JP6949598B2 - Inspection support system and inspection support device - Google Patents

Description

The techniques disclosed herein relate to inspection support systems.

An inspection support system used for inspecting structures such as buildings and civil engineering structures is known. Such an inspection support system includes a server device and a terminal device. The server device transmits data related to the inspection to the terminal device. The terminal device acquires data related to the inspection from the server device and displays the inspection contents on the display unit. The inspector inspects each preset inspection target while referring to the inspection contents displayed on the display of the terminal device (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2009-217694

The measurement required for inspection of the inspection target (for example, pile) (for example, measurement of the current value of the motor that rotationally drives the excavation drill, measurement of the amount of cement milk injected into the pile hole, etc.) shall be performed by the measuring device. There is. However, in the conventional inspection support system, the handling of the measurement result by the measuring device is not considered, and there is room for improvement in terms of labor saving and speeding up of the inspection referring to the measurement result.

This specification discloses a technique capable of solving at least a part of the above-mentioned problems.

The techniques disclosed herein can be realized, for example, in the following forms.

(1) The inspection support system disclosed in the present specification is an inspection support system that supports inspection of a structure, and includes a measuring device, a server device, and a terminal device, and the measuring device is described above. An identification information acquisition unit that acquires identification information that identifies an inspection target in a structure, and a measurement result information generation unit that displays the measurement results obtained by measuring the inspection target and generates measurement result information including the identification information. The server device has a measurement device side communication unit that transmits the measurement result information to the server device, and the server device receives the measurement result information transmitted from the measurement device and transmits the measurement result information to the server device. The terminal device has a server-side communication unit that transmits to the terminal device, and the terminal device has a drawing data acquisition unit that acquires drawing data representing a drawing of the structure, the identification information, and the inspection identified by the identification information. A map information data acquisition unit that acquires map information data including coordinate information indicating coordinates on a drawing of the structure corresponding to an object and icon information indicating an icon associated with the identification information, and the server device. A terminal-side communication unit that receives the measurement result information transmitted from, an instruction reception unit that receives an instruction, and a drawing of the structure are displayed on the display based on the drawing data, and based on the map information data. , The icon is displayed at a position corresponding to the inspection target on the drawing of the structure, and is associated with the selected icon in response to the instruction receiving unit receiving the instruction to select the icon. It also has a display control unit that displays a selective measurement result, which is the measurement result represented by the measurement result information including the identification information, on the display. According to this inspection support system, the measuring device generates measurement result information including identification information for identifying an inspection target. The terminal device acquires the measurement result information from the measuring device via the server device, and in response to receiving the instruction to select the icon displayed on the display, the measurement including the identification information associated with the selected icon. The selected measurement result, which is the result, is displayed on the display. As a result, the inspector can inspect the inspection target by referring to the measurement result without printing the measurement result or going to the site and checking it on the display provided in the measuring device. It is possible to improve labor saving and speeding up of inspections with reference to.

(2) In the inspection support system, the terminal device further includes a reference value information acquisition unit that acquires reference value information representing a reference value for the selected measurement result, and the display control unit of the terminal device is the display control unit. The display may be configured to display the selected measurement result and the reference value at the same time. According to this inspection support system, the selective measurement result and the reference value are displayed at the same time, so that the inspector can accurately inspect the selective measurement result with the reference value as a reference.

(3) In the inspection support system, the measurement result information includes information representing the measurement result as a graphic, the reference value information includes information representing the reference value as a graphic, and the display control unit is described. The display may be configured such that at least a part of the figure as the selective measurement result and at least a part of the figure as the reference value are superimposed and displayed. According to this inspection support system, the figure as the selective measurement result and the figure as the reference value are displayed in an overlapping manner, so that the inspector can easily confirm whether the selective measurement result satisfies the reference value. Can be done.

(4) In the inspection support system, in the display control unit of the terminal device, the instruction receiving unit is displayed between the figure as the selection measurement result and the figure as the reference value displayed on the display. The configuration may be such that the contrast ratio is changed in response to the reception of the instruction to change the contrast ratio. According to this inspection support system, the inspector can change the contrast ratio between the figure as the selective measurement result and the figure as the reference value. Therefore, for example, when the inspector wants to confirm the figure as the selective measurement result, the figure as the selective measurement result can be emphasized and displayed, and the figure as the selective measurement result and the figure as the reference value can be displayed. When it is desired to make a comparison, the contrast ratio can be set to be approximately 1: 1. Therefore, both the selective measurement result and the confirmation that the selective measurement result satisfies the reference value can be confirmed.

(5) In the inspection support system, the display control unit of the terminal device divides the figure as the reference value into a plurality of display portions and displays them on the display, and the instruction receiving unit displays the display portion. The display magnification of the display portion may be changed in response to the reception of the instruction to change the display magnification of. According to this inspection support system, the inspector can partially change the display magnification of the figure as a reference value. Therefore, even if the display magnification of the figure as the selection measurement result and the figure as the reference value displayed on the display are partially different due to differences in measurement conditions, for example, the reference value is set so that the display magnification is the same. The display magnification of the figure can be partially changed. Therefore, it is possible to surely confirm whether the selective measurement result satisfies the reference value.

(6) In the inspection support system, the reference value is the measurement result obtained by performing the same type of measurement as the selective measurement result on the inspection target different from the inspection target corresponding to the selective measurement result. It may have a certain configuration. According to this inspection support system, an inspector can accurately inspect the selective measurement result by using a reference value which is a measurement result for a different inspection target in which the same type of measurement as the selective measurement result is performed. Therefore, the selective measurement result can be accurately inspected by using a highly accurate reference value according to the site.

(7) In the inspection support system, the inspection target is a pile, and the measurement is a measurement of a motor current value during a work of rotating an excavation member by a motor to form a pile hole for installing the pile. It may be configured to include. According to this inspection support system, the pile holes related to the piles can be accurately inspected by displaying the motor current value at the time of the pile hole forming work on the display.

(8) In the inspection support system, the identification information may be configured to include a pile number set for each of the piles. According to this inspection support system, the selection measurement result can be identified by using the pile number set for each pile, and the identified selection measurement result can be displayed on the display, which saves labor in inspection with reference to the measurement result. It is possible to improve the speed and speed.

(9) In the inspection support system, the structure includes a plurality of the inspection targets that perform the same type of measurement, and the map information data acquisition unit of the terminal device corresponds to each of the inspection targets. The map information data is acquired, the identification information acquisition unit of the measuring device acquires position information indicating the measured position of the inspection target as the identification information, and the map information data is the coordinates as the identification information. The display control unit of the terminal device includes information, and in response to the instruction receiving unit receiving an instruction to select the icon, the position closest to the coordinate information associated with the selected icon is set. The display may display the selective measurement result represented by the measurement result information including the position information to be shown. According to this inspection support system, measurement result information can be identified using position information and the selected measurement result can be displayed on a display, and labor saving and speeding up of inspection referring to the measurement result can be improved. ..

(10) In the inspection support system, the measurement may include measurement of the position of the inspection target. According to this inspection support system, the position of the inspection target can be accurately inspected by displaying the position of the inspection target on the display.

(11) In the inspection support system, the terminal device further has a reference value information acquisition unit that acquires reference value information representing a reference value for the selected measurement result, and the reference value information corresponds to the coordinate information. This is information representing the reference position of the inspection target, and the display control unit of the terminal device may be configured to display the position of the inspection target and the reference position of the inspection target on the display at the same time. .. According to this inspection support system, the position of the inspection target and the reference position of the inspection target are displayed at the same time, so that the inspector can easily inspect whether the position of the inspection target is correct based on the reference position. be able to.

(12) The inspection support device disclosed in the present specification is an inspection support device that supports inspection of a structure, and includes a drawing data acquisition unit that acquires drawing data representing a drawing of the structure and the structure. Identification information for identifying the inspection target, coordinate information indicating coordinates on the drawing of the structure corresponding to the inspection target identified by the identification information, and icon information indicating an icon associated with the identification information. A map information data acquisition unit that acquires map information data including, and a measurement result information acquisition unit that displays the measurement results obtained by measuring the inspection target and acquires measurement result information including the identification information. The instruction receiving unit that receives the instruction, the drawing of the structure is displayed on the display based on the drawing data, and the icon is displayed at the position corresponding to the inspection target on the drawing of the structure based on the map information data. Selective measurement which is the measurement result represented by the measurement result information including the identification information associated with the selected icon in response to the instruction receiving unit receiving the instruction to select the icon. It has a display control unit for displaying the result on the display. According to the inspection support device, the inspection support device acquires measurement result information associated with the identification information that identifies the inspection target, and receives an instruction to select an icon displayed on the display. The selected measurement result, which is the measurement result including the identification information associated with the selected icon, is displayed on the display. As a result, the inspector can inspect the inspection target by referring to the measurement result displayed on the display without printing the measurement result or going to the site and checking on the display provided in the measuring device. This makes it possible to improve labor saving and speeding up of inspections that refer to measurement results.

The techniques disclosed in the present specification can be realized in various forms, for example, an inspection support system composed of a measuring device and a terminal device, an inspection support method, and a system or method thereof. It can be realized in the form of a computer program for realizing the function, a non-temporary recording medium on which the computer program is recorded, or the like.

It is a block diagram which shows the structure of inspection support system 10. It is explanatory drawing which shows the file structure of the inspection system data D100. It is a sequence diagram of the support implementation process. It is explanatory drawing which shows an example of the drawing display screen HF which displays drawing 30. It is explanatory drawing which shows an example of the drawing display screen HF which displays the enlarged drawing 30. It is explanatory drawing which shows an example of the inspection screen HS in a selection pile. It is explanatory drawing which shows an example of the measurement result screen HE in a selection pile. It is explanatory drawing which shows an example of the measurement result screen HE which displayed the measurement result graph of the selection test pile. It is explanatory drawing which shows an example of the measurement result screen HE which displayed the measurement result graph of a selection pile and the measurement result graph of a selection test pile overlapped. It is explanatory drawing which shows an example of the measurement result screen HE which the 2nd display part D2 of the measurement result graph of a selection test pile is reduced and displayed. It is explanatory drawing which shows an example of the inspection screen HS after the measurement result data D507 corresponding to the selected pile is received. It is explanatory drawing which shows an example of the inspection screen HS after the inspection result corresponding to the selected pile is input. It is explanatory drawing which shows an example of the drawing display screen HF which displays the drawing 30 after the inspection is performed.

A. Embodiment:
A-1. Configuration of inspection support system 10:
FIG. 1 is a block diagram showing a configuration of the inspection support system 10 according to the present embodiment. The inspection support system 10 is for supporting the inspection work of structures such as buildings and civil engineering structures, and includes a server device 100, a terminal device 200, a drawing data storage server 300, and a data generation device 400. , A measuring device 600 installed in the pile driver 500. The server device 100, the terminal device 200, the drawing data storage server 300, the data generation device 400, and the measurement device 600 are connected to each other via a network NW. Although one terminal device 200 is shown in FIG. 1, the number of terminal devices 200 included in the inspection support system 10 may be two or more. The terminal device 200 corresponds to an inspection support device within the scope of claims.

The pile driver 500 is a device for forming a pile hole, which is a hole for installing a pile of a structure, and installing a pile in the pile hole, and includes a motor 510, a current sensor 520, and a position. It includes a sensor 530 and a flow sensor 540. The motor 510 is a motor that rotationally drives an excavation head (not shown) for forming a pile hole. The current sensor 520 is a sensor that outputs a signal representing a current flowing through the motor 510 (hereinafter, referred to as “motor current”). Since the motor current changes in correlation with the hardness of the ground, it is used as an index value indicating the hardness of the ground. The position sensor 530 is a sensor that outputs a signal indicating the depth of the excavation head inserted into the ground. The flow rate sensor 540 is a sensor that outputs a signal indicating the amount of cement milk (consolidation liquid and pile circumference fixing liquid) injected into the pile hole in order to fix the pile to the ground. The excavation head corresponds to an excavation member in the claims.

The measuring device 600 is a device that measures the motor current, the depth of the excavation head, and the amount of cement milk based on the signals output from each sensor 520 to 540 provided in the pile driver 500, and is, for example, a personal computer. And so on. The measuring device 600 includes a control unit 610, a storage unit 620, a communication interface (I / F) 630, an indicator unit 640, a display unit 650, and a satellite signal receiving unit 670. The storage unit 620 is composed of, for example, a hard disk drive (hereinafter referred to as “HDD”), a ROM, a RAM, or the like, and various programs for controlling the measuring device 600, for example, measurement result data D507 (see FIG. 2) described later. ) Is stored in the program for generating. The communication I / F 630 is an interface that communicates with an external device by a wireless communication method or a wired communication method. The instruction unit 140 is composed of, for example, a keyboard, a mouse, or the like, and receives a user's instruction. The display unit 150 is composed of, for example, a liquid crystal display or the like. The satellite signal receiving unit 670 uses signals received from satellites 20 constituting GPS (Global Positioning System) and QZSS (Quasi-Zenith Satellite System) to perform its own current position. It is a device that acquires information (latitude, longitude and altitude) that identifies. The control unit 610 and the communication I / F 630 correspond to the communication unit on the measuring device side within the scope of the claims.

The control unit 610 is composed of, for example, a central control unit (hereinafter referred to as “CPU”) or the like, and executes various programs read from the storage unit 620. As a result, each function of the control unit 610 such as the identification information acquisition unit 612 and the measurement result information generation unit 614 is realized. Each of these functions will be described in "A-2. Inspection support processing" described later.

The server device 100 is a file server that handles the inspection system data D100 described later, and is, for example, a server computer or the like. The server device 100 includes a control unit 110, a storage unit 120, a communication I / F 130, an instruction unit 140, and a display unit 150. The storage unit 120 is composed of, for example, an HDD, a ROM, a RAM, or the like, and stores various programs for controlling the server device 100 and the inspection system data D100. The control unit 110 is composed of, for example, a CPU or the like, and executes various programs read from the storage unit 120. The communication I / F 130 is an interface that communicates with an external device by a wireless communication method or a wired communication method. The instruction unit 140 is composed of, for example, a keyboard, a mouse, or the like, and receives a user's instruction. The display unit 150 is composed of, for example, a liquid crystal display or the like. The control unit 110 and the communication I / F 130 correspond to the server-side communication unit within the scope of the claims.

The terminal device 200 is a device used by an inspector who carries out an inspection, and is, for example, a tablet terminal or a smartphone. The terminal device 200 includes a control unit 210, a storage unit 220, a communication I / F 230, and a display unit 240. The storage unit 220 is composed of, for example, an HDD, a ROM, a RAM, or the like, and stores various programs for controlling the terminal device 200. The communication I / F 230 is an interface that communicates with an external device by a wireless communication method or a wired communication method. The display unit 240 is composed of, for example, a liquid crystal display or the like, and displays drawings or the like. In the present embodiment, the display unit 240 has a touch panel and also functions as an instruction receiving unit that receives instructions from the user. The control unit 210 and the communication I / F 230 correspond to the terminal-side communication unit and the measurement result information acquisition unit in the claims.

The control unit 210 is composed of, for example, a CPU or the like, and executes various programs read from the storage unit 220. As a result, each function of the control unit 210 such as the drawing data acquisition unit 212, the map information data acquisition unit 214, the display control unit 216, and the reference value information acquisition unit 218 is realized. Each of these functions will be described in "A-2. Inspection support processing" described later.

The drawing data storage server 300 is a device that stores drawing data D301 (see FIG. 2) representing a two-dimensional drawing of a structure (hereinafter, simply referred to as “drawing”). The drawing data D301 is data representing, for example, a pile plan of a structure, a plan view of each floor, or the like, and is, for example, CAD data in DXF format.

The data generation device 400 is a device that generates data D100 for an inspection system. The server device 100 stores the inspection system data D100 generated by the data generation device 400.

FIG. 2 is an explanatory diagram showing a file structure of the inspection system data D100. The inspection system data D100 includes system data D101 and individual site data D102. The system data D101 is data for managing the individual site data D102, and is commonly used for all the target structures. The system data D101 includes, for example, icon image data D201 for displaying a pile icon AG, a test pile icon AC (see FIG. 5), or these different color icons (see FIG. 13).

The individual site data D102 is data set for each construction site of the structure. The individual site data D102 includes a plurality of inspection type-specific data D202. The inspection type data D202 is set for each inspection target (for example, pile, piping) of inspection performed on a structure such as pile inspection and piping inspection. As will be described in detail below, each inspection type data D202 includes drawing data D301 and map information data D302. The map information data D302 is data in which the ID data D401 of the structure, the position data D402, and the attribute data D403 are associated with each other, and is, for example, data in the Shape format. Specifically, the map information data D302 includes ID data D401, position data D402, attribute data D403, and correspondence data D404.

The ID data D401 is data for identifying the inspection target, and includes, for example, site information for identifying the site and a pile number set for each pile. The position data D402 is data indicating the coordinates on the drawing for each inspection target of the structure (hereinafter, simply referred to as “coordinates of the inspection target”), and specifically, the coordinate data included in the drawing data D301 is diverted. NS. The attribute data D403 is data indicating the attributes of each inspection target of the structure. Specifically, the icon data D501, the grid data D502, the grid identification data D503, the inspection data D504, and the ID display data. Includes D506 and. The ID data D401 corresponds to the identification information in the claims. The position data D402 corresponds to the coordinate information in the claims.

The icon data D501 is data for displaying an icon on the display unit 240 of the terminal device 200. For example, a specific type of icon is selected from a plurality of types of icons that can be displayed by the icon image data D201 included in the system data D101. Contains data to be selected. The grid grid data D502 is data for displaying the grid grid of the structure on the display unit 240 of the terminal device 200. The grid identification data D503 is data for displaying a grid identifier that identifies the grid. The inspection data D504 is data showing the inspection contents and inspection results in each inspection target of the structure. The inspection data D504 includes measurement result data D507 representing the measurement result obtained by measuring each inspection target of the structure. The ID display data D506 is data for displaying the ID data D401 on the display unit 240 of the terminal device 200. The icon data D501 is an example of icon information in the claims, and the measurement result data D507 corresponds to the measurement result information in the claims.

The correspondence data D404 is data that associates the ID data D401 with the position data D402 and also associates the ID data D401 with the attribute data D403. As a result, attributes such as a specific type of icon (hereinafter, simply referred to as “icon”) and grids indicated by the attribute data D403 are associated with the coordinates on the drawing indicated by the position data D402 via the ID data D401.

The control unit 210 of the terminal device 200 that functions as the display control unit 216 (FIG. 1) has a GIS (Geographic Information System) display function, and uses position information such as position data D402 as a key to provide information on space. It has a function of superimposing and displaying information on the position and the position on the display unit 240. Specifically, the terminal device 200 displays the drawing based on the drawing data D301 and displays the attributes based on the map information data D302. As described above, attributes such as icons and grids are associated with coordinates on the drawing. Therefore, when the attributes such as the icon and the grid are displayed on the display unit 240, they are displayed superimposed on the positions on the drawing corresponding to the coordinates associated with the attributes.

A-2. Inspection support processing:
Next, an operation example of the inspection support process in the inspection support system 10 of the present embodiment will be described. In the inspection support process, the support preparation process for creating the inspection system data D100 and the measurement result regarding the inspection target are displayed on the display unit 240 of the terminal device 200 based on the created inspection system data D100, and the inspector inspects the inspection. Includes support implementation processing to support.

(1) Support preparation process Since the support preparation process itself is not a novel content disclosed in the present specification, it will be briefly described below.

When the individual site data D102 is generated, the data generation device 400 acquires the drawing data D301 of the target structure from the drawing data storage server 300. Further, the data generation device 400 generates the map information data D302. In the structure, the inspection target requiring inspection and the inspection content of each inspection target are predetermined for each type of inspection. The data generation device 400 generates ID data D401 from, for example, site information or a pile number input by a user. Further, the data generation device 400 generates the position data D402 from the data indicating the coordinates of the inspection target input by reading the coordinates by the user. Further, the data generation device 400 generates the attribute data D403 from the data that specifies the type of the icon and the inspection content input from the user.

The data generation device 400 generates correspondence data D404 that associates the generated ID data D401, position data D402, and attribute data D403, and ID data D401, position data D402, attribute data D403, and correspondence data D404. Generates map information data D302 including. When the control unit 110 of the server device 100 generates the map information data D302, the control unit 110 generates the inspection type-specific data D202 including the drawing data D301 acquired from the drawing data storage server 300 and the map information data D302. The data generation device 400 generates the inspection type-specific data D202 for each site and for each inspection type in which the inspection is performed at each site, and generates individual site data D102. The data generation device 400 stores the generated individual site data D102 in the server device 100. With the above, the support preparation process is completed.

(2) Support Implementation Process FIG. 3 is a sequence diagram showing the flow of the support implementation process. In the following, as an example of the support implementation process, an operation example in a scene of performing a pile inspection of a pile foundation building will be described. The support implementation process includes a measurement process (S110 to S160) and an inspection process (S210 to S320).

(Measurement processing)
The measurement process is a process in which the measuring device 600 generates the measurement result data D507 and stores it in the server device 100, and is executed by the measuring device 600 and the server device 100. In the following, as an example of the measurement process, an operation example in the pile hole forming work for forming a pile hole for installing a pile having a pile number: 44 (hereinafter, referred to as “selective pile”) will be described.

The control unit 610 of the measuring device 600 starts the measurement process when the worker of the pile driver 500 starts the pile hole forming work of the selected pile. When starting the pile hole forming work, the worker inputs the site information, the pile number of the selected pile, and the like to the measuring device 600 via the indicator unit 640. The identification information acquisition unit 612 of the control unit 610 acquires ID data D401 including site information and the pile number of the selected pile from the information input by the worker (S110).

The control unit 610 of the measuring device 600 measures the motor current value using the current sensor 520 during the pile hole forming work, measures the depth of the excavation head using the position sensor 530, and uses the flow sensor 540 to measure the pile hole. Measure the amount of cement milk injected into. The control unit 610 acquires these measurement results (numerical data) (S120) and generates a graph (graphic) representing these measurement results. For example, the control unit 610 uses the measured depth of the excavation head, and the horizontal axis is the elapsed time from the start of the pile hole forming work, and the vertical axis is the depth of the excavation head. "Graph") is generated. When the pile driving machine 500 finishes the pile hole forming work of the selected pile, the control unit 610 generates measurement result data D507 including numerical data representing the measurement result and image data representing the measurement result graph, and the generated measurement result. As the file name of the data D507, the file name including the ID data D401 of the selected pile is set (S130). That is, the measurement result includes the numerical value and the graph, and the measurement result data D507 includes the ID data D401.

When the control unit 610 of the measuring device 600 receives the transmission instruction of the measurement result data D507 from the operator via the instruction unit 640, the control unit 610 transmits the generated measurement result data D507 to the server device 100 via the communication I / F 630. (S140).

When the control unit 110 of the server device 100 receives the measurement result data D507 transmitted from the measurement device 600 via the communication I / F 130 (S150), the ID data included in the file name of the received measurement result data D507 Based on D401, the map information data D302 corresponding to the selected pile is selected from the plurality of individual site data D102 stored in the storage unit 220. The control unit 110 adds and stores the received measurement result data D507 to the inspection data D504 included in the attribute data D403 of the map information data D302 corresponding to the selected pile (S160). With the above, the measurement process is completed. By executing the above measurement process for each pile, the measurement result data D507 of each pile is stored in the server device 100.

(Inspection processing)
Next, the inspection process will be described. The inspection process is a process in which the inspector inspects the inspection target using the terminal device 200, and is executed by the terminal device 200 and the server device 100. In the following, as an example of the inspection process, an operation example in the scene of inspecting the selected pile will be described.

When the control unit 210 of the terminal device 200 receives an instruction to start the inspection from the inspector via the display unit 240, the control unit 210 starts the inspection process. The inspector inputs the site information and the inspector information that identifies the inspector together with the instruction to start the inspection. When the control unit 210 acquires the site information and the inspector information (S210), the control unit 210 obtains the individual site data D102 of the target structure from the server device 100 via the communication I / F 230 based on the acquired site information. It is read out and stored in the storage unit 220. That is, the drawing data acquisition unit 212 of the control unit 210 acquires the drawing data D301 from the data generation device 400 via the communication I / F 230. Further, the map information data acquisition unit 214 of the control unit 210 acquires the map information data D302 from the data generation device 400 via the communication I / F 230 (S220). System data D101 is stored in advance in the storage unit 220. Therefore, when S220 is completed, the control unit 210 has completed the acquisition of the inspection system data D100 by the system data D101 stored in advance and the acquired individual site data D102.

The control unit 210 of the terminal device 200 has the inspection type data of the pile inspection from the plurality of inspection type data D202 included in the individual site data D102 based on the inspection type information input from the inspector to specify the inspection type. Select D202. The display control unit 216 of the control unit 210 causes the display unit 240 to display the drawing 30 (see FIG. 4) of the structure based on the drawing data D301 included in the selected inspection type data D202 (S230).

FIG. 4 is an explanatory diagram showing an example of a drawing display screen HF for displaying the drawing 30. FIG. 3 shows a state in which the entire drawing 30 is displayed on the display unit 240 of the terminal device 200. The drawing display screen HF includes a header area HU and a drawing display area HZ. The header area HU is an area for displaying an inspector code (for example, 123456) based on the inspector information and an inspection identifier (for example, pile inspection) based on the inspection type information. The drawing display area HZ is an area for displaying the drawing 30.

The control unit 210 of the terminal device 200 can change the display magnification and the display position of the drawing 30. Specifically, the control unit 210 can enlarge or reduce the drawing 30 to an arbitrary magnification or display the drawing 30 by scrolling through the display unit 240. For example, when the control unit 210 receives an enlargement instruction for the drawing 30 from the inspector, the control unit 210 enlarges and displays a part of the drawing 30 on the display unit 240.

FIG. 5 is an explanatory view showing an example of a drawing display screen HF for displaying an enlarged drawing 30. In the present embodiment, in a state other than the state in which the entire drawing 30 is displayed on the drawing display screen HF, as shown in FIG. 5, the control unit 210 of the terminal device 200 that functions as the display control unit 216 is the display unit 240. 30 is displayed, and the attribute is displayed based on the map information data D302 by the GIS display function. Specifically, the display control unit 216 of the control unit 210 displays the pile icon AG (AG1 to AG11) and the test pile icon AC1 based on the icon data D501, and the grid AS (lead core AS) based on the grid data D502. AS1 to AS5) are displayed, the grid identifier AM (AM1 to AM5) is displayed based on the grid identification data D503, and the pile numbers to be inspected (7 to 10, 37 to 39, based on the ID display data D506, 43 to 46, 51) are displayed.

Based on the grid data D502, the control unit 210 of the terminal device 200 displays the grid AS at a position corresponding to the coordinates on the drawing 30 associated with the grid AS. Therefore, the control unit 210 updates the display state of the grid AS in response to the change in the display magnification of the drawing 30. Specifically, when the drawing 30 is enlarged or reduced, the control unit 210 updates the position where the grid AS is displayed in accordance with the enlargement or reduction. Further, the grid identifier AM is associated with a position corresponding to the coordinates of the corresponding grid AS. Therefore, the control unit 210 updates the display state of the grid identifier AM in response to the change in the display magnification of the drawing 30. In the present embodiment, the grid identifier AM is displayed around one of the positions where the corresponding grid AS intersects the outer peripheral portion of the display unit 240.

The stake icon AG, the test stake icon AC1, and the ID data D401 are displayed at the positions indicated by the coordinates on the drawing 30 associated with them. As a result, the pile icon AG, the test pile icon AC1, and the ID data D401 are displayed at positions on the drawing with respect to the corresponding inspection targets (hereinafter, simply referred to as “positions of inspection targets”). The pile icon AG and the test pile icon AC1 include indications such as "pile" and "test pile" indicating the type of inspection target, and the display color is determined according to the inspection status of the corresponding inspection target. For example, if the inspection status of the inspection target is "unconfirmed" because the measurement for the corresponding inspection target has not been performed, the display color is yellow. When the measurement for the corresponding inspection target is performed and the measurement result is "acquired", the display color is orange. If the inspection result of the corresponding inspection position is "Fail", the display color becomes red. If the inspection result of the corresponding inspection position is "pass", the display color is blue. In FIG. 5, since the inspection status of the "test pile" (pile number: 43) is "pass", the test pile icon AC1 is displayed in blue, and the "pile" (pile number: 7 to 10) is displayed. , 37-39, 44-46, 51), all the pile icon AGs are displayed in yellow because the inspection status is "unconfirmed".

The control unit 210 of the terminal device 200 that functions as the display control unit 216 receives a tap on the pile icon AG1 displayed at the position of the selected stake via the display unit 240, and the selected stake is displayed on the display unit 240. The inspection screen HS in is displayed. FIG. 6 is an explanatory diagram showing an example of the inspection screen HS in the selected pile. FIG. 6 shows the inspection screen HS before the measurement on the selected pile is performed. The inspection screen HS is displayed based on the inspection data D504 corresponding to the selected pile. In addition to the header area HU described above, the inspection screen HS includes a member display area HB, a reduced drawing display area HG, an inspection result display area HK, a measurement result display area HC, and an image acquisition area HP.

The member display area HB has an identifier indicating the type of the selected pile (for example, member: main pile) and an identifier indicating the position of the selected pile on the drawing 30 with reference to the core AS (for example, X-street: X6-X7). Y street: Y3-Y4) and an identifier indicating the pile number of the selected pile (for example, pile number: 44) are displayed in this area.

The reduced drawing display area HG is an area for reducing and displaying the drawing 30 around the selected pile. The control unit 210 of the terminal device 200 displays the display magnification and the display position of the drawing 30 in the reduced drawing display area HG in an immutable manner. The control unit 210 displays the selected stake mark AW at the position of the selected stake on the drawing 30 in the reduced drawing display area HG.

The inspection result display area HK is an area for displaying the inspection result. Specifically, the inspection result display area HK1 and the icon display field HK1 displaying the same icon as the pile icon AG1 displayed at the position of the selected pile on the drawing 30 and the inspection. This is an area for displaying the inspection result input field HK2 for inputting the result. The inspection result input field HK2 is associated with a screen showing a multi-window (not shown) in which "unconfirmed", "acquisition", "failure", and "pass" indicating the inspection result are described. When the inspector inputs the inspection result in the inspection result input field HK2, the inspector can input the inspection result by tapping the inspection result input field HK2 and selecting the inspection result from the displayed multi-window.

The measurement result display area HC is an area for displaying the acquisition status of the measurement results used for the inspection of the selected pile. Specifically, the item display column HC1 for displaying the measurement items according to the inspection target and the measurement result This is an area for displaying the acquisition status column HC2 indicating the acquisition status. The acquisition status column HC2 is associated with screens indicating "unconfirmed" and "acquisition" indicating the acquisition status of the measurement results of the corresponding measurement items. Specifically, if the corresponding measurement result has not been acquired from the measuring device 600, "unconfirmed" is displayed in the acquisition status column HC2, and if the corresponding measurement result has been acquired, the acquisition status column HC2 is displayed. "Get" is displayed.

As shown in FIG. 3, when the control unit 210 of the terminal device 200 receives a tap on the acquisition status column HC2 (see FIG. 6) of the “unconfirmed” display displayed on the inspection screen HS via the instruction unit 140 (see FIG. 6). S240), the transmission request of the measurement result data D507 corresponding to the selected pile is transmitted to the server device 100 via the communication I / F 230 (S250). The control unit 210 designates the ID data D401 of the selective pile and the ID data D401 of the selective test pile described later in the transmission request.

When the control unit 110 of the server device 100 receives the transmission request transmitted from the terminal device 200, the control unit 110 identifies the map information data D302 corresponding to the selected pile from the ID data D401 of the selected pile specified by the transmission request, and the map. It is determined whether the measurement result data D507 is stored in the information data D302. When the measurement result data D507 is stored in the map information data D302 corresponding to the selected pile, the control unit 110 of the server device 100 measures the measurement result data D507 corresponding to the selected pile via the communication I / F 630. It is transmitted to 600 (S260). When the control unit 110 transmits the measurement result data D507 corresponding to the selective test pile, the control unit 110 further identifies the map information data D302 corresponding to the selective test pile from the ID data D401 of the selective test pile, and transmits the communication I / F 630. The measurement result data D507 stored in the map information data D302 is transmitted to the measuring device 600 via the above.

The control unit 210 of the terminal device 200 receives the measurement result data D507 corresponding to the selected stake transmitted from the server device 100 via the communication I / F 230 (S270), and stores the measurement result data D507 in the storage unit 220. Further, the reference value information acquisition unit 218 of the control unit 210 receives the measurement result data D507 corresponding to the selection test pile transmitted from the server device 100 and stores it in the storage unit 220. Display of control unit 210 Control unit 216 displays the measurement result screen HE of the selected pile based on the measurement result data D507 corresponding to the inspection target and the measurement result data D507 corresponding to the selected test pile transmitted from the server device 100. (S280).

FIG. 7 is an explanatory diagram showing an example of the measurement result screen HE in the selected pile. The measurement result screen HE includes a measurement result header area HD and a measurement result display area HT. The measurement result header area HD includes an identifier indicating the type and pile number of the selected pile (for example, the main pile number: 44), and the type and pile of the test pile (hereinafter referred to as “selective test pile”) associated with the selected pile. This is an area for displaying an identifier indicating a number (for example, test pile number: 43). Here, the test pile means a pile to be installed first among a plurality of piles included in the structure, and the main pile means a pile to be installed after the test pile is installed. The selective test pile, which is the main pile, is associated with the selective test pile in advance. Specifically, the selective test pile is associated with the test pile closest to the selective pile.

The measurement result display area HT is an area for displaying the measurement result. Specifically, the scroll bar HT2 for switching between the measurement result display column HT1 for displaying the measurement result and the measurement result displayed in the measurement result display column HT1. And is the area to display. The display control unit 216 of the control unit 210 that functions as the display control unit 216 causes the measurement result display column HT1 to display the measurement result graph of the selected pile and the measurement result graph of the selected test pile. For example, when the inspector displays the measurement result graph of the selected pile in the measurement result display field HT1, the inspector taps the knob HTM of the scroll bar HT2, and the scroll bar HT2 in which the "main pile" indicating the selected pile is displayed. Move the knob HTM to one end (see FIG. 8). When the inspector displays the measurement result graph of the selection test pile in the measurement result display column HT1, the inspector taps the knob HTM of the scroll bar HT2, and the scroll bar HT2 in which the "test pile" indicating the selection test pile is displayed. Move the knob HTM to the other end (see FIG. 8). The measurement result of the selective pile corresponds to the measurement result of the selective pile in the claims.

Further, when the inspector simultaneously displays the measurement result graph of the selected pile and the measurement result graph of the selected test pile in the measurement result display column HT1, the inspector taps the knob HTM of the scroll bar HT2 and shifts the knob HTM to the scroll bar HT2. It is moved to an intermediate part other than both ends of the above (see FIG. 9).

The control unit 210 of the terminal device 200 that functions as the display control unit 216 has a contrast ratio between the measurement result graph of the selective pile and the measurement result graph of the selective test pile displayed superimposed on the measurement result display column HT1 (hereinafter, It has a function of simply changing (referred to as "contrast ratio"). Specifically, when the inspector emphasizes and displays the measurement result graph of the selected pile in the measurement result display column HT1, the inspector taps the knob HTM of the scroll bar HT2 and puts the knob HTM in the middle part of the scroll bar HT2. , Move to the left side (“main pile” side) of FIG. 7 from the center of both ends. As a result, the display control unit 216 of the control unit 210 has a display density of NS of the measurement result graph of the selection pile displayed in the measurement result display column HT1 higher than the display density of the measurement result graph of the selection test pile: NK. Change the contrast ratio so that Further, when the inspector emphasizes and displays the measurement result graph of the selection test pile in the measurement result display column HT1, the inspector taps the knob HTM of the scroll bar HT2 and puts the knob HTM on both ends of the middle part of the scroll bar HT2. Move it to the right side of FIG. 7 (“test pile” side) from the center of the part. As a result, the display control unit 216 of the control unit 210 changes the contrast ratio so that the display density of the selection test pile: NK is higher than the display density of the selection pile: NS.

That is, when the inspector taps the knob HTM of the scroll bar HT2 and moves the knob HTM to the left side (“main pile” side) of FIG. 7, the display control unit 216 of the control unit 210 displays the display density of the selected pile. : NS is set higher than the display concentration of the selected test pile: NK, and when the inspector moves the knob HTM to the left end of FIG. 7, the display control unit 216 of the control unit 210 displays the display concentration of the selected pile. : Change the contrast ratio between NS and selective test pile display density: NK to "NS: NK = 1: 0". Further, when the inspector taps the knob HTM of the scroll bar HT2 and moves the knob HTM to the right side (“test pile” side) of FIG. 7, the display control unit 216 of the control unit 210 displays the selection test pile. Concentration: NK is set higher than the display concentration of the selected pile: NS, and when the inspector moves the knob HTM to the right end of FIG. 7, the display control unit 216 of the control unit 210 displays the display concentration of the selected pile. : Change the contrast ratio between NS and selective test pile display density: NK to "NS: NK = 0: 1".

As shown in the measurement result display column HT1 (see FIG. 7), in the pile hole forming work, the depth of the excavation head is increased by inserting the excavation head into the ground after the start of the pile hole forming work. When the excavation head reaches a relatively hard layer in the ground and the motor current value reaches the first threshold value, the rotational drive of the excavation head is stopped. The depth of the excavation head when the motor current value reaches the first threshold value is defined as the lower end depth LD. When the depth of the excavation head reaches the lower end depth LD, various confirmation operations for the pile hole forming work are executed, and cement is injected into the pile hole. Therefore, the depth of the excavation head is kept substantially constant. After the cement is injected, the drilling head is pulled out, reducing the depth of the drilling head. When the excavation head reaches the ground surface and the motor current value reaches the second threshold value lower than the first threshold value, the pile hole forming work is completed. The depth of the excavation head when the motor current value reaches the second threshold value, that is, the depth at which the excavation head reaches the ground surface is defined as the upper end depth LH. Therefore, during the pile driving period in which the pile hole forming work is carried out, the initial period TS in which the depth of the pile hole increases, the intermediate period TC in which the depth of the pile hole is kept substantially constant, and the depth of the pile hole are Includes a declining late period TK.

FIG. 8 is an explanatory diagram showing an example of the measurement result screen HE on which the measurement result graph of the selective test pile is displayed. The control unit 210 of the terminal device 200 that functions as the display control unit 216 displays the measurement result graph of the selection test pile on the first display portion D1 that displays the initial period TS and the second display portion that displays the intermediate period TC. It is divided into three display portions, D2 and a third display portion D3 for displaying the late period TK, and displayed on the measurement result screen HE.

Specifically, the control unit 610 of the measuring device 600 represents the image data representing the first display portion D1 and the second display portion D2 when generating the measurement result data D507 corresponding to the selective test pile. The measurement result data D507 is generated by dividing the image data into three image data, that is, the image data and the image data representing the third display portion D3. The control unit 210 of the terminal device 200 displays these three image data side by side in the horizontal axis direction. As a result, the above display is realized.

When displaying the measurement result graph of the selection test pile on the measurement result screen HE, the control unit 210 of the terminal device 200 further displays the first lane marking LL and the second lane marking LR in the measurement result display area HT. And the first instruction knob LLM and the second instruction knob LRM are displayed. The first division line LL is a line that partitions between the first display portion D1 and the second display portion D2. It is a line which divides between the 2nd display part D2 and the 3rd display part D3. The first lane marking LL and the second lane marking LR traverse the measurement result display column HT1 and extend to the upper side and the lower side of the measurement result display column HT1. The first indicator knob LLM is displayed on the first lane marking LL above the measurement result display column HT1. The second indicator knob LLM is displayed on the second lane marking LR above the measurement result display column HT1.

FIG. 9 is an explanatory diagram showing an example of the measurement result screen HE in which the measurement result graph of the selective pile and the measurement result graph of the selective test pile are displayed in an overlapping manner. As shown in FIG. 9, in the initial period TS, the measurement result graph of the selective pile and the measurement result graph of the selective test pile are substantially equal. This is due to the following reasons. That is, in the pile hole forming work, in order to prevent the pile hole from collapsing during the pile hole forming work, the insertion speed for inserting the excavation head is determined for each geology constituting each layer existing in the ground. Since the test pile located closest to the selective pile is selected as the selective test pile, the ground structure at the position of the selective pile and the ground structure at the position of the selective test pile are substantially equal, and the insertion speed at the selective pile is substantially equal. And the insertion speed in the selective test pile are equal. Therefore, the measurement result graph of the selective test pile can be said to be a reference value for determining whether or not the measurement result graph of the selective pile is correct. The measurement result data D507 corresponding to the selective test pile corresponds to the reference value information in the claims.

On the other hand, the intermediate period TC of the pile hole forming work of the selective test pile is longer than the intermediate period TC of the pile hole forming work of the selective pile. This is because, for example, since the test pile is the pile for which the pile hole forming work is first performed, the confirmation item of the confirmation operation carried out during the intermediate period TC of the pile hole forming work of the selective test pile is the pile of the selected pile. This is because there are more confirmation items of the confirmation operation performed in the intermediate period TC of the hole forming work. Therefore, as shown in FIG. 9, the late period TK of the pile hole forming work of the selective test pile is deviated in the horizontal axis (elapsed time) direction with respect to the late period TK of the pile hole forming work of the selective pile. By simply displaying the measurement result graph of the selective pile and the measurement result graph of the selective test pile in an overlapping manner, the inspector can omit the measurement result graph of the selective pile and the measurement result graph of the selective test pile in the latter period TK. It is not possible to judge whether they are equal or not.

The control unit 210 of the terminal device 200 that functions as the display control unit 216 changes the display magnification in the horizontal axis (elapsed time) direction of the second display portion D2 in the measurement result graph of the selection test pile to display the measurement result screen HE. It has a function to display. That is, when the display control unit 216 of the control unit 210 receives an instruction to change the display magnification of the second display portion D2 and display the display unit 240 via the instruction unit 140, the display unit 240 displays the second display. The display magnification of the portion D2 is changed and displayed, and the display magnifications of the first display portion D1 and the third display portion D3 are displayed without being changed. That is, when the display control unit 216 of the control unit 210 receives the above instruction, the display unit 240 receives the display magnification of the second display portion D2 and the display magnification of the first display portion D1 and the third display portion D3. Is displayed as a different display magnification.

Specifically, the inspector taps the second indicator knob LRM so that the second indicator knob LRM coincides with the boundary line between the intermediate period TC and the late period TK in the measurement result graph of the selected pile. The second lane marking LR is moved to. As a result, the second display portion D2 is reduced in the horizontal axis (elapsed time) direction, and the third display portion D3 is translated in the horizontal axis direction. , The late period TK of the pile hole forming work of the selected pile, and is displayed in an overlapping manner.

FIG. 10 is an explanatory diagram showing an example of the measurement result screen HE in which the second display portion D2 of the measurement result graph of the selective test pile is reduced and displayed. As shown in FIG. 10, in the late period TK, the measurement result graph of the selective pile and the measurement result graph of the selective test pile are substantially equal. Similar to the initial period TS, in the pile hole forming work, in order to prevent the pile hole from collapsing during the pile hole forming work, the excavation head is pulled out for each geology constituting each layer existing in the ground. This is because the speed is fixed.

The inspector taps the first instruction knob LLM on the first division line LL and translates the first instruction knob LRM in the horizontal axis (elapsed time) direction to obtain a second display portion. D2 can be enlarged or reduced in the horizontal axis (elapsed time) direction, and the first display portion D1 can be translated and displayed in the horizontal axis (elapsed time) direction.

FIG. 11 is an explanatory diagram showing an example of the inspection screen HS after the measurement result data D507 corresponding to the selected pile is received. When the measurement result data D507 corresponding to the selected pile is received, "acquisition" is displayed in the acquisition status column HC2 of the measurement result display area HC. When the input of the inspection result input field HK2 of the inspection result display area HK is updated from "unconfirmed" to "acquisition", the control unit 210 of the terminal device 200 receives an instruction via the display unit 240, and the inspection result display area HK icon display field The display color of the HK1 icon is changed to orange.

FIG. 12 is an explanatory view showing an example of the inspection screen HS after the inspection result corresponding to the selected pile is input, and FIG. 13 is a drawing display screen HF displaying the drawing 30 after the inspection is performed. It is explanatory drawing which shows an example. The inspector inspects the selected pile by referring to the degree of overlap between the measurement result graph of the selected pile and the measurement result graph of the selective test pile on the measurement result screen HE (see FIG. 10). In the following, an operation example in a situation where the inspector determines that the selected pile is "passed" will be described. When the inspector determines that the selected pile is "passed", the inspector updates the inspection result input field HK2 in the inspection result display area HK from "confirmation" to "passed" by an instruction via the display unit 240.

When the input of the inspection result input field HK2 in the inspection result display area HK is updated from "confirmation" to "pass", the control unit 210 of the terminal device 200 displays the icon of the inspection result display area HK icon display field HK1. Change the display color to blue. As a result, as shown in FIG. 13, when the display of the display unit 240 is switched from the inspection screen HS to the drawing display screen HF, the display color of the pile icon AG1 at the selected inspection position is changed to blue.

Further, as shown in FIG. 3, the control unit 210 of the terminal device 200 is "passed" by updating the input of the inspection result input field HK2 in the inspection result display area HK from "confirmation" to "pass". When the inspection result of (S290) is received, the inspection data D504 corresponding to the selected pile is transmitted to the server device 100 via the communication I / F 230 (S300).

When the control unit 110 of the server device 100 receives the inspection data D504 transmitted from the terminal device 200 (S310), the control unit 110 receives the inspection data D504 included in the attribute data D403 of the map information data D302 corresponding to the selected pile. It is replaced with the inspection data D504 and stored (S320). With the above, the support implementation process is completed.

As described above, in the inspection support system 10 of the present embodiment, the control unit 610 of the measuring device 600 generates the measurement result data D507 including the ID data D401. The control unit 210 of the terminal device 200 acquires the measurement result data D507 from the measuring device 600 via the server device 100, and receives a tap on the stake icon AG1 displayed on the display unit 240. The measurement result graph of the above is displayed on the display unit 240 (FIG. 7). As a result, the inspector refers to the measurement result graph displayed on the display unit 240 and inspects the object without printing the measurement result graph or going to the site and checking on the display unit 650 of the measuring device 600. Can be inspected, and labor saving and speeding up of inspection with reference to the measurement result can be improved.

In the inspection support system 10 of the present embodiment, when the control unit 210 of the terminal device 200 displays the measurement result graph of the selected pile on the display unit 240, the measurement result graph of the selected pile and the measurement result graph of the selected test pile are displayed. Is displayed on the display unit 240 at the same time (FIG. 9). Therefore, the inspector can accurately inspect the measurement result of the selective pile based on the measurement result of the selective test pile.

Both selective piles and selective test piles are structural piles and the same type of measurement is performed. The selective pile, which is the main pile, is a pile different from the selective test pile, which is the test pile. Therefore, the inspector can accurately inspect the measurement result of the selective pile by using the measurement result of the selective test pile in which the same type of measurement is performed on the pile different from the selective pile. Therefore, it is possible to accurately inspect the measurement result of the selection test pile by using the measurement result of the selection pile according to the site.

In the inspection support system 10 of the present embodiment, the control unit 210 of the terminal device 200 displays the measurement result graph of the selective pile and the measurement result graph of the selective test pile on the display unit 240 (FIG. 9). Therefore, the inspector can easily confirm whether the measurement result of the selective test pile is substantially equal to the measurement result of the selective pile.

In the inspection support system 10 of the present embodiment, the control unit 210 of the terminal device 200 has a function of changing the contrast ratio between the measurement result graph of the selective pile and the measurement result graph of the selective test pile. Therefore, even if the measurement result graph of the selection test pile and the measurement result graph of the selection pile are displayed in an overlapping manner, the inspector can confirm, for example, the measurement result graph of the selection pile by changing the contrast ratio. In addition, the measurement result graph of the selective test pile can be confirmed, and the measurement result graph of the selective test pile can be compared with the measurement result graph of the selective test pile. Therefore, it is possible to confirm both the measurement result of the selective test pile and whether the measurement result of the selective test pile is substantially equal to the measurement result of the selective test pile.

In the inspection support system 10 of the present embodiment, when the control unit 210 of the terminal device 200 displays the measurement result graph of the selective test pile on the display unit 240, the control unit 210 includes three display portions included in the measurement result graph of the selective test pile. It is possible to change only the display magnification of one display portion of D1 to D3 (FIG. 10). Therefore, even if the length of the intermediate period TC in the measurement result graph of the selective pile and the length of the intermediate period TC in the measurement result graph of the selective test pile are different, the control unit 210 of the terminal device 200 displays the intermediate period TC. By changing the display magnification of the second display portion D2, the length of the intermediate period TC in the measurement result graph of the selected pile and the length of the intermediate period TC in the measurement result graph of the selective test pile can be displayed in accordance with each other. Can be done. Therefore, it is possible to surely confirm whether the measurement result of the selective test pile is substantially equal to the measurement result of the selective pile.

B. Modification example:
The technique disclosed in the present specification is not limited to the above-described embodiment, and can be transformed into various forms without departing from the gist thereof, and for example, the following modifications are also possible.

B-1. First variant:
In the above embodiment, the example in which the pile number is used as the identification information is shown, but for example, the position information such as the position data D402 may be used as the identification information. In the following, the support implementation process performed when the location information is used as the identification information will be described.

In the first modification, in the measurement process, the control unit 610 of the measuring device 600 receives a satellite signal at the site of the pile hole forming work when the worker of the pile driver 500 starts the pile hole forming work of the selected pile. The unit 670 is used to measure information that identifies the current position of the measuring device 600. Information for converting the position of the measuring device 600 to the position to be inspected is acquired and stored in advance in the storage unit 620 of the measuring device 600, and the control unit 610 is used as information for specifying the current position of the measuring device 600. , Information for specifying the current position of the inspection target is generated from the information for converting the position of the measuring device 600 into the position of the inspection target. The control unit 610 sets a file name including information for specifying the current position of the inspection target as the file name of the generated measurement result data D507, and transmits the generated measurement result data D507 to the server device via the communication I / F 630. Send to 100. The information that identifies the current position of the inspection target corresponds to the position information in the claims.

When the control unit 110 of the server device 100 receives the measurement result data D507 transmitted from the measurement device 600 via the communication I / F 130, the control unit 110 of the server device 100 determines the current position of the inspection target included in the file name of the received measurement result data D507. It is converted into information indicating the coordinates on the drawing 30.
The control unit 110 identifies the map information data D302 including the position data D402 indicating the coordinates closest to the converted coordinates, and adds and stores the received measurement result data D507 to the inspection data D504 included in the map information data D302. do. As a result, when the control unit 210 of the terminal device 200 that functions as the display control unit 216 receives a tap on the acquisition status column HC2 (see FIG. 6) of the "unconfirmed" display displayed on the inspection screen HS of the selected pile. The measurement result graph is displayed on the display unit 240 based on the measurement result data D507 including the current position of the inspection target indicating the position closest to the position data D402 corresponding to the selected pile.

As described above, in the first modification, the measurement result data D507 is performed using the position information, and the measurement result graph is displayed on the display unit 240. As a result, the inspector can inspect the inspection target by referring to the measurement result graph displayed on the display unit 240, and can improve labor saving and speeding up of the inspection referring to the measurement result.

B-2. Other variants:
In the above embodiment, the inspection support system 10 includes a server device 100, a terminal device 200, a measurement device 600, a drawing data storage server 300, and a data generation device 400. The server device 100 and the drawing data storage server 300 may be configured by one server. Further, when the inspection system data D100 is generated by, for example, the server device 100, the data generation device 400 is not always necessary.

In the above embodiment, an example is shown in which the current sensor 520, the position sensor 530, and the flow rate sensor 540 are provided in the pile driver 500, but the present invention is not limited to this, and the measuring device 600 includes these sensors 520 to 520. 540 may be provided. Further, the pile driver 500 and the measuring device 600 may be configured by one device.

In the above embodiment, the control unit 210 of the terminal device 200 shows an example of displaying the measurement result graph on the display unit 240 of the terminal device 200, but the display on which the control unit 210 displays the measurement result graph is on the terminal device 200. The display is not limited to the provided display unit 240, and may be an external display of the terminal device 200.

In the above embodiment, the keyboard, mouse, and the like that receive instructions by operation are exemplified as the instruction unit, but the device is not limited to this, and a device that receives instructions by voice or eye movement may be used.

In the above embodiment, the display unit 240 of the terminal device 200 also serves as an instruction receiving unit, but the terminal device 200 may include an instruction receiving unit separately from the display unit 240.

In the above embodiment, an example in which only the two-dimensional drawing is used as the drawing of the structure is shown, but the three-dimensional drawing may be used instead of the two-dimensional drawing or together with the two-dimensional drawing. For example, a three-dimensional drawing and a two-dimensional drawing of the structure are displayed on the display unit 240 of the terminal device 200 so as to be switchable, and the inspector can display the structure on the display unit 240 of the terminal device 200 as needed. The dimensional drawing may be displayed and the above inspection support process may be performed.

In the above embodiment, an example is shown in which the measurement result graph includes a graph showing the relationship between the elapsed time and the depth of the excavation head, but the present invention is not limited to this, and instead of or in addition to the above graph, A graph showing the relationship between the elapsed time and the motor current value and a graph showing the relationship between the elapsed time and the amount of cement milk may be included.

In the above embodiment, an example in which the reference value is a measurement result graph of the selective test pile is shown, but the present invention is not limited to this, and design data or the like may be used. As the design data, for example, when the inspection target is a pile, it may be a table showing the geology constituting each layer existing in the ground and the insertion speed of the excavation head set in each place.

In the above embodiment, an example in which the selective measurement result and the reference value are displayed at the same time is shown, but the present invention is not limited to this. Note that "displayed at the same time" is not limited to the case where the display start timings are simultaneous, and it is sufficient that both the selected measurement result and the reference measurement result are displayed on the display at an arbitrary timing.

In the above embodiment, an example in which the measurement result includes a numerical value and a graph is shown, but the present invention is not limited to this, and instead of at least one of the above numerical value and the graph, or at least one of the above numerical value and the graph. In addition, for example, a figure other than a graph may be included.

In the above embodiment, an example in which the inspection target is a pile is shown, but the inspection target is not limited to this, and may be a foundation, piping, each room of a building, or the like. For example, in the inspection when the inspection target is the foundation, the amount of cement injected into the ground is measured. In the inspection when the inspection target is a pipe, the pipe gradient and the like are measured. Further, when the pipe is a water supply pipe, water pressure or the like may be measured. In the inspection when the inspection target is each room of the building, noise, illuminance, vibration, etc. are measured.

In the above embodiment, an example of measuring the motor current value or the like in the measurement process is shown, but for example, the current position of the inspection target may be measured as the measurement result. The method of measuring the current position of the inspection target is as shown in the first modification. In this case, the control unit 210 of the terminal device 200 converts the position data D402 into information indicating an actual position (hereinafter, referred to as “conversion position”), and the control unit 210 of the terminal device 200 that functions as the display control unit 216 , The current position of the inspection target and the conversion position may be displayed on the display unit 240 at the same time. The conversion position corresponds to the reference position of the inspection target in the claims, and the information indicating the conversion position corresponds to the reference value information in the claims.

In the first modification, the satellite 20 is exemplified as an acquisition destination for the control unit 610 of the measuring device 600 to acquire the information for specifying the current position of the measuring device 600, but the present invention is not limited to this, and a communication device such as a beacon is used. But it may be.

In the above embodiment, an example including the display of “pile”, “test pile” and the like is shown as the icon, but the icon is not limited to the above example. For example, the icon may include a display of the stake number. Further, it is not necessary to include any display, and the measurement result graph may be displayed on the display unit 240 by tapping the position of the inspection target on the drawing 30.

10: Inspection support system 100: Server device 110: Control unit 120: Storage unit 130: Communication I / F 140: Indicator unit 150: Display unit 200: Terminal device 210: Control unit 212: Drawing data acquisition unit 214: Map information data Acquisition unit 216: Display control unit 218: Reference value information acquisition unit 220: Storage unit 230: Communication I / F 240: Display unit 300: Drawing data storage server 400: Data generator 500: Pile driving machine 510: Motor 520: Current Sensor 530: Position sensor 540: Flow sensor 600: Measuring device 610: Control unit 612: Identification information acquisition unit 614: Measurement result information generation unit 620: Storage unit 630: Communication I / F 640: Indicator 650: Display unit 670: Satellite signal receiver

Claims (12)

An inspection support system that supports the inspection of structures
Measuring device and
With the server device
Equipped with a terminal device,
The measuring device is
An identification information acquisition unit that acquires identification information that identifies an inspection target in the structure,
A measurement result information generation unit that represents the measurement result obtained by measuring the inspection target and generates measurement result information including the identification information.
A communication unit on the measuring device side that transmits the measurement result information to the server device,
Have,
The server device has a server-side communication unit that receives the measurement result information transmitted from the measurement device and transmits the measurement result information to the terminal device.
The terminal device is
A drawing data acquisition unit that acquires drawing data representing a drawing of the structure, and a drawing data acquisition unit.
Map information including the identification information, coordinate information indicating coordinates on a drawing of the structure corresponding to the inspection target identified by the identification information, and icon information indicating an icon associated with the identification information. Map information data acquisition department to acquire data and
A terminal-side communication unit that receives the measurement result information transmitted from the server device, and
The instruction reception department that accepts instructions and
The drawing of the structure is displayed on the display based on the drawing data, and the icon is displayed at a position corresponding to the inspection target on the drawing of the structure based on the map information data. In response to the reception unit receiving the instruction to select the icon, the selection measurement result, which is the measurement result represented by the measurement result information including the identification information associated with the selected icon, is displayed on the display. Display control unit to make
Has an inspection support system. The inspection support system according to claim 1.
The terminal device further includes a reference value information acquisition unit that acquires reference value information representing a reference value for the selective measurement result.
The display control unit of the terminal device is an inspection support system that simultaneously displays the selected measurement result and the reference value on the display. The inspection support system according to claim 2.
The measurement result information includes information representing the measurement result as a graphic.
The reference value information includes information representing the reference value as a graphic.
The display control unit is an inspection support system that displays at least a part of the figure as a selection measurement result and at least a part of the figure as a reference value on the display. The inspection support system according to claim 3.
The display control unit of the terminal device has received an instruction for the instruction receiving unit to change the contrast ratio between the figure as the selective measurement result and the figure as the reference value displayed on the display. An inspection support system that changes the contrast ratio accordingly. The inspection support system according to claim 3 or 4.
The display control unit of the terminal device divides the figure as a reference value into a plurality of display portions and displays them on the display, and the instruction receiving unit receives an instruction to change the display magnification of the display portion. An inspection support system that changes the display magnification of the display portion according to the situation. The inspection support system according to any one of claims 2 to 5.
The reference value is an inspection support system, which is a measurement result obtained by performing the same type of measurement as the selective measurement result on the inspection target different from the inspection target corresponding to the selective measurement result. The inspection support system according to claim 6.
The inspection target is a pile.
The measurement is an inspection support system including measurement of a motor current value during a work of rotating an excavating member by a motor to form a pile hole for installing the pile. The inspection support system according to claim 7.
The identification information includes an inspection support system including a pile number set for each pile. The inspection support system according to any one of claims 1 to 8.
The structure includes a plurality of said inspection objects that make the same type of measurement.
The map information data acquisition unit of the terminal device acquires the map information data corresponding to each inspection target, and obtains the map information data.
The identification information acquisition unit of the measuring device acquires position information indicating the measured position of the inspection target as the identification information, and obtains the position information indicating the measured position of the inspection target.
The map information data includes the coordinate information as the identification information, and includes the coordinate information.
The display control unit of the terminal device indicates the position closest to the coordinate information associated with the selected icon in response to the instruction receiving unit receiving the instruction to select the icon. An inspection support system for displaying the selected measurement result represented by the measurement result information including the above on the display. The inspection support system according to any one of claims 1 to 9.
The measurement is an inspection support system including measurement of the position of the inspection target. The inspection support system according to claim 10.
The terminal device further includes a reference value information acquisition unit that acquires reference value information representing a reference value for the selective measurement result.
The reference value information is information representing the reference position of the inspection target corresponding to the coordinate information.
The display control unit of the terminal device is an inspection support system that simultaneously displays the position of the inspection target and the reference position of the inspection target on the display. It is an inspection support device that supports the inspection of structures.
A drawing data acquisition unit that acquires drawing data representing a drawing of the structure, and a drawing data acquisition unit.
Represents identification information for identifying an inspection target in the structure, coordinate information indicating coordinates on a drawing of the structure corresponding to the inspection target identified by the identification information, and an icon associated with the identification information. A map information data acquisition unit that acquires map information data including icon information, and
A measurement result information acquisition unit that represents the measurement result obtained by measuring the inspection target and acquires the measurement result information including the identification information.
The instruction reception department that accepts instructions and
The drawing of the structure is displayed on the display based on the drawing data, and the icon is displayed at a position corresponding to the inspection target on the drawing of the structure based on the map information data. In response to the reception unit receiving the instruction to select the icon, the selection measurement result, which is the measurement result represented by the measurement result information including the identification information associated with the selected icon, is displayed on the display. Display control unit to make
Has an inspection support device.

Images