JP4620101B2 - Fatigue crack detection device and fatigue crack detection system - Google Patents

Description

  The present invention relates to a fatigue crack detection device and a fatigue crack detection system that improve the accuracy of visual inspection performed on structures such as bridges.

  Structures such as bridges are subject to repeated vibration over a long period of time and may crack due to metal fatigue, so early detection and countermeasures are necessary from the viewpoint of safety management. However, since a fine crack is overlooked by visual inspection, Patent Document 1 below proposes a fatigue crack detection system for early detection of the occurrence and location of a crack.

FIG. 7 is an overall view of a bridge to which a conventional fatigue crack detection system is applied. The fatigue crack detection system 100 is a system for detecting cracks in the bridge 101 that is an object to be detected, and is a fracture detection line (hereinafter simply referred to as two crack sensors) arranged along the surface of the bridge 200. It includes a) 110 of "sense line", and a crack localization device 120. Two detection lines 110 arranged in parallel are wired in a one-stroke form through the assumed crack portion of the bridge 200 and bonded to the surface of the bridge 200.

For example, when a crack is generated by the railway vehicle 300 passing through the bridge 200 many times, the detection line 110 bonded to the crack portion is also disconnected. Therefore, in the fatigue crack inspection, micro pulses are intermittently transmitted from the crack location identification device 120 connected to the detection line 110 . Since the micro pulse is reflected at the position where the detection line 110 is disconnected, the micro pulse transmitted through the detection line 110 is received again, and the round trip time to the object to be measured is measured. The crack occurrence location is specified by measuring.
JP 2005-156552 A

  By the way, in the inspection of structures such as bridges, the above-mentioned fatigue cracks are particularly important, but it is necessary to check not only the inspection items but also the peeling of paint, cracks in floor boards and abutments. These inspection items are not visually inspected because a system as shown in Patent Document 1 is not constructed. Therefore, although the effect of installing the fatigue crack detection system is great, it has been impossible to eliminate the periodic visual inspection of structures such as bridges.

On the other hand, if the inspection operator confirms the fatigue crack by visual inspection without using the fatigue crack detection system, it is likely that inspection errors are likely to occur due to human factors such as the skill level of the operator and the lack of manpower. It is done. In some cases, fatigue cracks may not be present at locations that can be easily visually inspected. If the discovery of fatigue cracks is delayed due to oversight, construction for restoration must be carried out immediately, and traffic closure is necessary, which greatly affects traffic.
Furthermore, with the aging of social capital, the importance of maintaining and managing structures such as bridges is increasing from the viewpoint of safety confirmation. Under such circumstances, the aging and decrease in the number of workers engaged in inspections are expected to increase due to the declining birthrate and aging population. In addition, improvement of inspection accuracy, efficiency of inspection work, and reduction of maintenance costs are required.

  Therefore, an object of the present invention is to provide a fatigue crack detection device and a fatigue crack detection system that improve the inspection quality of a fatigue crack inspection performed during visual inspection in order to solve such a problem.

The fatigue crack detection device according to the present invention includes a detection line fixed by an adhesive to an assumed crack location in an object to be inspected, a power supply for energizing the detection line, and preset identification information. stored in the storage unit, and a IC tag that controls the radio transmission of the identification information performed through the transceiver unit by the control unit, the IC tag, the control unit is obtained by energizing the cutoff state of the detection line The disconnection information is stored in a storage unit, and the disconnection information and the identification information are wirelessly transmitted, and the control unit confirms energization after a predetermined time after detecting the disconnection, and detects disconnection and electrical noise. Further, the disconnection information is stored in the storage unit by confirming energization a predetermined number of times after detecting energization interruption of the detection line .

Further , the fatigue crack detection apparatus according to the present invention is generated from the piezoelectric element disposed at a location where the power source receives an impact when the moving body passes through the inspection object, and the piezoelectric element that has received the impact. It is preferable to have a charger for charging the generated electric power.
Moreover, it is preferable that the fatigue crack detection apparatus according to the present invention includes a display unit that displays disconnection information by light emission by the control unit when the detection line is disconnected.

In the fatigue crack detection system according to the present invention, the fatigue crack detection device is installed for each assumed crack location for a plurality of assumed crack locations in the object to be inspected, and by inputting the identification information, It has a portable information collection device that enables wireless transmission with one of the plurality of the fatigue crack detection devices, and stores the disconnection information received from the fatigue crack detection device in a storage unit. And
The fatigue crack detection system according to the present invention includes an arithmetic processing unit that is connected to the portable information collection device, stores the disconnection information in a storage unit, and creates a management table based on the disconnection information. Preferably there is.

  According to the present invention, it is possible to store the disconnection information obtained by cutting off the energization of the detection line in the storage unit by the IC tag and wirelessly transmit the disconnection information together with the identification information by an information collecting device such as a PDA. It is possible to collect disconnection information regarding fatigue cracks without applying it, and it is possible to incorporate this information collection work into a part of conventional visual inspection work. As a result, the visual inspection of fatigue cracks can be eliminated and the inspection quality can be improved. In addition, the inspection work can be made efficient and the maintenance work costs can be reduced.

  Next, an embodiment of a fatigue crack detection apparatus and a fatigue crack detection system according to the present invention will be described below with reference to the drawings. FIG. 1 is a diagram conceptually showing the fatigue crack detection system of this embodiment. In particular, a state in which a plurality of fatigue crack detection devices 10 (10a to 10d) are installed on the bridge 1 is shown. In the fatigue crack detection system of the present embodiment, the detection line is not extended over a long distance on the side of the bridge as in the conventional example, but the fatigue crack detection independent of each of a plurality of assumed cracks of the bridge 1 is performed. The apparatus 10a-10d is configured to be installed. In a structure such as the bridge 1, a place where a crack is generated can be assumed, and thus the fatigue crack detection devices 10 a to 10 d are attached to the assumed crack place.

  Next, FIG. 2 is a diagram illustrating a specific installation state of the fatigue crack detection device 10. In the bridge 1, a plurality of main girders 2 arranged in the width direction are arranged in the longitudinal direction, and adjacent main girders 2 are connected by a horizontal girder 3. FIG. 2 shows a portion where the cross beam 3 is connected to the web (belt plate) 201 of the main beam 2 so as to be abutted from the orthogonal direction. The main beam 2 is formed by a web 201 and upper and lower flanges 202, and the horizontal beam 3 is similarly formed with flanges 302 on the upper and lower sides of the intermediate plate 301. And the edge part of the cross beam 3 is abutted by the web 201 of the main girder 2 as shown in figure, and the abutting part is weld-connected.

  In the bridge 1 having such a structure, it is this connecting portion that may be repeatedly subjected to a load when a vehicle passes over the bridge 1 to cause a crack. That is, the web 201 of the main girder 1 tends to concentrate stress at the tip of the lower flange 302 of the cross girder 3 and may crack. Therefore, the fatigue crack detection device 10 is attached so that a crack generated from the tip portion of the lower flange 302 can be confirmed. In addition, since there are a plurality of locations where the cross beam 3 is connected to the web 201 of the main girder 1 in the bridge 1, the fatigue crack detection device 10 as shown in FIG. 2 is installed at each location.

  The fatigue crack detection device 10 is arranged such that a fracture detection line (hereinafter simply referred to as “detection line”) 11 as a crack sensor is arranged along the lower flange 302 of the cross beam 3, with respect to the web 201 of the main beam 1. The adhesive 19 is pasted so as to be hardened. The detection device main body 12 fixed to the lower surface of the lower flange 302 is connected to the detection line 11. In addition to the power supply, the detection device main body 12 is provided with a configuration for detecting disconnection of the detection line 11 and transmitting information. In the present embodiment, disconnection information can be collected via the fatigue crack detection device 10 in visual inspection of each item with respect to the bridge 1. In addition, although the case where an electrical noise influences the fatigue crack detection apparatus 10 is considered, this influence is coped with by the device of an internal program.

Next, FIG. 3 is a block diagram showing a part of the fatigue crack detection system. The fatigue crack detection device 10 of the present embodiment uses a non-contact type IC tag as will be described later, and is configured so that disconnection information can be collected by transmission and reception with the IC tag.
In the fatigue crack detection device 10, the detection line 11 is fixed to an assumed crack location where a crack R is predicted to occur on the inspection target object W such as the bridge 1. As shown in the drawing, the detection line 11 is wired so that the forward path and the return path are parallel to each other. In the case of the bridge 1 shown in FIG. 2, such detection lines 11 are separated from the detection device main body 12 in two left and right directions, and are wired in a U-shape. Since the detection line 11 is attached to the inspection object W with an adhesive so as to be hardened, when the inspection object W has a crack R as shown in FIG. 3, it also reaches the bonded portion. Therefore, the detection line 11 is disconnected.

  The detection device main body 12 is provided with an IC tag 13 that stores state information of the detection line 11 and transmits / receives information to / from the information collection device 30. The IC tag 13 includes a control unit 21 composed of a CPU that controls storage and transmission / reception of information, a memory 22 that stores disconnection information, a self-holding circuit 23 that holds a power-off state due to disconnection of the detection line 11, and wireless transmission For example, a transmission / reception unit 24 composed of a transmission / reception circuit and an antenna is provided and formed by an integrated circuit chip. The fatigue crack detection device 10 is configured to detect a disconnection of the detection line 11 that occurs along with the generation of the crack R when a current is passed from the power supply 15 to the detection line 11 via the control unit 21 and the energization is interrupted. ing.

Since the crack R is very small at the initial stage of the fatigue crack, the crack R closes when the bridge 1 is not loaded with a vehicle, and the disconnected portion of the detection line 11 comes into contact with it, so that the energized state is restored. Therefore, when a load is applied, the crack portion spreads and the energization is cut off. However, since it returns to the energization state instantaneously, it is difficult to confirm the occurrence of a crack. Therefore, in this embodiment, the self-holding circuit 23 is provided to hold the energization cut-off state once the detection line 11 is disconnected. However, if the initial stage fatigue crack can be detected without the self-holding circuit 23, the self-holding circuit 23 is not an essential component. For example, there is a case where it is only necessary to detect whether or not a permanent crack has occurred.

  Further, the detection line 11 may be disconnected due to a collision such as dust or other problems. For this reason, when the self-holding circuit 23 is provided, it cannot be determined whether the energization interruption state is due to fatigue cracks or disconnection due to defects. Therefore, in this embodiment, a disconnection detection program is provided to determine whether the disconnection is an initial stage fatigue crack or a simple disconnection due to other problems. This is because a simple disconnection is not as urgent as a fatigue crack occurs. The determination is performed by switching the self-holding circuit 23 at regular time intervals and storing the energization state in the memory 22 so that the inspection operator can check the detection history. The collection of disconnection information using the information collection device 30 will be described later.

  By the way, since the display part 16 which outputs disconnection information according to the disconnection signal from the control part 21 is further provided in the apparatus main body 12, a wireless uncertainty is complemented and disconnection information can be confirmed visually. The display unit 16 is provided with green and red LEDs, and is configured to be switched on and off by the control unit 21 depending on the situation. That is, normally, the green LED is connected to the power source 15 and lights up, and when the detection line 11 is disconnected, the red LED is connected to the power source 15 and lights up. On the other hand, when energization from the power supply 15 is interrupted due to a failure or the like, both LEDs are turned off.

  As shown in FIG. 2, in the fatigue crack detection device 10, the detection line 11 is bonded and fixed along the lower flange 7, and the detection device main body 12 is attached to the lower surface of the lower flange 7. At this time, since the fatigue crack detection device 10 is configured so that a crack can be confirmed by the LED of the display unit 16, the detection device is configured so that the administrator can confirm the blinking of the LED when viewed from below the bridge 1. A main body 12 is attached. Alternatively, the display unit 16 may be separated from the detection apparatus main body 12, and only the display unit 16 may be installed at a position that is easy for the inspection operator to see.

The fatigue crack detection device 10 includes a power supply 15 that causes a current to flow through the detection line 11 and turns on the LED of the display unit 16. Since this fatigue crack detection device 10 has low power consumption and can be used for a long time, the power source 15 can be a dry battery, a solar battery, a small windmill, or the like. In addition to dry batteries and solar batteries, it is also effective to use as the power source 15 a power generation device that generates an electromotive force by applying an impact to the piezoelectric element. FIG. 4 is a perspective view showing a part of a bridge provided with a power generation device using a piezoelectric element.
As described above, in the bridge 1, a plurality of main girders 2 arranged in the width direction are arranged in the longitudinal direction, and adjacent main girders 2 are connected by a horizontal girder (not shown). A slab 5 such as a concrete plate is provided on these girders.

  The main girder 2 is provided with a gutter 7 for the purpose of distributing the load so that the weight of the entire bridge is not locally applied to the pier 6. A plurality of eaves 7 arranged on the pier 6 are installed so that a thin plate-like piezoelectric element member is sandwiched between them, and a disconnection signal detection device 13 or the like is connected to the piezoelectric element member via a charger 17. The Therefore, vibration is generated when the automobile passes over the bridge 1, the vibration is transmitted to the piezoelectric element member, and the electric power generated by the piezoelectric effect is accumulated in the charger 17. And the electric power accumulate | stored in this charger 17 is utilized for the fatigue crack detection mentioned above. In general, power generation by a piezoelectric element is very inefficient, but it is suitable as a power generation device serving as a regular power source under the condition that a very large impact acts on a large-scale structure such as a bridge.

  Further, the power generation device using the piezoelectric element may be provided on the expansion / contraction device 8 or the slab 5 in addition to the ridge 7. The bridge girder as shown in the figure is provided with a gap because the bridge girder before and after it expands and contracts depending on the temperature, and an expansion / contraction device 8 is provided for riding comfort and protection of the floor slab. Therefore, a thin plate-like piezoelectric element member may be installed in the expansion / contraction device 8 so that the electric power generated by the impact of passing the vehicle is accumulated in the charger 17. Further, the slab 5 may be provided with a thin plate-shaped piezoelectric element plate 9 in the concrete pavement, and the electric power generated by the impact caused by the passage of the vehicle may be stored in the charger 17. Thus, by providing a power generation device using a piezoelectric element as a power source in the fatigue crack detection system, it becomes possible to operate the battery permanently without the need for battery replacement.

  Next, in the fatigue crack detection system of the present embodiment, the information collection device 30 for collecting disconnection information for the plurality of fatigue crack detection devices 10a to 10d is used. The information collection device 30 is a mobile PC or a personal digital assistant (PDA), and includes a control unit 31, an IC tag transmission / reception unit 32, a memory 33, a display unit 34, and an operation unit 35, as shown in FIG. . The control unit 31 includes a CPU, and is connected to each unit such as the IC tag transmission / reception unit 32 and controls execution of information collection from the fatigue crack detection device 10.

  The IC tag transmission / reception unit 32 receives information of the IC tag 13 corresponding to the identification number of the fatigue crack detection device 10 and acquires the disconnection information of each. The operation unit 35 includes a numeric keypad for operating the information collecting device 30. In this embodiment, the operation unit 35 displays information on a specific fatigue crack detection device 10 by inputting the identification number of the fatigue crack detection device 10. I am doing so. The display unit 34 is a display device such as a liquid crystal display, and displays an operation state of the information collecting device 30, an operation input screen for the inspection operator, and information acquired from the IC tag 13. Note that it is possible to receive a plurality of IC tags 13 as long as they are within the receivable range. In this case, the identification can be made by the ID number, thereby improving the efficiency of the inspection confirmation work.

The fatigue crack detection system of the present embodiment is configured such that information collected by the information collection device 30 can be collectively managed by a personal computer (management PC) at a management office.
As shown in FIG. 5, the information collecting apparatus 30 and the management PC 40 are connected via a transmission path 41 such as RS232 or USB, and information communication is possible. The management PC 40 is a normal PC including a hard disk, a display, a keyboard, and the like in addition to a control unit including a CPU, a ROM, and a RAM. In particular, the management PC 40 stores an information management program in the ROM, and is configured to create a management file from the information collected by the information collection device 30 and store it in the storage unit.

  Subsequently, the inspection work using the fatigue crack detection system will be described. As shown in FIG. 1, in the plurality of fatigue crack detection devices 10 a to 10 d installed on the bridge, a current is constantly flowing from the power supply 15 to the detection line 11 via the control unit 21. And if the fatigue crack R generate | occur | produces in any location of the fatigue crack detection apparatuses 10a-10d, the detection line 11 fixed to the part with the adhesive will also break. In the initial stage of the fatigue crack, the disconnected detection line 11 comes into contact to restore the energized state, but the self-holding circuit 23 is activated and the energized cut-off state is maintained.

Here, FIG. 6 is a diagram showing a flowchart of a disconnection detection program executed by the fatigue crack detection apparatus 10. As described above, the detection line 11 is always energized (S101), and it is confirmed whether or not a disconnection has occurred (S102). And when there is no disconnection (S102: NO), it lights by energizing to the green LED of the display part 16 (S103). On the other hand, when the disconnection occurs in the detection line 11 (S102: YES), determination of electrical noise (S104) and confirmation of whether or not the self-holding circuit 23 is released after a predetermined time and the energized state is restored. theft is carried out (S105). This is to confirm the difference from a simple disconnection due to electrical noise or defects that are not fatigue cracks.

  The fatigue crack detection device 10 detects a momentary disconnection but needs to be distinguished from electrical noise. It has been experimentally found that electrical noise occurs in a very short time. In this embodiment, energization is confirmed 5 ms after disconnection detection (S104), and electrical noise is discriminated and removed. If energized (S104: YES), it is determined that it is an electrical noise and not a fatigue crack, and lighting is performed by energizing the green LED of the display unit 16 (S103). On the other hand, when there is no energization (S104: NO), it proceeds to the next step on the assumption that a fatigue crack or a disconnection due to a failure has occurred. In addition, as a specific noise generation source, a strong electromagnet (for magnetic particle flaw detection test), a high voltage electric wire, a pantograph, a spark plug, etc. can be considered.

  By the way, when a fatigue crack occurs, if a vehicle such as a train or an automobile passes through the bridge 1, a load is applied and the disconnection portion of the detection line 11 is opened and cannot be determined. Therefore, a time interval T is set in consideration of the passing time of the train or the car, and the energization and the interruption in the self-holding circuit 23 are repeated. Therefore, if the self-holding circuit 23 is not returned to the energized state even after being released for a certain time T (S105: NO), it is determined that the disconnection is simply due to a malfunction, and the subsequent disconnection process is performed (S106). That is, the energization on the green LED side of the display unit 16 is interrupted, and the red LED is switched to the energized state. Then, the memory 22 of the IC tag 13 stores disconnection information between the ID number and the time T.

  On the other hand, when the self-holding circuit 23 is released to return to the energized state (S105: YES), it is considered that the fatigue crack is in the initial stage, and thus the energized state is confirmed a plurality of times. In this embodiment, since it is performed three times, it is confirmed whether or not the number of times is the third time (S107). Therefore, if it is not the third time (S107: NO), steps S101, S102, S105, and S107 are repeated.

  If the disconnection is due to fatigue cracks, an energized state occurs during time T (S105: YES), and the same process is repeated. When the third energization is confirmed after the disconnection (S107: YES), it is determined that it is a fatigue crack, and the subsequent disconnection process is performed (S108). That is, the energization on the green LED side of the display unit 16 is interrupted, and the red LED is switched to the energized state. The memory 22 of the IC tag 13 stores disconnection information obtained by repeating the ID number, disconnection, and energization. The number of repetitions and the measurement interval (time) can be appropriately set according to the load condition of the structure to be applied in order to improve the detection accuracy.

  In the fatigue crack detection device 10, such fatigue cracks are always confirmed, and when a determination is made, information that determines the state is stored in the IC tag 13. The bridge 1 in which such fatigue crack detection devices 10a to 10d are installed is visually inspected regularly (for example, once a day) by an inspection operator. The work inspector performs visual inspections such as peeling of paint on the bridge 1 and cracks in the floor board and the abutment, and further confirms the display unit 16 for fatigue cracks. For example, it can be seen that a disconnection has occurred by confirming that the red LED is lit.

  At that time, the inspection operator collects the disconnection information using the information collection device 30 together with the visual inspection. The inspection worker stands on the bridge under the bridge 1 to be inspected or on the bridge, and sequentially collects the disconnection information stored in the memory from the IC tags 13 of the fatigue crack detection devices 10a to 10d within the communication distance. To go. At this time, the inspection operator can identify the target fatigue crack detection device 10 by inputting the identification number from the operation unit 35 of the information collection device 30 and display the state on the screen for confirmation. If reception with a plurality of IC tags 13 is possible, disconnection information is collectively collected.

  That is, information is sent from the fatigue crack detection device 10 to the information collection device 30. The fatigue crack detection apparatus 10 includes an ID (identification number) for uniquely identifying itself (IC tag 13) in the memory 22 and a simple disconnection with respect to the detection line 11 as described above or a disconnection due to a fatigue crack. Disconnection information indicating whether or not there is stored. Therefore, when the detection line 11 of the fatigue crack detection device 10 is disconnected, the information collection device 30 transmits the ID number and the disconnection information together. In the IC tag 13, the data is reset in the memory 22 by such transmission processing.

Further, the inspection operator moves to a position where the IC tag 13 can communicate with the next fatigue crack detection device 10 and inputs the ID number from the operation unit 35 of the information collection device 30 to confirm the information on the IC tag 13. To go. Information collection by the inspection operator is performed for all fatigue crack detection devices 10, and each ID number and disconnection information of the detection lines 11 are stored in the memory 33 of the information collection device 30. During information acquisition, the disconnection information and the identification number transmitted from the fatigue crack detection device 10 is to be displayed on the display unit 34 of the information collection device 30, the inspector is installed in the display and bridges of the display unit 34 The situation can be grasped from the lighting of the LED of the display unit 16.

  The inspection operator goes around all the other bridges to be inspected, and performs visual inspection of items determined in the same manner for each of them and information collection using the information collection device 30. After returning to the management office, the information collection device 30 is connected to the management PC 40, and the information stored in the memory 22 is sucked up and stored in the memory of the management PC 40. In the management PC 40, a management table is created from the information collected by the information management program and stored as a management file. In the future, if the radio waves transmitted from the IC tag 13 and the performance of the fatigue crack detection device 10 are improved, the inspection worker can receive the state of the IC tag 13 while riding the car or train.

  In the management table created by the information management program, the bridge name, the installation position of the fatigue crack detection device 10 in the bridge, and the disconnection information of the detection line 11 at that position are displayed. As for disconnection information, if the detection line 11 is not disconnected, no comment is displayed. However, if disconnection occurs, the disconnection record obtained from the energization operation performed in step S105 in FIG. 6 is displayed. The difference between mere disconnection and disconnection due to fatigue cracks can be understood. As inspection result information, in addition to the bridge name, measurement point (ID), and disconnection information, it is possible to simultaneously manage information such as measurement time, temperature, and measurer. In addition to improving the efficiency of recording and organizing inspection results, it is possible to formulate an efficient maintenance management plan that leads to asset management from the inspection history.

  Thus, in the fatigue crack detection device and the fatigue crack detection system according to the present embodiment, the information collection device 30 is used, and disconnection information regarding the fatigue crack can be collected without taking time and effort. It can be incorporated into part of the visual inspection work being performed. Further, the fatigue crack detection device 10 and the fatigue crack detection system installed at a plurality of assumed crack locations can greatly reduce costs compared to the conventional one in which the detection line 110 is bonded and fixed over several hundred meters. It became so. In particular, the entire system is made inexpensive by configuring the fatigue crack detection device 10 with the IC tag 13.

  In addition, since the disconnection information collected by the information collecting device 30 is moved to the management PC 40 and the created management table is stored as a management file, information management can be performed easily and reliably. From this, it became possible to make an objective judgment on fatigue cracks, not just by visual inspection. Therefore, for example, even an inexperienced inspector can make a determination with a certain degree of accuracy, leading to early detection of fatigue cracks, and improving the quality for inspection. In addition, the inspection time for fatigue cracks is shortened, and costs can be reduced in this respect.

As mentioned above, although one embodiment of the fatigue crack detection apparatus and fatigue crack detection system concerning this invention was described, this invention is not limited to this, A various change is possible in the range which does not deviate from the meaning.
The IC tag 13 transmits unidirectionally at a constant time interval, but power consumption can be saved by increasing the transmission interval. Therefore, you may make it use a dry cell for the power supply 15 of the fatigue crack detection apparatus 10.
Moreover, although the said embodiment demonstrated and demonstrated the inspection of the fatigue crack which arises in a bridge as an example, structures, such as a steel tower and a roller coaster, may be sufficient.

A wireless communication network using a plurality of transmission type IC tags (active type) can be constructed, and a system that can be collectively monitored from a management office can also be constructed.
In this system, in addition to the unidirectional IC tag, it is possible to adopt an IC tag according to the equipment and environmental conditions to be applied, even if the IC tag is a bidirectional type that returns only when the information collecting device accesses. .
Furthermore, the display for confirming the presence or absence of cracks may be a mechanical method such as an irreversible thermo paint that changes color depending on temperature, or a bar that serves as a mark protrudes from the IC tag case in addition to the LED. .

It is the figure shown notionally about the fatigue crack detection system of this embodiment. It is the figure which showed the specific installation state of the fatigue crack detection apparatus. It is the block diagram which showed a part of fatigue crack detection system. It is the perspective view which showed a part of bridge which installed the electric power generating apparatus using a piezoelectric element. It is the figure which showed the information collection device and management PC. It is the figure which showed the flowchart of the disconnection detection program performed with a fatigue crack detection apparatus. It is a general view of a bridge to which a conventional fatigue crack detection system is applied.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Bridge 10 Fatigue crack detection apparatus 11 Detection line 13 IC tag 15 Power supply 16 Display part 21 Control part 22 Memory 23 Self-holding circuit 24 Transmission / reception part 30 Information collection apparatus 40 Management PC

Claims (5)

A detection line that is fixed by an adhesive to an assumed crack in the object to be inspected,
A power source for energizing the detection line;
An identification tag that is set in advance is stored in the storage unit, and the control unit controls the wireless transmission of the identification information that is performed via the transmission / reception unit.
The IC tag is for the control unit stores the disconnection information obtained by the current cut-off state of the detection wire in the storage unit, and the said disconnection and identification information to be wirelessly transmitted,
The control unit confirms energization after a predetermined time after detecting the disconnection to determine disconnection and electrical noise, and further, confirms energization a predetermined number of times after detecting energization interruption of the detection line, A fatigue crack detection apparatus characterized in that disconnection information is stored in the storage unit. In the fatigue crack detection device according to claim 1 ,
The power source includes a piezoelectric element disposed at a location that receives an impact when a moving object passes through the inspection target, and a charger that charges electric power generated from the impacted piezoelectric element. A fatigue crack detecting device characterized by being. In the fatigue crack detection device according to claim 1 or 2 ,
A fatigue crack detection apparatus comprising: a display unit that displays disconnection information by light emission by the control unit when the detection line is disconnected. The fatigue crack detection device according to any one of claims 1 to 3 is installed for each assumed crack location with respect to a plurality of assumed crack locations existing in the inspection object,
By inputting the identification information, it is possible to perform wireless transmission with one of the plurality of fatigue crack detection devices, and to store the disconnection information received from the fatigue crack detection device in a storage unit. A fatigue crack detection system comprising an apparatus. In the fatigue crack detection system according to claim 4 ,
A fatigue crack detection system comprising an arithmetic processing unit that is connected to the portable information collection device, stores the disconnection information in a storage unit, and creates a management table based on the disconnection information.

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