JP2015162095A - Landslide maintenance management system and landslide maintenance management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow any worker to quickly, easily, and appropriately formulate measures according to a type of accident or abnormality of a structure such as a transmission line tower and land due to landslide.SOLUTION: A landslide maintenance management system 1 for supporting formulation of measures according to an accident or trouble due to landslide, detects displacement or deformation generated in a transmission line tower 2 or the like due to landslide by a ground extensometer 12, a total station 13, and a strain gauge 14, determines the type of the accident or abnormality on the basis of the detection results and outputs measures support information corresponding to each type of the accident/abnormality. The type of the accident/abnormality includes, for example, ground crack, washout of sediment, exposure of foundation of a steel tower, irregular displacement of the foundation, irregular displacement of the steel tower, buckling of the steel tower, destruction of the steel tower and the like. When a steel tower has been destructed already, or it is determined to have a high risk of the destruction the steel tower, the landslide maintenance management system outputs information for supporting planning of temporary route construction.

Description

  The present invention relates to a landslide maintenance management system and a landslide maintenance management method for providing information on countermeasures in response to accidents / abnormalities caused by landslides.

  The frequency of landslides and slope failures has increased in recent years mainly in mountainous areas due to abnormal torrential rain. Such landslides and slope failures may cause ground cracks, sediment loss, etc. in areas where power transmission towers are installed in mountainous areas. In addition, when the level of landslide is large, there is a risk of developing into a more serious abnormal situation such as exposure of the foundation of the tower, non-displacement of the foundation, non-displacement of the tower, buckling of the tower. Furthermore, if a very large landslide occurs, there is a risk of collapse of the steel tower.

  In order to prevent the occurrence of tower accidents and abnormalities due to landslides, the risk of occurrence of tower accidents and abnormalities due to landslides is predicted, and countermeasures are taken according to the risk of accidents and abnormalities.・ It is important to take measures before an abnormality occurs.

  At present, workers are manually conducting the prediction of the risk of occurrence of tower accidents and abnormalities due to landslides, and the formulation of countermeasures according to the risk of accidents and abnormalities.

However, neither risk prediction nor countermeasure formulation can be carried out accurately without sufficient experience, so there is no choice but to rely on the individual skills of veteran workers, and the workers are burdened heavily. There is a problem. In addition, regarding the risk prediction and the formulation of countermeasures, a wide variety of matters such as topography, spring water, vegetation, geology, tower structure, and rainfall conditions must be investigated and examined. For this reason, work by manpower takes a long time, and it is difficult to perform accurate prediction or formulation. In addition, prediction and formulation are likely to be arbitrary and errors may occur.
The following Patent Document 1 describes a system that automatically predicts the risk of occurrence of a tower accident / abnormality due to a landslide. This system assigns a predetermined weight to the items listed in the survey sheet prepared for each predetermined area including the point where the steel tower is installed, and performs an arithmetic process to evaluate the evaluation points for each predetermined area. And the risk of landslide can be predicted for each of the predetermined areas based on actual precipitation and evaluation points. According to this system, the prediction of the risk of steel tower accidents and anomalies due to landslides has to rely on the personal skills of experienced workers, and it takes a long time for the prediction work, making accurate prediction difficult. Can solve the problem that the prediction tends to be arbitrary.

JP 2013-23891 A

  However, in the system described in the above-mentioned Patent Document 1, it is not possible to adequately formulate measures in accordance with the risk of an accident / abnormality of a steel tower due to a landslide. As a result, even if the above system is used, the formulation of countermeasures in response to tower accidents and abnormalities due to landslides still has to rely on the individual skills of experienced workers, and it takes a long time for the formulation work. It is difficult to formulate appropriate countermeasures, and the contents of countermeasures are likely to be arbitrary.

  Certainly, the above system outputs a tower and foundation reinforcement list when there is a high risk of accidents / abnormalities in the tower due to landslides. Using this list, the operator will be able to immediately identify the tower or foundation to be reinforced.

  However, the operator cannot specify what measures should be specifically taken from the list for the specified tower or foundation. In other words, there are various types of tower accidents / abnormalities such as ground cracks, sediment loss, foundation exposure, foundation undisplacement, tower undisplacement, tower buckling, and specific measures to be taken for each type differ. . Even with the above-mentioned tower and foundation reinforcement list in hand, workers must still investigate and identify the types of accidents / abnormalities in the tower and formulate specific measures to be taken for the identified types. . In addition, if a steel tower collapses, the construction of a temporary route using steel pillars must proceed immediately, but the specific contents of the temporary route construction, such as the selection of a temporary route, must be investigated manually from the beginning. There must be.

  The present invention has been made in view of, for example, the problems described above, and the problem of the present invention is that any worker can quickly develop a countermeasure such as a structure such as a steel tower due to a landslide or a land accident or abnormality. It is another object of the present invention to provide a landslide maintenance management system and a landslide maintenance management method that can be performed easily and accurately.

  In order to solve the above-mentioned problems, a first landslide maintenance management system of the present invention is a landslide maintenance management system that supports the formulation of measures in response to an accident or abnormality caused by a landslide, and is generated in a structure or land due to a landslide. As a result of the detection by the displacement detector, a storage unit storing countermeasure support information corresponding to each of a plurality of types of accidents or abnormalities to be obtained, a displacement detector that detects displacement or deformation generated in a structure or land due to a landslide, and An abnormality type determination unit that determines the type of accident or abnormality based on the information output unit that reads out and outputs the countermeasure support information corresponding to the type of accident or abnormality determined by the abnormality type determination unit from the storage unit It is characterized by having.

  The second landslide maintenance management system of the present invention is the above-described first landslide maintenance management system of the present invention, wherein the structure is a power transmission tower, and the type of the accident or abnormality includes ground cracks, sediment loss. , Characterized in that it includes exposure of a foundation of a steel tower, displacement of a foundation of a steel tower, displacement of a steel tower or buckling of a steel tower.

  The third landslide maintenance management system of the present invention is the above-described first landslide maintenance management system of the present invention, wherein the structure is a power transmission tower, and the countermeasure support information includes plan support information for temporary route construction. Is included.

  A fourth landslide maintenance management system according to the present invention is the landslide maintenance management system according to any one of the first to third aspects of the present invention described above, wherein the displacement detector includes a ground extensometer, a total station, and a strain gauge. It is a combination of any two or more of the above.

  Further, a fifth landslide maintenance management system of the present invention is the above-described landslide maintenance management system of any one of the first to fourth of the present invention, a data acquisition unit for acquiring precipitation data in a predetermined area; When the precipitation indicated by the precipitation data acquired by the data acquisition unit is equal to or greater than a predetermined threshold, the detection by the displacement detection unit, the determination by the abnormality type determination unit, and the output by the information output unit are executed. And an execution control unit.

  In order to solve the above-mentioned problem, the landslide maintenance management method of the present invention is a landslide maintenance management method that supports the formulation of measures in response to accidents or abnormalities caused by landslides, and the displacement or deformation caused in the structure or land by the landslide. A displacement detecting step for detecting a fault, an abnormal type determining step for determining a type of the accident or abnormality based on a detection result in the displacement detecting step, and a plurality of types of accidents or abnormalities that can occur in a structure or land due to a landslide An information output step of reading out and outputting the countermeasure support information corresponding to the type of accident or abnormality determined in the abnormality type determination step from the storage unit storing the countermeasure support information corresponding to each Features.

  According to the present invention, it becomes possible for any worker to quickly and easily and accurately formulate a countermeasure in response to an accident or abnormality of a structure or land caused by a landslide.

It is explanatory drawing which shows the whole landslide maintenance management system structure by embodiment of this invention. It is a block diagram which shows the structure of the landslide maintenance management apparatus in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the specific example of the survey form in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the specific example of the survey form following FIG. It is explanatory drawing which shows the specific example of the weighting data in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the specific example of the weighting data following FIG. It is explanatory drawing which shows the specific example of the weighting data following FIG. It is explanatory drawing which shows the specific example of the analysis and evaluation form in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the specific example of the analysis and evaluation form following FIG. It is explanatory drawing which shows the landslide management data in the landslide maintenance management system by embodiment of this invention. It is a flowchart which shows the landslide prediction process in the landslide maintenance management system by embodiment of this invention. It is a flowchart which shows the accident and abnormality countermeasure process in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the specific example of the plan support information of temporary route construction in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the other specific example of the plan support information of temporary route construction in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the other specific example of the plan assistance information of temporary route construction in the landslide maintenance management system by embodiment of this invention. It is explanatory drawing which shows the other specific example of the plan assistance information of temporary route construction in the landslide maintenance management system by embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Landslide maintenance management system)
FIG. 1 shows a landslide maintenance management system according to an embodiment of the present invention together with a transmission tower (construction). In FIG. 1, the landslide maintenance management system 1 according to the embodiment of the present invention predicts the risk of accidents / abnormalities in the power transmission tower 2 and the surrounding land due to landslides when rainfall occurs in the jurisdiction. At the same time, it is a system that provides information on countermeasures according to the risk of accidents and abnormalities. In the present embodiment, the landslide maintenance management system 1 provides information on the prediction of risk and the countermeasures for a plurality of predetermined areas belonging to the jurisdiction (hereinafter referred to as “target areas”). This is performed for each target area. Each target area is, for example, a rectangular area of 150 m × 150 m including a point where the power transmission tower 2 is installed.

  As shown in FIG. 1, the landslide maintenance management system 1 includes a landslide maintenance management device 11, a ground extensometer 12, a total station 13, a strain gauge 14, a communication device 15, and a battery 16.

  The landslide maintenance management device 11 generates landslide management data, predicts the risk of accidents / abnormalities occurring in the transmission tower 2 due to landslides, and information on countermeasures according to the risk of accidents / abnormalities in the transmission tower 2 etc. It is a device that provides and the like. The landslide maintenance management device 11 is provided at a control station or the like located away from the target area, for example.

  The ground extensometer 12 is a device that mainly measures the ground fluctuation (displacement of land) at the point where the transmission tower 2 is installed. The ground extensometer 12 can measure the amount of expansion and contraction in a section sandwiching a crack or a step caused by a landslide. The landslide maintenance management system 1 according to the present embodiment includes, for example, a ground extensometer 12 that detects or measures ground fluctuation in the east-west direction, and a ground extensometer 12 that detects or measures ground fluctuation in the north-south direction orthogonal to the east-west direction. Yes. Any ground extensometer 12 is provided in the vicinity of the power transmission tower 2.

  The total station 13 is a device that measures a distance and an angle with a target, and has a function of receiving and measuring a signal from a GPS (Global Positioning System) satellite with a GPS receiver, for example. The total station 13 can measure the amount of displacement of the steel tower, the foundation of the steel tower, and the earth and sand around the steel tower caused by the landslide. The total station 13 is arranged in the vicinity of the power transmission tower 2.

  The strain gauge 14 is a device that is attached to a lower frame portion of the power transmission tower 2 and detects deformation of the lower frame portion. The strain gauge 14 can detect an axial force or the like applied to the frame portion of the power transmission tower 2 by a landslide.

  The communication device 15 transmits the measurement data output from the ground extensometer 12, the measurement data output from the total station 13, and the detection data output from the strain gauge 14 to the landslide maintenance management device 11 as abnormality monitoring data, for example, wirelessly. It is a device to do. The communication device 15 is provided for each target area, for example. A ground extensometer 12, a total station 13, and a strain gauge 14 are connected to the communication device 15 via, for example, a cable, and measurement data or detection data output from these devices is connected to the communication device 15 via the cable. Is transmitted.

  The battery 16 is, for example, a solar panel, and is a power source for the ground extensometer 12, the total station 13, the strain gauge 14, and the communication device 15.

  FIG. 2 shows the configuration of the landslide maintenance management apparatus 11. The landslide maintenance management apparatus 11 can be realized by a personal computer, for example. As shown in FIG. 2, the landslide maintenance management apparatus 11 includes a data generation unit 21, a landslide prediction unit 22, an accident / abnormality countermeasure unit 23, a storage unit 24, a communication unit 25, an input unit 26, and an output unit 27. Yes.

  The data generation unit 21 has a function of generating landslide management data. The landslide prediction unit 22 has a function of predicting the risk of occurrence of an accident or abnormality in the power transmission tower 2 or the like due to a landslide. The accident / abnormality countermeasure unit 23 has a function of providing information on countermeasures according to the risk of accidents / abnormalities in the power transmission tower 2 or the like. The data generation unit 21, the landslide prediction unit 22, and the accident / abnormality countermeasure unit 23 are realized by causing a CPU (central processing unit) of a personal computer to read and execute a computer program.

  The storage unit 24 is a storage device including, for example, a hard disk drive. The communication unit 25 includes a communication circuit that can be connected to, for example, a mobile communication network or the Internet, and can communicate with the communication device 15. The input unit 26 is, for example, a keyboard, a mouse, or an optical disk drive, and further includes an external input device such as a USB (Universal Serial Bus). The output unit 27 is, for example, a liquid crystal display device, and includes a printer when the printer is connected to a personal computer.

  The landslide maintenance management system 1 having such a configuration specifically predicts (1) a process for generating landslide management data, and (2) a risk of occurrence of an accident / abnormality in the transmission tower 2 or the like due to the landslide. Processing and (3) Processing for providing information on countermeasures according to the risk of accidents / abnormalities in the transmission tower 2 or the like. Hereinafter, these processing contents will be described.

(Landslide management data generation process)
The landslide management data is data indicating the total evaluation score of the degree of risk that an accident or abnormality occurs in the transmission tower 2 or the like due to the landslide for each target area. The landslide management data is used for a landslide prediction process described later.

  The generation of landslide management data is achieved by a survey using a survey sheet by a worker and a landslide management data generation process by the landslide maintenance management device 11.

  Specifically, first, the worker surveys the survey items described in the survey form for one target area, and records the survey results for each survey item in the survey form. Subsequently, the worker inputs the survey result described in the survey form to the landslide maintenance management apparatus 11 via the input unit 26. Subsequently, the data generation unit 21 of the landslide maintenance management apparatus 11 weights each input survey result based on the weighted data, and calculates an evaluation score for each survey result. Furthermore, the data generation unit 21 calculates the sum of evaluation scores of all the survey results input this time for one target area. Subsequently, the data generation unit 21 generates landslide management data by associating the transmission tower number (tower number), the line name of the transmission tower, the calculated evaluation point total, and the like included in the one target area. The generated landslide management data is stored in the storage unit 24. Further, the data generation unit 21 outputs an analysis / evaluation vote in which the total evaluation score of the one target area is written via the output unit 27. The generation of landslide management data as described above is performed, for example, for all target areas in the jurisdiction area. FIG. 10 shows a specific example of landslide management data.

  Here, the survey form, the weighting data, and the analysis / evaluation form will be described. The survey form is a list of survey items related to landslides. The survey items are mainly matters that can cause landslides. For example, the survey items are matters relating to features of topography, features of slopes, spring water on slopes, vegetation status, geological features, surrounding conditions, tower conditions, and the like. Workers can conduct surveys on landslides by conducting surveys using survey forms and recording the survey results in survey forms. 3 and 4 show specific examples of survey forms.

  The weighting data is evaluation point data for weighting evaluation to the analysis result of the survey item regarding the landslide. The weighting data is stored in advance in the storage unit 24 of the landslide maintenance management apparatus 11. 5 to 7 show specific examples of weighting data.

  The analysis / evaluation vote is a vote that describes the total evaluation score of the degree of risk that an accident or abnormality occurs in the transmission tower 2 due to a landslide. In addition, the analysis / evaluation form describes in detail the analysis contents of survey items related to landslides. 8 and 9 show specific examples of analysis / evaluation votes. The explanation of handling of analysis / evaluation forms is omitted.

  The details of the generation process of such landslide management data can be referred to the description in Patent Document 1 above.

(Landslide prediction process)
FIG. 11 shows a landslide prediction process by the landslide maintenance management apparatus 11. The landslide prediction process is a process for predicting the risk of an accident or abnormality occurring in the power transmission tower 2 or the like due to a landslide.

  The landslide maintenance management apparatus 11 performs a landslide prediction process using, for example, rainfall information provided from a disaster prevention information system of a local government. This rainfall information includes data indicating the rainfall area, 48h precipitation, and continuous precipitation.

  As shown in FIG. 11, when the landslide prediction unit 22 of the landslide management maintenance apparatus 11 receives the rainfall information in the jurisdiction area via the communication unit 25 (step S1: YES), the landslide prediction unit 22 then receives the information. Based on the rainfall information thus made, it is determined whether or not the 48h precipitation amount is, for example, 300 mm or more (step S2).

  If the 48h precipitation is 300 mm or more (step S2: YES), then the landslide prediction unit 22 determines whether the continuous precipitation is, for example, 150 mm or more (step S3).

  When the continuous precipitation is 150 mm or more (step S3: YES), the landslide prediction unit 22 determines whether the continuous precipitation is 200 mm or more, for example (step S4).

  As a result of the determination in step S4, when the continuous precipitation is not 200 mm or more (step S4: NO), that is, when the continuous precipitation is in the range of 150 mm or more and less than 200 mm, the landslide prediction unit 22 By referring to the landslide management data stored in the storage unit 24, a target area having a total evaluation score of, for example, 50 or more is specified, and a periodic check required list in which the track name and the tower number of the specified target area are written is generated (step) S5). Subsequently, the landslide prediction unit 22 outputs the generated periodic check necessity list via the output unit 27. The worker can perform periodic confirmation of the transmission tower 2 and the surrounding land by using the outputted periodic confirmation requirement list. If the 48h precipitation is 300 mm or more and the continuous precipitation is 150 mm or more and less than 200 mm, there is a low risk of accidents and abnormalities occurring in the transmission tower 2 etc. due to landslides. A relatively simple and relatively infrequent periodic check is performed, and if necessary, a simple reinforcing measure or the like is applied to the transmission tower 2 or the like, so that sufficient safety can be ensured.

  On the other hand, as a result of the determination in step S4, if the continuous precipitation is 200 mm or more (step S4: YES), then the landslide prediction unit 22 determines whether the continuous precipitation is, for example, 250 mm or more. (Step S6).

  As a result of the determination in step S6, if the continuous precipitation is not 250 mm or more (step S6: NO), that is, if the continuous precipitation is in the range of 200 mm or more and less than 250 mm, the landslide prediction unit 22 By referring to the landslide management data stored in the storage unit 24, a target area having a total evaluation score of, for example, 70 or more is specified, and a constant confirmation required list in which the track name and the tower number of the specified target area are recorded is generated (step) S7). Subsequently, the landslide prediction unit 22 outputs the generated constant confirmation necessity list via the output unit 27. The worker can always check the power transmission tower 2 and the surrounding land using the always-on confirmation list that is output. If the 48h precipitation is 300 mm or more and the continuous precipitation is 200 mm or more and less than 250 mm, the risk of accidents / abnormalities in the power transmission tower 2 due to landslides is not so high. Although the personnel are relatively simple, it is possible to ensure sufficient safety by performing a relatively frequent constant check and applying simple reinforcement measures to the transmission tower 2 as necessary.

  On the other hand, as a result of the determination in step S6, when the continuous precipitation is 250 mm or more (step S6: YES), the landslide prediction unit 22 refers to the landslide management data stored in the storage unit 24, and evaluates the score. For example, a target area having a total of 100 or more is specified, and a command to start an accident / abnormality countermeasure process is issued to the specified target area (step S8). If the 48h precipitation is 300 mm or more and the continuous precipitation is 250 mm or more, there is a high risk of accidents and abnormalities occurring in the transmission tower 2 etc. due to landslides. Transition.

  On the other hand, if the 48h precipitation is not 300 mm or more as a result of the determination in step S2 (step S2: NO), or if the continuous precipitation is not 150 mm or more as a result of the determination in step S3 (step S3: NO) ) The landslide prediction unit 22 stores the 48h precipitation amount or the continuous precipitation amount in the storage unit 24 (step S9). Thereby, it is possible to keep a record of the rainfall situation.

(Accident / Abnormality Countermeasure Processing)
FIG. 12 shows accident / abnormality countermeasure processing by the landslide maintenance management apparatus 11. The accident / abnormality countermeasure processing is processing for providing information on countermeasures according to the risk of accident / abnormality of the power transmission tower 2 or the like due to a landslide.

  In the landslide prediction process described above, when an accident / abnormality countermeasure processing start command is issued (step S8 in FIG. 11), the accident / abnormality countermeasure process shown in FIG. 12 is started. The accident / abnormality countermeasure process is performed for each target area with respect to all target areas having a total evaluation score of 100 or more specified in step S8 of the landslide prediction process. The accident / abnormality countermeasure processing for one target area will be described.

  In the accident / abnormality countermeasure processing, first, the accident / abnormality countermeasure unit 23 of the landslide maintenance management apparatus 11 receives abnormality monitoring data from the communication device 15 via the communication unit 25 (step S21). The abnormality monitoring data includes measurement data output from the ground extensometer 12, measurement data output from the total station 13, and detection data output from the strain gauge 14.

  Subsequently, the accident / abnormality countermeasure unit 23 determines the type of accident / abnormality based on the received abnormality monitoring data (step S22). In this embodiment, the types of accidents / abnormalities include, for example, ground cracks, earth and sand loss, steel tower foundation exposure, steel tower foundation non-displacement, steel tower non-displacement, steel tower buckling, and steel tower collapse.

  For example, based on the measurement data output from the ground extensometer 12, when it is recognized that the expansion / contraction amount of the section sandwiching the crack is equal to or greater than a predetermined expansion / contraction amount threshold, the accident / abnormality type is ground crack. Determined.

  In addition, when it is recognized that the amount of earth and sand movement displacement around the tower is greater than or equal to the predetermined first earth and sand movement displacement threshold based on the measurement data output from the total station 13, the accident / abnormality type is the sediment loss. It is determined that

  Further, when it is recognized that the amount of movement displacement of the earth and sand around the tower is greater than or equal to a predetermined second earth and sand movement displacement threshold based on the measurement data output from the total station 13, the accident / abnormality type is the basic body. Determined to be exposure. Here, the second sediment movement displacement threshold value is larger than the first sediment movement displacement threshold value.

  Further, when it is recognized based on the measurement data output from the total station 13 that the movement displacement amount of the foundation is equal to or greater than a predetermined first foundation movement displacement threshold value, the accident / abnormality type is the foundation non-uniform displacement. It is determined.

  In addition, when it is recognized that the moving displacement amount of the steel tower is equal to or larger than the predetermined first steel tower moving displacement threshold based on the measurement data output from the total station 13, the accident / abnormality type is the tower non-uniform displacement. It is determined.

  In addition, even when it is recognized that the axial force applied to the frame portion of the steel tower is greater than or equal to the predetermined first axial force threshold based on the detection data output from the strain gauge 14, the accident / abnormality type is not the same as the steel tower. It is determined that the displacement.

  Further, based on the measurement data output from the total station 13, the moving displacement amount of the tower is greater than or equal to a predetermined second tower moving displacement threshold value, and the moving displacement amount of the foundation is greater than or equal to the predetermined second foundation moving displacement threshold value. When it is recognized that the axial force applied to the frame portion of the tower is greater than or equal to the predetermined second axial force threshold based on the detection data output from the strain gauge 14, the accident / abnormality type is tower buckling. It is determined that Here, the second steel tower movement displacement threshold is a value larger than the first steel tower movement displacement threshold, the second foundation movement displacement threshold is a value larger than the first foundation movement displacement threshold, The axial force threshold value 2 is a value larger than the first axial force threshold value.

  Moreover, based on the abnormality monitoring data received this time and the later-described progress data stored in the storage unit 24, for example, ground crack, sediment discharge, foundation body exposure, foundation displacement, tower tower displacement, tower buckling, etc. When it is recognized that a plurality of abnormality types are continuously generated at a predetermined short interval, it is determined that the tower collapse has already occurred or that the tower collapse has occurred in a short period of time.

  The specific method for determining the accident / abnormality type described above is merely an example.

  Subsequently, the accident / abnormality countermeasure unit 23 determines whether or not temporary route construction is necessary (step S23). For example, if it is determined in step S22 that the tower has already collapsed or the tower collapse has occurred in a short period of time, the accident / abnormality countermeasure unit 23 determines that temporary route construction using the steel pillar is necessary. (Step S23: YES).

  When temporary route construction is necessary, the accident / abnormality countermeasure unit 23 reads the temporary route construction plan support information from the storage unit 24, and outputs the read temporary route construction plan support information via the output unit 27. (Step S24).

  Here, the temporary route construction plan support information includes, for example, a recovery plan form as shown in FIG. The recovery plan form includes an outline of the facility for the temporary route, a process plan, a construction plan, a material plan, and a transportation plan. In addition, the route selection plan includes, for example, a route selection slip in the temporary route construction plan support information. The route selection slip includes, for example, an aerial photograph as shown in FIG. 14, a plan view as shown in FIG. 15, and a longitudinal view as shown in FIG. Such temporary route construction plan support information is stored in the storage unit 24 in advance.

  The accident / abnormality countermeasure unit 23 ends the accident / abnormality countermeasure processing after outputting the planning support information for the temporary route construction.

  On the other hand, if it is determined in step S22 that the steel tower has not collapsed and that the steel tower will not collapse in a short period of time, the accident / abnormality countermeasure unit 23 does not require temporary route construction. Judgment is made (step S23: YES).

  In this case, since it is determined in step S22 that the type of accident / abnormality is any one of ground crack, sediment discharge, foundation body exposure, foundation non-displacement, steel tower non-displacement, steel tower buckling. The accident / abnormality countermeasure unit 23 selects countermeasure support information corresponding to the determined accident / abnormality type, reads the selected countermeasure support information from the storage unit 24, and outputs the read countermeasure support information to the output unit 27. (Steps S25 to S29).

  Here, the storage unit 24 stores in advance a plurality of countermeasure support information respectively corresponding to a plurality of types of accidents / abnormalities that may occur in the target area. In the storage unit 24, each accident / abnormality type is associated with countermeasure support information for an accident / abnormality type that may occur next to the accident / abnormality type. In other words, accidents and abnormalities due to landslides are likely to proceed in the order of ground cracks, sediment runoff, foundation body exposure, foundation non-displacement, tower non-displacement, and tower buckling. Therefore, when any accident / abnormality type is determined, it is desirable to take measures in advance for an accident / abnormality type that may occur after the determined accident / abnormality type. Based on this concept, countermeasure support information for an accident / abnormality type that may occur after the accident / abnormality type is associated with each accident / abnormality type and stored in the storage unit 24.

  Specifically, in the storage unit 24, the ground support crack is associated with countermeasure support information for sediment loss that is likely to occur next to the ground crack. Therefore, when it is determined as a ground crack in step S22, the accident / abnormality countermeasure unit 23 outputs countermeasure support information for sediment loss (step S25). The countermeasure support information for sediment loss includes countermeasure support information for reducing slope failure. Further, the countermeasure support information for reducing slope failure includes, for example, implementation methods and know-how about prevention sheet curing, drainage groove installation, and crack closure.

  Further, in the storage unit 24, countermeasure support information for a non-foundation displacement that is likely to occur next to the foundation body exposure is associated with the sediment loss or foundation body exposure. Therefore, when it is determined in step S22 that the sediment has been lost or the foundation body has been exposed, the accident / abnormality countermeasure unit 23 outputs countermeasure support information for the inconsistent foundation displacement (step S26). The countermeasure support information for the basic uneven displacement includes countermeasure support information for reducing the basic uneven displacement. Further, the countermeasure support information for reducing the uneven displacement of the foundation includes, for example, implementation methods and know-how about the rigid connection between the foundations and the installation of the flow-stop branch line.

  Further, in the storage unit 24, countermeasure support information for a tower undetermined displacement that is likely to occur next to the foundation unequal displacement is associated with the foundation unequal displacement. Therefore, when it is determined in step S22 that the foundation is indistinct displacement, the accident / abnormality countermeasure unit 23 outputs countermeasure support information for the tower indistinct displacement (step S27). The countermeasure support information for the tower-independent displacement includes countermeasure support information for reducing the tower-independent displacement. The countermeasure support information for reducing the displacement of the steel tower includes, for example, an implementation method and know-how about the bottom joint.

  In the storage unit 24, countermeasure support information for tower buckling that is likely to occur next to the tower non-uniform displacement is associated with the tower non-uniform displacement. Therefore, when it is determined in step S22 that the tower is not displaced, the accident / abnormality countermeasure unit 23 outputs countermeasure support information for tower buckling (step S28). Countermeasure support information for steel tower buckling includes countermeasure support information for foundation reinforcement. Further, the countermeasure support information for the foundation reinforcement includes, for example, an implementation method and know-how about the lifting strength compensation.

  Further, in the storage unit 24, countermeasure support information for a tower collapse that is likely to occur next to the tower buckling is associated with the tower buckling. Therefore, when it is determined in step S22 that the tower is buckled, the accident / abnormality countermeasure unit 23 outputs countermeasure support information for the collapse of the tower (step S29). Countermeasure support information for tower collapse includes countermeasure support information for steel tower reinforcement. Further, the countermeasure support information for reinforcing the steel tower includes, for example, an implementation method and know-how for buckling deformation material reinforcement.

  After outputting the countermeasure support information as described above, the accident / abnormality countermeasure unit 23 stores the determination result of the accident / abnormality type in step S22 as progress data together with information indicating the current date and time. (Step S30).

  Subsequently, the accident / abnormality countermeasure unit 23 determines whether an instruction to end the accident / abnormality countermeasure processing is input to the landslide maintenance management apparatus 11 via the input unit 26 by the worker ( Step S30).

  If a command to end the abnormality countermeasure process is not input (step S30: NO), the accident / abnormality countermeasure unit 23 proceeds to step S21 after a predetermined time (for example, 12 hours) has elapsed. return. While the command to end the abnormality countermeasure process is not input, the process returns from step S31 to step S21 many times every predetermined time. During that time, the determination result of the accident / abnormality type is accumulated as elapsed data in step S30. Go. In the accumulated data, in step S22, a plurality of abnormal types such as ground cracks, sediment discharge, foundation body exposure, foundation non-displacement, tower non-displacement, and tower buckling are continuously generated at predetermined short intervals. Used to determine whether or not It should be noted that during repeated execution of steps S21 to S31, it is desirable not to output duplicate countermeasure support information within a short time.

  On the other hand, when an instruction to end the accident / abnormality countermeasure process is input by the worker in step S30 (step S30: YES), the accident / abnormality countermeasure unit 23 performs the accident / abnormality countermeasure process. finish.

As described above, according to the landslide maintenance management system 1 according to the embodiment of the present invention, the type of accident / abnormality that has occurred in the target area due to the landslide is measured from the ground extensometer 12, the total station 13, and the strain gauge 14. Data and detection data are automatically determined, and countermeasure support information corresponding to the determined type of accident / abnormality is automatically output. To quickly, easily, and accurately formulate measures that correspond to the type of accident / abnormality that occurs (measures for the type of accident / abnormality that may occur next to the current type of accident / abnormality) Can do.
Further, according to the landslide maintenance management system 1, it is possible to determine the ground / cracking / sediment loss, foundation exposure, foundation non-displacement, tower non-displacement, tower buckling, and tower collapse as accident / abnormality types. Since such detailed accident / abnormality type determination can be performed, accurate countermeasure support information can be provided to the worker.

  Further, according to the landslide maintenance management system 1, provisional route construction support plan information can be provided to workers. Temporary route construction has a wide range of items to be formulated, and it takes a very long period of time to consider all the tasks that need to be done by human power alone. By obtaining support plan information for temporary route construction from the landslide maintenance management system 1, the worker can greatly reduce the time spent for formulating temporary route construction.

  Further, according to the landslide maintenance management system 1, the combination of the ground extensometer 12, the total station 13, and the strain gauge 14 detects the displacement and deformation of the power transmission tower 2 and the displacement of the land around the power transmission tower 2, and an accident / abnormality is detected. Since the abnormality monitoring data necessary for the determination of the type is acquired, the detailed determination of the accident / abnormality type as described above can be realized.

  In addition, according to the landslide maintenance management system 1, based on the data indicating 48h precipitation and continuous precipitation and the landslide management data, when there is a high risk of occurrence of an accident / abnormality in the transmission tower 2 due to the landslide, Since the abnormality countermeasure process is executed, the countermeasure support information in the accident / abnormality countermeasure process or the plan support information for the temporary route construction can be provided to the worker at an appropriate timing.

  In the above-described embodiment, the case where the accident / abnormality countermeasure processing is executed when the risk of occurrence of an accident / abnormality in the power transmission tower 2 or the like due to the landslide is high is given as an example. The invention is not limited to this. Accident / abnormality countermeasure processing may always be executed. In this case, in the accident / abnormality countermeasure processing, it is always received between the step of receiving the abnormality monitoring data output from the ground extensometer 12, the total station 13, and the strain gauge 14, and the step of determining the accident / abnormality type. It is desirable to insert a step for determining whether an accident or abnormality has occurred in the transmission tower 2 or the like based on the abnormality monitoring data.

  In the above-described embodiment, the case where the ground extensometer 12, the total station 13, and the strain gauge 14 are used in combination as a displacement detection unit that detects displacement or deformation generated in the power transmission tower 2 or the like due to a landslide has been described as an example. The present invention is not limited to this. Any two of the ground extensometer 12, the total station 13, and the strain gauge 14 may be used in combination.

  In addition, the landslide maintenance management system 1 according to the above-described embodiment has exemplified the case of providing information on countermeasures according to the risk of accidents / abnormalities such as the transmission tower 2 caused by landslides caused by rainfall. The present invention may provide information related to countermeasures according to the risk of accidents / abnormalities in the power transmission tower 2 or the like caused by a landslide caused by another cause. For example, the present invention provides information on measures according to the risk of accidents / abnormalities such as landslides caused by slope cuts of land near power transmission towers due to road construction, etc., and power transmission towers caused by landslides caused by snow cover. It can also be applied to the provision.

  In addition, the present invention can also be applied to a case where an accident / abnormality danger occurs due to a landslide in a structure other than a power transmission tower, such as an antenna tower, for example, and information relating to countermeasures according to the degree of danger is provided. .

  Further, the present invention can be appropriately changed without departing from the spirit or idea of the invention which can be read from the claims and the entire specification, and a landslide maintenance management system and a landslide maintenance management method accompanied with such changes are also provided. It is also included in the technical idea of the present invention.

1 Landslide maintenance management system 2 Transmission tower (construction)
11 Landslide maintenance management device 12 Ground extensometer (displacement detector)
13 Total station (displacement detector)
14 Strain gauge (displacement detector)
DESCRIPTION OF SYMBOLS 15 Communication apparatus 16 Battery 21 Data generation part 22 Landslide prediction part (execution control part)
23 Accident / Abnormality Countermeasures Department (Abnormality Classifier, Information Output Department)
24 storage unit 25 communication unit (data acquisition unit)
26 Input section 27 Output section

Claims (6)

A landslide maintenance management system that supports the formulation of measures in response to accidents or abnormalities caused by landslides,
A storage unit storing countermeasure support information corresponding to each of a plurality of types of accidents or abnormalities that may occur in a structure or land due to a landslide;
A displacement detector for detecting displacement or deformation caused to the structure or land by a landslide;
An abnormality type determination unit that determines the type of the accident or abnormality based on the detection result by the displacement detection unit;
A landslide maintenance management system comprising: an information output unit that reads out and outputs the countermeasure support information corresponding to the type of accident or abnormality determined by the abnormality type determination unit.   The structure is a power transmission tower, and the type of accident or anomaly includes ground cracks, earth and sand loss, steel tower foundation exposure, steel tower foundation displacement, tower tower displacement or tower buckling. The landslide maintenance management system according to claim 1.   The landslide maintenance management system according to claim 1, wherein the structure is a power transmission tower, and the countermeasure support information includes plan support information for temporary route construction.   The landslide maintenance management system according to any one of claims 1 to 3, wherein the displacement detector is a combination of any two or more of a ground extensometer, a total station, and a strain gauge. A data acquisition unit for acquiring precipitation data in a predetermined area;
When the precipitation indicated by the precipitation data acquired by the data acquisition unit is equal to or greater than a predetermined threshold, the detection by the displacement detection unit, the determination by the abnormality type determination unit, and the output by the information output unit are executed. The landslide maintenance management system according to any one of claims 1 to 4, further comprising an execution control unit. A landslide maintenance management method that supports the formulation of countermeasures in response to accidents or abnormalities caused by landslides,
A displacement detection step for detecting displacement or deformation caused in the structure or land by the landslide;
An abnormality type determination step of determining the type of the accident or abnormality based on the detection result in the displacement detection step;
The countermeasure support corresponding to the type of the accident or abnormality determined in the abnormality type determination step from the storage unit storing the countermeasure support information respectively corresponding to the plurality of types of accidents or abnormalities that may occur in the structure or land due to the landslide A landslide maintenance management method comprising an information output step of reading and outputting information.