JP2012184939A - Sheet for detection work and underground radar system using sheet for detection work - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sheet for detection work with which a work load on an operator of an underground radar can be reduced at low cost, and an underground radar system using the sheet for detection work.SOLUTION: An underground radar 11 comprises an electromagnetic wave transmitting section which transmits electromagnetic waves toward underground and an electromagnetic wave receiving section which receives reflection waves of the transmitted electromagnetic waves. On a sheet member 2, measuring lines 5 for moving the underground radar 11 are drawn in a lattice shape. In at least one end of each of the measuring lines on the sheet member 2, a positional information medium 3 is provided which has positional information of that point. The positional information is read by a reading section 12 which is provided in the underground radar 11.

Description

  The present invention relates to a detection work sheet capable of reducing the work load of an operator of a ground penetrating radar and a ground penetrating radar system using the detection work sheet.

  In road construction or railway track improvement construction, for example, it may be performed with excavation work of concrete or the like. Prior to such excavation work, the state of burial of existing facilities such as gas pipes and power cables may be investigated to ensure work safety. Such an investigation of the burial condition is generally performed by an operator moving the underground radar and analyzing various data obtained.

  Here, as this kind of underground radar, there is one described in Patent Document 1, for example. The underground radar described in Patent Document 1 includes an electromagnetic wave transmission unit that transmits an electromagnetic wave toward the ground, and an electromagnetic wave reception unit that receives a reflected wave of the transmitted electromagnetic wave, and is received by the electromagnetic wave reception unit. It is the structure which detects the buried object buried in the ground by the received wave data etc. based on electromagnetic waves. In general, this type of ground penetrating radar, for example, reads the number of rotations of a wheel provided in the radar main body to measure the moving distance, and based on the obtained moving distance data and received wave data, Two-dimensional B-scope display image data is generated with the distance in the moving direction of the radar as the horizontal axis and the underground depth (time) as the vertical axis. When investigating the burial situation using such a general ground penetrating radar, the operator sets the measurement lines in a grid pattern in the survey area, and places the measurement lines in a grid pattern with chalk or the like on the road surface in the survey area. Draw and detect the buried object by moving the ground penetrating radar along each measurement line. At the time of this measurement, the operator makes a note of information that allows the user to know later on which measurement line the image data of the B scope display obtained for each measurement line. The operator then arranges the B scope display images in the order of measurement lines based on the recorded information, analyzes the embedded state of the embedded object, and marks the embedded position on the road surface etc. based on the already drawn measurement line. Or create a report with drawings, etc. depicting the location of buried objects. In this way, excavation workers and the like can identify the buried position of the buried object, and the safety of the excavation work is ensured.

JP 2010-151603 A

  However, conventionally, when investigating the burial situation using this type of underground radar, the operator draws a measurement line in a grid pattern on the road surface in the investigation area or moves the underground radar along each measurement line When operating, the B scope display image data obtained for each measurement line must be noted down to the location where the data on the measurement line is drawn. There is a problem that the workload of investigation work is high.

  By the way, using the GPS (Global Positioning System) or a laser ranging system that can measure the position with high accuracy by tracking a moving object, the position of the radar main body is known. If a ground penetrating radar system is constructed in which the positional information of the obtained ground penetrating radar and the image data of the B scope display are linked and stored, the operator can measure the image data and the measurement of the B scope display. It is considered that the work of associating the position of the line becomes unnecessary. However, when GPS is used, the accuracy of the obtained position information is about 1 meter. On the other hand, since the interval between the measurement lines is usually narrower than 1 meter, the GPS uses the position information to the ground penetrating radar. It is considered that the providing means is inferior in accuracy. Further, there is a problem that the laser ranging system is very expensive.

  Accordingly, the present invention pays attention to the above-mentioned problems, and provides a detection work sheet that can reduce the work load of an underground radar operator at a low cost, and a ground penetrating radar system using the detection work sheet. For the purpose.

  In order to achieve the above object, a detection work sheet according to the present invention includes an electromagnetic wave transmitting unit that transmits an electromagnetic wave toward the ground and an electromagnetic wave receiving unit that receives a reflected wave of the transmitted electromagnetic wave. A reading unit provided in the ground radar, comprising a position information medium having the position information of the point at least one end of each measurement line of the sheet member on which the measurement lines for moving the radar are drawn in a lattice shape The position information is read by the above.

  In order to achieve the above object, a ground penetrating radar system according to the present invention includes an electromagnetic wave transmitting unit that transmits an electromagnetic wave toward the ground, and an electromagnetic wave receiving unit that receives a reflected wave of the transmitted electromagnetic wave. A ground penetrating radar system that detects a buried object buried in the ground from received wave data based on the electromagnetic wave received by the electromagnetic wave receiving unit. The detection work sheet according to claim 1, a distance measuring unit attached to the ground radar and measuring a movement distance of the ground radar, and attached to the ground radar and provided on the detection work sheet A reading unit capable of reading the position information of the position information medium, and laying the detection work sheet in a detection area, moving the ground radar along the measurement line of the detection work sheet, Above A storage unit for storing the positional information read from the positional information medium by the reading unit, the received wave data based on the electromagnetic wave received by the electromagnetic wave receiving unit, and the movement distance data obtained by the distance measuring unit; Is provided.

  According to the detection work sheet of the present invention, the position information medium provided on at least one end of each measurement line drawn on the sheet member is used to obtain the position information of the point where the position information medium is provided, and the reading unit of the ground radar With the configuration of providing the information by reading the information, it is possible to provide the position information of the point where the position information medium is provided with a simple structure. Therefore, it is possible to provide the position information of the point where the position information medium is provided at a lower cost than the GPS or laser ranging system. Furthermore, the ground radar operator can use the measurement lines drawn in a grid pattern on the detection work sheet as a reference line for moving the ground radar. Thus, it is not necessary to draw measurement lines in a grid pattern. Of course, it is not necessary to delete the measurement line from the road surface.

  Further, according to the underground radar system of the present invention, the underground radar is moved along the measurement line, and at least the position information of one end of the measurement line, the received wave data, and the movement distance data are stored in association with each other. Therefore, it can be understood later where the image data of the B scope display generated based on the received wave data and the moving distance data obtained when the underground radar is moved is the data on the measurement line. There is no need to write down information. In this way, the workload of the underground radar operator can be reduced. Further, since the detection work sheet is used, position information can be obtained at low cost. In this way, it is possible to provide a detection work sheet and a ground radar system using this detection work sheet that can reduce the work load of the operator of the ground radar at a low cost.

It is a figure which shows 1st Embodiment of the sheet | seat for detection work by this invention, and is a top view. It is sectional drawing of the sheet | seat for detection work of the said embodiment. It is a figure explaining the operation | movement operation | work which investigates the burial condition of the underground buried object using the detection work sheet | seat of the said embodiment. It is sectional drawing which shows the KK line | wire cross section of FIG. It is a figure which shows the condition which moved the underground radar diagonally with respect to the measurement line. It is a figure which shows 2nd Embodiment of the sheet | seat for detection work, and is a top view. It is a figure which shows 3rd Embodiment of the sheet | seat for detection work, and is a top view. It is a schematic block diagram which shows one Embodiment of the underground radar system by this invention. It is a figure explaining the condition which detects an embedded object using the underground radar system of the said embodiment. It is the figure which showed each received waveform of the electromagnetic wave receiving part. It is a figure which shows the image display example of B scope display which a display part displays. It is a work flow figure showing the procedure which investigates the burial situation of the underground buried object using the underground radar system of the above-mentioned embodiment. It is an image figure which arranged each image of B scope display.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a detection work sheet according to the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a top view showing a first embodiment of a detection work sheet according to the present invention.
In FIG. 1, a detection work sheet 1 according to the present embodiment includes a sheet member 2 and a position information medium 3.

  The sheet member 2 is formed in a sheet shape, and lines are drawn in a lattice shape on the surface thereof. The grid-like line includes an electromagnetic wave transmitting unit that transmits an electromagnetic wave toward the ground and an electromagnetic wave receiving unit that receives a reflected wave of the transmitted electromagnetic wave, and detects a buried object 4 embedded in the ground. This is a measurement line 5 for the operator to move the middle radar 11 (see FIG. 3 etc.). The operator of the underground radar 11 moves the underground radar 11 along the measurement line 5. In the present embodiment, the sheet member 2 is transparent, for example, and is formed so that the outer edge has a quadrangular shape as shown in FIG. Each measurement line 5 is printed on the surface of the sheet member 2 with, for example, a line width of about 2 to 3 cm and an interval between the measurement lines 5 of about 20 to 50 cm. Note that the thickness of the sheet member 2 is exaggerated in FIG. 2 and FIGS. 4, 8, and 9, which will be described later. It is a thing. Further, when the sheet member 2 is transparent as in the present embodiment, for example, when the operator of the underground radar 11 lays the sheet member 2 in a detection area such as a road surface and performs measurement, the sheet member 2 passes through the transparent sheet member 2. You can see the road surface and other conditions. Therefore, when noise is added to the measurement data, the operator easily determines whether the noise is due to existing equipment provided on the road surface, such as irregular reflection by a manhole cover. be able to. The sheet member 2 is not limited to a transparent sheet member, and may be an opaque sheet member such as blue used for a curing sheet, for example.

  Moreover, when the sheet | seat member 2 is transparent like this embodiment, it is good to draw the measurement line 5 on the front and back of the transparent sheet | seat member 2 so that identification with a different color is possible. Accordingly, for example, when the underground state is investigated using the underground radar 11, when the sheet member 2 is used by being folded in accordance with the investigation area, the measurement line 5 is Since the colors are different, the operator can move the ground radar 11 along the measurement line without wondering which measurement line 5 is drawn on the table. In addition, although the measurement line 5 shall be printed, it is not restricted to this, You may form by sticking an adhesive tape on the surface of the sheet | seat member 2 in a grid | lattice form. In this case, in order to make the color of the measurement line 5 different between the front and back of the sheet member 2, for example, an adhesive tape having different colors on the surface and the adhesive surface is used, or tapes having different colors on the front and back of the sheet member 2. Or paste each of them.

  The position information medium 3 has position information of a point where the position information medium 3 is provided. As shown in FIG. 3 and FIG. 4 to be described later, this position information is configured to be read by a reading unit 12 that is attached to the ground radar 11 and configured by a communication unit capable of wireless communication. In the present embodiment, the position information medium 3 is provided at each intersection of the measurement lines 5. In the present embodiment, each position information medium 3 is a wireless medium such as an IC chip configured to be able to read position information wirelessly. The position information is provided by causing the reading unit 12 to read the position information when the reading unit 12 is in close proximity to each position information medium 3 made of a wireless medium. Here, the position information is, for example, information indicating a position in a two-dimensional coordinate system set in advance on the sheet member 2 by an address (α, β), and specifically, for example, as shown in FIG. In this way, the α direction is represented by alphabets, and the β direction orthogonal to the α direction is represented by numerals.

  Next, using the detection work sheet 1 configured as described above, an operation in which the operator investigates the burial condition of the buried object buried in the ground is used as the buried object 4 and two pipes are embedded in parallel. An example of investigating the detected detection area will be briefly described with reference to FIGS. In the following description, it is assumed that it is known whether the buried object 4 is extended and buried in the β direction shown in FIG. 3 before the survey, and the underground radar 11 is placed in the α direction within the detection area. A description will be given of a case where detection is performed by moving along the measurement line 5.

  First, the detection work sheet 1 is laid in the detection area so that, for example, the measurement line 5 in the β direction and the extending direction of the embedded object 4 are parallel to each other. Next, the underground radar 11 is moved along the measurement line 5 in the α direction. For example, in FIG. 3, when the underground radar 11 is moved in the α direction from one end to the other end along the fifth measurement line 5 from the bottom in the β direction, each position information medium 3 is When the reading unit 12 attached to the middle radar 11 approaches, the address (α, β) of the two-dimensional coordinate system is provided as position information. At this time, the position information obtained by the reading unit 12 is (A, 5), (B, 5), (C, 5)... (J, 5). At this time, the subsurface radar 11 can determine where the data obtained when the measurement is performed along the measurement line 5 is the data on the measurement line 5. The data obtained above and the position information of the measurement line 5 are stored in association with each other. The position information of the measurement line 5 is information indicated by addresses on the two-dimensional coordinates of the start and end of the measurement line 5, and is, for example, drawn in the α direction, the fifth from the bottom in the β direction as described above. In the case of the measurement line 5, the position information of the measurement line 5 is (A-5 to J-5).

  With this configuration, the detection work sheet 1 according to the present embodiment has the position of the point where the position information medium 3 is provided by the position information medium 3 provided at the intersection of the measurement lines 5 drawn on the sheet member 2. By adopting a configuration in which information is provided to the reading unit 12, position information can be provided with a simple structure. Therefore, position information can be provided at a lower cost than GPS and laser ranging systems. Furthermore, the operator of the ground penetrating radar 11 may use the measuring line 5 drawn in a grid pattern on the sheet member 2 of the detection work sheet 1 as a measuring line that becomes a guide when moving the ground penetrating radar 11. This eliminates the need to draw a measurement line on the road surface in the survey area. Of course, it is not necessary to delete the measurement line from the road surface. In this way, it is possible to provide the detection work sheet 1 that can reduce the workload of the operator of the ground radar 11 at a low cost.

  In the above-described embodiment, the position information medium 3 has been described as a wireless medium that allows the position information to be read by the reading unit 12 wirelessly. For example, it may be a one-dimensional barcode printed or a one-dimensional printed pattern (for example, QR code (registered trademark)). In this case, the reading unit 12 is not configured by a communication unit capable of wireless communication, but is configured by, for example, a CCD camera or the like so that position information can be optically read. With this configuration, the position information medium 3 can be easily provided by printing, and therefore the position information medium 3 can be provided at a lower cost than a wireless medium.

  Normally, the ground radar 11 is moved and operated along the measurement line 5, but as shown in FIG. 5, the ground radar 11 is moved and operated in one oblique direction with respect to the measurement line 5. There is also a case. In this case, it is necessary to know in which direction the data stored in the underground radar 11 is the data when the underground radar 11 is specifically moved and operated. For example, when the position information medium 3 is printed in a two-dimensionally coded pattern (for example, QR code (registered trademark)), the orientation of the pattern read by the reading unit 12 constituted by a CCD camera or the like is set. Based on this, information on the moving direction of the ground radar 11 is generated, and this direction information and each data are associated with each other and stored in the ground radar 11. In this case, the direction information of the underground radar 11 can be provided only by passing through the vicinity of at least one position information medium 3. Further, when the position information medium 3 is composed of the above-described wireless medium, for example, position information obtained at two or more positions obtained at the time of measurement in one oblique direction (for example, obtained at the beginning and the end). Information on the movement direction of the ground radar 11 is generated based on the position information), and the direction information and each data are associated with each other and stored in the ground radar 11.

  In the above-described embodiment, the position information medium 3 has been described in the case where it is provided at each intersection of the measurement lines 5. However, the present invention is not limited thereto, and may be provided between the intersections. It is good also as a structure provided only in the end of each measurement line 5, and is good also as a structure provided only in the both ends of each measurement line 5. FIG.

  When the position information medium 3 is also provided between the intersections of the measurement lines 5, for example, by providing a plurality of positions between the intersections, the position information can be densely provided to the reading unit 12 of the ground radar 11. .

  When the position information medium 3 is simply provided at one end of each measurement line 5 of the sheet member 2 as in the second embodiment shown in FIG. 6 and the third embodiment shown in FIG. 11 is normally moved along the measurement line 5 from one end side to the other end side of each measurement line 5 and performs a single measurement operation. For the purpose of associating whether the data is moved when moving along the line 5, it is sufficient to provide it at one end of each measurement line 5.

  Further, as shown in FIG. 6, when the position information medium 3 is provided, for example, the position information medium 3 provided at one end of each measurement line 5 on the ground radar 11 side is measured start information on each measurement line 5. 6, after the measurement on the single measurement line 5 is finished, as shown by the white arrow in FIG. The underground radar 11 can be moved to the front of the measurement line 5. Therefore, as shown in FIG. 7, compared to the case where the movement operation direction at the time of measurement of the ground penetrating radar 11 is the same, after the measurement on the single measurement line 5 is finished, before the beginning of the next measurement line 5. It is possible to reduce the distance for moving the underground radar 11 to the maximum.

  In addition, as shown in FIG. 7, when the position information medium 3 is provided only at one end on the same side of the sheet member 2, for example, the detection area is a sidewalk parallel to the road, and a curb or This is useful when there are obstacles such as planting. In such a detection area, when the underground radar 11 is moved and operated in a direction orthogonal to the road, the obstacle becomes an obstacle, and after the measurement on the single measurement line 5 is completed, the above-described FIG. As described above, it is difficult to reverse the ground radar 11 and move the ground radar 11 to the position before the beginning of the next measurement line 5. Accordingly, in such a detection area, the position information medium 3 is provided at one end on the same side of the sheet member 2 in the measurement line 5 in the direction orthogonal to the road. Can be used to provide information on the start of measurement on each measurement line 5. In this case, the movement operation at the time of measurement of the underground radar 11 is in one direction as shown by the white arrow in FIG.

Although not shown, in the case of a configuration in which the position information medium 3 is provided only at both ends of each measurement line 5,
The position information medium 3 can also be used to provide information on the start and end of measurement on a single measurement line 5.

Next, an embodiment of the ground radar system according to the present invention will be described in detail with reference to the accompanying drawings.
FIG. 8 is a schematic configuration diagram of the underground radar system 10 of the present embodiment, and is a configuration using the detection work sheet 1 shown in FIG. 1 described above.
In FIG. 8, the underground radar system 10 of the present embodiment is configured to include a detection work sheet 1 and an underground radar 11, and the underground radar 11 includes a reading unit 12, an electromagnetic wave transmitting unit 13, The electromagnetic wave receiving unit 14, the distance measuring unit 15, the signal processing unit 16, the storage unit 17, and the display unit 18 are provided.

  The ground radar 11 includes the electromagnetic wave transmission unit 13 and the electromagnetic wave reception unit 14 as described above, and transmits the electromagnetic wave toward the ground by the electromagnetic wave transmission unit 13 and is based on the electromagnetic wave received by the electromagnetic wave reception unit 14. From the received wave data, it becomes a main body that detects the burial status of the buried object 4 buried in the ground. As shown in FIG. 8, the ground radar 11 has wheels 20 attached to the bottom thereof. As shown in FIG. 9, a handle is attached to the upper part of the underground radar 11 and the like so that the underground radar 11 can be easily moved by an operator or the like. At this time, the measurement line 5 drawn in a lattice shape becomes a measurement line as a guide when the operator moves the underground radar 11. Further, the embedded object 4 is, for example, a metal tube, a vinyl chloride tube, or the like, and is extended and embedded in a direction (vertical direction in the drawing) perpendicular to the moving direction of the underground radar 11 as shown in FIG. In some cases, there are various cases, such as a case where the wire is extended or embedded in a direction parallel to the moving direction although not shown.

  The reading unit 12 lays the detection work sheet 1 in the detection area, moves the ground radar 11 along the measurement line 5 of the detection work sheet 1, and moves the position from the position information medium 3 that is a wireless medium. The communication unit is configured to be able to read information wirelessly. The reading unit 12 is provided, for example, at the front of the underground radar 11 and at the approximate center of the underground radar 11 (see FIGS. 3 and 5). The reading unit 12 can appropriately set a range in which position information can be read (a range in which radio can be received), and a position information medium in the immediate vicinity of the reading unit 12 can be set by narrowing the readable range. The position information can be read only from 3. Further, the position information read by the reading unit 12 is stored in the storage unit 17 in association with received wave data and movement distance data, as will be described later.

  As shown in FIG. 8, the electromagnetic wave transmission unit 13 transmits an electromagnetic wave (transmission wave) toward the ground. The electromagnetic wave generation unit 21 that generates an electromagnetic wave, and the electromagnetic wave generated from the electromagnetic wave generation unit 21 A transmission wave amplifier 22 that amplifies the output and a transmission antenna 23 that transmits the amplified electromagnetic wave toward the ground are provided.

  The electromagnetic wave receiving unit 14 receives an electromagnetic wave (received wave) reflected based on the transmitted electromagnetic wave (transmitted wave) and amplifies the output. As shown in FIG. A reception antenna 24 for receiving and a reception wave amplifier 25 for amplifying the output of the received electromagnetic wave are provided.

  The distance measuring unit 15 measures the movement distance of the ground penetrating radar 11. For example, the distance measuring unit 15 reads the rotational speed of the wheels 20 provided in the ground penetrating radar 11 to measure the moving distance of the ground penetrating radar 11. For example, the travel distance data is output to the storage unit 17. The movement distance data is stored in the storage unit 17 in association with the received wave data and the position information. In the present embodiment, the distance measuring unit 15 starts measuring the moving distance from the place where the underground radar 11 is located (below the receiving antenna 24) when the operator presses a measurement start switch or the like. It is configured as follows.

  The signal processing unit 16 is a general unit that processes a signal output from the reception wave amplifier 25. Although not shown, the signal processing unit 16 includes, for example, a waveform processing unit that removes harmonic noise of the reception wave. The received wave data of the received wave processed by the signal processing unit 16 includes the movement distance data of the underground radar 11 obtained by the distance measuring unit 15 when the received wave is received, and the position information read by the reading unit 12. The data are stored in the storage unit 17 in association with each other.

  Here, for example, FIG. 9 is unknown about the exact burying position of the buried object 4 such as piping, but in a place where it is known in advance that the buried object 4 is stretched in the vertical direction of the drawing. This represents a situation in which the underground radar 11 is moved along the measurement line 5 in a direction orthogonal to the embedded object 4 to detect the embedded object 4. FIG. 10 shows the waveform of the reflected wave received at each position by the receiving antenna 24 when the electromagnetic wave is transmitted from the electromagnetic wave transmission unit 13 at a plurality of positions on the same measurement line 5 in the situation of FIG. It is the figure which time-shifted the transmission time of the transmission wave in the position as the start of time, and displayed the waveform of the reception wave in each position. The vertical axis in FIG. 10 represents the delay time from when the electromagnetic wave is transmitted until the reflected wave is received. The lower the value is, the longer the delay time is, and the longer the distance between the antenna and the embedded object 4 is, The further you go, the shorter the delay time and the closer the distance. As shown by a broken line in FIG. 10, when the distance between the antenna and the embedded object 4 gradually decreases and then increases, it indicates that the closest distance is directly above the embedded object 4. Since the movement distance of the underground radar 11 on the measurement line 5 in the detection area at the time is measured by the distance measuring unit 15, the position directly above the buried object 4, that is, the buried position can be known. The distance at which the distance is closest indicates the embedment depth from the ground surface of the embedment 4. Therefore, when the rough arrangement direction of the buried object 4 is known in advance, the accurate buried position and the buried depth of the buried object 4 can be detected by moving the ground radar 11 so as to cross the buried object 4 and detecting it. Can be specified.

  In FIG. 9, the underground radar 11 is placed on the measurement line 5 in the direction orthogonal to the buried object 4 in a place where it is known in advance in which direction the buried object 4 such as piping is extended and buried. Although the case where it moves along was demonstrated, generally it may not be understood in what direction the embedded object 4 is extended | stretched and embedded. In such a case, in order to specify the exact burying position of the buried object 4, the underground radar 11 is moved along each measurement line 5 drawn in two orthogonal directions, so that the It is preferable to detect the buried object 4 so that the underground radar 11 crosses the buried object 4.

  The storage unit 17 lays the detection work sheet 1 in the detection area and moves the ground radar 11 along the measurement line 5 of the detection work sheet 1 to detect the buried object 4. 12, the positional information read from the positional information medium 3 by 12, the received wave data based on the electromagnetic wave received by the electromagnetic wave receiving unit 14, and the movement distance data obtained by the distance measuring unit 15 are stored in association with each other. In the present embodiment, as will be described later, the storage unit 17 uses the display unit 18 to measure the position of the two-dimensional B-scope display image data generated for each measurement performed along each measurement line 5. The image data on the B scope and the positional information on the measurement line 5 are associated with each other and stored so that the data on the line 5 can be understood later. The position information of the measurement line 5 is information indicated by addresses on the two-dimensional coordinates of the start end and the end of the measurement line 5, and is, for example, the fifth measurement line 5 drawn in the α direction from the bottom in the β direction. In this case, the position information of the measurement line 5 is (A-5 to J-5).

  The display unit 18 displays an image of the detection result of the buried object 4 and the like. When the display unit 18 moves the ground radar 11 in one direction along the single measurement line 5 and transmits the electromagnetic wave from the electromagnetic wave transmission unit 13 at a plurality of positions, the reception antenna 24 receives the signal at each position. The reception wave data of the electromagnetic wave is read from the storage unit 17, the time data in the reception wave data is shifted with the transmission time of the transmission wave at each position as the start of time, the reception intensity is displayed in shades, and each reception General B scope display image data that has been position-shifted (shifted in the moving direction of the ground penetrating radar 11) based on the moving distance data stored in the storage unit 17 in association with the wave data is converted into a single measurement line. 5 for each measurement performed along the line 5. The display unit 18 displays an image of the detection result of the embedded object 4 along each measurement line 5 based on the image data. Here, FIG. 11 is a diagram illustrating an image display example of B scope display displayed on the display unit 18 when the underground radar 11 is moved so as to cross the embedded object 4, as in FIG. 9. . In FIG. 11, the horizontal axis indicates the distance in the moving direction of the underground radar 11, and the vertical axis indicates the underground depth (time). In FIG. 11, for simplification of the drawing, only the portion with the highest reception intensity at each position is displayed and the other portions are omitted.

  Next, using the underground radar system 10 configured as described above, the burial status of the buried object 4 is investigated, and the flow of work for excavating the road surface and the operation of the underground radar system 10 are shown in FIG. As shown in FIG. 4, as an example of investigating the inside of a detection area in which two pipes are buried in parallel as the buried object 4, with reference to FIGS. 3, 4, 12 and 13 in detail. explain. In the following description, it is assumed that the buried object 4 is extended and buried in the β direction shown in FIG. 3 before the investigation, and the underground radar 11 is placed in the α direction within the detection area. A description will be given of a case where detection is performed by moving along each measurement line 5.

  First, as shown in FIGS. 3 and 4, the operator lays the detection work sheet 1 so as to cover the entire detection area (STEP 1).

  Next, the operator, for example, from the start end of one side of the measurement line 5 whose start address is (A, 1) and end address is (J, 1) (hereinafter referred to as (A-1 to J-1). The ground radar 11 is arranged so as to be movable along the line), and the ground radar 11 is turned on. When the measurement preparation is completed, the operator, for example, presses a measurement start switch or the like to start the transmission of the electromagnetic wave from the electromagnetic wave transmission unit 13 and also starts the movement distance measurement operation by the distance measurement unit 15. The underground radar 11 is pushed in one direction (the direction of arrow α in FIG. 10) along the line 1 to J-1) and moved to the end of the line (A-1 to J-1). During this movement, the electromagnetic wave transmission unit 13 transmits the electromagnetic wave toward the ground at a plurality of positions, and the electromagnetic wave reception unit 14 is reflected based on the electromagnetic wave (transmission wave) transmitted from the electromagnetic wave transmission unit 13. An electromagnetic wave (received wave) is received at each position, and a signal of each received wave is output to the signal processing unit 16. The signal processing unit 16 removes harmonic noise in the received wave signal and outputs the received wave signal after noise removal to the storage unit 17 as received wave data. The received wave data is stored in association with the moving distance data obtained by the distance measuring unit 15 when received and the position information obtained by the reading unit 12. It should be noted that the reading unit 12 is appropriately set in a readable range so that the position information can be obtained only when the underground radar 11 is located in the vicinity of the position information medium 3. Accordingly, when the received wave data is obtained by receiving the electromagnetic wave, if the position information medium 3 is not in the vicinity of the ground penetrating radar 11, the storage unit 17 simply stores the received wave data and the movement distance data in association with each other. To do. When the ground radar 11 reaches the end of the line (A-1 to J-1), the operator presses a measurement interruption switch or the like, for example, and starts the next measurement line 5, for example, (A-2 to J-2) Arrange the underground radar 11 so that it can move along the line (A-2 to J-2) from the beginning of the line, and perform the same measurement as on the line (A-1 to J-1). taking measurement. Thereafter, the measurement on each measurement line (A-3 to J-3, A-4 to J-4,... A-10 to J-10) is similarly performed (STEP 2).

  Here, the display unit 18 generates B-scope display image data for each measurement performed along the measurement line 5, and the storage unit 17 stores the B-scope display image data and the position information of the measurement line 5. (For example, in the case of the fifth measurement line 5 from the bottom in the β direction, (A-5 to J-5)) is stored in association with each other. The display unit 18 displays an image of the detection result of the embedded object 4 on each measurement line 5 based on the image data. This B-scope display image is printed via, for example, an external printer. Then, the operator arranges the printed images of the respective B scopes by arranging them in the order in which the actual measurement lines 5 are drawn, based on the position information of the respective measurement lines 5, as shown in FIG. The detection result is analyzed and the burying position of the buried object 4 is specified (STEP 3).

  When the analysis of the detection result (specification of the embedded position) is completed as described above, the operator, for example, a reference object (for example, a reference for the positional relationship between the position where the detection work sheet 1 is laid and the detection area) Vending machine, etc.), and the positional relationship between the reference object and the detection work sheet 1 is recorded, then the detection work sheet 1 is removed, and a drawing or the like depicting the embedded position of the embedded object with reference to the reference object is attached. Create a completed report. Then, based on the report, the excavation worker marks the buried position on the excavation area with chalk or the like (STEP 4). Finally, the excavation operator confirms the embedment position of the embedded object 4 based on the marks drawn on the road surface or the like, and performs the excavation work so as not to damage the embedded object 4 (STEP 5). When the burial status investigation work and excavation work are performed as a series of work, the operator may mark the burial position on the excavation area with chalk or the like based on the detection result.

  With such a configuration, according to the underground radar system 10 in the present embodiment, when detecting the buried object 4 by moving the underground radar 11 along the measurement line 5, the positional information and reception of the measurement line 5 are received. Since the wave data and the movement distance data can be stored in association with each other, where is the B-scope display image data generated based on the received wave data and the movement distance data obtained when the underground radar 11 is moved and operated? It is not necessary to make a note of information that can later be understood whether the data is on the line at the position of. Moreover, since it is the structure using the detection work sheet | seat 1, position information can be obtained at low cost. In this way, it is possible to provide the underground radar system 10 that can reduce the operator's workload at a low cost.

  In the above embodiment, the moving distance measuring unit 15 starts measuring the moving distance starting from the place where the underground radar 11 is located (below the receiving antenna 24) when the measurement start switch or the like is pressed by the operator. However, the present invention is not limited to this, and when the underground radar 11 is moved, the measurement of the movement distance is started with the position based on the position information first read by the reading unit 12 as the starting point. Also good. In this case, for example, when the position information on both ends of each measurement line 5 is stored in advance in the reading unit 12 and the position information on the other end is read after the position information on one end is read, It is preferable that the operator can be notified of the end of the measurement on the measurement line 5. Thereby, useless moving operation can be reduced. As described above, the position information medium 3 provided at both ends of each measurement line 5 may be used as information for starting and ending each measurement.

  In the above embodiment, the ground radar system 10 has been described in the case where the detection work sheet 1 of the first embodiment shown in FIG. 1 is applied. However, the present invention is not limited to this, and any of the configurations described above can be used. The detection work sheet 1 can also be applied.

DESCRIPTION OF SYMBOLS 1 Detection work sheet | seat 2 Sheet | seat member 3 Position information medium 4 Embedded object 5 Measuring line 10 Underground radar system 11 Underground radar 12 Reading part 13 Electromagnetic wave transmission part 14 Electromagnetic wave reception part 15 Distance measurement part 17 Storage part

Claims (11)

  A sheet member in which measurement lines for moving an underground radar including an electromagnetic wave transmission unit for transmitting an electromagnetic wave toward the ground and an electromagnetic wave reception unit for receiving a reflected wave of the transmitted electromagnetic wave are drawn in a lattice shape The position information medium having the position information of the point is provided at at least one end of each measurement line, and the position information is read by the reading unit provided in the ground penetrating radar. Detection work sheet.   The detection work sheet according to claim 1, wherein the position information medium is provided only at one end of the same side of the sheet member.   The detection work sheet according to claim 1, wherein the position information medium is provided at both ends of each measurement line.   The detection work sheet according to claim 1, wherein the position information medium is provided at each intersection of the measurement lines.   The detection work sheet according to claim 4, wherein the position information medium is also provided between intersections of the measurement lines.   6. The detection work sheet according to claim 1, wherein the position information medium is printed so that the position information can be optically read by the reading unit.   The detection work sheet according to claim 6, wherein the position information medium is printed with a pattern in which the position information is two-dimensionally encoded.   6. The detection work sheet according to claim 1, wherein the position information medium is a wireless medium capable of reading the position information wirelessly.   The sheet for detection work according to claim 1, wherein the sheet member is transparent.   The detection work sheet according to claim 9, wherein the measurement line is drawn on the front and back of the transparent sheet member so as to be distinguishable with different colors. An electromagnetic wave transmission unit that transmits an electromagnetic wave toward the ground and an electromagnetic wave reception unit that receives a reflected wave of the transmitted electromagnetic wave, and is based on the electromagnetic wave received by the electromagnetic wave reception unit A ground penetrating radar system that detects buried objects buried in the ground from received wave data,
The detection work sheet according to any one of claims 1 to 10,
A distance measuring unit attached to the ground penetrating radar and measuring a moving distance of the ground penetrating radar;
A reading unit attached to the subsurface radar and capable of reading the position information of the position information medium provided on the detection work sheet;
Positioning the detection work sheet in a detection area, moving the ground radar along the measurement line of the detection work sheet, the position information read from the position information medium by the reading unit, and A storage unit that stores the received wave data based on the electromagnetic wave received by the electromagnetic wave receiving unit and the movement distance data obtained by the distance measuring unit in association with each other,
A ground penetrating radar system characterized by comprising: