within the range of the cathodic protection control standard.

  Such a cathodic protection facility 10 is provided for each anticorrosion target section partitioned by an insulating joint of each pipeline 1, and a plurality of cathode protection facilities 10 are provided for each pipeline 1. And the monitoring part 20 is provided in each of such a cathodic protection facility.

The monitoring unit 20 measures the output voltage V and the output current I of the cathodic protection facility 10 (DC power supply device 12), and if necessary, the pipe ground potential _{VP / S} that serves as an index of the anticorrosion status of the pipeline 1. And operating state measurement control means 21 for measuring the DC current density of the probe. Further, the operating state measurement control means 21 controls the output voltage of the DC power supply device 12 based on the measurement value that is an index of the anticorrosion status of the pipeline 1 in addition to the acquisition of each measurement value described above. May be.

  Furthermore, the monitoring unit 20 includes a data transmission unit 22 that transmits measurement data of the operating state measurement control unit to a transmission destination described later. The data transmission means 22 is wirelessly connected to a communication network 2 such as a wireless packet network, for example, and transmits measurement data to the communication network 2 by digital wireless communication.

  The communication network 2 is connected to the Internet 3 by a gateway (not shown) or the like, and can transmit and receive data to and from the Internet 3. An e-mail server 4 and a web server 5 are connected to the Internet 3, and a later-described soundness evaluation device 30 is connected. Further, a remote monitor terminal (portable computer) 6 can be appropriately connected. It is in a state.

  That is, the measurement data transmitted from the monitoring unit 20 of the cathodic protection facility 10 is transmitted to the web server 5 and the soundness evaluation device 30 via the Internet 3, and the measurement data and the evaluation result by the soundness evaluation device 30 are electronic. It is sent to the mail server 4 and registered on the home page of the web server 5. Then, the remote monitoring terminal 6 accesses the home page on the web server 5 via the Internet 3, so that the remote monitoring terminal 6 uses the measurement data and the soundness evaluation device 30 of each cathodic protection facility 10. The evaluation results can be viewed.

  In addition, the measurement data transmitted to the Internet 3 and the evaluation result of the soundness evaluation device 30 are also transmitted to the e-mail server 4, and the measurement data and the evaluation result of the soundness evaluation device 30 are periodically or as necessary. Such information can be transmitted to each remote monitor terminal 6 by electronic mail.

  In the above description, the cathodic protection facility using the external power supply method has been described. However, the monitoring device is similarly used when a corrosion prevention facility such as a forced drainage method is adopted instead of the facility using the external power supply method. 20 can be provided to transmit and receive output voltage, output current and the like.

  Next, a data measurement method and a data transmission method by the monitoring device 20 of the cathodic protection facility 10 will be described with reference to FIG. FIG. 2 shows an example of a time chart of data measurement and data transmission in the monitoring unit 20 of the cathodic protection facility 10.

  For example, the monitoring unit 20 of the cathodic protection facility 10 transmits measurement data that is constantly measured every basic measurement period of 2 hours. Of the basic measurement period of 2 hours, for example, 1 hour 59 minutes 30 seconds is used for the measurement period used for data measurement, and the remaining 30 seconds is used for the transmission period used for data transmission.

In the illustrated example, the measurement period is further divided into sub-measurement periods of 1 second intervals, and there are 7170 sub-measurement periods in the measurement period of 1 hour 59 minutes 30 seconds (7170 seconds). become. Here, the operating state measurement control means 21 of the monitoring unit 20 measures four data of the output voltage V, the output current I, the tube-to-ground potential V _{P / S} , and the probe DC current I _P , so 100 ms is devoted to the measurement of the output voltage V, the next 100 ms is devoted to the measurement of the output current I, the next 100 ms is devoted to the measurement of the tube-to-ground potential _{VP / S} , and the next 100 ms is used as the probe DC current I. It is devoted to the measurement of _P. Then, devotes the remainder of the sub-measuring period _{V, I, V P / S} , the average value of I _P each measurement data, the maximum value and the minimum value, and maximum value, the data processing for obtaining the respective measurement time of the minimum value ing.

Output voltage V, the output current I, the tube ground potential _{V P / S,} the measuring probe DC current _{I P,} e.g., the measurement data at the sampling intervals of 0.1m sec acquisition made was in the 1000 between 100m sec Data is acquired. These measurement data are temporarily stored in an internal memory in the operating state measurement control means 21. Then, the data is read from the internal memory during the data processing period, and the average value, the maximum value and the minimum value, and the measurement time of the maximum value and the minimum value for each sub-measurement period are obtained, and these are further stored in the internal memory. .

The transmission period after the end one of the basic measurement period, the output voltage V determined in each sub-measuring period, the output current I, the tube ground potential V _{P / S,} the average value of the probe DC current I _P, the maximum and minimum values, In addition, each measurement time of the maximum value and the minimum value is transmitted to the communication network 2 as time series data.

  FIG. 3 is a block diagram showing the configuration of the soundness evaluation device 30. The soundness evaluation device 30 can be configured by a computer having an input / output unit 30A, an arithmetic processing unit 30B, and a storage unit 30C as hardware configurations, and displays the arithmetic processing result on the arithmetic processing unit 30B as necessary. The display device 30D to be connected is connected. And the soundness evaluation apparatus 30 is provided with the measurement data collection part 31 and the soundness evaluation part 32 as a software structure. Here, an example in which the measurement data collection unit 31 is provided will be described on the assumption that a remote evaluation system is constructed. However, the measurement data collection unit 31 is indispensable in a single soundness evaluation device 30 separated from the remote evaluation system. Instead of the configuration, it is sufficient if there is a means (a means for reading data from a recording medium or the like) that directly supplies measurement data to the soundness evaluation unit 32.

  The measurement data collection unit 31 includes a data reception unit 31A and a data storage unit 31B. The data receiving unit 31A has a function of receiving the measurement data transmitted by the data transmitting unit 22 of the monitoring unit 20 by using the reception function of the input / output unit 30A, and the data storage unit 31B stores the received measurement data. It has the function to memorize | store in the part 30C.

  The soundness evaluation unit 32 includes output value acquisition means 32A, circuit resistance value calculation means 32B, and anticorrosion facility update determination means 32C as basic elements, and further includes operating state evaluation means 32D and load state evaluation means as additional elements. 32E, anticorrosion target defect detection means 32F, calculation result output means 32G, and the like.

  The output value acquisition unit 32A has a function of acquiring the output voltage value and the output current value of the cathode anticorrosion facility 10 in time series from the measurement data. Specifically, from the measurement data (average value data for each sub-measurement period) of the output voltage V and output current I sent every basic measurement period, the average value calculation means 32A1 (from the measurement data within a predetermined measurement period) The average value within the basic measurement period is obtained. That is, there are 7170 pieces of measurement data of the output voltage V and the output current I in one basic measurement period of 2 hours, and the basic measurement is obtained by calculating the sum of these and multiplying by (1/7170). An averaged output voltage value and output current value within the period are obtained. The output voltage value and the output current value obtained in this way are paired and stored in a storage area defined for each basic measurement period, so that the time series output voltage in units of the basic measurement period (2 hours) is obtained. Value and output current value can be obtained. Further, when the storage capacity of the storage unit 30C is large, the average value data for each sub-measurement period sent is stored as it is in correspondence with the storage area corresponding to the sub-measurement period, so that a more detailed time series is stored. Data can also be acquired.

  The circuit resistance value calculation means 32B has a function of obtaining a circuit resistance value that is a value obtained by dividing the acquired output voltage value by the output current value at the same time in a time series. The value obtained by dividing the output voltage V of the DC power supply device 12 by the output current I is the ground resistance of all external electrodes 11 (anodes) in the cathodic protection facility 10, the ground resistance of the pipeline 1 (cathode) that is the anticorrosion target, The value includes the electrical resistance between the anode and the cathode and the electrical resistance such as cables and screws. Usually, there are a plurality of external electrodes 11 of the cathodic protection facility 10 (external power source facility). A value obtained by summing up the values of each of the external electrodes 11 during operation is obtained, which is referred to as the total circuit resistance of the DC power supply device. The circuit resistance value obtained by the circuit resistance value calculating means 32B corresponds to the total circuit resistance described above. The circuit resistance value can be obtained for each basic measurement period, but since it is necessary to grasp the long-term fluctuation trend, the monthly average value or the annual average value is obtained so that these time series changes can be grasped. .

FIG. 4 schematically shows an example of an address map of output voltage values, output current values, and circuit resistance values stored in the storage unit 30C. The address map is arranged in the time series of the basic measurement period with the four storage areas [t _n0 ], [t _n1 ], [t _n2 ], and [t _n3 ] allocated for each basic measurement period as a set. Each of the storage areas [t ₁₀ ]... [T _n0 ] has a structure in which start or end times T ₁ ... T _n in a predetermined basic measurement period are respectively stored, and the storage area [t ₁₁ ]. ... the _{[t n1],} the basic measurement output voltage value in the period _{(average) a} 1 ... _{a n} are stored, the storage area _[t 12] ... the _{[t n2],} the output current at each elementary measurement period the stored value _b 1 ... _{b n,} storage area _[t 13] ... in _{[t n3]} is circuit resistance value _c 1 ... _{c n} in each basic measurement period are stored.

Therefore, in this embodiment, in the output value acquisition means 32A, the output voltage value a _n and the output current value b _n obtained by calculating the time T _n and the measurement data corresponding to the time are stored in the storage areas, respectively. _{[t n0], [t n1} ], stored in the _{[t n2], [t 10} ] ... [t n0], [t 11] ... [t n1], the storage area of _{[t 12] ... [t n2} ] There will be filled with the value in the entire measurement period, respectively (the time T _n, the output voltage value a _n, the output current value b _n).

Then, the circuit resistance calculating unit 32B, the output current value _{b n} acquired from the storage area output voltage value obtained from the _{[t n1] a n} and the storage area _{[t n2], c n =} a n / b n The operation is performed, and the operation result is stored in the storage area [t _n3 ]. As a result, circuit resistance values c ₁ ... C _n arranged in time series are stored in the storage areas [t ₁₃ ]... [T _n3 ], respectively.

  Next, the anticorrosion facility update determination means 32 </ b> C has a function of determining whether or not the cathodic protection facility 10 needs to be updated based on a long-term change tendency of the circuit resistance value. The total circuit resistance of the DC power supply described above gradually increases with the passage of operating time mainly due to the consumption of the external electrode (anode) and backfill (filler) of the external power supply facility. Therefore, it is possible to determine the necessity of renewal of the cathodic protection facility 10 by calculating a long-term change tendency of the circuit resistance value corresponding to the total circuit resistance.

In this case, it is defined as follows permissible maximum circuit resistance R _p and the required protection current I _n with respect to cathodic protection facility 10 of judgment target.

Required protection current I _n is tubular ground potential V _{P / S} of the pipeline 1 is anticorrosive target anticorrosion potential (if the reference electrode 14 is composed of a saturated copper sulphate electrode is -0.85 V) becomes Probe direct current density flowing into all probes 13 (simulating coating defects) electrically connected to the cathodic protection object is the minimum anticorrosion current necessary for the inspection. Refers to the minimum anticorrosion current required to pass the cathodic protection control standard using density as an index. This required protection current I _n are major environmental changes (high voltage AC transmission line established, etc.) without relative cathodic protection object, formation and expansion of defects (paint-covering defects against sudden cathodic protection object to be described later, If there is no occurrence of metal touch, etc., the fluctuation range is small. Setting this required protection current I _n is usually based on the cathodic protection installation or during periodic inspection of the facility 10 (once every six months, etc.) pipe ground potential V _{P / S} or probe direct current density I _P measurement result when Is done.

In contrast, since the direct-current power supply 12 there is the rated voltage V _max is a limit value of the steady output voltage, allowable maximum circuit resistance value obtained by dividing the rated voltage V _max in the required protection current I _n It is defined as R _p (= V _max / I _n ).

FIG. 5 shows an example of long-term fluctuations in circuit resistance values, with the yearly average of circuit resistance values acquired in time series as the vertical axis and the elapsed years (years) after installation of the cathodic protection facility 10 as the horizontal axis. It is the shown graph. Here, as an example, when an external power source facility with a rated voltage V _max of 60 V, a rated current of 30 A, and a required anticorrosion current of 2 A is targeted, the allowable maximum circuit resistance R _p described above is 30 A. As shown, it means that the circuit resistance value gradually increases with the lapse of years, the situation where the circuit resistance value approaches the allowable maximum circuit resistance R _p in the decisions, the update necessity for cathodic protection facilities 10 Judgment can be made.

At this time, it is also outputs the rated voltage V _max of the direct-current power supply 12 is not obtained the required protection current I _n the case where the circuit resistance value the allowable maximum circuit resistance R _p exceeds, cathodic protection of the external power supply system because be performed immediately update facility 10 is very difficult, considering the health maintenance anticorrosion target pipeline 1, updates required for cathodic protection facility 10 before the circuit resistance value reaches the permissible maximum circuit resistance R _p It is necessary to judge sex. Accordingly, the anticorrosion Update property determination means 32C, the allowable maximum circuit safety factor to the resistance R _p (e.g., 70-80%) the value obtained by multiplying the set threshold, chronologically acquired circuit resistance value in this preset threshold It functions to output the judgment of necessity of updating when the value reaches.

Further, the anticorrosion facility update determination means 32C may obtain a difference between circuit resistance values before and after the set elapsed time, and determine whether the cathodic protection facility 10 needs to be updated based on an increasing tendency of the difference. That is, as shown in FIG. 5, the difference ΔR between the circuit resistance value at the lapse of 15 years and the circuit resistance value after 3 years (set elapsed time: ΔY) has been obtained, and its increasing tendency (ΔR / circuit resistance value on the assumption that the [Delta] Y) is followed by predicting the elapsed years leading to permissible maximum circuit resistance R _p. Then, it functions to output a determination of the necessity for renewal when it reaches the number of years elapsed by multiplying the predicted number of years elapsed by the safety factor.

  In addition, since the plurality of cathodic protection facilities 10 are targeted for evaluation in the soundness evaluation apparatus 30, it is possible that a determination of necessity for renewal is output to the plurality of cathodic protection facilities 10 at the same time. On the other hand, the update priority setting means 32C1 shown below can be added to the anticorrosion facility update determination means 32C.

  The update priority setting unit 32C1 is an update target based on the evaluation results of the operation state evaluation unit 32D and the load state evaluation unit 32E described later when the determination result of the anticorrosion facility update determination unit 32C needs to be updated. An update priority order is set for the plurality of cathodic protection facilities 10.

  Here, the operating state evaluation unit 32D evaluates the operating state of the cathodic protection facility within the evaluation period based on the output current value acquired in time series, and the output current value with respect to the total number of days within the evaluation period. The operating rate is calculated by the ratio of the number of operating days that has occurred for a predetermined time or more, and the operating state is evaluated by comparing the operating rate with a reference value.

  That is, for example, in the inspection month (evaluation period) of the DC power supply device 12, the operation rate is determined as {(day when the output current value exceeds zero) / (number of days in the inspection month)} × 100 (%). The operating state is evaluated based on whether or not is 100%. In the above example, the output current value is acquired every 2 hours in the basic measurement period. However, if the output current value exceeds zero within this basic measurement period, it is considered that the current day is operating, and all the days in the evaluation period. The operation rate is assumed to be 100%.

  Here, when setting update priorities, priority is given to those with a high operating rate (100%), and those with a low operating rate (less than 100%) are lowered. The cathodic protection facility 10 with a low operation rate despite the absence of a failure / failure can be considered as having reduced the need for anticorrosion due to changes in the surrounding environment or the renewal of the protection object itself. Renewal prioritization is set low for such cathodic protection facilities 10.

  However, in recent years, external power supply facilities are sometimes installed for the purpose of local cathodic protection, which is a target of anticorrosion embedded in the vicinity of places with low ground leakage resistance such as railroad crossings and vehicle depots. On the other hand, in the case of a railroad crossing, in order to eliminate the risk of corrosion due to rail leakage current that occurs when the vehicle passes, if it is a vehicle base, In order to eliminate the risk of corrosion due to rail inflow current, the DC power supply device 12 of the external power supply facility may be operated. In such a case, the installation purpose of the external power supply facility can be achieved by operating for a certain period of time, so if the output current value of the DC power supply exceeds zero within the basic measurement period of 2 hours, the external power supply The facility is considered to have been operating on that day, and the above-mentioned operating rate is calculated.

  The load state evaluation means 32E evaluates the load state of the cathodic protection facility 10 during the evaluation period based on the comparison between the output current value and the rated current of the cathodic protection facility 10, and operates within the evaluation period. Percentage of days in which the daily average output current value approaches the rated current in the cathodic protection facility relative to the number of days; {(number of days in which the daily average output current value approaches the rated current in the cathodic protection facility) / (number of working days in the evaluation period) )} × 100 (%), specifically, {(the day when the output current value showed 80% or more of the rated current) / (the day when the output current value exceeded zero in the inspection month)} × 100 (% ), And the load state is evaluated by comparing the load factor with a reference value.

Here, when setting priorities, priority is given to those with a high load factor, and priority is lowered for those with a low load factor. What load factor is high, because it is the time from the circuit resistance value exceeds the set threshold value up to the maximum allowable circuit resistance R _p short is predicted, an update of such cathodic protection facility 10 in preference By doing so, the soundness maintenance of the anticorrosion target pipeline 1 is ensured.

  More specifically, the operating state evaluation unit 32D acquires the output current value stored in the storage unit 30C, determines whether or not it exceeds zero for each basic measurement period, and if it exceeds zero Raises a flag. When this operation is performed for one day (12 basic measurement periods) and at least one flag is set, that day is regarded as an operating day and another flag is set. And this operation | movement is performed for 1 evaluation period (for example, January), and the operation rate in the 1 evaluation period is calculated from the count value of another flag and the day count value in 1 measurement period. Whenever the output current value is stored in the storage unit 30C, the above-described operation is repeated as needed to output the operating rate for each evaluation period.

  On the other hand, the load state evaluation means 32E obtains the output current value for one basic measurement period stored in the storage unit 30C for one day (12 basic measurement periods), calculates the average value for one day, It is determined whether or not the average value is 80% or more of the rated current of the cathodic protection facility 10 (previously stored in the storage unit 30C). If it exceeds 80%, a flag is set. This operation is performed for one evaluation period (for example, January), and the load factor within the one evaluation period is calculated based on the count value of the flag and the count value of the number of working days in the above-described operation state evaluation unit 32D. Whenever the output current value is stored in the storage unit 30C, the above-described operation is repeated as needed to output the load factor for each evaluation period.

  Further, the anticorrosion target failure detection means 32F detects sudden occurrence of the anticorrosion target based on the short-term fluctuation state of the output current value, and in particular, outputs before and after the set short-term elapsed time. The occurrence of a malfunction is detected by detecting that the difference between the current values is greater than or equal to the allowable range and that the subsequent difference before and after the short-term elapsed time is within the allowable range.

  Specifically, the anticorrosion target defect detection unit 32F calculates the average value of the output current value for one day in the same manner as the load state evaluation unit 32E described above, and obtains the difference between the average values for each day. Then, the difference is compared with the reference value to confirm that the daily difference is within an allowable range. When the daily difference exceeds the allowable range and the next daily difference is within the allowable range, that is, after the average value of the output current value has once increased, the increased value is maintained. Detects the occurrence of a problem by detecting that it has entered a state.

  FIG. 6 is a graph showing a variation example of the daily average value of the output current value. In this example, it can be seen that the daily average value of the output current value greatly increases by ΔI between the fourth day and the fifth day, and thereafter the increased value is substantially maintained.

  Such fluctuation of the output current value is caused when a coating defect portion is formed in the pipeline 1 that is a corrosion protection target, or when a metal touch that contacts another steel pipe or the like occurs in the corrosion protection target pipeline 1. The fluctuation is characterized in that the output current value that has increased in the short term is maintained after the increase. In other words, the formation of a coating defect or the occurrence of a metal touch causes an increase in the output current value, but the output current value does not decrease unless these phenomena are eliminated. Detection of fluctuation conditions in which the output current value is maintained, that is, the difference between the output current values before and after the set short-term elapsed time exceeds the allowable range, and the difference between the short-term elapsed times thereafter is within the allowable range. By the detection, it is possible to detect a sudden failure such as a metal touch.

  FIG. 7 shows an example of the processing flow of the soundness evaluation apparatus 30 described above. Here, the processing operation for one cathode protection facility 10 will be described, but the same processing is also performed in parallel processing for different cathode protection facilities.

First, when one of the cathodic protection facilities 10 is selected and the process is started, the output value acquisition unit 32A performs data reception (S1) every basic measurement period (2 hours), and receives data once. 7170 pieces of output voltage V in the example of the basic measurement period is 2 hours, output current I, the tube ground potential V _{P / S,} the data of the probe DC current I _P (average value for each sub measurement period, etc.) is received .

Then, for each data reception (S1), an average value (output voltage value V ₀ (expression 1-1), output current value I ₀ (expression 1-2)) for each basic measurement period is obtained by the following expression. (Average value calculation: S2). In addition, the average value of the tube-to-ground potential _{VP / S} for each basic measurement period and the probe DC current density for each basic measurement period are obtained.

Then, each obtained data is stored in a predetermined storage area of the storage unit 30C (data storage: S2). FIG. 8A shows an example of the form of the storage area set at this time. Here, the output voltage value V ₀ (n) and the output current value I ₀ (n) used in the following description will be described. Similarly, the storage area is also related to the tube-to-ground potential V _{P / S} and the probe DC current I _P. Will be formed. In this example, a storage area for 24 hours (1 day) on the assumption that a set of output voltage value V ₀ (n) and output current value I ₀ (n) is obtained every 2 hours of the basic measurement period. Is set. That is, a storage area in which 12 sets of data can be stored in time series is set by combining the basic measurement period end time Tn, the output voltage value V ₀ (n), and the output current value I ₀ (n). Yes.

When the output current value I ₀ for each basic measurement period is obtained, the operation state confirmation (S4) is performed by I ₀ > 0, and the operation state is confirmed when the operation state is confirmed (I ₀ > 0 is YES). When the state confirmation flag F1 is set to F1 = 1 (flag set: S5) and the operation state is not confirmed, the operation state confirmation flag F1 holds the default value 0.

The processing steps S1 to S5 so far are performed for each data reception (every 2 hours), and this is repeated in units of 24 hours (24 hours elapsed ?: S6). Then, every 24 hours when each data is stored in the storage area shown in FIG. 8A, the output value acquisition means 32A causes the daily average value of the output voltage value V ₀ and the output current value I ₀ according to the following equation. V _DA (Formula 2-1) and I _DA (Formula 2-2) are obtained (daily value average calculation: S7).

After that, the circuit resistance value R _DA = V _DA / I _DA is executed by the circuit resistance value calculation means 32B (circuit resistance value calculation: S8). That is, the circuit resistance value R _DA is obtained by the daily average values V _DA and I _DA of the same day every time the daily average value V _{DA of} the output voltage value and the daily average value I _DA of the output current value are calculated. become.

  Then, at the stage where the processing for one day (S1 to S6) is completed, the operation state evaluation means 32D extracts the operation day by the operation state confirmation flag F1> 0 (operation day extraction: S9). That is, when F1> 0 is YES at the stage where the processing for one day (S1 to S6) is completed, the day is regarded as an operating day, and the operating day extraction flag F2 = 1 is set (flag set S10). ), And when F1> 0 is NO, it is regarded as a non-working day, and the working day extraction flag F2 is not set, and the process moves to a result storing step S13.

Further, when it is set in operation day extraction flag F2 = 1, the load state check of the load state by the evaluation unit 32E (S11) is performed, the output current value determined daily value average I _DA and evaluation of target Comparison with the rated current of the DC power supply device 12 in the cathodic protection facility 10 is made. If I _DA > (rated current) × 0.8 (safety factor 80%) is YES, the high load state is evaluated, the load state confirmation flag F3 = 1 is set, and I _DA When> (rated current) × 0.8 (safety factor 80%) is NO, it is evaluated that the load state is not high, and the load state confirmation flag F3 is not set, and the process proceeds to the result storing step S13. .

And the result of the arithmetic processing of step S7-S12 is memorize | stored in the predetermined memory area of the memory | storage part 30C (result memory | storage: S13). FIG. 8B shows a form example of the storage area set at this time. In this example, for each day, a daily average value V _DA (n) of a set of output voltage values, a daily average value I _DA (n) of output current values, and a circuit resistance value R _DA (n) are obtained. Assuming that the operating state and the load state are confirmed, the storage area for one inspection month is set in time series. That is, the measurement date (DATE), the daily average value V _DA (n) of the output voltage value, the daily average value I _DA (n) of the output current value, the circuit resistance value R _DA (n), the operating day extraction flag F2, the load A storage area is set in which the status confirmation flag F3 is set as one set and the data for the set for one month can be stored in time series.

Here, at the stage where the result storage (S13) is made every day, the processing (S14 to S16) by the anticorrosion target defect detection means 32F is sequentially executed. That is, after the third day of the daily average value I _DA of the output current value is stored (n ≧ 3), the processes S14 to S16 are executed, and I _DA (n) of the nth day is stored. After that, the output current value difference calculation (S14) is executed, and ΔI _DA (n−2) = | I _DA (n−1) −I _DA (n−2) |, ΔI _DA (n−1) = │I _DA (n) -I _DA (n-1) │ is obtained.

Then, in the first stage (S15) of detection of the corrosion protection target defect, ΔI _DA (n−2)> (allowable range set value) is determined, and ΔI _DA (n−2)> (allowable range set value) is NO. In the case of, it is evaluated that there is no defect. Further, when ΔI _DA (n−2)> (allowable range set value) is YES, the second stage evaluation of corrosion protection target defect detection is performed (S16), and ΔI _DA (n−1)> (allowable range). When the set value) is NO, it is evaluated that a failure such as a metal touch has occurred in the anticorrosion target pipeline 1, and the anticorrosion status confirmation / measure measure (S30) is performed.

When ΔI _DA (n−1)> (allowable range set value) is YES in step S16, the same as when ΔI _DA (n−2)> (allowable range set value) is NO in step S15. Then, it is evaluated that there is no defect, and the processing from the data reception S1 is continued.

That is, the anticorrosion target defect detection means 32F detects a defect based on the daily average values I _DA (n-2), I _DA (n-2), and I _DA (n) of the output current values for three days. When the output current value fluctuates greatly between the first day and the second day exceeding the allowable range setting value, and the output current value fluctuates immediately before the second day and the third day. It is evaluated that a failure such as a metal touch has occurred in the pipeline 1 to be evaluated. Since the increase in the output current value due to the occurrence of a metal touch or a coating defect is once maintained, it is maintained. Therefore, the occurrence of a defect such as a metal touch is detected by detecting this fluctuation state.

  Also, the output current value fluctuated greatly between the first day and the second day exceeding the allowable range setting value, but the output current value fluctuated again again between the second day and the third day, and the original state When there is no significant fluctuation in all three days, it is evaluated that there is no problem in the anticorrosion target pipeline 1.

Such failure detection of corrosion protection is performed every day after the first 3 days to discover early whether or not a failure such as metal touch has occurred in the pipeline 1 to be protected, and such failure has been discovered. case, check the corrosion situation from instrumented tube ground potential V _{P / S} and the probe DC current I _P, it measures measures accordingly to ascertain quickly the cause (S30).

  If the anticorrosion target defect detection means 32F does not detect a defect, the processing steps S7 to S16 are repeatedly executed until one month has passed (inspection month (January) elapsed: S17), and one month has elapsed. The processing of the next S18 to S21 is performed every time, and determination by the anticorrosion facility update determination means 32C is performed (S22).

  That is, prior to the determination process by the anticorrosion facility update determination unit 32C, the anticorrosion target defect detection process (S15, S16) for detecting a sudden defect occurrence in the anticorrosion target pipeline 1 is executed, and the occurrence of the defect is not detected. In such a case, the anticorrosion facility update determination process (S22) is performed.

The anticorrosion facility update determination process (S22) will be described. First, at the stage where the calculation results for January of the inspection month are stored in the predetermined storage area of the storage unit 30C as the result storage (S13), the output voltage value and the output Monthly average values V _MA , I _MA , R _{MA of} current values and circuit resistance values are calculated (monthly average calculation: S18).

In addition, the operating rate α is calculated (operating rate calculation: S19), and the load factor β is calculated (loading rate calculation: S20). The operating rate α can be calculated by α = ΣF2 / (the number of days in the inspection month), and the load factor β can be calculated by β = ΣF3 / ΣF2. The calculation results of the monthly average values V _MA , I _MA , R _MA and the operation rate α and the load factor β are stored in a predetermined storage area of the storage unit 30C every month (result storage: S21).

Then, as processing of corrosion Update property determining means 32F, comparing the monthly average value R _MA of circuit resistance value preset threshold (anticorrosion Update property determination: S22). Here, the set threshold is a value obtained by multiplying the above-described allowable maximum circuit resistance R _P by a safety factor (for example, 80%), and R _MA > (set threshold) = R _P × 0.8 is determined. _{If MA} > (set threshold value) is NO, the process proceeds to a determination process (S23) of whether or not the evaluation period is ended. If R _MA > (set threshold value) is YES, it is considered that the anticorrosion facility needs to be updated. Then, the process proceeds to the next update prioritization process (S40).

In this example, the monthly average value _RMA of the circuit resistance value is the object of determination. However, after the monthly average value _RMA is stored for one year, the annual average value of the circuit resistance value is obtained, and the annual average value is calculated. Comparison with a set threshold value may be performed as a determination target.

  In process step S23, if the evaluation period has not ended, the process from the data reception (S1) every basic measurement period (2 hours) continues, and if the evaluation period has ended, the process ends.

The update prioritization processing S40 will be described with reference to FIG. This update prioritization process S40 is required to be updated in the anticorrosion facility update determination process (S22) as a result of the parallel processing of the process shown in FIG. _A process is started in a state where a plurality of items determined as _MA > the setting threshold is YES are collected (S41).

  In this example, it is necessary to update for the time being, such as when the anticorrosion effect distance of the cathodic protection facility to be updated is short (less than 10 km) or when a backup anticorrosion facility exists within the same anticorrosion target section of the cathodic protection facility to be updated. Confirmation is made when there is no possibility (update necessity confirmation: S42). If it is determined that there is no need for updating, the process returns to the data reception (S1) of the processing flow shown in FIG. 7 again, and the remote evaluation is continued (S43).

  If it is determined that there is a need for updating, it is determined whether or not the operation rate α obtained in processing step S19 is less than 100% (S44). If it is less than 100% (operation rate α When <100% is YES), the update priority is set to the lowest (fifth).

  When the operation rate α is 100% (when the operation rate α <100% is NO), whether or not the load factor β obtained in the processing step S20 is less than the set height (80% here). Is determined (S45), and if it is less than 80% (when the load factor β <80% is YES), it is assumed that the deterioration rate of the anticorrosion facility is slow, and the update priority is set low. In response to this, a determination is made regarding the installation age of the facility to be updated (S46). For example, if it is less than 20 years after installation, the fourth update priority order is set, and it may exceed 20 years after installation. For example, the third update priority order is set.

  When the load factor β exceeds 80% (when the load factor β <80% is NO), it can be considered that the deterioration rate of the anticorrosion facility is fast due to the high load factor operation, so the update priority is increased. Set. In response to this, a determination is made regarding the installation age of the facility to be updated (S47). For example, if it is less than 20 years after installation, the second update priority order is set, and it may exceed 20 years after installation. For example, the first update priority order is set.

  The evaluation results of the anticorrosion facility update determination means 32C, the update priority setting means 32C1, the anticorrosion target defect detection means 32F, etc. of the soundness evaluation apparatus 30 described above are evaluated for soundness by the operation result output means 32G. While being output and displayed on the display device 30D of the device 30, it is transmitted from the input / output unit 30A to the e-mail server 4 and the web server 5 via the Internet and registered in a predetermined homepage. Therefore, in the management facility where the soundness evaluation device 30 is installed, it is possible to remotely grasp the evaluation results and the like from the display device 30D of the soundness evaluation device 30, and a remote monitor that can be connected to the Internet. By accessing a home page on the web server 5 by the terminal (portable computer) 6, the evaluation result for each cathodic protection facility 10 can be browsed remotely.

  In addition, when a sudden failure of the anticorrosion target pipeline 1 is detected by the anticorrosion target failure detection means 32F, an alarm e-mail can be sent from the e-mail server 4 to each remote monitoring terminal 6. It becomes possible to cope with an unexpected failure of the pipeline 1 to be protected against corrosion at an early stage.

  In the embodiment described above, an external power source system facility is shown as an example of the cathode anticorrosion facility 10, but the present invention is not limited to this, and other anticorrosion facilities such as a forced drainage system are used. It can be targeted as well.

According to the embodiment of the present invention described above, the output voltage value V and the output current value I of the cathodic protection facility 10 are acquired in time series, and the obtained output voltage value V and output current value I are used as a circuit. The monthly average value _RMA or annual average value of the resistance value is obtained in time series. Then, it is possible to grasp the consumption deterioration state of the external electrode 11 from a long-term tendency of change gradually monthly mean R _MA or annual average value of the circuit resistance increases, thereby updating need for an external power supply facilities It becomes possible to judge sex.

At this time, an average value (monthly average value or yearly average value) within a predetermined measurement period is obtained from the measurement data of the output voltage value V and the output current value I measured when the cathodic protection facility is operated, and thereby the circuit described above. By obtaining the monthly average value _RMA or the annual average value of the resistance value, it is possible to appropriately grasp the long-term change tendency that excludes time-series fluctuations in a short time.

Further, whether to update the cathodic protection facility 10 determines the DC power supply is determined by whether it can provide the required protection current against corrosion object, the rated output voltage V _max of the cathodic protection facilities 10 It judged by circumstances required protection current I is divided by _n in the maximum permissible circuit increasing the resistance R _P determined above described circuit resistance value R _MA anticorrosive target approaches. In this case, the allowable maximum circuit resistance R _P rather than the decision in the circuit stage of the resistance value R _MA exceeds lower than the allowable maximum circuit resistance R _P value (e.g., maximum allowable circuit resistance × 0.8 (safety By setting the rate)) as a threshold value, it becomes possible to detect a failure / failure of the cathodic protection facility 10 in advance.

Then, when the result of the update determination of the cathodic protection facility 10 needs to be updated, the update prioritization of a plurality of cathodic protection facilities 10 is performed according to the evaluation of the operating state and the load state of the cathodic protection facility 10. Here, after confirming that the operating state of the cathodic protection facility 10 is always operating (operating rate α100%), priority is given to those having a high load state (people with a high load factor β). In the case of a high load, the rate of increase in the circuit resistance value _RM is high, and it is predicted that the period until the maximum allowable circuit resistance _RP is reached after exceeding the above-mentioned threshold value is given priority. By updating, it is possible to prevent a failure / failure of the cathodic protection facility 10 in advance, and to shorten the period during which the anticorrosion target is in an anticorrosion state by stopping the operation of the cathodic protection facility 10 as much as possible. Moreover, by considering the evaluation of the load state, it is possible to level the load of the cathodic protection facility 10 installed in one anticorrosion target pipeline at the time of re-installation.

On the other hand, it is possible to detect a sudden failure occurs against corrosion object such as metal touch based on short-term fluctuations status of the output current I _DA. When the occurrence of a malfunction based on the short-term fluctuation state of the output current value I _DA is detected by the corrosion protection target malfunction detection means 32F, the corrosion protection status (tube-to-ground potential _{VP / S} or probe DC current) of the corrosion protection target at that time. The density) often meets the cathodic protection standards, but it is important to take this detection as a sign that threatens the health of the anticorrosion target and take appropriate measures.

In addition, since the increased output current value I _DA is not lowered unless the cause of metal touch or the like is eliminated, the above-described failure detection of the anticorrosion target is performed before and after the set short-term elapsed time. The occurrence of a malfunction can be detected by detecting that the difference between the two is equal to or greater than the allowable range, and that the difference between the subsequent short-term elapsed times is within the allowable range. As a result, it is possible to distinguish between fluctuations in the output current due to disturbance and fluctuations due to the occurrence of a problem.

  Thus, the embodiment of the present invention evaluates the soundness of the anticorrosion target pipeline 1 by grasping the situation in which the plurality of cathode anticorrosion facilities 10 installed in the anticorrosion target pipeline 1 are operating properly. At this time, it is possible to detect a sign of threatening the soundness of the pipeline 1 to be protected from the change in the operating state of the cathodic protection facility 10, and the failure and malfunction of the cathodic protection facility can be predicted from the change in the operating state of the cathodic protection facility 10. Can be sensed. Furthermore, it is possible to make a planned renewal of the cathodic protection facility 10 that requires time and cost to renew. In addition, it is possible to remotely monitor the decrease in the ground resistance of the pipeline 1 to be protected from the change in the operating state of the cathodic protection facility 10 as a change in the output current value, and to quickly understand the factors that threaten the health of the corrosion protection target. Become.

It is explanatory drawing which shows the structure of the soundness remote evaluation system of the anticorrosion object pipeline containing the soundness evaluation apparatus of the pipeline which is the anticorrosion object which concerns on embodiment of this invention. It is explanatory drawing which shows the data measurement method and data transmission method by the monitoring apparatus of a cathodic protection facility. It is the block diagram which showed the structure of the soundness evaluation apparatus which concerns on embodiment of this invention. It is explanatory drawing which showed typically the address map of the output voltage value, output current value, and circuit resistance value which were memorize | stored in the memory | storage part of the soundness evaluation apparatus which concerns on embodiment of this invention. It is the graph which showed an example of the long-term fluctuation of circuit resistance value. It is the graph which showed the example of change of the daily average value of output current value It is explanatory drawing which showed an example of the processing flow of the soundness evaluation apparatus which concerns on embodiment of this invention. It is explanatory drawing of the storage area formed in the memory | storage part of the soundness evaluation apparatus which concerns on embodiment of this invention. It is explanatory drawing explaining the update prioritization process of the soundness evaluation apparatus which concerns on embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Pipeline 2 Communication network 3 Internet 4 E-mail server 5 Web server 6 Remote monitoring terminal 10 Cathodic protection facility 11 External electrode 12 DC power supply device 13 Probe 14 Reference electrode 15 Ammeter 16 Voltmeter 20 Monitoring unit 21 Operation state measurement Control means 22 Data transmission means 30 Soundness evaluation apparatus 30A Input / output part 30B Operation processing part 30C Storage part 30D Display device 31 Measurement data collection part 31A Data reception means 31B Data storage means 32 Soundness evaluation part 32A Output value acquisition means 32A1 Average Value calculation means 32B Circuit resistance value calculation means 32C Corrosion protection facility update determination means 32C1 Update priority setting means 32D Operating state evaluation means 32E Load state evaluation means 32F Corrosion protection target defect detection means 32G Calculation result output means

Claims (15)

In the soundness evaluation apparatus for the anticorrosion target pipeline that evaluates the soundness of the anticorrosion target by grasping the situation in which a plurality of cathodic protection facilities installed in the pipeline that is the anticorrosion target are operating properly,
Output value acquisition means for acquiring the output voltage value and the output current value of the cathodic protection facility in time series,
A circuit resistance value calculating means for obtaining a circuit resistance value which is a value obtained by dividing the acquired output voltage value by the output current value of the same period in a time series;
Corrosion protection facility update judging means for judging the necessity of renewal of the cathodic protection facility from a long-term change tendency of the circuit resistance value;
An apparatus for evaluating the soundness of a corrosion-resistant pipeline, comprising:   The output value acquisition means includes an average value calculation means for obtaining an average value within a predetermined measurement period from measurement data, and the output voltage value and the output current value are obtained by measuring the output voltage and the output current of the cathodic protection facility. It is an average value each calculated | required from data, The soundness evaluation apparatus of the anticorrosion object pipeline described in Claim 1 characterized by the above-mentioned.   The said anticorrosion facility update judgment means calculates | requires the difference of the said circuit resistance value before and behind setting elapsed time, and judges the update necessity of the said cathodic protection facility by the upward tendency of this difference, The Claim 1 or 2 characterized by the above-mentioned. A device for evaluating the integrity of a pipeline subject to corrosion protection.   The anticorrosion facility renewal determination means is configured to determine whether the cathode anticorrosion facility has the maximum allowable circuit resistance obtained by dividing the rated output voltage of the cathodic anticorrosion facility by the required anticorrosion current of the anticorrosion target, according to the situation where the circuit resistance value approaches. The soundness evaluation apparatus for an anticorrosion target pipeline according to any one of claims 1 to 3, wherein the necessity for renewal is determined. Based on the output current value, the operating state evaluation means for evaluating the operating state of the cathodic protection facility within the evaluation period, and based on the comparison between the output current value and the rated current of the cathodic protection facility, within the evaluation period Comprising a load state evaluation means for evaluating the load state of the cathode anticorrosion facility,
Update priority setting means for setting an update priority of the cathodic protection facility based on the evaluation results of the operating state evaluation unit and the load state evaluation unit when the determination result of the anticorrosion facility update determination unit needs to be updated. The soundness evaluation apparatus for an anticorrosion target pipeline according to any one of claims 1 to 4, further comprising:   The operating state evaluation means obtains an operating rate calculated by a ratio of operating days in which the output current value is generated for a predetermined time or more with respect to the total number of days in the evaluation period, and compares the operating rate with a reference value. 6. The apparatus for evaluating the soundness of an anticorrosion target pipeline according to claim 5, wherein the operating state is evaluated.   The load state evaluation means obtains a load factor calculated by a ratio of the number of days when the output current value of the daily average approaches the rated current in the cathodic protection facility with respect to the operating days in the evaluation period, and the load factor is used as a reference The apparatus for evaluating the soundness of an anticorrosion target pipeline according to claim 5 or 6, wherein the load state is evaluated by comparing with a value.   The anticorrosion target fault detection means for detecting a sudden fault occurrence of the anticorrosion target based on a short-term fluctuation state of the output current value is provided. Equipment for evaluating the health of the target pipeline.   The anticorrosion target failure detection means detects that the difference between the output current values before and after a set short-term elapsed time is greater than or equal to an allowable range, and that the difference between the subsequent short-term elapsed times is within an allowable range. The soundness evaluation apparatus for an anticorrosion target pipeline according to claim 8, wherein the occurrence of the malfunction is detected. A monitoring unit that is installed in each of the plurality of cathode protection facilities installed in the pipeline to be protected against corrosion, monitors the cathode protection facility, a measurement data collection unit that collects measurement data from the monitoring unit, and the measurement A soundness remote evaluation system for an anticorrosion target pipeline comprising a soundness evaluation unit that evaluates the soundness of the pipeline based on measurement data collected by a data collection unit,
The monitoring unit
An operation state measurement control means for measuring at least an output voltage and an output current indicating an operation state of the cathodic protection facility;
Data transmission means for transmitting measurement data measured by the operating state measurement control means to the measurement data collection unit;
The measurement data collection unit
Data receiving means for receiving the measurement data transmitted by the data transmitting means;
Data storage means for storing the measurement data received by the data receiving means,
The soundness evaluation unit
Output value acquisition means for acquiring an output voltage value and an output current value in time series from the stored measurement data;
A circuit resistance value calculating means for obtaining a circuit resistance value which is a value obtained by dividing the acquired output voltage value by the output current value of the same period in a time series;
An anticorrosion pipeline soundness remote evaluation system comprising: an anticorrosion facility renewal judging means for judging whether or not the cathodic anticorrosion facility needs to be renewed based on a long-term change tendency of the circuit resistance value. The soundness evaluation unit
The soundness of the anticorrosion pipeline according to claim 10, further comprising anticorrosion target failure detection means for detecting occurrence of a sudden failure of the anticorrosion target based on a short-term fluctuation state of the output current value. Remote evaluation system. In the method for evaluating the soundness of the anticorrosion target pipeline for evaluating the soundness of the anticorrosion target by grasping the situation in which a plurality of cathodic anticorrosion facilities installed in the pipeline subject to the anticorrosion are operating properly,
Output value acquisition processing for acquiring the output voltage value and the output current value of the cathodic protection facility in time series,
A circuit resistance value calculation process for obtaining a circuit resistance value which is a value obtained by dividing the acquired output voltage value by the output current value at the same time in a time series;
Corrosion protection facility update determination processing for determining the necessity of updating the cathode protection facility from a long-term change tendency of the circuit resistance value,
A method for evaluating the soundness of an anticorrosion target pipeline, characterized in that Prior to the anticorrosion facility update determination process,
The soundness of the anticorrosion target pipeline according to claim 12, wherein the anticorrosion target defect detection processing is performed to detect a sudden failure occurrence of the anticorrosion target based on a short-term fluctuation state of the output current value. Sex evaluation method. A pipeline health assessment program for assessing the health of the anticorrosion target by grasping the situation in which a plurality of cathodic protection facilities installed in the pipeline subject to corrosion protection are operating properly,
A computer comprising at least a storage unit storing measurement data obtained by measuring the operating state of the cathodic protection facility and an arithmetic processing unit that performs arithmetic processing on the measurement data stored in the storage unit,
Output value acquisition means for acquiring the output voltage value and the output current value of the cathodic protection facility in time series from the stored measurement data,
Circuit resistance value calculation means for obtaining a circuit resistance value in a time series, which is a value obtained by dividing the acquired output voltage value by the output current value at the same time;
Corrosion prevention facility update judgment means for judging the necessity of renewal of the cathodic protection facility from a long-term change tendency of the circuit resistance value,
A program for evaluating the integrity of a pipeline subject to anticorrosion, characterized by functioning as The computer,
15. The anticorrosion target pipeline according to claim 14, wherein the anticorrosion target pipeline further functions as an anticorrosion target defect detecting means for detecting a sudden defect occurrence of the anticorrosion target based on a short-term fluctuation state of the output current value. Health assessment program.

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