JP6371027B1 - Reinforced concrete member discrimination system and reinforced concrete member discrimination program - Google Patents

Abstract

Analysis of inspection data by artificial intelligence makes it possible to determine the deterioration status of a reinforced concrete member with high accuracy. A first association degree acquisition step for obtaining in advance three or more first association degrees between past inspection data for a reinforced concrete member and a determination result of a deterioration state of the reinforced concrete member with respect to the inspection data; The first input step of inputting inspection data obtained by inspecting the reinforced concrete member 7 for determining the deterioration state, and the first association degree acquired in the first association degree acquisition step, refer to the above. The computer is caused to execute a first determination step for determining a deterioration state of the reinforced concrete member 7 based on the inspection data input in the first input step. [Selection] Figure 1

Description

  The present invention relates to a reinforced concrete member discrimination system and a reinforced concrete member discrimination program for discriminating a deterioration state of a reinforced concrete member.

  Conventionally, a reinforced concrete member used for a bridge or the like may deteriorate due to salt damage, neutralization, alkali aggregate reaction, and the like, and the concrete may be peeled off. For this reason, conventionally, the deterioration status of the reinforced concrete member is determined by inspection. Examples of this inspection method include inspection concerning cracks, inspection by natural potential method, inspection by polarization resistance method, inspection by vibration measurement, inspection on chloride ion amount, inspection on neutralization depth, and inspection by X-ray diffraction method. EPMA (Electron Probe Micro Analyzer) inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, uranyl acetate fluorescence inspection, and polarization microscope inspection are used.

JP 2000-206098 A

  However, even if inspection data can be acquired by these inspection methods, it is not easy to accurately determine the deterioration status of the reinforced concrete member based on the inspection data. Actually, it takes considerable skill to accurately predict the deterioration status of reinforced concrete members from inspection data alone, and even with skilled experience, it sometimes makes a wrong decision. There was a case.

  For this reason, there has been a demand for a technique that can automatically perform accurate determination without special skill in determining the deterioration status of a reinforced concrete member. A technical idea for improving accuracy by automatically determining the deterioration status of the reinforced concrete member by artificial intelligence is also conceivable.

  In particular, Patent Document 1 receives an ultrasonic reflection echo from a building structure, acquires shape information of a flaw in a pillar, etc., and information on the shape of the flaw and an inspection reference database obtained by artificial intelligence or the like. A technique for performing comparison and discriminating the degree of maintenance of a building is disclosed.

  However, the technique disclosed in Patent Document 1 does not specifically disclose a technique for determining the deterioration status of a reinforced concrete member by analyzing inspection data using artificial intelligence.

  Therefore, the present invention has been devised in view of the above-described problems, and the object of the present invention is to determine a reinforced concrete member determination system and a reinforced concrete member determination for determining the deterioration status of a reinforced concrete member by inspection. An object of the present invention is to provide a discrimination system for a reinforced concrete member and a discrimination program for a reinforced concrete member capable of determining the deterioration status of the reinforced concrete member with high accuracy by analyzing the inspection data by artificial intelligence.

  In the discrimination system for reinforced concrete members according to the present invention, the first association degree of three or more stages of the past inspection data for the reinforced concrete member and the discrimination result of the deterioration state of the reinforced concrete member for the inspection data is stored in advance. Refer to the association database, input means for inputting inspection data obtained by newly inspecting a reinforced concrete member that newly determines the deterioration state, and the first association degree stored in the first association database. Discriminating means for discriminating the deterioration status of the reinforced concrete member based on the inspection data input through the input means, and the first relational database includes inspection concerning cracks, inspection by natural potential method, polarization resistance method Inspection by vibration, inspection by vibration measurement, inspection on chloride ion content, neutralization depth Inspection, X-ray diffraction inspection, EPMA (Electron Probe Micro Analyzer) inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, uranyl acetate fluorescence inspection, and polarization microscope inspection The combination of two or more types of past inspection data and the first link degree of three or more stages of the result of determining the deterioration status of the reinforced concrete member corresponding to the combination is stored in advance, and the input means newly determines the deterioration status Inspection data obtained by performing any two or more of the above-described inspections constituting the above combination on the reinforced concrete member to be input is input.

  The discrimination program for a reinforced concrete member according to the present invention is a first association degree that obtains in advance three or more levels of first association between past inspection data for a reinforced concrete member and a determination result of a deterioration state of the reinforced concrete member for the inspection data. An acquisition step, a first input step for inputting inspection data obtained by inspecting a reinforced concrete member for newly determining a deterioration state, and the first association degree acquired in the first association degree acquisition step The computer executes a first determination step for determining the deterioration state of the reinforced concrete member based on the inspection data input in the first input step. In the first association degree acquisition step, an inspection for cracks, Inspection by potential method, inspection by polarization resistance method, by vibration measurement Inspection, chloride ion inspection, neutralization depth inspection, X-ray diffraction inspection, EPMA (Electron Probe Micro Analyzer) inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, acetic acid The first degree of association in three or more stages in advance is a combination of two or more types of past inspection data of inspection by uranyl fluorescence method and inspection by polarization microscope inspection, and the determination result of the deterioration status of the reinforced concrete member for the combination. Acquired, and in the first input step, the inspection data obtained by performing any two or more of the above-described inspections constituting the above combination for the reinforced concrete member for newly determining the deterioration state is input. And

  According to the present invention having the above-described configuration, it is possible to easily grasp the deterioration state of a reinforced concrete member without requiring special skill. Moreover, according to this invention, it becomes possible to grasp | ascertain the deterioration condition of a reinforced concrete member with high precision. Furthermore, by configuring the above-mentioned association degree with artificial intelligence, it is possible to further improve the discrimination accuracy by learning this.

It is a block diagram which shows the whole structure of the discrimination system of the reinforced concrete member to which this invention is applied. It is a figure which shows the specific structural example of a discrimination device. It is a figure for demonstrating the search concept of the output solution by the discrimination system of the reinforced concrete member to which this invention is applied. It is a flowchart which shows the processing operation of the discrimination system of the reinforced concrete member to which this invention is applied. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection regarding a crack as a test | inspection method. It is a figure which shows the 1st connection degree of the combination in the case of utilizing the test | inspection regarding a crack as an inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection by a natural potential method as a test | inspection method. It is a figure which shows the example of the 1st connection degree of the combination in the case of utilizing the test | inspection by a natural potential method as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection by a polarization resistance method as a test | inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection by a polarization resistance method as a test | inspection method. It is a figure which shows the example of the 1st connection degree in the case of utilizing the test | inspection by vibration measurement as a test | inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection by vibration measurement as a test | inspection method. It is a figure which shows the example of the 1st connection degree in the case of utilizing the test | inspection regarding a chloride ion amount as a test | inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection regarding the amount of chloride ions as an inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection regarding the neutralization depth as a test | inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection regarding the neutralization depth as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection by X-ray diffraction method as a test | inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection by X-ray diffraction method as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection by EPMA (Electron Probe Micro Analyzer) as a test | inspection method. It is a figure which shows the example of the 1st connection degree of the combination in the case of utilizing the test | inspection by EPMA (Electron Probe Micro Analyzer) as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the inspection by a scanning electron microscope as an inspection method. It is a figure which shows the example of the 1st association degree of the combination in the case of utilizing the test | inspection by a scanning electron microscope as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the test | inspection by fluorescent X-ray elemental analysis as a test | inspection method. It is a figure which shows the example of the 1st relevance of the combination in the case of utilizing the test | inspection by a fluorescent X-ray elemental analysis as a test | inspection method. It is a figure which shows the example of the 1st connection degree in the case of utilizing the test | inspection by the uranyl acetate fluorescence method as a test | inspection method. It is a figure which shows the example of the 1st connection degree of the combination in the case of utilizing the test | inspection by the uranyl acetate fluorescence method as a test | inspection method. It is a figure which shows the example of the 1st relevance in the case of utilizing the inspection by a polarizing microscope as an inspection method. It is a figure which shows the example of the 1st connection degree of the combination in the case of utilizing the test | inspection by a polarization microscope as a test | inspection method. It is a figure which shows the example of the 1st relevance of the combination of the inspection data of 2 or more types of inspection methods. It is a figure which shows the example of the 1st correlation of the combination of the inspection data and member information of 2 or more types of inspection methods. It is a flowchart which shows the processing operation at the time of discriminating a remaining useful life by the discrimination system of a reinforced concrete member to which the present invention is applied. It is a figure which shows the example of the 2nd connection degree of the degradation condition of the reinforced concrete member discriminate | determined, and the residual lifetime for the said degradation condition. It is a flowchart which shows the processing operation | movement at the time of discriminating the countermeasure with respect to a degradation condition with the discrimination system of the reinforced concrete member to which this invention is applied. It is a figure which shows the example of the 3rd correlation of the degradation condition of the reinforced concrete member discriminate | determined, and the countermeasure with respect to the said degradation condition.

  Hereinafter, a discrimination system for a reinforced concrete member to which the present invention is applied will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram showing the overall configuration of a reinforced concrete member discrimination system 1 to which the present invention is applied. The discrimination system 1 for a reinforced concrete member discriminates a deterioration state of a reinforced concrete member 7 used for a bridge. The discrimination system 1 for reinforced concrete members includes an inspection unit 8, an evaluation device 9 connected to the inspection unit 8, a discrimination device 2 connected to the evaluation device 9, and a database 3 connected to the discrimination device 2. Yes.

  In the reinforced concrete member 7, a reinforcing bar 72 is disposed inside the concrete 71. The reinforced concrete member 7 may be, for example, a PC (prestressed concrete) structure constructed by one or both of a pre-tension method and a post-tension method. When the reinforced concrete member 7 is constructed by the pre-tension method and the post-tension method, for example, pre-tension is applied in the bridge axis direction (longitudinal direction of the concrete member 7), and the bridge axis orthogonal direction (short of the concrete member 7). Post tension may be applied in the (hand direction). Reinforced concrete members 7 are used for bridges and PC bridges, for example, upper structures such as girders, lower structures such as abutments and piers, foundation structures, floor slabs placed on girders, wall railings, ground cover, etc. It is. The reinforced concrete member 7 may be formed in a rectangular cross section or the like and used for a box girder bridge. The reinforced concrete member 7 may be formed in a T-shaped section, an I-shaped section, or the like and used for a girder bridge. The reinforced concrete member 7 may be used for a floor slab bridge and a suspension structure bridge. The reinforced concrete member 7 may be used for a composite structure bridge connected to a steel girder. When the concrete member 7 is connected to the steel beam, it may be connected to the upper end of the steel beam or may be connected to the upper and lower ends of the steel beam. The reinforced concrete member 7 may be used for any of a box girder bridge, a girder bridge, a floor slab bridge, a suspension structure bridge, a composite structure bridge, and a bridge in which these are combined.

  The inspection unit 8 includes, for example, an inspection on a crack, an inspection by a natural potential method, an inspection by a polarization resistance method, an inspection by vibration measurement, an inspection on a chloride ion amount, an inspection on a neutralization depth, an inspection by an X-ray diffraction method, EPMA (Electron Probe Micro Analyzer) inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, uranyl acetate fluorescence inspection, polarization microscope inspection, and other inspection methods are used to determine the deterioration status of reinforced concrete members 7. Inspection data to detect is detected. The inspection unit 8 transmits the detected inspection data to the evaluation device 9.

  The evaluation device 9 is composed of electronic devices such as a PC (personal computer), a smartphone, a tablet terminal, and a wearable terminal. If the inspection data acquired by the inspection unit 8 is a waveform, the evaluation device 9 appropriately analyzes the analysis data to evaluate the degree of filling of the grout in the sheath 71. To do. For example, the evaluation device 9 may perform FFT (Fast Fourier Transform) conversion on the obtained frequency axis data to convert time axis waveform data into frequency axis spectrum data. The evaluation device 9 transmits the inspection data appropriately processed in this way to the determination device 2.

  Further, the evaluation device 9 performs a Fourier transform on the acquired waveform indicating the relationship between time and amplitude, converts the waveform into a waveform indicating the relationship between time and frequency, and then removes the specific frequency region. Furthermore, by performing an inverse Fourier transform, the waveform may be converted to a waveform indicating the relationship between the time remaining in the specific frequency region and the fluctuation width. In addition, the evaluation device 9 further performs a Fourier transform on the waveform indicating the relationship between the time and the amplitude that leaves the specific frequency region, thereby obtaining the relationship between the frequency and the amplitude that leaves the specific frequency region. You may convert into the waveform shown.

  The evaluation device 9 may perform wavelet transform on the acquired waveform as the inspection data to convert it into a waveform indicating the relationship between time and frequency. By applying the wavelet transform, it is possible to leave the time characteristics that are lost in the Fourier transform. For this reason, by performing wavelet transform, it is converted into a waveform indicating the relationship between time and frequency.

  The evaluation device 9 may extract a cepstrum coefficient and a formant by performing a cepstrum analysis on the acquired waveform as inspection data. Moreover, the evaluation apparatus 9 may perform AFTE (Auditory filterbank temporal envelope) conversion on the waveform as the acquired inspection data.

  Incidentally, the evaluation device 9 can display each inspection data via a display unit including a display (not shown), for example. Further, the evaluation device 9 can record each data in the storage, display the data on the display unit based on a command from the user, or write the data to the portable memory. The user can remove the portable memory from the evaluation device 9 and carry it freely. Furthermore, the evaluation device 9 can transfer these data to other electronic devices via the public communication network.

  In the present invention, the configuration of the evaluation device 9 is not essential and may be omitted. In such a case, the inspection data output from the inspection unit 8 is directly transmitted to the determination device 2.

  In the database 3, a first relational database 31 relating to the condition for determining the deterioration status of the reinforced concrete member 7 to be provided is constructed. Further, in the database 3, a second linkage database 32 relating to the condition for determining the remaining useful life of the reinforced concrete member 7 to be provided is constructed. Further, in the database 3, a third linkage database 33 relating to a determination condition for countermeasures against the deterioration status of the reinforced concrete member 7 to be provided is constructed. The database 3 stores information sent via a public communication network or information input by a user of this system. Further, the database 3 transmits the accumulated information to the determination device 2 based on a request from the determination device 2.

  The discriminating device 2 is composed of electronic devices such as a personal computer (PC), for example. In addition to the PC, the discriminating device 2 can be embodied in any other electronic device such as a mobile phone, a smartphone, a tablet terminal, and a wearable terminal. It may be made. The user can determine whether or not the reinforced concrete member is deteriorated by obtaining the determination result of the deterioration state of the reinforced concrete member 7 as a search solution by the determination device 2.

  FIG. 2 shows a specific configuration example of the discrimination device 2. The discrimination device 2 performs wired communication or wireless communication with a control unit 24 for controlling the discrimination device 2 as a whole, and an operation unit 25 for inputting various control commands via operation buttons, a keyboard, and the like. A communication unit 26 for searching, a search unit 27 for searching for an optimum design condition, and a storage unit 28 for storing a program for performing a search to be executed, represented by a hard disk or the like, are connected to the internal bus 21, respectively. Has been. Further, a display unit 23 as a monitor for actually displaying information is connected to the internal bus 21.

  The control unit 24 is a so-called central control unit for controlling each component mounted in the determination device 2 by transmitting a control signal via the internal bus 21. Further, the control unit 24 transmits various control commands via the internal bus 21 in accordance with an operation via the operation unit 25.

  The operation unit 25 is embodied by a keyboard or a touch panel, and an execution command for executing a program is input from the user. When the execution command is input from the user, the operation unit 25 notifies the control unit 24 of this. Upon receiving this notification, the control unit 24 executes a desired processing operation in cooperation with each component including the search unit 27.

  The search unit 27 searches for a determination result of the deterioration state of the reinforced concrete member 7. Further, the search unit 27 searches for a determination result of the remaining useful life of the reinforced concrete member 7. Further, the search unit 27 searches for a determination result of countermeasures against the deterioration state of the reinforced concrete member 7. The search unit 27 reads various information stored in the storage unit 28 as necessary information and various information stored in the database 3 when executing these search operations. The search unit 27 may be controlled by artificial intelligence. This artificial intelligence may be based on any known artificial intelligence technology.

  The display unit 23 includes a graphic controller that creates a display image based on control by the control unit 24. The display unit 23 is realized by, for example, a liquid crystal display (LCD).

  When the storage unit 28 is composed of a hard disk, based on the control by the control unit 24, predetermined information is written to each address and is read out as necessary. The storage unit 28 stores a program for executing the present invention. This program is read by the control unit 24 and executed.

  The operation of the discrimination system 1 for a reinforced concrete member having the above-described configuration will be described.

  In the reinforced concrete member discriminating system 1, for example, as shown in FIG. 3, an output solution relating to the result of discriminating the deterioration status of the reinforced concrete member 7 is searched based on input parameters including inspection data A, B,. The determination result of the deterioration state of the reinforced concrete member 7 may simply indicate only deterioration factors such as salt damage, neutralization, alkali-aggregate reaction, and these combined deteriorations. It may indicate what distribution causes salt damage, neutralization, alkali-aggregate reaction, complex degradation of these, and the like. Moreover, the discrimination | determination result of the deterioration condition of the reinforced concrete member 7 may be shown as information discriminate | determined as a degradation degree by percentage, such as 0%, 50%, 100%, for example. The degree of deterioration may be indicated by, for example, a percentage with respect to a deterioration factor such as a degree of salt damage deterioration of 10% and neutralization of 30%.

  The input parameters are inspection data detected by the inspection unit 8 and processed and analyzed by the evaluation device 9 as necessary. Inspection data A, B,... Are input as input parameters.

  After the inspection data is detected by the inspection unit 8 in this way, the processing operation by the discrimination program is actually executed. The processing operation flow of this discrimination program is shown in FIG.

  The evaluation device 9 performs various analyzes on the inspection data detected by the inspection unit 8 in step S11, and processes the various data to facilitate the search by the subsequent search device 2 (step S12).

  Next, the process proceeds to step S13, where the inspection data analyzed and processed in step S12 and the output solution of the first association degree are searched. Before this search, the first relational database 31 has three or more stages of reference parameters (hereinafter referred to as reference input parameters) and determination results of deterioration status of the reinforced concrete member 7 as an output solution. The first association degree is acquired in advance.

FIG. 5 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 5, as an inspection method in the inspection unit 8, an inspection method related to cracks in the reinforced concrete member 7 is used. This inspection method related to cracking is, for example, a method of determining deterioration of the reinforced concrete member 7 by measuring the crack width, crack depth, and crack length of the reinforced concrete member 7. The inspection data detected by the inspection unit 8 based on the inspection method related to the crack is composed of, for example, a crack width of the reinforced concrete member 7 and a crack frequency distribution indicating the frequency. For example, the crack frequency distribution may be represented by an image or the like obtained by mapping the distribution of cracks with respect to a predetermined area of the reinforced concrete member 7 in addition to the histogram. For this reason, in the reference input parameter, the crack frequency distribution data is learned in advance. Of course, the crack frequency distribution may indicate a crack depth and its frequency, or may indicate a crack length and its frequency.

  The database 3 (first relational database 31) includes 3 between the crack frequency distribution measured based on the crack-related inspection as the input parameter for reference and the determination result of the deterioration state of the reinforced concrete member 7 as the output solution. The first degree of relevance at the stage or higher is stored in advance. According to the example of FIG. 5, when the reference input parameter is the crack frequency distribution c1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali “Composite deterioration with aggregate reaction” is set at a first association degree of 60%, and “complex deterioration between neutralization and alkali aggregate reaction” is set at a first association degree of 30%. In addition, when the reference input parameter is the crack frequency distribution c2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “salt damage and neutralization” “Composite deterioration” is set at a first association degree of 20%, and “complex deterioration between salt damage and alkali-aggregate reaction” is set at a first association degree of 50%.

  These first association degrees are the frequency distributions c1, c2,..., And the deterioration status as a result of the determination when database 3 (first association database) is used. 31) may be stored in advance and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the crack frequency distribution when the inspection related to the crack is performed. For example, for the crack frequency distribution c1, “salt damage” with a first association degree of 80% is close to the most accurate judgment, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60%. This is an accurate judgment that follows, and “neutralization” with a first association degree of 40% is an accurate judgment that follows this, and a “neutralization and alkali-aggregate reaction with a first association degree of 30%. "Combined degradation" is an accurate decision that follows. Similarly, with regard to the crack frequency distribution c2, “neutralization” with a first association degree of 90% is closest to the most accurate judgment, and “alkaline aggregate reaction” with a first association degree of 70% is the next accurate decision. This is a judgment, and “combined deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 50% is the next accurate judgment, and “salt damage and neutralization with a first association degree of 20%. “Composite deterioration” is the next accurate decision.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first association shown in FIG. 5 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the crack frequency distribution of the input parameter analyzed in step S12 is the crack frequency distribution c1 as the reference input parameter or an approximation thereof, when referring to the first relevance described above, The “salt damage” having the highest first relation is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. Of course, an output solution that is not connected with an arrow may be selected. That is, the selection of the deterioration status of the reinforced concrete member 7 is not limited to the case where the first association degree is selected in order from the highest one, but is selected in the order from the first association degree which is low according to the case. May be selected, or may be selected in any other priority order.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  Note that the method of selecting an output solution for the input parameter analyzed in step S12 is not limited to the method described above, and may be executed based on any method that refers to the first association degree. Good. Further, the search operation in step S13 may be performed using artificial intelligence.

  Next, the process proceeds to step S14, and the deterioration state of the reinforced concrete member 7 as the selected optimum solution is displayed via the display unit 23. As a result, the user can immediately grasp the determination result of the deterioration state of the reinforced concrete member 7 by visually recognizing the display unit 23.

  FIG. 6 shows three or more levels of combinations of crack frequency distributions c1, c2,... As the inspection data of the past inspection regarding cracks and member information regarding the reinforced concrete member 7 and the deterioration status of the reinforced concrete member 7 with respect to the combination. This shows an example in which the first degree of association is set.

  The member information of the reinforced concrete member 7 includes installation information related to the installation of the reinforced concrete member 7, cross-sectional information related to the member cross section of the reinforced concrete member 7, management information related to the maintenance management of the reinforced concrete member 7, and photographic information related to the appearance photograph of the reinforced concrete member 7 Is included.

  The installation information includes location information regarding the location where the reinforced concrete member 7 is installed, such as a mountainous part, a port part, a marine atmospheric part, a splash zone, a tidal zone, a seawater part, a middle part of the submarine soil, and a temperature at which the reinforced concrete member 7 is installed. Climate information such as humidity, and vehicle information relating to a vehicle traveling on a structure in which the reinforced concrete member 7 is used, vehicle traveling frequency, and the like. The cross-section information includes information on the cross-sectional dimensions of the reinforced concrete member 7, the concrete cover thickness, the amount of reinforcing bars disposed, the wetness of the concrete surface, and the like. The management information includes a repair history of the reinforced concrete member 7, an inspection frequency, a service period after the reinforced concrete member 7 is constructed, and the like. The photographic information includes information regarding the appearance photograph of the reinforced concrete member 7 captured by an imaging device such as a digital camera, or an imaging device built in a smartphone, a tablet terminal, a wearable terminal, or the like. Incidentally, in the example of FIG. 6, the case where the installation information and the cross-section information are included in the member information constituting the combination is exemplified, but the management information and the photographic information may be included.

  In this case, as shown in FIG. 6, the first association degree is expressed as a set of combinations of crack frequency distributions c1, c2,... As inspection data and member information as so-called hidden layer nodes 61a to 61e. Will be. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, the node 61a is associated with a crack frequency distribution c1 having a first association degree of 80%, and a cover thickness “100 mm to 150 mm” as cross-sectional information is associated with a first association degree of 80%. The node 61c has a crack frequency distribution c2 having a first association degree of 60%, location information “splash zone” as installation information having a first association degree of 60%, and a cover thickness of “200 mm to 250 mm” as cross-section information. It is linked with 40% of one degree of association.

  Similarly, when the first relevance is set, when the process proceeds to step S13, crack frequency distributions c1, c2,... As inspection data of inspection as input parameters extracted in step S12. And the output solution according to the 1st relevance degree of installation information or cross-section information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 6 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the crack frequency distribution c1 and the location information “tidal zone” as the installation information, the node 61b is associated via the first association degree, and this node 61b "Neutralization" is the first linkage 60%, "Salt damage and neutralization combined degradation" is the first linkage 40%, "Neutralization and alkali aggregate reaction combined degradation" is the first One association is 20%.

  Based on this search result, the discrimination program outputs a solution in step S14 as well.

Inspection Using the Natural Potential Method In the example of FIG. 7, the natural potential method is used as the inspection method in the inspection unit 8. This natural potential method is a method for judging deterioration of the reinforced concrete member 7 by measuring a potential difference between the reinforcing bar 72 disposed in the reinforced concrete member 7 and the reference electrode. The inspection data detected by the inspection unit 8 based on the natural potential method is composed of, for example, an image representing a potential or the like with contour lines. For this reason, in the reference input parameter, the data of these images is learned in advance.

  The database 3 (first association database 31) stores in advance three or more levels of first association between the image as the reference input parameter and the determination result of the deterioration state of the reinforced concrete member 7 as the output solution. Let me. According to the example of FIG. 7, in the case of the reference input parameter image r <b> 1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first association degrees are the images r1, r2, r3,..., And the salt damage, neutralization, alkali aggregate reaction, It is also possible to store the deterioration state such as these combined deteriorations in the database 3 (first associative database 31) in advance and set based on them. This first association degree may be configured by a so-called neural network. This first degree of association indicates the accuracy in determining the actual deterioration status of the reinforced concrete member 7 based on the data when the inspection is performed based on the natural potential method. For example, for the image r3 based on the natural potential method, “combined deterioration between salt damage and alkali-aggregate reaction” having a first association degree of 70% is closest to the most accurate judgment, and “alkaline bone having a first association degree of 60%”. “Aggregate reaction” will be an accurate judgment that follows this, and “combined deterioration of salt damage, neutralization and alkali-aggregate reaction” with a first linkage of 40% will be an accurate judgment that follows this, “Compound deterioration of neutralization and alkali-aggregate reaction” with a first degree of association of 30% is an accurate judgment that follows. Similarly, for the image r2 based on the natural potential method, “neutralization” with a first association degree of 90% is closest to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is the most appropriate judgment. This is an accurate judgment that follows, and “the combined deterioration of salt damage and alkali-aggregate reaction” with a first linkage of 50% is the subsequent accurate judgment. "Compound deterioration with neutralization" is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first association shown in FIG. 7 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the input parameter analyzed in step S12 is the image r1 as the reference input parameter or an approximation thereof, when the first association degree is referred to, the first association degree is the highest. Select high “salt damage” as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 8 shows the first of three or more stages of the combination of the images r1, r2,... As the inspection data of the past inspection by the natural potential method and the member information and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which the association degree is set is shown. Incidentally, in the example of FIG. 8, the case where the member information includes the installation information and the management information is mentioned, but the cross-section information and the photographic information may be included.

  In such a case, as shown in FIG. 8, the first association degree is expressed as a set of so-called hidden layer nodes 61a to 61e, which is a set of combinations of images r1, r2,. The Rukoto. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the service period “5 years” as the management information is associated with the first association degree of 80%. The node 61c has an image r2 having a first association degree of 60%, vehicle information “100 units / hour” as installation information has a first association degree of 60%, and a service period “10 years” as management information has a first association. It is linked at 40%.

  Similarly, when the first relevance is set, when the process proceeds to step S13, images r1, r2,... As inspection data of the inspection as input parameters extracted in step S12, An output solution corresponding to the first association degree of the installation information and management information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 8 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the vehicle information “10 units / hour” as the installation information, the node 61b is associated through the first association degree. 61b, “neutralization” is 60% of the first association, “combined degradation of salt damage and neutralization” is the first association of 40%, “combined degradation of neutralization and alkali-aggregate reaction” The first association is 20%.

Inspection by Polarization Resistance Method In the example of FIG. 9, the polarization resistance method is used as an inspection method in the inspection unit 8. This polarization resistance method is a method for determining deterioration of the reinforced concrete member 7 by measuring polarization resistance obtained by passing a minute alternating current through the reinforcing bar 72. The inspection data detected by the inspection unit 8 based on this polarization resistance method is composed of, for example, an image representing polarization resistance and the like with contour lines. For this reason, in the reference input parameter, the data of these images is learned in advance.

  The database 3 (first association database 31) stores in advance three or more levels of first association between the image as the reference input parameter and the determination result of the deterioration state of the reinforced concrete member 7 as the output solution. Let me. According to the example of FIG. 9, in the case of the reference input parameter image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first degrees of association are the images r1, r2, r3,..., And the salt damage, neutralization, and alkali aggregates as a result of the discrimination when the non-destructive inspection was previously performed based on the polarization resistance method. Deterioration conditions such as reactions and complex degradation of these may be stored in advance in the database 3 (first association database 31) and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on data obtained when the inspection is performed based on the polarization resistance method. For example, for the image r3 based on the polarization resistance method, “combined deterioration of salt damage and neutralization” with a first association degree of 70% is closest to the most accurate determination, and “alkaline aggregate” with a first association degree of 60%. “Reaction” will be an accurate judgment that follows this, and “combined deterioration of salt damage, neutralization and alkali-aggregate reaction” with a first linkage of 40% will be an accurate judgment that follows this. “Combined degradation of neutralization and alkali-aggregate reaction” with a degree of association of 30% is an accurate judgment that follows this. Similarly, for the image r2 based on the natural potential method, “neutralization” with a first association degree of 90% is closest to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is the most appropriate judgment. This is an accurate judgment that follows, and “the combined deterioration of salt damage and alkali-aggregate reaction” with a first linkage of 50% is the subsequent accurate judgment. "Compound deterioration with neutralization" is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 9 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the input parameter analyzed in step S12 is the image r1 as the reference input parameter or an approximation thereof, when the first association degree is referred to, the first association degree is the highest. Select high “salt damage” as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 10 shows the first of three or more stages of the combination of the images r1, r2,... As the inspection data of the past inspection by the polarization resistance method and the member information and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which the association degree is set is shown. Incidentally, in the example of FIG. 10, the member information includes the case where the installation information and the cross-section information are included, but the management information and the photo information may be included.

  In such a case, as shown in FIG. 10, the first association degree is expressed as a set of combinations of images r1, r2,... As inspection data and member information as so-called hidden layer nodes 61a to 61e. It will be. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the sectional dimension “2000 mm × 500 mm” as the sectional information is associated with the first association degree of 80%. Further, in the node 61c, the image r2 has a first association degree of 60%, the temperature “30 ° C.” as installation information has a first association degree of 60%, and the cross-sectional dimension “1000 mm × 1000 mm” as cross-section information has a first association degree. 40% are linked.

  Similarly, when the first relevance is set, when the process proceeds to step S13, images r1, r2,... As inspection data of the inspection as input parameters extracted in step S12, An output solution corresponding to the first association degree of the installation information and the cross-section information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 10 acquired in advance is referred to. For example, if the input parameter analyzed in step S12 is the image r1 and the temperature is “0 ° C.” as the installation information, the node 61b is associated via the first association degree, "Neutralization" is the first association 60%, "combined degradation of salt damage and neutralization" is the first association 40%, "combined degradation of neutralization and alkali-aggregate reaction" is the first The association is 20%.

Inspection by Vibration Measurement In the example of FIG. 11, vibration measurement is used as an inspection method in the inspection unit 8. This vibration measurement is a method of measuring the vibration of the reinforced concrete member 7 with an accelerometer and judging the deterioration of the reinforced concrete member 7 from the vibration characteristics. The inspection data detected by the inspection unit 8 based on this vibration measurement is composed of data such as a logarithmic decay rate of acceleration measured in time series. For this reason, in the reference input parameter, data such as a change in logarithmic decay rate is learned in advance.

  The database 3 (first linkage database 31) includes three or more levels of first linkage between the logarithmic decay rate of acceleration as a reference input parameter and the determination result of the deterioration state of the reinforced concrete member 7 as an output solution. The degree is stored in advance. According to the example of FIG. 11, when the logarithmic decay rate of the reference input parameter is “0 to 0.5%”, “salt damage” is the first association degree 80% and “neutralization” is the first association. 40%, “combined deterioration between salt damage and alkali-aggregate reaction” is set at 60% for the first association, and “combined deterioration between neutralization and alkali-aggregate reaction” is set at the first for 30%. . When the reference input parameter is a logarithmic decay rate of “0.5 to 1%”, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “ “Combined deterioration between salt damage and neutralization” is set at a first association degree of 20%, and “combined deterioration between salt damage and an alkali aggregate reaction” is set at a first association degree of 50%.

  These first relevance levels are based on the logarithmic decay rate at the time of previous inspection based on vibration measurement, and the degradation status of salt damage, neutralization, alkali aggregate reaction, etc. as a result of the discrimination. The data may be stored in advance in the one-related database 31) and set based on them. This first association degree may be configured by a so-called neural network. This first relevance indicates the accuracy in determining the actual deterioration status of the reinforced concrete member 7 based on the data when the inspection is performed based on the vibration measurement. For example, for the logarithmic attenuation rate “1 to 2%” based on vibration measurement, “combined deterioration of salt damage and neutralization” with a first association degree of 70% is close to the most accurate judgment, and the first association degree 60 % “Alkaline-aggregate reaction” is the subsequent accurate judgment, and “combined deterioration of salt damage, neutralization and alkali-aggregate reaction” with the first linkage 40% is the subsequent accurate judgment. Thus, “combined deterioration between neutralization and alkali-aggregate reaction” with a first relevance of 30% is an accurate judgment that follows. Similarly, for the logarithmic attenuation rate “0.5 to 1%” based on vibration measurement, “neutralization” with a first association degree of 90% is closest to the most accurate determination, and “ “Alkali-aggregate reaction” will be the next accurate judgment, and “the combined deterioration of salt damage and alkali-aggregate reaction” with the first relevance of 50% will be the next accurate judgment. “Combined deterioration of salt damage and neutralization” with an association degree of 20% is an accurate judgment that follows this.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 11 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the input parameter analyzed in step S12 is the logarithmic attenuation rate “0 to 0.5%” as a reference input parameter or approximates it, the above-mentioned relevance is referred to The “salt damage” having the highest first relation is selected as the optimum solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 12 shows three or more levels of first correlation between the logarithmic decay rate as inspection data of past inspection by vibration measurement and the deterioration status of the PC steel material 72 with respect to the combination of member information and acceleration information of the reinforced concrete member 7. An example of setting is shown. This acceleration information is composed of information related to the magnitude of acceleration of vibration measurement, various factors causing vibration, and the like. Incidentally, in the example of FIG. 12, the member information includes a case where management information is included, but installation information, cross-sectional information, and photographic information may be included.

  In such a case, as shown in FIG. 12, the first relevance degree is a set of one or more combinations of each logarithmic decay rate as inspection data and location information and acceleration information of the reinforced concrete member 7. It will be expressed as nodes 61a-61e. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the logarithmic decay rate “0 to 0.5%” is associated with the first association degree 80%, and the acceleration information “± 0.04 to 0.08” is associated with the first association degree 80%. ing. The node 61c has a logarithmic decay rate of “0.5 to 1%” having a first association degree of 60%, a repair history “no repair” as management information having a first association degree of 60%, and acceleration information of “± 0. "01-0.04" is associated with a first association degree of 40%.

  Similarly, when such a first association degree is set, when the process proceeds to step S13, the logarithmic decay rate as the inspection data as the input parameter extracted in step S12 and the management information of the reinforced concrete member 7 are used. And an output solution corresponding to the first association degree of acceleration information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 12 acquired in advance is referred to. For example, in the input parameter analyzed in step S12, when the logarithmic decay rate is “0 to 0.5%” and the management history is repair history “with repair”, the node 61b is associated via the first association degree. In this node 61b, “neutralization” has a first association degree of 60%, “complex deterioration of salt damage and neutralization” has a first association degree of 40%, “neutralization and alkali-aggregate reaction” "Combined deterioration" with a first association degree of 20%.

Examination Regarding Chloride Ion Amount FIG. 13 shows an example of the first association degree acquired in advance in this database 3 (first association database 31). In the example of FIG. 13, an inspection method related to the amount of chloride ions contained in the reinforced concrete member 7 is used as an inspection method in the inspection unit 8. Examples of the inspection method relating to the chloride ion amount include a fluorescent X-ray method and a drill method. In the fluorescent X-ray method, the amount of chloride ions contained in a sample is measured using characteristic X-rays emitted when the reinforced concrete member 7 is irradiated with X-rays, and deterioration of the reinforced concrete member 7 is judged. It is a technique. When measuring the amount of chloride ions by the fluorescent X-ray method, the reinforced concrete member 7 installed at the site may be irradiated with X-rays, or a sample collected from the reinforced concrete member 7 installed at the site may be used. Alternatively, X-rays may be irradiated. The drill method is a method of measuring deterioration of the reinforced concrete member 7 by measuring a chloride ion amount using powder obtained by drilling the reinforced concrete member 7 with a drill bit or the like. When measuring the amount of chloride ions by the drill method, for example, the “Testing Method for Chloride Ions Contained in Hardened Concrete” (JIS A 1154) defined by Japanese Industrial Standards or the Japan Concrete Institute It may be measured by the “simple analysis method of total salt contained in hardened concrete” (JCI-SC5). The inspection data detected by the inspection unit 8 based on the inspection method relating to the amount of chloride ions is composed of data on the amount of chloride ions. For this reason, in the reference input parameter, data on the amount of chloride ions is learned in advance.

In the database 3, 3 between the data of the chloride ion amount measured based on the inspection method relating to the chloride ion amount as the input parameter for reference and the determination result of the deterioration state of the reinforced concrete member 7 as the output solution. The first degree of relevance at the stage or higher is stored in advance. According to the example of FIG. 13, when the reference input parameter is the chloride ion amount “0.1 kg / m ³ ”, “combined deterioration of salt damage and neutralization” has a first association degree of 70%, “ "Alkali-aggregate reaction" is the first linkage 60%, "combined degradation of salt damage, neutralization and alkali-aggregate reaction" is the first linkage 40%, "combined degradation of neutralization and alkali-aggregate reaction" Is set at a first relevance of 30%. When the reference input parameter is the chloride ion amount “1.0 kg / m ³ ”, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “Combined deterioration between salt damage and neutralization” is set at a first association degree of 20%, and “combined deterioration between salt damage and an alkali aggregate reaction” is set at a first association degree of 50%.

These first relevance levels are stored in the database 3 (first associative database 31) as the amount of chloride ions when the inspection was previously performed based on the inspection method relating to the amount of chloride ions and the degradation status as a result of the determination. May be stored in advance and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the chloride ion amount when the inspection relating to the chloride ion amount is performed. For example, with respect to the chloride ion amount of “2.0 kg / m ³ ”, “salt damage” with a first association degree of 80% is the most accurate judgment, and “salt damage and alkali aggregate reaction with a first association degree of 60%”. ”Combined degradation” and “neutralization” with a first relevance of 40% are subsequent accurate judgments, and “medium” with a first relevance of 30% The combined deterioration of oxidization and alkali-aggregate reaction is an accurate judgment that follows. Similarly, for a chloride ion amount of “1.0 kg / m ³ ”, “neutralization” with a first association degree of 90% is the most accurate judgment, and “alkaline aggregate” with a first association degree of 70% “Reaction” is an accurate judgment that follows this, and “complex deterioration of salt damage and alkali-aggregate reaction” with a first association degree of 50% is an accurate judgment that follows this. % “Combined degradation of salt damage and neutralization” is the next accurate judgment.

After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 13 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, if the chloride ion amount of the input parameter analyzed in step S12 is the chloride ion amount “2.0 kg / m ³ ” as the input parameter for reference or approximates it, the above-mentioned When referring to the first association degree When referring to the first association degree described above, the “salt damage” having the highest first association degree is selected as the optimum solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 14 shows the combination of chloride ion amount data and member information as inspection data of past inspections by the inspection method relating to the chloride ion amount contained in the reinforced concrete member 7, and the deterioration status of the reinforced concrete member 7 with respect to the combination This shows an example in which the first relevance level of three or more levels is set. Incidentally, in the example of FIG. 14, the member information includes the case where the installation information and the photo information are included, but the cross-section information and the management information may be included.

In such a case, as shown in FIG. 14, the first association degree indicates that a set of combinations of chloride ion amount data as inspection data and member information is expressed as so-called hidden layer nodes 61 a to 61 e. It becomes. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the chloride ion amount “2.0 kg / m ³ ” is associated with the first association degree 80%, and the appearance photograph P1 as photographic information is associated with the first association degree 80%. Further, the node 61c has a chloride ion amount “1.0 kg / m ³ ” having a first association degree of 60%, location information “splash zone” as installation information has a first association degree of 60%, and an appearance photograph as photographic information. P2 is associated with a first association degree of 40%.

Similarly, when the first relevance is set, when the process proceeds to step S13, the chloride ion amount data as the inspection data of the inspection as the input parameter extracted in step S12, and the installation An output solution corresponding to the first association degree of information and management information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 14 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the chloride ion amount “2.0 kg / m ³ ” and the location information “tidal zone” as the installation information, the node 61b is connected via the first association degree. In this node 61b, “neutralization” has a first association degree of 60%, “complex deterioration of salt damage and neutralization” has a first association degree of 40%, and “neutralization and “Composite degradation with alkali-aggregate reaction” is associated with a first association of 20%.

FIG. 15 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 15, an inspection method related to the neutralization depth of the reinforced concrete member 7 is used as an inspection method in the inspection unit 8. The method for inspecting the neutralization depth is, for example, measuring the neutralization depth by a concrete neutralization depth measurement method (JIS A 1152) stipulated in Japanese Industrial Standards, and deteriorating the reinforced concrete member 7. It is a method to judge. The inspection data detected by the inspection unit 8 based on the inspection method relating to the neutralization depth is constituted by data on the neutralization depth. For this reason, the neutralization depth data is learned in advance for the reference input parameter.

  In the database 3 (first relational database 31), the data of the neutralization depth measured based on the inspection method regarding the neutralization depth as the reference input parameter, and the deterioration state of the reinforced concrete member 7 as the output solution The first relevance in three or more stages with the determination result is stored in advance. According to the example of FIG. 15, when the reference input parameter is the neutralization depth “5 mm”, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “Combined deterioration between salt damage and alkali-aggregate reaction” is set at a first association degree of 60%, and “combined deterioration between neutralization and alkali-aggregate reaction” is set at a first association degree of 30%. When the reference input parameter is a neutralization depth of “10 mm”, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “salt damage and medium” “Combined deterioration with oxidization” is set at a first association degree of 20%, and “complex deterioration between salt damage and alkali-aggregate reaction” is set at a first association degree of 50%.

  These first relevance levels are obtained by using the database 3 (first relevance data) and the neutralization depth data obtained by the previous inspection based on the neutralization depth inspection method and the degradation status as a result of the determination. It may be stored in advance in the database 31) and set based on them. This first association degree may be configured by a so-called neural network. This first degree of association indicates the accuracy in determining the actual deterioration status of the reinforced concrete member 7 based on the data of the neutralization depth when the inspection related to the neutralization depth is performed. is there. For example, for a neutralization depth of “20 mm”, “complex deterioration of salt damage and neutralization” with a first association degree of 70% is closest to the most accurate judgment, and “alkaline bone with a first association degree of 60%” “Aggregate reaction” will be an accurate judgment that follows this, and “combined deterioration of salt damage, neutralization and alkali-aggregate reaction” with a first linkage of 40% will be an accurate judgment that follows this, “Compound deterioration of neutralization and alkali-aggregate reaction” with a first degree of association of 30% is an accurate judgment that follows. Similarly, for a neutralization depth of “10 mm”, “neutralization” with a first association degree of 90% is close to the most accurate judgment, and “alkaline aggregate reaction” with a first association degree of 70% is the most appropriate judgment. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first linkage of 50% is an accurate decision following this, and “salt damage with a first linkage of 20%. "Compound deterioration with neutralization" is the next accurate decision.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. In determining the deterioration state of the reinforced concrete member 7, the first association degree shown in FIG. For example, if the chloride ion content of the input parameter analyzed in step S12 is the neutralization depth “5 mm” as the reference input parameter or approximates it, the first relevance described above When the first association degree mentioned above is referred to, the “salt damage” having the highest first association degree is selected as the optimum solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 16 shows a combination of the neutralization depth data as the inspection data of the past inspection by the inspection method relating to the neutralization depth of the reinforced concrete member 7 and the member information, and the deterioration state of the reinforced concrete member 7 with respect to the combination. This shows an example in which the first relevance level of three or more levels is set. Incidentally, in the example of FIG. 16, the member information includes the case where the cross-section information and the management information are included, but the installation information and the photo information may be included.

  In such a case, as shown in FIG. 16, the first association degree is a set of combinations of neutralization depth data as inspection data and member information expressed as so-called hidden layer nodes 61 a to 61 e. It will be. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, the node 61a is associated with a neutralization depth of “5 mm” with a first association degree of 80% and a service period of “5 years” as management information with a first association degree of 80%. The node 61c has a neutralization depth of “10 mm” with a first relevance of 60%, a cover thickness of “200 mm to 250 mm” as installation information of a first relevance of 60%, and a service period of “10 years as management information”. Are linked at a first link degree of 40%.

  Similarly, when such a first association degree is set, when the process proceeds to step S13, the neutralization depth data as the inspection data of the inspection as the input parameter extracted in step S12, An output solution corresponding to the first association degree of the installation information and management information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 16 acquired in advance is referred to. For example, in the input parameter analyzed in step S12, when the neutralization depth is “5 mm” and the cover thickness is “100 mm to 150 mm” as installation information, the node 61b is associated via the first association degree. In this node 61b, “neutralization” has a first association degree of 60%, “complex deterioration of salt damage and neutralization” has a first association degree of 40%, “neutralization and alkali-aggregate reaction Is associated with a first association degree of 20%.

Examination by X-ray Diffraction Method FIG. 17 shows an example of the first association degree acquired in advance in this database 3 (first association database 31). In the example of FIG. 17, an inspection method using an X-ray diffraction method is used as an inspection method in the inspection unit 8. This inspection method by the X-ray diffraction method is, for example, a method of irradiating a sample collected from a reinforced concrete member 7 installed on site to determine deterioration of the reinforced concrete member 7. The inspection data detected by the inspection unit 8 based on the inspection method based on the X-ray diffraction method includes an X-ray intensity spectrum image obtained by the X-ray diffraction method, a component analysis result analyzed by the X-ray diffraction method, and the like. The In the example shown in FIG. 17, an X-ray intensity spectrum image is learned in advance for the reference input parameter. Of course, the component analysis result analyzed by the X-ray diffraction method may be learned in advance for the reference input parameter.

  The database 3 (first relational database 31) includes X-ray intensity spectrum images r1, r2,... Measured based on an X-ray diffraction inspection method as a reference input parameter, and reinforced concrete as an output solution. First relations of three or more levels with the determination result of the deterioration state of the member 7 are stored in advance. According to the example of FIG. 17, when the reference input parameter is the image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first relevance levels are obtained by comparing the images r1, r2,..., And the deterioration status as a result of the determination in the database 3 (first relevance). It may be stored in advance in the database 31) and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the image obtained when the inspection is performed by the X-ray diffraction method. For example, for the image r1, “salt damage” with a first association degree of 80% is closest to the most accurate determination, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60% follows. Therefore, “neutralization” with a first relevance of 40% is an accurate decision that follows this, and “combining neutralization with an alkali-aggregate reaction” with a first relevance of 30%. “Deterioration” is an accurate judgment that follows. Similarly, for the image r2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is an accurate determination following this. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and the relationship between salt damage and neutralization with a first degree of association of 20%. “Composite degradation” is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 17 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the image of the input parameter analyzed in step S12 is the image r1 as the reference input parameter or an approximation thereof, the first association described above when the first association described above is referred to. When the degree is referred to, the “salt damage” having the highest first relation is selected as the optimum solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 18 shows the first of three or more stages of the combination of the images r1, r2,... As the inspection data of the past inspection by the X-ray diffraction method and the member information, and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which the association degree is set is shown. Incidentally, in the example of FIG. 18, the member information includes the case where the cross-section information and the management information are included, but the installation information and the photo information may be included.

  In this case, as shown in FIG. 18, the first association degree is a set of combinations of images r1, r2,... As inspection data and member information, which are expressed as so-called hidden layer nodes 61a to 61e. It will be. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the repair history “with repair” as management information is associated with the first association degree of 80%. In the node 61c, the image r2 has a first relevance of 60%, the cross-sectional dimension “1000 mm × 1000 mm” as installation information has a first relevance of 60%, and the repair history “no repair” as management information has a first relevance of 40 % Are related.

  Similarly, when such a first association degree is set, when the process proceeds to step S13, an image of an X-ray intensity spectrum as inspection data as an input parameter extracted in step S12, and a cross section An output solution corresponding to the first association degree of information and management information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting the optimum solution, the first association shown in FIG. 18 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the cross-sectional dimension “2000 mm × 500 mm” as the installation information, the node 61b is associated via the first association degree. "Neutralization" is the first linkage 60%, "Salt damage and neutralization combined degradation" is the first linkage 40%, "Neutralization and alkali aggregate reaction combined degradation" is the first One association is 20%.

Inspection by EPMA (Electron Probe Micro Analyzer) FIG. 19 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 19, an inspection method using EPMA is used as an inspection method in the inspection unit 8. This EPMA inspection method irradiates a concrete sample taken from the reinforced concrete member 7 with an electron beam and analyzes the elements contained in the sample using characteristic X-rays emitted from atoms constituting the sample. This is a method for judging the deterioration of the reinforced concrete member 7. The inspection data detected by the inspection unit 8 based on this EPMA inspection method is composed of an element distribution image analyzed by EPMA, an element analysis result, and the like. In the example shown in FIG. 19, an element distribution image is learned in advance for the reference input parameter. Of course, the elemental analysis results analyzed by EPMA may be learned in advance for the reference input parameters.

  In the database 3 (first relational database 31), the element distribution images r1, r2,... Analyzed based on the EPMA inspection method as the input parameters for reference, and the deterioration status of the reinforced concrete member 7 as the output solution The first relevance in three or more stages with the determination result is stored in advance. According to the example of FIG. 19, when the reference input parameter is the image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first association degrees are the images 3, r 2,..., And the deterioration status as a result of the discrimination when the inspection was performed based on the inspection method by EPMA before (database 1 (first association database 31)). It is also possible to store in advance and set based on them. This first association degree may be configured by a so-called neural network. This first degree of association indicates accuracy in determining the actual deterioration status of the reinforced concrete member 7 based on the image when the inspection is performed by EPMA. For example, for the image r1, “salt damage” with a first association degree of 80% is closest to the most accurate determination, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60% follows. Therefore, “neutralization” with a first relevance of 40% is an accurate decision that follows this, and “combining neutralization with an alkali-aggregate reaction” with a first relevance of 30%. “Deterioration” is an accurate judgment that follows. Similarly, for the image r2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is an accurate determination following this. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and the relationship between salt damage and neutralization with a first degree of association of 20%. “Composite degradation” is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 19 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the image r1 of the input parameter analyzed in step S12 is the image r1 as the reference input parameter or approximates it, the first association is referred to when the first association degree is referred to. The highest degree of “salt damage” is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 20 shows three or more stages of first relations between combinations of images r1, r2,... And member information as inspection data of past inspections by the EPMA inspection method, and deterioration status of the reinforced concrete member 7 with respect to the combinations. An example in which the degree is set is shown. Incidentally, in the example of FIG. 20, the member information includes the case where the installation information and the cross-section information are included, but the management information and the photo information may be included.

  In such a case, as shown in FIG. 20, the first association degree is a set of combinations of images r1, r2,... As inspection data and member information expressed as so-called hidden layer nodes 61a to 61e. The Rukoto. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the cover thickness “100 mm to 150 mm” as the cross-sectional information is associated with the first association degree of 80%. The node 61c has an image r2 having a first relevance of 60%, vehicle information “10 units / hour” as installation information having a first relevance of 60%, and a cover thickness of “200 mm to 250 mm” as cross-sectional information. It is linked with 40% of one degree of association.

  Similarly, when such first association is set, when the process proceeds to step S13, an element distribution image as inspection data as an input parameter extracted in step S12, installation information, An output solution corresponding to the first association degree of the cross-section information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimum solution, the first association shown in FIG. 20 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the vehicle information “100 units / hour” as the installation information, the node 61b is associated through the first association degree. 61b, “Neutralization” has a first association degree of 60%, “Combined deterioration of salt damage and neutralization” has a first association degree of 40%, “Neutralization and alkali aggregate reaction combined deterioration” Is associated with a first relevance of 20%.

Inspection by Scanning Electron Microscope FIG. 21 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 21, an inspection method using a scanning electron microscope is used as an inspection method in the inspection unit 8. This inspection method using a scanning electron microscope is a technique for judging deterioration of a reinforced concrete member 7 by imaging a sample collected from the reinforced concrete member 7 using a scanning electron microscope. The inspection data detected by the inspection unit 8 based on the inspection method using the scanning electron microscope is composed of an image captured by the scanning electron microscope. For this reason, in the reference input parameter, the data of these images is learned in advance.

  In the database 3 (first relational database 31), images r1, r2,... Captured based on an inspection method using a scanning electron microscope as reference input parameters, and the deterioration status of the reinforced concrete member 7 as an output solution The first relevance in three or more stages with the determination result is stored in advance. According to the example of FIG. 21, when the input parameter for reference is the image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first association degrees are the images 3, 1,..., And the degradation state as a result of the discrimination when the inspection is performed based on the inspection method using the scanning electron microscope before the database 3 (first association). It may be stored in advance in the database 31) and set based on them. This first association degree may be configured by a so-called neural network. This first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the image obtained when the inspection is performed with the scanning electron microscope. For example, for the image r1, “salt damage” with a first association degree of 80% is closest to the most accurate determination, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60% follows. Therefore, “neutralization” with a first relevance of 40% is an accurate decision that follows this, and “combining neutralization with an alkali-aggregate reaction” with a first relevance of 30%. “Deterioration” is an accurate judgment that follows. Similarly, for the image r2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is an accurate determination following this. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and the relationship between salt damage and neutralization with a first degree of association of 20%. “Composite degradation” is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first association shown in FIG. 21 acquired in advance for determining the deterioration state of the reinforced concrete member 7. For example, when the image r1 of the input parameter analyzed in step S12 is the image r1 as the reference input parameter or approximates it, the first association is referred to when the first association degree is referred to. The highest degree of “salt damage” is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 22 shows three or more stages of the combination of the image information r1, r2,... And the member information as the inspection data of the past inspection by the inspection method using the scanning electron microscope and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which the first association degree is set is shown. Incidentally, in the example of FIG. 22, a case is described in which the installation information is included in the member information, but cross-section information, management information, and photographic information may be included.

  In such a case, as shown in FIG. 22, the first association degree is expressed as a set of combinations of images r1, r2,... As inspection data and member information as so-called hidden layer nodes 61a to 61e. The Rukoto. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree 80%, and the vehicle information “100 units / hour” as the installation information is associated with the first association degree 80%. Further, in the node 61c, the image r2 has a first association degree of 60%, the temperature “30 ° C.” as installation information has a first association degree of 60%, and the vehicle information “10 units / hour” as installation information has a first association degree of 40. % Are related.

  Similarly, when the first association degree is set, when the process proceeds to step S13, the image as the inspection data of the inspection as the input parameter extracted in step S12 and the first association of the installation information. Search the output solution according to the degree. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 22 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the temperature “0 ° C.” as the installation information, the node 61b is associated via the first association degree, "Neutralization" is the first linkage 60%, "combined degradation of salt damage and neutralization" is the first linkage 40%, "combined degradation of neutralization and alkali-aggregate reaction" is the first linkage Associated with 20% degree.

Examination by X-ray fluorescence elemental analysis FIG. 23 shows an example of the first association degree acquired in advance in this database 3 (first association database 31). In the example of FIG. 23, an inspection method based on fluorescent X-ray elemental analysis is used as an inspection method in the inspection unit 8. This inspection method by fluorescent X-ray elemental analysis is included in a sample using characteristic X-rays emitted when a concrete sample cut out from a reinforced concrete member 7 is irradiated with X-rays by a fluorescent X-ray analyzer. This is a method for qualitative and quantitative analysis of the elements that are present to determine the deterioration of the reinforced concrete member 7. The inspection data detected by the inspection unit 8 based on the inspection method based on the fluorescent X-ray elemental analysis is composed of an element analysis result analyzed by the fluorescent X-ray analyzer, an image of a characteristic X-ray intensity spectrum, and the like. In the example shown in FIG. 23, the quantitative analysis result data is learned in advance for the reference input parameter. Of course, with reference input parameters, image data of a characteristic X-ray intensity spectrum may be learned in advance.

  In the database 3 (first association database 31), the analysis results g1, g2,... Analyzed based on the inspection method by the fluorescent X-ray elemental analysis as the reference input parameters, and the reinforced concrete member 7 as the output solution First relations of three or more stages with the determination result of the deterioration state are stored in advance. According to the example of FIG. 23, when the reference input parameter is the analysis result g1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkaline bone “Composite deterioration with material reaction” is set at a first association degree of 60%, and “Composite deterioration between neutralization and alkali aggregate reaction” is set at a first association degree of 30%. When the reference input parameter is the analysis result g2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combining salt damage and neutralization” “Deterioration” is set at a first relevance of 20%, and “combined deterioration between salt damage and alkali aggregate reaction” is set at a first relevance of 50%.

  These first relevance levels are obtained by analyzing the analysis results g1, g2,..., And the deterioration status as the discrimination results when the inspection is performed based on the inspection method based on the fluorescent X-ray elemental analysis before. The data may be stored in advance in the one-related database 31) and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the data of the analysis result when the inspection by the fluorescent X-ray elemental analysis is performed. For example, for the analysis result g1, “salt damage” with a first association degree of 80% is close to the most accurate determination, followed by “combined deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60%. It is an accurate judgment, and “neutralization” with a first association degree of 40% is an accurate judgment that follows this, and a “neutralization and alkali-aggregate reaction with a first association degree of 30%. “Composite degradation” is an accurate decision that follows. Similarly, for the analysis result g2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is the subsequent accurate determination. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and “salt damage and neutralization with a first degree of association of 20%. "Combined degradation" is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first degree of association shown in FIG. 23 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the analysis result g1 of the input parameter analyzed in step S12 is the analysis result g1 as the reference input parameter or approximates it, when the first association degree described above is referred, The “salt damage” with the highest degree of association is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 24 shows three stages: a combination of analysis results g1, g2,... And member information as inspection data of past inspections by an inspection method using fluorescent X-ray elemental analysis, and a deterioration state of reinforced concrete member 7 with respect to the combination. An example in which the above first association degree is set is shown. Incidentally, in the example of FIG. 24, the member information includes the case where the cross-section information is included, but the installation information, management information, and photographic information may be included.

  In this case, as shown in FIG. 24, the first association degree is expressed as a set of combinations of analysis results g1, g2,... As inspection data and member information as so-called hidden layer nodes 61a to 61e. Will be. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, the node 61a is associated with an analysis result g1 having a first association degree of 80% and a cover thickness “100 mm to 150 mm” as cross-sectional information having a first association degree of 80%. The node 61c has an analysis result g2 having a first association degree of 60%, a cross-sectional dimension “1000 mm × 1000 mm” as the cross-section information is a first association degree 60%, and a cover thickness “200 mm to 250 mm” as the installation information is the first association It is linked at 40%.

  Similarly, when the first association degree is set, when the process proceeds to step S13, the analysis result data as the inspection test data as the input parameter extracted in step S12, and the installation information An output solution corresponding to the first association degree is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 24 acquired in advance is referred to. For example, in the input parameter analyzed in step S12, when the analysis result is g1 and the cross-sectional dimension is “2000 mm × 500 mm” as the cross-sectional information, the node 61b is associated through the first association degree. 61b, “neutralization” is 60% of the first association, “combined degradation of salt damage and neutralization” is the first association of 40%, “combined degradation of neutralization and alkali-aggregate reaction” The first association is 20%.

Examination by uranyl acetate fluorescence method FIG. 25 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 25, an inspection method using the uranyl acetate fluorescence method is used as the inspection method in the inspection unit 8. This inspection method by the uranyl acetate fluorescence method is a method for judging deterioration of the reinforced concrete member 7 by applying a uranyl acetate solution to the reinforced concrete member 7 and irradiating it with ultraviolet rays. The inspection data detected by the inspection unit 8 based on the inspection method based on this uranyl acetate fluorescence method is composed of an image or the like when irradiated with ultraviolet rays. For this reason, in the reference input parameter, the data of these images is learned in advance.

  In the database 3 (first relational database 31), the images r1, r2,... Imaged based on the inspection method by the uranyl acetate fluorescence method as the reference input parameter and the deterioration of the reinforced concrete member 7 as the output solution First relations of three or more levels with the situation determination result are stored in advance. According to the example of FIG. 25, when the reference input parameter is the image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first association degrees are the images r1, r2,..., Which were previously inspected based on the inspection method based on the uranyl acetate fluorescence method, and the degradation status as a result of the determination in the database 3 (first association). It may be stored in advance in the database 31) and set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the image obtained when the inspection by the uranyl acetate fluorescence method is performed. For example, for the image r1, “salt damage” with a first association degree of 80% is closest to the most accurate determination, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60% follows. Therefore, “neutralization” with a first relevance of 40% is an accurate decision that follows this, and “combining neutralization with an alkali-aggregate reaction” with a first relevance of 30%. “Deterioration” is an accurate judgment that follows. Similarly, for the image r2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is an accurate determination following this. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and the relationship between salt damage and neutralization with a first degree of association of 20%. “Composite degradation” is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. In determining the deterioration state of the reinforced concrete member 7, the first association degree shown in FIG. For example, when the image r1 of the input parameter analyzed in step S12 is the image r1 as the reference input parameter or approximates it, the first association is referred to when the first association degree is referred to. The highest degree of “salt damage” is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 26 shows the first of three or more stages of the combination of the images r1, r2,... As the inspection data of the past inspection by the uranyl acetate fluorescence method and the member information and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which the association degree is set is shown. Incidentally, in the example of FIG. 26, the member information includes the case where the management information is included, but the installation information, the cross-sectional information, and the photographic information may be included.

  In such a case, as shown in FIG. 26, the first association degree is a set of combinations of images r1, r2,... As inspection data and member information of the reinforced concrete member 7, so-called hidden layer nodes 61a. It will be expressed as 61e. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the inspection frequency “one time / 5 years” as the management information is associated with the first association degree of 80%. The node 61c has an image r2 having a first relevance of 60%, a service period of “10 years” as management information having a first relevance of 60%, and an inspection frequency of “once / year” as management information. It is linked with 40% of one degree of association.

  Similarly, when the first association degree is set, when the process proceeds to step S13, the image as the inspection data of the inspection as the input parameter extracted in step S12 and the first association of the management information. Search the output solution according to the degree. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 26 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the service period “5 years” as management information, the node 61b is associated via the first association degree, , "Neutralization" is the first linkage 60%, "Salt damage and neutralization combined" is the first linkage 40%, "Neutralization and alkali aggregate reaction combined degradation" The first association is 20%.

Inspection by Polarizing Microscope FIG. 27 shows an example of the first association degree acquired in advance in the database 3 (first association database 31). In the example of FIG. 27, an inspection method using a polarizing microscope is used as an inspection method in the inspection unit 8. This inspection method using a polarizing microscope is a method of judging deterioration of the reinforced concrete member 7 by imaging a sample cut out from the reinforced concrete member 7 with a polarizing microscope. The inspection data detected by the inspection unit 8 based on the inspection method using the polarizing microscope includes an image captured by the polarizing microscope, data of a component analysis result analyzed by the polarizing microscope, and the like. In the example shown in FIG. 27, the image data is learned in advance for the reference input parameters. Of course, the component analysis result data may be learned in advance for the reference input parameters.

  In the database 3 (first association database 31), images r1, r2,... Imaged based on an inspection method using a polarization microscope as a reference input parameter, and determination of the deterioration status of the reinforced concrete member 7 as an output solution First relations of three or more levels between the results are stored in advance. According to the example of FIG. 27, when the input parameter for reference is the image r1, “salt damage” is the first association degree 80%, “neutralization” is the first association degree 40%, “salt damage and alkali aggregate” “Combined deterioration with reaction” is set at a first association degree of 60%, and “Compound deterioration with neutralization and alkali aggregate reaction” is set at a first association degree of 30%. Further, when the input parameter for reference is the image r2, “neutralization” is the first association degree 90%, “alkaline aggregate reaction” is the first association degree 70%, “combined deterioration of salt damage and neutralization” "Is set at a first degree of association of 20%, and" combined deterioration between salt damage and alkali aggregate reaction "is set at a first degree of association of 50%.

  These first association degrees are the images 3, 1,..., And the deterioration status as a result of the discrimination when the inspection is performed based on the inspection method using the polarizing microscope. ) In advance, and may be set based on them. This first association degree may be configured by a so-called neural network. The first degree of association indicates accuracy in determining the actual deterioration state of the reinforced concrete member 7 based on the image obtained when the inspection is performed with the polarization microscope. For example, for the image r1, “salt damage” with a first association degree of 80% is closest to the most accurate determination, and “complex deterioration between salt damage and alkali-aggregate reaction” with a first association degree of 60% follows. Therefore, “neutralization” with a first relevance of 40% is an accurate decision that follows this, and “combining neutralization with an alkali-aggregate reaction” with a first relevance of 30%. “Deterioration” is an accurate judgment that follows. Similarly, for the image r2, “neutralization” with a first association degree of 90% is close to the most accurate determination, and “alkaline aggregate reaction” with a first association degree of 70% is an accurate determination following this. Therefore, “combined deterioration between salt damage and alkali-aggregate reaction” with a first degree of association of 50% is an accurate judgment that follows this, and the relationship between salt damage and neutralization with a first degree of association of 20%. “Composite degradation” is an accurate decision that follows.

  After shifting to step S13, the determination program performs an operation of determining the deterioration status of the reinforced concrete member 7 based on the input parameters analyzed in step S12. Reference is made to the first association shown in FIG. 27 acquired in advance to determine the deterioration status of the reinforced concrete member 7. For example, when the image r1 of the input parameter analyzed in step S12 is the image r1 as the reference input parameter or approximates it, the first association is referred to when the first association degree is referred to. The highest degree of “salt damage” is selected as the optimal solution. However, it is not essential to select the one with the highest degree of association as the optimal solution. Although the degree of association is low, the association itself is recognized as “combined deterioration between salt damage and alkali-aggregate reaction”, “medium ”And“ combined deterioration of neutralization and alkali-aggregate reaction ”may be selected as optimum solutions. The selection of the deterioration status of the reinforced concrete member 7 may be selected in order from the lowest first association degree according to the case, or may be selected in any other priority order.

  In addition, when the input parameter analyzed in step S12 is partially similar to the image r2 as the reference input parameter, but partially similar to the image r3, and it is not known to which one can be assigned, For example, the determination may be made based on the feature amount on the image through deep learning.

  Thus, after assigning the input parameter analyzed in step S12 to the reference input parameter, the deterioration state of the reinforced concrete member 7 as the output solution is selected based on the first association degree set in the reference input parameter. Will do.

  FIG. 28 shows three or more stages of combinations of the images r1, r2,... As the inspection data of the past inspection by the inspection method using the polarization microscope and the member information and the deterioration state of the reinforced concrete member 7 with respect to the combination. An example in which one degree of association is set is shown. Incidentally, in the example of FIG. 28, the member information includes the case where the installation information and the management information are included, but the cross-section information and the photo information may be included.

  In such a case, as shown in FIG. 28, the first association degree is a set of combinations of images r1, r2,... As inspection data and member information expressed as so-called hidden layer nodes 61a to 61e. The Rukoto. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the image r1 is associated with the first association degree of 80%, and the repair history “with repair” as management information is associated with the first association degree of 80%. In addition, the node 61c has an image r2 having a first association degree of 60%, location information “splash band” as installation information having a first association degree of 60%, and a repair history “no repair” as management information having a first association degree. 40% are linked.

  Similarly, when the first association degree is set, when the process proceeds to step S13, the image as the inspection data of the inspection as the input parameter extracted in step S12, the installation information and the management information An output solution corresponding to the first association degree is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 28 acquired in advance is referred to. For example, when the input parameter analyzed in step S12 is the image r1 and the location information “tidal zone” as the installation information, the node 61b is associated via the first association degree. , "Neutralization" is the first linkage 60%, "Salt damage and neutralization combined" is the first linkage 40%, "Neutralization and alkali aggregate reaction combined degradation" The first association is 20%.

  In the above-described embodiments, various examples of the inspection method have been described. However, the present invention is not limited to this, and may be replaced by any other inspection method. .

  In any of the inspection methods, the user can grasp the deterioration status of the reinforced concrete member 7 based on the output discrimination result.

  In particular, according to the present invention, it is possible to easily grasp the deterioration state of the reinforced concrete member 7 without requiring special skill. Moreover, according to this invention, it becomes possible to grasp | ascertain the deterioration condition of the reinforced concrete member 7 with high precision. Further, by configuring the first association degree described above with artificial intelligence, it is possible to further improve the discrimination accuracy by learning this.

  Further, the present invention is characterized in that an optimum result of determining the deterioration state of the reinforced concrete member 7 is searched through the first relevance set in three or more stages. The first degree of association can be described by a numerical value of 0 to 100%, for example, but is not limited to this, and may be configured at any stage as long as it can be described by a numerical value of three or more levels. Good.

  By searching on the basis of the first relevance expressed by numerical values of three or more stages as described above, in a situation where the determination result of the deterioration state of the plurality of reinforced concrete members 7 is selected, the first relevance is in descending order. It is also possible to search and display. Thus, if it can be displayed to the user in the order of the first degree of association, it can be urged to preferentially select the determination result of the deterioration status of the reinforced concrete member 7 with higher possibility. On the other hand, even the determination result of the deterioration state of the reinforced concrete member 7 having the low first association degree can be displayed in the meaning of the second opinion, and can exhibit usefulness when the first opinion cannot be analyzed well.

  In addition to this, according to the present invention, it is possible to make a determination without overlooking the determination result of the deterioration state of the reinforced concrete member 7 whose first relevance is as low as 1%. Even if the result of determining the deterioration status of the reinforced concrete member 7 with the first degree of association is extremely low, it is connected as a slight sign, and the determination of the deterioration status of the reinforced concrete member 7 is performed once every tens or hundreds of times. It can alert the user that it may be useful as a result.

  Furthermore, according to the present invention, there is an advantage that a search policy can be determined in a manner of setting a threshold by performing a search based on the first relevance of three or more stages. If the threshold value is lowered, it is possible to pick up without omission even if the first relevance is 1%, but it is unlikely that the determination result of the deterioration status of the reinforced concrete member 7 can be suitably detected, and noise is reduced. There may be a lot of picking up. On the other hand, if the threshold value is increased, there is a high possibility that the optimum determination result of the deterioration state of the reinforced concrete member 7 can be detected with a high probability. Sometimes a good solution that comes out once is overlooked. It is possible to decide which to place importance on the basis of the idea on the user side and the system side, but it is possible to increase the degree of freedom in selecting points to place such emphasis.

  Furthermore, in the present invention, the first association degree described above may be updated. This update may reflect information provided via a public communication network such as the Internet. When new knowledge about the relationship between input parameters (inspection data) and output solutions (determination results of deterioration status of reinforced concrete members 7) is discovered through site information and writing that can be obtained from the public communication network Depending on the knowledge, the first association degree is increased or decreased.

  The update of the first degree of association is performed by the system side or the user side based on the contents of research data, papers, conference presentations, newspaper articles, books, etc. by experts other than based on information obtainable from the public communication network. It may be updated artificially or automatically. Artificial intelligence may be used in these update processes.

  In the present invention, the deterioration status of the reinforced concrete member 7 may be determined by combining two or more inspection methods.

  FIG. 29 shows an example in which the deterioration state of the reinforced concrete member 7 is determined by combining two different inspection methods, ie, an inspection method relating to the amount of chloride ions and an inspection method using EPMA.

  That is, a combination of the data of chloride ions as inspection data of the past inspection by the inspection method relating to the amount of chloride ions and images r1, r2,... 3 shows an example in which three or more levels of first association with the deterioration status of the reinforced concrete member 7 for the combination are set.

In this case, as shown in FIG. 29, the first association degree is a set of combinations of chloride ion amount data as inspection data and images r1, r2,... As inspection data by an inspection method using EPMA. It is expressed as so-called hidden layer nodes 61a to 61e. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61a, the chloride ion amount “2.0 kg / m ³ ” is associated with the first association degree 80%, and the image r3 is associated with the first association degree 80%. The node 61d is associated with a chloride ion amount “0.1 kg / m ³ ” having a first association degree of 30% and an image r4 having a first association degree of 90%.

Similarly, when the first association degree is set, when the process proceeds to step S13, the data of the chloride ion amount as the inspection data of the inspection as the input parameter extracted in step S12 and the image r1. , R2,... Are input. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 29 acquired in advance is referred to. For example, in the input parameter analyzed in step S12, when the chloride ion amount is “2.0 kg / m ³ ” and the image r1, the node 61b is associated through the first association degree, and this node 61b, “neutralization” is 60% of the first association, “combined degradation of salt damage and neutralization” is the first association of 40%, “combined degradation of neutralization and alkali-aggregate reaction” The first association is 20%. These can be output as output solutions.

  The type of the reference input parameter is not limited to the combination of the inspection method related to the chloride ion amount and the inspection method using EPMA. Inspection for cracks, inspection by natural potential method, inspection by polarization resistance method, inspection by vibration measurement, inspection for neutralization depth, inspection by X-ray diffraction method, inspection by scanning electron microscope, inspection by X-ray fluorescence elemental analysis The first association degree may be configured by a combination of inspection data of any two or more of inspection methods such as an inspection by the uranyl acetate fluorescence method and an inspection by a polarizing microscope. In other words, the first degree of association shown in FIG. 29 is based on an inspection relating to cracking, an inspection using the natural potential method, an inspection using the polarization resistance method, and vibration measurement as an alternative to the combination of the inspection method relating to the chloride ion amount and the inspection method using EPMA. Inspection, neutralization depth inspection, X-ray diffraction inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, uranyl acetate fluorescence inspection, polarization microscope inspection, etc. It is set by a combination of the above inspection data.

  By searching for an optimal solution based on a combination of two or more types of inspection methods, it is possible to improve the search accuracy.

  FIG. 30 shows images r1, r2,... And members when the inspection is performed based on the chloride ion amount data as the inspection data of the past inspection by the inspection method relating to the chloride ion amount and the inspection method by the EPMA. The example in which the 1st relevance of three or more steps of the combination with information and the deterioration condition of the reinforced concrete member 7 with respect to the said combination is set is shown. Incidentally, in the example of FIG. 30, the member information includes the case where the installation information is included, but the cross-section information, management information, and photographic information may be included.

In such a case, as shown in FIG. 30, the first association degree is a set of combinations of chloride ion amount data as inspection data, images r1, r2,... Nodes 61a to 61e. In each of the nodes 61a to 61e, a weight for the reference input parameter and a weight for the output solution are set. This weighting is the first degree of association of three or more levels. For example, in the node 61b, the chloride ion amount “2.0 kg / m ³ ” is the first association degree 40%, the image r1 is the first association degree 50%, and the location information “tidal zone” as the installation information is the first. The association is 40%. The node 61c has a chloride ion amount “1.0 kg / m ³ ” having a first association degree of 60%, an image r2 having a first association degree of 60%, and location information “spray zone” as installation information having a first association degree. It is linked at 40%.

Similarly, when the first relevance is set, when the process proceeds to step S13, the data of the chloride ion amount as the inspection data of the inspection as the input parameter extracted in step S12, and the image And the output solution according to the 1st relevance degree of installation information is searched. The discrimination program performs an operation of selecting one or more optimum solutions from the output solutions based on the input parameters analyzed in step S12. In selecting this optimal solution, the first association shown in FIG. 30 acquired in advance is referred to. For example, if the input parameter analyzed in step S12 is the chloride ion amount “2.0 kg / m ³ ”, the image r1, and the location information “tidal zone” as installation information, the first association degree The node 61b is associated with the node 61b, the "neutralization" is the first association degree 60%, "the combined deterioration of salt damage and neutralization" is the first association degree 40%, “Compound deterioration of neutralization and alkali-aggregate reaction” is associated with a first degree of association of 20%.

  By searching for an optimal solution based on a combination of two or more types of inspection methods and member information, the search accuracy can be further improved.

  In the present invention, the remaining useful life of the reinforced concrete member 7 may be determined with respect to the determined deterioration state of the reinforced concrete member 7.

  FIG. 31 shows a processing operation flow of the determination program when determining the remaining useful life of the reinforced concrete member 7. After performing step S11 to step S14 described above, the determination program inputs the deterioration status of the reinforced concrete member 7 determined in step S13 or displayed in step S14 in step S21.

  Next, the process proceeds to step S22, and the deterioration status of the reinforced concrete member 7 input in step S21 and the remaining useful life of the reinforced concrete member 7 having a high second relation are searched. Before performing this search, the database 3 (second association database 32) obtains in advance a second association degree between the deterioration state of the reinforced concrete member 7 as a reference input parameter and the remaining useful life of the reinforced concrete member 7. deep.

  FIG. 32 shows an example of the second association degree acquired in advance in the database 3 (second association database 32).

  The database 3 (second relational database 32) includes three or more stages between the deterioration status of the reinforced concrete member 7 as a reference input parameter and the determination result of the remaining useful life of the reinforced concrete member 7 as an output solution. Two degrees of association are stored in advance. According to the example of FIG. 32, when the reference input parameter is “salt damage”, the remaining lifetime “40 years” is the second association degree 80%, and the remaining lifetime “30 years” is the second association degree 40%. Is set in When the reference input parameter is “combined deterioration of salt damage and neutralization”, the remaining service life “10 years” has a second relevance of 70%, and the remaining service life “5 years” has a second relevance of 60. It is set in%.

  These second relevance levels are stored in advance in the database 3 (second relevance database 32), in which the deterioration status of the reinforced concrete member 7 in the past and the remaining useful life of the reinforced concrete member 7 as a result of the determination are stored in advance. You may make it set based on. This second association degree may be configured by a so-called neural network. This second degree of association indicates accuracy in determining the actual remaining useful life of the reinforced concrete member 7 based on the deterioration state of the reinforced concrete member 7 determined in step S13. For example, for the deterioration condition “salt damage” of the reinforced concrete member 7, the remaining service life “40 years” with the second connection degree 80% is the most accurate judgment, and the remaining service life “40 years” with the second connection degree 40%. "Is an accurate judgment that follows this. Similarly, for the deterioration status of the reinforced concrete member 7 “combined deterioration of neutralization and alkali-aggregate reaction”, the remaining useful life “3 years” with a second linkage of 40% is close to the most accurate judgment. The remaining useful life of “20 years” with a relevance of 30% is an accurate decision following this.

  After shifting to step S22, the determination program performs an operation of determining the remaining useful life of the reinforced concrete member 7 based on the input parameters input in step S21. In determining the remaining useful life of the reinforced concrete member 7, the second association degree shown in FIG. 32 acquired in advance is referred to. For example, when the deterioration state of the reinforced concrete member 7 of the input parameter input in step S21 is the deterioration state “salt damage” of the reinforced concrete member 7 as the input parameter for reference, when referring to the above-described second association degree, The remaining useful life “40 years” having the highest second association is selected as the optimal solution. However, it is not essential to select the optimal solution with the highest degree of second association, and select the remaining lifetime “30 years” that is recognized as the optimal solution, although the second association degree is low. May be. Of course, an output solution that is not connected with an arrow may be selected. That is, the selection of the remaining useful life of the reinforced concrete member 7 is not limited to the case in which the second association degree is selected in descending order, but is selected in order from the one having the second association degree in accordance with the case. May be selected, or may be selected in any other priority order.

  In this way, after assigning the input parameter input in step S21 to the reference input parameter, the remaining lifetime of the reinforced concrete member 7 as the output solution is set based on the second association degree set in the reference input parameter. Will choose.

  Note that the method of selecting an output solution for the input parameter input in step S21 is not limited to the method described above, and may be executed based on any method as long as it refers to the second association degree. Good. Further, the search operation in step S22 may be performed using artificial intelligence.

  Next, the process proceeds to step S23, and the remaining useful life of the reinforced concrete member 7 as the selected optimum solution is displayed via the display unit 23. Thereby, the user can grasp | ascertain immediately the discrimination | determination result of the residual lifetime of the reinforced concrete member 7 by visually recognizing the display part 23. FIG.

  In the above-described embodiment, the deterioration situation of the reinforced concrete member 7 has been described taking salt damage, neutralization, alkali aggregate reaction, combined deterioration of these, and the like as examples, but is not limited thereto. Of course, it may be replaced with the deterioration situation of any other reinforced concrete member 7.

  In any deterioration state of the reinforced concrete member 7 determined in step S13, the user can grasp the remaining useful life of the reinforced concrete member 7 based on the output determination result.

  According to the present invention, it is possible to easily grasp the deterioration status of the reinforced concrete member 7 and grasp the remaining useful life of the reinforced concrete member 7 without requiring special skills.

  In particular, according to the present invention, the remaining useful life of the reinforced concrete member 7 can be grasped based on the deterioration state of the reinforced concrete member 7 determined in step S13. Moreover, according to this invention, it becomes possible to grasp | ascertain the remaining useful life of the reinforced concrete member 7 with higher precision. Further, by configuring the second association degree described above with artificial intelligence, it is possible to further improve the discrimination accuracy by learning this.

  In addition, the present invention is characterized in that an optimum result of the remaining life of the reinforced concrete member 7 is searched through the second relevance set in three or more stages. The second association degree can be described by a numerical value of 0 to 100%, for example, but is not limited to this, and may be configured at any stage as long as it can be described by a numerical value of three or more levels. Good.

  By searching based on the second relevance expressed by the numerical values of three or more stages, the second relevance is high in a situation where the determination result of the remaining lifetime of the reinforced concrete members 7 is selected. It is also possible to search and display in order. Thus, if it can display to a user in order with the 2nd highest degree of association, it can also be urged to preferentially select the determination result of the remaining useful life of the reinforced concrete member 7 with higher possibility. On the other hand, even if it is the discrimination result of the remaining useful life of the reinforced concrete member 7 with a low second association degree, it can be displayed in the meaning of the second opinion, and can be used when the first opinion cannot be analyzed well. .

  In addition to this, according to the present invention, it is possible to make a determination without missing the determination result of the remaining useful life of the reinforced concrete member 7 having a very low second association degree of 1%. Even if it is the result of determining the remaining useful life of the reinforced concrete member 7 with a very low second relation, it is connected as a slight sign, and once every tens or hundreds of times, the remaining useful life of the reinforced concrete member 7 It is possible to alert the user that it may be useful as a determination result.

  Furthermore, according to the present invention, there is an advantage that a search policy can be determined in a manner of setting a threshold by performing a search based on the second relevance of three or more stages. If the threshold value is lowered, it is possible to pick up without omission even if the above-mentioned second association degree is 1%, but it is unlikely that the discrimination result of the remaining useful life of the reinforced concrete member 7 can be suitably detected, and noise. There are times when you will pick up a lot. On the other hand, if the threshold value is increased, there is a high possibility that the optimum result of determining the remaining useful life of the reinforced concrete member 7 can be detected with a high probability. Sometimes a good solution that comes out once in a hundred times is overlooked. It is possible to decide which to place importance on the basis of the idea on the user side and the system side, but it is possible to increase the degree of freedom in selecting points to place such emphasis.

  Furthermore, in the present invention, the second association degree described above may be updated. This update may reflect information provided via a public communication network such as the Internet. A new relationship between input parameters (determination result of deterioration status of reinforced concrete member 7) and output solution (determination result of remaining lifetime of reinforced concrete member 7) through site information and writing that can be obtained from the public communication network. When knowledge is discovered, the second association degree is increased or decreased according to the knowledge.

  In addition to the case of updating the second association degree based on information that can be obtained from the public communication network, the system side or the user side can update based on the contents of research data, papers, conference presentations, newspaper articles, books, etc. by experts. It may be updated artificially or automatically. Artificial intelligence may be used in these update processes.

  Moreover, according to this invention, based on each discrimination | determination condition memorize | stored in the 1st linkage database 31 and the 2nd linkage database 32 which are respectively different, the remaining lifetime of the reinforced concrete member 7 can be discriminate | determined. Accordingly, when only one of the first association database 31 and the second association database 32 is newly updated, it is not necessary to update either the first association database 31 or the second association database 32. For this reason, it becomes possible to suppress the load which updates the 1st linkage database 31 or the 2nd linkage database 32 with the update of any one of the 1st linkage database 31 or the 2nd linkage database 32. FIG.

  In the present invention, the display of the deterioration state in step S14 may be performed when the remaining useful life is displayed in step S23.

  In the present invention, a measure against the deterioration state of the determined reinforced concrete member 7 may be determined.

  FIG. 33 shows a processing operation flow of the discrimination program when discriminating measures against the deterioration state of the reinforced concrete member 7. After performing step S11 to step S14 described above, the determination program inputs the deterioration status of the reinforced concrete member 7 determined in step S13 or displayed in step S14 in step S31.

  Next, the process proceeds to step S32, and a countermeasure for the deterioration state of the reinforced concrete member 7 input in step S31 and the deterioration state of the reinforced concrete member 7 having a high third relation is searched. Before performing this search, the database 3 (third linkage database 33) obtains in advance a third degree of association between the deterioration status of the reinforced concrete member 7 as a reference input parameter and a countermeasure against the deterioration status of the reinforced concrete member 7. Keep it.

  FIG. 34 shows an example of the third association degree acquired in advance in the database 3 (third association database 33). In the example of FIG. 34, as countermeasures, countermeasure methods such as a cross-sectional repair method, a desalting method, an anticorrosion method, a surface coating method, a surface impregnation method, a thickening method, a realkalization method, a lithium impregnation method, a waterproof method, etc. are illustrated. doing.

  The database 3 (third linkage database 33) includes three or more stages between the deterioration status of the reinforced concrete member 7 as the input parameter for reference and the determination result of the countermeasure against the deterioration status of the reinforced concrete member 7 as the output solution. The third association degree is stored in advance. According to the example of FIG. 34, when the input parameter for reference is “salt damage”, the “cross-section repair method” as the countermeasure is the third association degree 80%, and the “corrosion protection method” as the countermeasure is the third association degree. It is set at 40%. When the reference input parameter is “combined deterioration due to salt damage and neutralization”, “Cross section repair method” as a countermeasure is 50% of the third relation, and “Surface impregnation method” as the countermeasure is the third relation. The degree is set at 30%.

  These third association degrees are stored in the database 3 (third association database 33) in advance in the database 3 (the third association database 33) as measures against the deterioration state of the reinforced concrete member 7 in the past and the deterioration state of the reinforced concrete member 7 as a result of the determination. You may make it set based on. This third association degree may be configured by a so-called neural network. The third degree of association indicates the accuracy in determining the countermeasure against the actual deterioration state of the reinforced concrete member 7 based on the deterioration state of the reinforced concrete member 7 determined in step S13. For example, with regard to the deterioration status of the reinforced concrete member 7 “salt damage”, the “cross-section repair method” with a third degree of association of 80% is the most accurate judgment, and the “corrosion protection method” with a third degree of association of 40% It will be an accurate judgment that follows. Similarly, for the deterioration status of reinforced concrete member 7 “combined deterioration between neutralization and alkali-aggregate reaction”, “waterproofing method” with a third linkage degree of 40% is the most accurate judgment, and the third linkage degree The 30% “thickening method” is the next accurate decision.

  After shifting to step S32, the determination program performs an operation of determining a countermeasure against the deterioration state of the reinforced concrete member 7 based on the input parameters input in step S31. Reference is made to the third degree of association shown in FIG. 34 acquired in advance to determine the countermeasure against the deterioration state of the reinforced concrete member 7. For example, when the deterioration state of the reinforced concrete member 7 of the input parameter input in step S31 is the deterioration state “salt damage” of the reinforced concrete member 7 as the input parameter for reference, when referring to the above-described third relation, The “section repair method” having the highest third degree of association is selected as the optimal solution. However, it is not essential to select the most relevant solution with the third degree of association as the optimum solution, and the “corrosion protection method” that allows the association itself although the third degree of association is low may be selected as the optimum solution. Good. Of course, an output solution that is not connected with an arrow may be selected. That is, the selection of measures against the deterioration state of the reinforced concrete member 7 is not limited to the case where the third association degree is selected in order from the highest third association degree. Or may be selected in any other priority order.

  Thus, after assigning the input parameter input in step S31 to the input parameter for reference, measures against the deterioration state of the reinforced concrete member 7 as the output solution based on the third relation set in the input parameter for reference Will be selected.

  Note that the method of selecting an output solution for the input parameter input in step S31 is not limited to the method described above, and any method may be used as long as it refers to the third association degree. Good. Further, the search operation in step S32 may be performed using artificial intelligence.

  Next, the process proceeds to step S33, and a countermeasure against the deterioration state of the reinforced concrete member 7 as the selected optimum solution is displayed via the display unit 23. Accordingly, the user can immediately grasp the determination result of the countermeasure against the deterioration state of the reinforced concrete member 7 by visually recognizing the display unit 23.

  Further, in the above-described embodiment, as measures against the deterioration state of the reinforced concrete member 7, the cross-sectional repair method, the desalting method, the cathodic protection method, the surface coating method, the surface impregnation method, the thickening method, the realkalization method, the lithium impregnation method The construction method, the waterproof construction method, and the like have been described as examples. However, the present invention is not limited to this, and it is needless to say that it may be replaced with a countermeasure against the deterioration state of any other reinforced concrete member 7.

  In any deterioration state of the reinforced concrete member 7 determined in step S13, the user can grasp a countermeasure against the deterioration state of the reinforced concrete member 7 based on the output determination result.

  According to the present invention, it is possible to easily grasp the deterioration state of the reinforced concrete member 7 and grasp the countermeasure against the deterioration state without requiring special skills.

  In particular, according to the present invention, it is possible to grasp the countermeasure against the deterioration state of the reinforced concrete member 7 based on the deterioration state of the reinforced concrete member 7 determined in step S13. Moreover, according to this invention, it becomes possible to grasp | ascertain the countermeasure with respect to the deterioration condition of the reinforced concrete member 7 with high precision. Furthermore, by configuring the third degree of association described above with artificial intelligence, it is possible to further improve the discrimination accuracy by learning this.

  In addition, the present invention is characterized in that a search is made for a determination result of countermeasures for the optimum deterioration state of the reinforced concrete member 7 through the third degree of association set in three or more stages. The third degree of association can be described by a numerical value of 0 to 100%, for example, but is not limited to this, and can be configured at any stage as long as it can be described by three or more numerical values. Good.

  By searching based on the third relevance expressed by the numerical values of three or more stages, the third relevance of the third relevance can be obtained in a situation where the determination result of the countermeasure for the deterioration situation of the plurality of reinforced concrete members 7 is selected. It is also possible to search and display in descending order. Thus, if it can be displayed to the user in the order of the third degree of association, it can be urged to preferentially select the determination result of the countermeasure against the more likely deterioration state of the reinforced concrete member 7. On the other hand, even if it is the discrimination result of the countermeasure against the deterioration state of the reinforced concrete member 7 with the low third relation degree, it can be displayed in the meaning of the second opinion, and it can be useful when the first opinion cannot be analyzed well. it can.

  In addition, according to the present invention, it is possible to make a determination without overlooking the determination result of the countermeasure against the deterioration state of the reinforced concrete member 7 having an extremely low third relevance of 1%. Even if it is the discrimination result of the countermeasures against the deterioration state of the reinforced concrete member 7 with the extremely low third relation, it is connected as a slight sign, and once every tens or hundreds of times, the deterioration state of the reinforced concrete member 7 It is possible to alert the user that it may be useful as a determination result of measures against the problem.

  Furthermore, according to the present invention, there is an advantage that a search policy can be determined in a manner of setting a threshold by performing a search based on the third relevance of three or more stages. If the threshold value is lowered, it is possible to pick up without omission even if the third degree of association described above is 1%, but it is unlikely that the determination result of the countermeasure for the deterioration state of the reinforced concrete member 7 can be suitably detected. Sometimes it picks up a lot of noise. On the other hand, if the threshold value is increased, there is a high possibility that the determination result of the countermeasure for the optimum deterioration state of the reinforced concrete member 7 can be detected with high probability, but usually the third relevance is low and it is slewed several times, Sometimes you miss a good solution that comes out once every few hundred times. It is possible to decide which to place importance on the basis of the idea on the user side and the system side, but it is possible to increase the degree of freedom in selecting points to place such emphasis.

  Furthermore, in the present invention, the third association degree described above may be updated. This update may reflect information provided via a public communication network such as the Internet. New relationship between input parameters (determination result of deterioration status of reinforced concrete member 7) and output solution (determination result of measures against deterioration status of reinforced concrete member 7) through site information and writing that can be obtained from public communication network If a new finding is found, the third association degree is raised or lowered according to the finding.

  The update of the third association degree is performed by the system side or the user side based on the contents of research data, papers, conference presentations, newspaper articles, books, etc. by experts, in addition to the case based on information obtainable from the public communication network. It may be updated artificially or automatically. Artificial intelligence may be used in these update processes.

  Moreover, according to this invention, the countermeasure with respect to the deterioration condition of the reinforced concrete member 7 can be discriminate | determined based on each discrimination | determination condition memorize | stored in the respectively different 1st linkage database 31 and the 3rd linkage database33. Accordingly, when only one of the first association database 31 and the third association database 33 is newly updated, it is not necessary to update either the first association database 31 or the third association database 33. For this reason, it becomes possible to suppress the load which updates the 1st linkage database 31 or the 3rd linkage database 33 with the update of any one of the 1st linkage database 31 or the 3rd linkage database 33.

  In the present invention, the display of the deterioration status in step S14 may be performed when the countermeasure is displayed in step S33.

DESCRIPTION OF SYMBOLS 1 Discriminating system 2 Discriminating device 21 Internal bus 23 Display part 24 Control part 25 Operation part 26 Communication part 27 Search part 28 Storage part 3 Database 31 1st linkage database 32 2nd linkage database 33 3rd linkage database 61 Node 7 Reinforced concrete member 71 Concrete 72 Reinforcing bar 8 Inspection unit 9 Evaluation device

Claims (10)

A first linkage database in which three or more levels of first linkage between past inspection data for a reinforced concrete member and a determination result of deterioration status of the reinforced concrete member for the inspection data are stored in advance;
Input means for inputting inspection data obtained by newly inspecting a reinforced concrete member for newly determining the deterioration state;
A determination unit that refers to the first association degree stored in the first association database and determines the deterioration status of the reinforced concrete member based on the inspection data input through the input unit;
The first relational database includes inspections related to cracks, natural potential method inspections, polarization resistance method inspections, vibration measurement inspections, chloride ion content inspections, neutralization depth inspections, X-ray diffraction inspections, EPMA (Electron Probe Micro Analyzer) inspection, scanning electron microscope inspection, fluorescent X-ray elemental analysis inspection, uranyl acetate fluorescence inspection, and polarization microscope inspection inspection of two or more past inspection data The first association degree of three or more stages of the combination and the determination result of the deterioration state of the reinforced concrete member for the combination is stored in advance,
The input means inputs the inspection data obtained by performing any two or more of the above inspections constituting the above combination for the reinforced concrete member for newly determining the deterioration state. Discriminating system. The first linkage database stores in advance three or more levels of first linkage between a combination of member information relating to the reinforced concrete member and past inspection data by the inspection, and a determination result of the deterioration state of the reinforced concrete member with respect to the combination. And
The system according to claim 1, wherein the input means further receives member information relating to a reinforced concrete member constituting the combination. The reinforced concrete member discriminating system according to claim 1 or 2, wherein the reinforced concrete member is used for a bridge. The reinforced concrete member is used for any one of a box girder bridge, a girder bridge, a floor slab bridge, a suspension structure bridge, a composite structure bridge, and a bridge in which these are combined. A discrimination system for reinforced concrete members as set forth in claim 1. The reinforced concrete member discriminating system according to any one of claims 1 to 4, wherein the reinforced concrete member is used for a PC bridge. A first association degree acquisition step of obtaining in advance three or more first association degrees of past inspection data for a reinforced concrete member and a determination result of a deterioration state of the reinforced concrete member for the inspection data;
A first input step for inputting inspection data obtained by inspecting a reinforced concrete member for newly determining a deterioration state;
Referring to the first association degree acquired in the first association degree acquisition step, the computer executes a first determination step for determining the deterioration status of the reinforced concrete member based on the inspection data input in the first input step. ,
In the first relevance acquisition step, an inspection related to cracking, an inspection based on a natural potential method, an inspection based on a polarization resistance method, an inspection based on vibration measurement, an inspection regarding chloride ion content, an inspection regarding neutralization depth, and an X-ray diffraction method Past inspection of any two or more of inspection, inspection by EPMA (Electron Probe Micro Analyzer), inspection by scanning electron microscope, inspection by fluorescent X-ray elemental analysis, inspection by uranyl acetate fluorescence method, and inspection by polarization microscope inspection Acquire in advance three or more levels of first association between the combination of data and the determination result of the deterioration status of the reinforced concrete member for the combination,
In the first input step, inspection data obtained by performing any two or more of the above-described inspections constituting the above combination on a reinforced concrete member that newly determines a deterioration state is input. Member identification program. In the first association degree acquisition step, the first association degree of three or more levels of the combination of the member information on the reinforced concrete member and the past inspection data by the inspection and the determination result of the deterioration state of the reinforced concrete member with respect to the combination is obtained in advance. Acquired,
7. The computer program for determining a reinforced concrete member according to claim 6, wherein in the first input step, member information relating to a reinforced concrete member constituting the combination is further input. The reinforced concrete member discrimination program according to claim 6 or 7, wherein the reinforced concrete member is used for a bridge. The reinforced concrete member is used for any one of a box girder bridge, a girder bridge, a floor slab bridge, a suspension structure bridge, a composite structure bridge, and a bridge in which these are combined. The discrimination program of the reinforced concrete member of Claim 1. The reinforced concrete member identification program according to any one of claims 6 to 9, wherein the reinforced concrete member is used for a PC bridge.

Images