JP2008107198A - Self-management support system of concrete structure, self-management support server, and self-management support program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To facilitate self-management of a concrete structure. <P>SOLUTION: This self-management support system of the concrete structure comprises a manager terminal 20, a self-management support server 30 and a network 40. The manager terminal 20 transmits to the self-management support server 30, crack width data of the concrete structure measured periodically by a manager by using a portable crack width measuring device for determining the crack width of the concrete structure by optical measurement. The self-management support server 30 receives the crack width data transmitted from the manager terminal 20, stores the received crack width data in time series, determines the deterioration degree of the concrete structure based on a change with time of the crack width data measured periodically, and transmits a deterioration degree determination result to the manager terminal 20. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a self-management support system, a self-management support server, and a self-management support program that support self-management of concrete structures, and more specifically, a portable type that quantifies the crack width of a concrete structure by optical measurement. By regularly measuring the crack width of concrete structures using a crack width measuring device and sending the measured crack width data to the self-management support server, the crack width data measured periodically can be stored in time series. In addition, the present invention relates to a self-management support system, a self-management support server, and a self-management support program for a concrete structure that can obtain a highly accurate deterioration degree determination result related to the concrete structure.

  In recent years, interest in the strength of concrete structures has increased due to the effects of anti-vibration camouflage problems. Especially in condominiums where many people live, the degree of deterioration of concrete structures is necessary in order to resolve residents' concerns about lack of strength and to properly determine the timing of regular large-scale repair work. There is a growing demand to accurately understand the situation.

  The degree of deterioration of concrete structures can be accurately diagnosed using conventional diagnostic techniques such as radiation transmission, ultrasonic testing, magnetic testing, eddy current testing, and strain measurement. Deterioration degree diagnosis by these diagnostic techniques is usually difficult to carry out unless requested by a specialist, so that there is a problem that appropriate costs are required and it cannot be easily performed.

  Therefore, paying attention to cracks (cracks) that are most easily visually confirmed among the deformations that occur in concrete structures and have a very high correlation with the degree of deterioration of concrete structures, the width of the cracks is determined by the administrator. It is proposed to self-diagnose the deterioration degree of concrete structures based on the measured values. For example, the crack width is measured using a crack scale made of a transparent resin plate with a plurality of straight lines having different width dimensions and a numerical value indicating the width of each straight line, and the condition of the concrete structure based on the measured values. Make a grasp.

  However, the crack width measurement using the crack scale is a visual measurement in which the actual crack width is compared with the width of multiple straight lines, the straight line that appears to be closest is selected, and the numerical value attached to the straight line is read. Therefore, there is a problem that the operator's ambiguous judgment is inevitably involved, and as a result, there is a possibility that a large measurement error may occur, and the measurement result varies depending on the operator who performs the measurement.

Therefore, the inventor of the present invention uses a portable crack width measuring device (see Patent Document 1) that quantifies the crack width of a concrete structure by optical measurement, or a portable crack width measuring device. In the past, a crack width measuring auxiliary tool (see Patent Document 2) used for periodically measuring a location has been proposed.
Japanese Patent No. 3611777 JP 2003-240513 A

  By using the crack width measuring device and crack width measuring aid as described above, even an administrator who does not have expertise in diagnostic technology can accurately measure the width of cracks generated in concrete structures. However, since it takes time to perform secondary processing of the measured crack width data, there is a possibility that the administrator will be burdened with a large burden.

  In other words, in order to self-diagnose the degree of deterioration of the concrete structure based on the measured value by the manager himself / herself, the crack width data measured periodically are recorded and stored in time series, Since it is necessary to judge the change over time of crack width data and determine the degree of deterioration using a predetermined reference value, it is not only a heavy burden for an administrator who does not have expertise, but also an incorrect decision. Results may be derived.

The present invention was created to solve these problems in view of the above circumstances, and supports the manager terminal used by the manager of the concrete structure and the independent management of the concrete structure. A self-management support system for a concrete structure comprising a self-management support server that performs communication and a network that connects these so that they can communicate with each other, wherein the manager terminal quantifies the crack width of the concrete structure by optical measurement A self-management support server, comprising: crack width data transmission means for transmitting to the self-management support server crack width data of a concrete structure periodically measured by an administrator using a portable crack width measurement device Includes a crack width data receiving means for receiving crack width data transmitted from the administrator terminal, and the received crack crack data. Crack width data storage means for storing width data in time series, deterioration level determination means for determining the deterioration level of concrete structures based on changes over time in crack width data measured periodically, and deterioration level determination results Deterioration degree determination result transmission means for transmitting the message to the manager terminal. In this way, the crack width of the concrete structure is periodically measured using a portable crack width measuring device that quantifies the crack width of the concrete structure by optical measurement, and the measured crack width data is independently used. By only transmitting to the management support server, the crack width data measured periodically can be stored in time series, and a highly accurate deterioration degree determination result related to the concrete structure can be obtained.
Further, the deterioration degree determination means compares the crack width data measured periodically with a predetermined absolute value determination reference value, and determines whether or not the crack width data exceeds the absolute value determination reference value. And determining the degree of deterioration of the concrete structure. If it does in this way, a highly accurate degradation degree determination can be performed based on the absolute value of a crack width. For example, even when the change rate of the crack width is small, when the absolute value of the crack width exceeds 0.5 mm, it is possible to determine that the degree of deterioration is severe and to send an alert.
Further, the deterioration degree determination means calculates a change rate of the crack width data measured periodically, compares the calculated change rate with a predetermined reference value for determining the change rate, and the crack width data determines the change rate. It is characterized in that the degree of deterioration of the concrete structure is determined based on whether or not the reference value is exceeded. If it does in this way, a highly accurate degradation degree determination can be performed based on the change rate of a crack width. For example, even when the absolute value of the crack width is 0.5 mm or less, when the rate of change of the crack width exceeds 50%, it is possible to determine that the degree of deterioration is severe and send an alert.
Further, the crack width data receiving means receives temperature data at the time of measurement together with the crack width data, and the deterioration degree judging means is based on the crack width data in which the temperature error is corrected based on the temperature data. It is characterized by determining the degree of deterioration of the structure. In this way, the temperature error included in the crack width data can be eliminated as much as possible, and a highly accurate deterioration degree determination can be performed.
Further, the self-management support server, when the deterioration degree determination means determines that the deterioration degree of the concrete structure is severe, a remeasurement request for transmitting a crack width remeasurement request to the corresponding administrator terminal. Transmitting means, and erroneous measurement confirmation means for confirming the presence or absence of erroneous measurement based on crack width data transmitted from the administrator terminal in response to a remeasurement request and stored data in the crack width data storage means It is characterized by. In this way, erroneous determination based on erroneous measurement can be eliminated, and the reliability of the determination result can be improved.
In addition, the self-management support server is transmitted from the administrator terminal in response to the temporary measurement request, and a temporary measurement request transmission unit that transmits a temporary measurement request for the crack width to the administrator terminal in response to the occurrence of a natural disaster. Damage determining means for determining damage to the concrete structure due to natural disasters based on the crack width data and the data stored in the crack width data storage means. If it does in this way, the damage of the concrete structure by natural disaster can be determined, and the determination result can be provided to the administrator.
Further, the self-management support server refers to a deterioration degree determination result based on an absolute value of crack width data measured periodically and a deterioration degree determination result based on a change rate of crack width data measured periodically. When only the deterioration degree determination result based on the absolute value is abnormal, only when the deterioration degree determination result based on the change rate is abnormal, and when the deterioration degree determination result based on the absolute value and the deterioration degree determination result based on the change rate are abnormal, And an alert selection means for selecting a type of alert processing to be applied for each case. In this way, the content of the alert process can be changed according to the abnormality determination type in the deterioration degree determination, so that it is possible to execute an alert process suitable for the abnormality determination type.
Moreover, it is a self-management support server which supports the self-management of a concrete structure, Comprising: It operate | moves as one of said self-management support servers, It is characterized by the above-mentioned. In this way, the present invention can be implemented as a self-management support server.
Moreover, it is a self-management support program which supports the self-management of a concrete structure, Comprising: A computer is operated as said self-management support server. In this way, the present invention can be implemented as a self-management support program.

  According to the present invention configured as described above, the crack width of a concrete structure is periodically measured using a portable crack width measuring device that quantifies the crack width of a concrete structure by optical measurement. By simply transmitting the measured crack width data to the voluntary management support server, it is possible not only to store the regularly measured crack width data in time series, but also to obtain a highly accurate degradation determination result related to the concrete structure.

[Crack width measuring device]
Next, embodiments of the present invention will be described with reference to the drawings. 1 to 5, reference numeral 1 denotes a portable crack width measuring device that quantifies the width of a crack 3 generated in a concrete structure 2 by optical measurement. In addition, a grip portion 1a gripped by a hand, a measurement switch 4 that can be pushed while gripping the grip portion 1a, and a measurement portion 1b extending forward from the grip portion 1a are provided.

  When measuring the crack width, the measurement switch 4 is operated in a state where the front end face 1c of the measurement unit 1b is pressed against the measurement target position of the concrete structure 2. A rectangular measurement window 5 is formed on the front end face 1c of the measurement unit 1b. Around the periphery of the measurement window 1b, the crack width measurement device 1 is prevented from rattling and the ambient light is prevented from entering the measurement window 5. An elastic cushioning material 6 is attached. Furthermore, when the front end face 1c of the measuring part 1b is pressed against the measurement target position of the concrete structure 2 around the elastic cushioning material 6, the crack width measuring device 1 and the concrete are brought into contact with the concrete structure 2 A plurality of convex portions 7 that define the distance from the structure 2 are formed.

  Inside the crack width measuring device 1, a pair of left and right light emitting elements 8 that illuminate a specific target position of the crack 3 through the measurement window 5, an image sensor 9 disposed at a position facing the measurement window 5, and the above A lens 10 that forms an image of the crack 3 taken in from the measurement window 5 on the image sensor 9, a control board 11 that measures the crack width based on the output signal of the image sensor 9, and a display unit that displays the measurement result 12 and a battery 13 for supplying power are provided. The basic principle of crack width measurement in the crack width measuring apparatus 1 is the same as that of the crack width measuring apparatus disclosed in Japanese Patent No. 3611777 (Japanese Patent Laid-Open No. 2002-22419), and detailed description thereof is omitted. To do.

  When the crack width is measured by the crack width measuring apparatus 1, it is preferable to use the crack width measuring auxiliary tool 14 shown in FIGS. The crack width measuring auxiliary tool 14 is a substantially square thin plate made of a transparent resin, and is formed using, for example, polyethylene terephthalate (PET). A measurement position specifying window (measurement position specifying window part) 14a corresponding to the shape of the measurement window 5 is formed at the center of the crack width measuring auxiliary tool 14, and the crack 3 is measured at the time of crack width measurement. The measurement position specifying window 14a is aligned with the position.

  A plurality of marking holes (marking portions) 14b are formed outside the measurement position specifying window 14a. The marking hole 14b is for marking the position of the crack width measuring auxiliary tool 14 in the state in which the measurement position specifying window 14a is aligned with the measurement target position of the crack 3 on the concrete structure 2, and in this embodiment. Then, it forms as a linear long hole. After marking the concrete structure 2 along the marking hole 14b, the crack width measuring auxiliary tool 14 is positioned at the same position by aligning the marking hole 14b with the mark attached to the concrete structure 2 thereafter. Accurate alignment is possible. The marking holes 14b of the present embodiment are arranged radially (in the form of a cross in the present embodiment) centering on the measurement position specifying window 14a. Thereby, the X, Y, and θ positions of the crack width measuring aid 14 are defined, and the crack width measuring aid 14 can be accurately aligned.

  Further, a plurality of divided measuring device positioning ribs (measuring device positioning portions) 14c are formed around the measurement position specifying window 14a. The measuring device positioning ribs 14c guide the positioning of the crack width measuring device 1 with respect to the measurement position specifying window 14a, and have a configuration capable of fitting and holding the measuring portion 1b of the crack width measuring device 1. That is, after the measurement position specifying window 14a of the crack width measuring auxiliary tool 14 is aligned with the measurement target position of the crack 3, the crack width measuring apparatus 1 is set on the measuring device positioning rib 14c of the crack width measuring auxiliary tool 14. This makes it possible to accurately align the crack width measuring device 1 with respect to the measurement target position of the crack 3.

  A plurality of through holes 14d are formed around the measurement position specifying window 14a. The position of the through hole 14d corresponds to the position of the convex portion 7 formed in the crack width measuring device 1, and when the measuring portion 1b of the crack width measuring device 1 is set on the measuring device positioning rib 14c, The convex portion 7 is in direct contact with the concrete structure 2 through the through hole 14d. Thereby, even if the crack width measuring auxiliary tool 14 is interposed, the distance between the crack width measuring apparatus 1 and the concrete structure 2 can be appropriately maintained. In the drawing, 14e is a crack scale provided for visual measurement, and 14f is a test pattern for confirming the operation of the crack width measuring apparatus 1.

[Self management support system]
As illustrated in FIG. 9, the concrete structure self-management support system according to the embodiment of the present invention supports the manager terminal 20 used by the manager of the concrete structure 2 and the self-management of the concrete structure 2. A self-management support server (a computer that operates according to a self-management support program) 30 and a network 40 that connects these to be communicable are configured. The administrator terminal 20 may be any terminal that can communicate with the self-management support server 30 via the network 40. For example, a personal computer equipped with a browser function (WEB page browsing software) or a mailer function (e-mail transmission / reception software). A computer, a mobile phone terminal, a PHS terminal, or the like can be used. The self-management support server 30 may be any server that can communicate with the administrator terminal 20 via the network 40, and for example, a server computer equipped with a WEB server function may be used. In the present embodiment, the Internet is assumed as the network 40, but an intranet or a dedicated line may be used.

  The administrator terminal 20 uses the portable crack width measuring device 1 that quantifies the crack width of the concrete structure 2 by optical measurement, and uses the crack width data of the concrete structure 2 periodically measured by the administrator. Crack width data transmission means for transmitting to the self-management support server 30 is provided. For example, when the self-management support server 30 is configured by a WEB server, the crack management data input screen data is downloaded from the self-management support server 30 and the crack width data input to the input screen is downloaded to the self-management support server 30. The browser to transmit to corresponds to crack width data transmission means. It should be noted that the crack width data may be transmitted via dedicated software or e-mail without using a browser.

  The measurement time of the crack width by the administrator can be arbitrarily set as long as it is regular. For example, the basic measurement number is 2 times / month, and the administrator can select from 1 to 4 times / month. To. The measurement location and the number of measurement points of the crack width in the concrete structure 2 can also be set arbitrarily. For example, 1 to 50 measurement points are set in advance by an administrator or a specialist, and regular fixed point observation is performed for these measurement points. The initial width of cracks suitable for determining the degree of deterioration is about 0.2 mm, in which the degree of deterioration is determined to be mild or moderate, and by periodically measuring such a crack, it is possible to determine the degree of deterioration with high accuracy. It becomes possible.

  Since the concrete structure 2 undergoes minute expansion / contraction in response to changes in temperature, the time for measuring the crack width is preferably the same every time. More preferably, the temperature is also recorded when the crack width is measured, and the temperature data is transmitted to the independent management support server 30 together with the measured crack width data. In this way, the self-management support server 30 corrects the temperature error of the crack width data based on the temperature data, and accurately determines the deterioration degree of the concrete structure 2 based on the crack width data that has been temperature corrected. It becomes possible.

  An example of the input screen for transmitting the crack width data from the administrator terminal 20 to the self-management support server 30 is shown in FIG. The input screen 50 shown in this figure is displayed on the administrator terminal 20 after the administrator terminal 20 logs on to the self-management support server 30, and the name of the concrete structure 2 registered in advance (for example, ABC) The measurement date input field 51, the air temperature input field 52, the crack width input field 53, the previous crack width display field 54, and the like are included. The crack width input field 53 and the previous crack width display field 54 are displayed for each measurement point (for example, outdoor measurement points 1 to 3 and indoor measurement points 1 to 3), and data is input to the corresponding input fields 51 to 53. Thereafter, the input data is transmitted to the self-management support server 30 by clicking the transmission button 55.

  The voluntary management support server 30 includes a crack width data receiving unit that receives crack width data transmitted from the administrator terminal 20, a crack width data storage unit that stores the received crack width data in time series, and a periodic measurement. Deterioration level determination means for determining the deterioration level of the concrete structure 2 based on the time-dependent change of the crack width data, and a deterioration level determination result transmission means for transmitting the deterioration level determination result to the administrator terminal 20. I have. In this way, the crack width of the concrete structure 2 is periodically measured using a portable crack width measuring device 1 that quantifies the crack width of the concrete structure 2 by optical measurement, and the measured crack width is measured. By simply transmitting the data to the self-management support server 30, not only can the regularly measured crack width data be stored in time series, but also a highly accurate deterioration degree determination result related to the concrete structure 2 can be obtained.

  More specifically, the crack width data receiving means is a WEB server function for receiving data input to the input screen 50 in the administrator terminal 20 or a mailer function for receiving an e-mail containing crack width data. The crack width data storage means can be realized by a storage device such as a hard disk. When the crack width data is stored in the hard disk, the name, measurement date, temperature, and crack location name of the concrete structure 2 are stored together with the crack width data.

  The degradation degree determination means compares the crack width data measured periodically with a predetermined reference value for absolute value determination, and determines whether the crack width data exceeds the absolute value determination reference value. The degree of deterioration of the object 2 can be determined. For example, as shown in FIG. 11, with respect to three stages of deterioration (mild, moderate, and severe), outdoor reference values and indoor reference values are set in advance, and crack width data measured periodically. The degree of deterioration of the concrete structure 2 is determined in three stages based on whether or not exceeds the reference values. If it does in this way, a highly accurate degradation degree determination can be performed based on the absolute value of a crack width. For example, even when the change rate of the crack width is small, when the absolute value of the crack width exceeds 0.5 mm, it is possible to determine that the degree of deterioration is severe and to send an alert.

  Further, the deterioration degree determination means calculates a change rate of the crack width data measured periodically, and uses the calculated change rate as a predetermined change rate determination reference value (for example, a change rate of 50% per 6 months). In comparison with the above, the degree of deterioration of the concrete structure 2 can be determined based on whether or not the crack width data exceeds the reference value for rate of change determination. If it does in this way, a highly accurate degradation degree determination can be performed based on the change rate of a crack width. For example, even in a situation where the absolute value of the crack width is 0.5 mm or less, when the rate of change of the crack width exceeds 50% in 6 months, it can be determined that the degree of deterioration is severe and an alert can be sent.

Further, when the deterioration degree determination means determines the deterioration degree of the concrete structure 2 based on the regularly measured crack width data, the crack width data in which the temperature error is corrected based on the temperature data is used. It is preferable. For example, the temperature correction of the crack width data is performed using the following arithmetic expression. In this way, the temperature error included in the crack width data can be eliminated as much as possible, and a highly accurate deterioration degree determination can be performed.
As a method for correcting crack width data based on temperature data, refer to a method for obtaining corrected crack width data by substituting temperature data and crack width data into a predefined correction equation, and a predefined correction table. Thus, a method of obtaining corrected crack width data, a method of estimating a correlation from accumulated past crack width data and temperature data and deriving corrected crack width data can be used.

  The deterioration level determination result transmission means transmits a Web server function for transmitting the deterioration level determination result of the concrete structure 2 to the administrator terminal 20 as a WEB page, and an e-mail including the deterioration level determination result to the administrator terminal 20. This can be realized by the mailer function. When the deterioration degree determination result is transmitted to the administrator terminal 20 as a WEB page, for example, a screen configuration as shown in FIG. 12 is used. The degradation degree determination result display screen 60 shown in this figure includes the current measurement date display field 61, the current temperature display field 62, the current crack width display field 63, the previous crack width display field 64, the absolute value, along with the name of the concrete structure 2. The deterioration degree determination result display column 65 by the deterioration rate, the deterioration degree determination result display column 66 by the change rate, and the like are included. The current crack width display field 63, the previous crack width display field 64, the deterioration degree determination result display field 65 based on absolute values, and the deterioration degree determination result display field 66 based on the change rate are displayed for each measurement location.

  In addition, the self-management support server 30 transmits a re-measurement request for transmitting a crack width re-measurement request to the corresponding administrator terminal 20 when the deterioration degree determination unit determines that the deterioration degree of the concrete structure 2 is severe. And a transmission means and an erroneous measurement confirmation means for confirming the presence or absence of erroneous measurement based on the crack width data transmitted from the administrator terminal 20 in response to the remeasurement request and the stored data of the crack width data storage means. preferable. In this way, erroneous determination based on erroneous measurement can be eliminated, and the reliability of the determination result can be improved.

  Specifically, the remeasurement request transmission means can be easily realized by the WEB server function or the mailer function. For example, the remeasurement request display message 67 and the remeasurement data are displayed on the deterioration degree determination result display screen 60 shown in FIG. An input field 68 may be inserted. Confirmation of the erroneous determination by the erroneous measurement confirmation means includes, for example, the remeasurement crack width data transmitted from the administrator terminal 20 in response to the remeasurement request, and the current crack width data stored in the crack width data storage means ( And data based on whether or not the seriousness determination is made), and based on whether or not the difference between the two exceeds a reference value for erroneous measurement determination. If it is determined that the measurement is wrong, the deterioration level determination is performed again based on the remeasurement crack width data transmitted from the administrator terminal 20 in response to the remeasurement request, and this is adopted as a normal determination result. Is preferred.

  In addition, the self-management support server 30 is transmitted from the administrator terminal 20 in response to the temporary measurement request and a temporary measurement request transmission unit that transmits a temporary measurement request for the crack width to the administrator terminal 20 in response to the occurrence of a natural disaster. It is preferable to include damage determination means for determining damage to the concrete structure 2 due to natural disasters based on the crack width data and the data stored in the crack width data storage means. If it does in this way, it will become possible to determine the damage of the concrete structure 2 by a natural disaster, and to provide the determination result to an administrator.

  More specifically, the temporary measurement request transmission means can be easily realized by the mailer function of the self-management support server 30 if a temporary measurement request message (temporary measurement request mail) is created in advance. For example, by using earthquake occurrence information from an earthquake information providing site existing on the Internet as a trigger, temporary measurement request mails are simultaneously transmitted to all the administrator terminals 20 or the administrator terminals 20 in the earthquake occurrence area. The damage determination means can perform damage determination of the concrete structure 2 due to natural disasters using a technique equivalent to the deterioration degree determination means. For example, the crack width data temporarily measured is compared with a predetermined reference value for damage determination, and the damage of the concrete structure due to natural disaster is determined based on whether the crack width data exceeds the damage determination reference value. .

  Next, the specific operation of the self-management support system and the processing procedure of the self-management support server 30 will be described with reference to FIGS. As shown in FIG. 13 and FIG. 14, the administrator who regularly measured the crack width of the concrete structure 2 using the crack width measuring device 1 transmits a login request from the administrator terminal 20 to the self-management support server 30. (S101). The self-management support server 30 receives the login request (S102, S201), performs user authentication based on the user ID and password included in the login request (S103, S202), and stores in advance if the user is a regular user. The input screen data into which the name of the concrete structure 2 that is being used, the name of the measurement location, the crack width last time, and the like are inserted is transmitted to the administrator terminal 20 (S104, S203).

  The administrator terminal 20 receives the input screen data and displays it (S105). Thereafter, it is determined whether or not the input of the measurement data on the input screen is complete (S106), and when the determination result is YES, the input measurement data is transmitted to the self-management support server 30 (S107). Upon receiving the measurement data (S108, S204), the self-management support server 30 stores the data in time series (S109, S205), and then corrects the temperature error of the crack width data based on the temperature data (S110, S205). S206), the degree of deterioration is determined based on the temperature-corrected crack width data (current and past data) (S111, S112, S207, S208). In this deterioration degree determination, the above-described deterioration degree determination method based on an absolute value or the deterioration degree determination method based on a change rate can be used. When the deterioration degree determination is completed, deterioration degree determination display screen data including the deterioration degree determination result is created and transmitted to the administrator terminal 20 (S113, S209).

  The administrator terminal 20 receives the deterioration degree determination display screen data and displays it (S114). If there is no severe deterioration degree determination result on the deterioration degree determination display screen, the process ends as it is, but if the serious deterioration degree determination result is included and a remeasurement request message regarding the measurement location is inserted, Waiting for the input of the remeasured crack width data (S115). If remeasurement data is input, it is transmitted to the self-management support server 30 (S116). When the self-management support server 30 has a severe determination (S210) and receives remeasurement data (S117, S211), the remeasurement data is compared with the regular measurement data, and whether the regular measurement data is an erroneous measurement. It is confirmed whether or not (S118, S212). Here, when it is determined that the measurement is incorrect (S119, S213), the deterioration degree determination result based on the remeasurement data is stored as the final determination result, and the process ends (S122, S215). On the other hand, when it is determined that the measurement is not an erroneous measurement, an alert is transmitted to the manager terminal 20 (S120, S121, S214), and the manager is notified of the danger level of the concrete structure 2.

  As shown in FIGS. 15 and 16, the self-management support server 30 determines the occurrence of a natural disaster (S301, S401), and transmits a temporary measurement request to the administrator terminal 20 when the determination result is YES. (S302, S402). The administrator terminal 20 receives the temporary measurement request (S303). When the administrator measures the crack width of the concrete structure 2 using the crack width measuring device 1 in response to the temporary measurement request, the administrator terminal 20 transmits a login request to the self-management support server 30 (S304). ). The self-management support server 30 receives the login request (S305, S403), performs user authentication based on the user ID and password included in the login request (S306, S404), and stores in advance if the user is a regular user. The input screen data into which the name of the concrete structure 2 that is being used, the name of the measurement location, the crack width last time, etc. are inserted is transmitted to the administrator terminal 20 (S307, S405).

  The administrator terminal 20 receives the input screen data and displays it (S308). Thereafter, it is determined whether or not measurement data has been input to the input screen (S309). If the determination result is YES, the input measurement data is transmitted to the self-management support server 30 (S310). When the self-management support server 30 receives the measurement data (S311 and S406), and stores the measurement data (S312 and S407), it corrects the temperature error of the crack width data based on the temperature data (S313 and S408). Damage determination is performed based on the temperature-corrected crack width data (current and past data) (S314, S315, S409, and S410). As the damage determination method, the above-described deterioration degree determination method based on an absolute value or the deterioration degree determination method based on a change rate can be used. When the damage determination is completed, determination result display screen data including the damage determination result is generated and transmitted to the administrator terminal 20 (S316, S317, S411).

  According to this embodiment configured as described, the manager terminal 20 used by the manager of the concrete structure 2 and the voluntary management support server 30 that supports the voluntary management of the concrete structure 2 can communicate with each other. A self-management support system for a concrete structure 2 including a network 40 connected to the administrator terminal 20, wherein the manager terminal 20 quantifies the crack width of the concrete structure by optical measurement. The crack width data of the concrete structure periodically measured by the administrator is transmitted to the self-management support server 30, and the self-management support server 30 receives the crack width data transmitted from the administrator terminal 20. At the same time, the received crack width data is stored in chronological order, and further, the crack width data measured periodically is changed over time. In addition, the deterioration degree of the concrete structure 2 is determined and the deterioration degree determination result is transmitted to the manager terminal 20, so the manager of the concrete structure 2 Not only can the crack width data be periodically measured using the crack width measuring apparatus 1, and the crack width data measured periodically can be stored in chronological order simply by sending the crack width data to the self-management support server 30. In addition, a highly accurate deterioration degree determination result related to the concrete structure 2 can be obtained.

  Further, the self-management support server 30 compares the crack width data measured periodically with a predetermined absolute value determination reference value, and based on whether the crack width data exceeds the absolute value determination reference value. Since the degree of deterioration of the concrete structure 2 is determined, it is possible to determine the degree of deterioration with high accuracy based on the absolute value of the crack width. For example, even when the change rate of the crack width is small, when the absolute value of the crack width exceeds 0.5 mm, it is possible to determine that the degree of deterioration is severe and to send an alert.

  The self-management support server 30 calculates the rate of change of the crack width data measured periodically, compares the calculated rate of change with a predetermined reference value for determining the rate of change, and the crack width data determines the rate of change. Since the deterioration degree of the concrete structure 2 is determined based on whether or not the reference value is exceeded, it is possible to perform a highly accurate deterioration degree determination based on the change rate of the crack width. For example, even when the absolute value of the crack width is 0.5 mm or less, when the rate of change of the crack width exceeds 50%, it is possible to determine that the degree of deterioration is severe and send an alert.

  The self-management support server 30 receives the temperature data at the time of measurement together with the crack width data, and determines the deterioration degree of the concrete structure 2 based on the crack width data in which the temperature error is corrected based on the temperature data. Therefore, the temperature error included in the crack width data can be eliminated as much as possible, and a highly accurate deterioration determination can be performed.

  In addition, when the self-management support server 30 determines that the deterioration degree of the concrete structure 2 is severe, the self-management support server 30 transmits a crack width remeasurement request to the corresponding administrator terminal 20 and manages it according to the remeasurement request. Since the presence / absence of erroneous measurement is confirmed based on the crack width data and stored data transmitted from the person terminal 20, it is possible to eliminate erroneous determination based on the erroneous measurement and improve the reliability of the determination result.

  The self-management support server 30 transmits a temporary measurement request for the crack width to the administrator terminal 20 in response to the occurrence of a natural disaster, and the crack width data and the storage data transmitted from the administrator terminal 20 in response to the temporary measurement request. Since the damage of the concrete structure 2 due to natural disaster is determined based on the above, the damage determination result of the concrete structure 2 due to natural disaster can be provided to the administrator.

[Second Embodiment]
Next, an independent management support server 30 (independent management support system) according to the second embodiment of the present invention will be described with reference to FIG. As shown in this figure, the voluntary management support server 30 of the second embodiment has a deterioration degree determination result based on an absolute value of crack width data measured periodically, and a rate of change of the crack width data measured periodically. The deterioration degree judgment result by the absolute value, the deterioration degree judgment result by the absolute value, the case where only the deterioration degree judgment result by the change rate is abnormal, the deterioration degree judgment result by the absolute value, and the change rate It differs from the above embodiment in that it includes alert selection means for selecting the type of alert processing to be applied for each case depending on whether the deterioration degree determination result is abnormal. For example, the alert process 1 applied when only the deterioration degree determination result based on the absolute value is abnormal, the alert process 2 applied when only the deterioration degree determination result based on the change rate is abnormal, and the deterioration degree determination based on the absolute value Contents of alert processing 3 applied when the result and the deterioration degree judgment result based on the change rate are abnormal (for example, alert destination, number of alert transmissions, presence / absence of survey estimate, presence / absence of survey request, repair work estimate The user can individually set in advance whether or not a certificate is attached, whether or not a repair work request is attached, and whether or not survey / repair company information is attached. In this way, the content of the alert process can be changed according to the abnormality determination type in the deterioration degree determination, so that it is possible to execute an alert process suitable for the abnormality determination type.

  Specifically, in the alert selection processing (alert selection means) of the self-management support server 30, first, it is determined whether or not the deterioration degree determination result based on the absolute value is abnormal (S501), and the determination result is YES. In this case, it is determined whether or not the deterioration degree determination result based on the rate of change is abnormal (S502). If the determination result is YES, a preset alert process 3 is executed (S503), and if NO, a preset alert process 1 is executed (S504). On the other hand, even when the deterioration degree determination result based on the absolute value is not abnormal, it is determined whether or not the deterioration degree determination result based on the change rate is abnormal (S505). If the determination result is YES, a preset alert process 2 is executed (S506). If NO, the process returns to the upper routine without executing the alert process.

It is a top view of a crack width measuring apparatus. It is a side view of a crack width measuring apparatus. It is a front view of a crack width measuring apparatus. It is a rear view of a crack width measuring apparatus. It is a top view which shows the inside of a crack width measuring apparatus. It is a top view of the auxiliary tool for crack width measurement. It is XX sectional drawing of the auxiliary tool for crack width measurement. It is a perspective view which shows the usage example of the auxiliary tool for crack width measurement. The block diagram which shows the independent management assistance system of a concrete structure. It is a front view which shows the input screen of crack width data. It is explanatory drawing of the reference value for absolute value determination used for deterioration degree determination. It is a front view which shows the display screen of a degradation degree determination result. It is a flowchart which shows operation | movement of the self-management support system at the time of a regular measurement. It is a flowchart which shows the process sequence of the self-management support server at the time of a periodic measurement. It is a flowchart which shows operation | movement of the self-management support system at the time of natural disaster occurrence. It is a flowchart which shows the process sequence of the self-management support server at the time of natural disaster occurrence. It is a flowchart which shows the process sequence of the alert selection process which concerns on 2nd embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Crack width measuring apparatus 2 Concrete structure 14 Auxiliary tool 20 for width measurement Manager terminal 30 Voluntary management support server 40 Network 50 Input screen 60 Degradation degree determination result display screen

Claims (9)

A concrete structure self-management support system comprising an administrator terminal used by a concrete structure manager, a self-management support server that supports the self-management of the concrete structure, and a network that connects them in a communicable manner. And
The administrator terminal is
Transmits the crack width data of a concrete structure regularly measured by an administrator to the self-management support server using a portable crack width measuring device that quantifies the crack width of a concrete structure by optical measurement. With crack width data transmission means
The self-management support server
Crack width data receiving means for receiving crack width data transmitted from the administrator terminal;
Crack width data storage means for storing the received crack width data in time series;
Degradation degree judging means for judging the deterioration degree of the concrete structure based on the temporal change of the crack width data measured periodically,
A self-management support system for a concrete structure, comprising: a deterioration degree determination result transmitting means for transmitting a deterioration degree determination result to the manager terminal.   The deterioration degree determination means compares the crack width data measured periodically with a predetermined reference value for absolute value determination, and based on whether the crack width data exceeds the reference value for absolute value determination, concrete The voluntary management support system for a concrete structure according to claim 1, wherein the deterioration degree of the structure is determined.   The deterioration degree determination means calculates a change rate of the crack width data measured periodically, compares the calculated change rate with a predetermined reference value for determining a change rate, and the crack width data is a reference for determining the change rate. 3. The self-management support system for a concrete structure according to claim 1, wherein the deterioration degree of the concrete structure is determined based on whether or not the value exceeds the value. The crack width data receiving means receives the temperature data at the time of measurement together with the crack width data,
The said deterioration degree determination means determines the deterioration degree of a concrete structure based on the crack width data by which the temperature error was correct | amended based on temperature data. Voluntary management support system for concrete structures. The self-management support server
When the deterioration degree determination means determines that the deterioration degree of the concrete structure is severe, a remeasurement request transmission means for transmitting a remeasurement request for the crack width to the manager terminal concerned,
And an erroneous measurement confirmation means for confirming the presence or absence of erroneous measurement based on the crack width data transmitted from the administrator terminal in response to the remeasurement request and the stored data of the crack width data storage means. The self-management support system of the concrete structure in any one of Claims 1-4. The self-management support server
A temporary measurement request transmitting means for transmitting a temporary measurement request for a crack width to the manager terminal in response to the occurrence of a natural disaster;
Damage determination means for determining damage to the concrete structure due to natural disasters based on crack width data transmitted from the administrator terminal in response to a temporary measurement request and storage data of the crack width data storage means. A self-management support system for a concrete structure according to any one of claims 1 to 5. The self-management support server
Degradation degree judgment result based on absolute value of crack width data measured regularly,
Refer to the degradation degree judgment result by the rate of change of crack width data measured periodically,
When only the deterioration degree judgment result by the absolute value is abnormal,
Only when the deterioration rate judgment result based on the rate of change is abnormal,
It is divided into the case when the deterioration degree judgment result by the absolute value and the deterioration degree judgment result by the change rate are abnormal,
The self-management support system for a concrete structure according to any one of claims 1 to 6, further comprising an alert selection unit that selects a type of alert processing to be applied for each case.   A self-management support server that supports self-management of a concrete structure, and operates as the self-management support server according to any one of claims 1 to 7.   A self-management support program for supporting self-management of a concrete structure, wherein the computer is operated as the self-management support server according to claim 8.

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