JP6461335B2 - Core collection device, boring device and core collection method - Google Patents

Description

  The present invention relates to a core collection device that collects a core from the ground, a boring device, and a core collection method.

  When collecting a core from the ground as a geological survey material, a core barrel (core collecting device) is connected to the rod, and a boring device is used to collect the core in the core barrel while rotating and raising and lowering the rod and the core barrel (for example, patents) Reference 1).

  When the core is collected in a place where the ground is dense, the boring apparatus can collect a core that accurately reflects the ground. However, when the core is sampled where there is a gap in the ground, the core located on the lower side of the gap is pushed upward as the ground is excavated in the core barrel, and the core located on the upper side of the gap. As a result, the void disappears, so it is impossible to collect a core that accurately reflects the ground. Moreover, in the said boring apparatus, it cannot be judged whether the core which reflected the ground accurately was collected.

JP 2001-323771 A

  An object of the present invention is to provide a core collection device capable of acquiring data for examining the accuracy of a collected core, a boring device using the same, and a core collection method.

  The core collecting device is detachable from one end of the rod of the boring device, and has a tubular core barrel having a core collecting unit for collecting a core of the ground, and a first core for measuring the displacement of the core entering the core collecting unit. A displacement meter.

  In the core sampling apparatus, the first displacement meter is a wire type displacement meter in which the wire advances and retreats in a direction substantially parallel to the axis of the core barrel at the core sampling unit, and a contact portion with which the core contacts is provided at the tip of the wire. May be.

  The boring device is capable of transmitting a measurement signal measured by a displacement meter to an information processing device, and is connected to one end of the rod and a tubular core barrel having a core collecting unit for collecting a core of the ground inside, A first displacement meter that measures the displacement of the core that enters the core collection unit, a boring device body that rotates the rod about its axis and advances and retreats in the axial direction, and the advance and retreat of the rod A second displacement meter that measures the displacement of the first displacement meter, a first transmitter for transmitting the measurement signal of the first displacement meter to the information processing device, and a measurement signal of the second displacement meter transmitted to the information processing device A second transmission unit for performing the operation.

The boring device is configured such that a core barrel is connected to one end of a rod with a tubular outer tube, spaced from the outer tube, coaxially arranged in the outer tube, and externally connected to the outer tube via the connecting rod so as not to rotate. A double core barrel connected to the tube and having a tubular inner tube that serves as a core collecting portion, the first displacement meter is provided in the inner tube, the rod is tubular, and has a space inside. And the first transmission unit electrically connects the cable , the rotating body and the non-rotating body, and the second rotating connector which electrically connects the rotating body and the non-rotating body. And may be provided.
In this case, one end of the cable is connected to the first displacement meter, passes through the core barrel and the rod, extends to the outside of the rod, and the other end can be connected to the information processing apparatus. Some of the cables are fixed to one or both of the core barrel and the rod, and rotate with the rotation of the rod. The cables other than some cables do not rotate with the rotation of the rod. Some are connected to a displacement meter and some can be connected to an information processing device that does not rotate with the rotation of the rod. Some cables and the cable connected to the first displacement meter are connected via the first rotation connector. A part of the cables and a cable connectable to the information processing apparatus are connected via the second rotary connector.

The core collecting method is connected to one end of a rod of a boring device, and rotates and advances and retracts a tubular core barrel having a core collecting part that becomes a space for collecting a core of the ground, and collects the core in the core collecting part a step of measuring the displacement of the reciprocating rod when the core displacement and coring entering the core adoption isolation portion, and the step of obtaining the entry length of the core that enters from the displacement of the core to the coring unit, reciprocating rods And a step of determining the advance / retreat distance of the rod from the displacement, and a step of comparing the approach length of the core and the length of the advance / retreat distance of the rod.

  According to the core sampling device and the boring device including the core sampling device, the accuracy of the sampled core is determined by including the first displacement meter that measures the displacement of the core or the second displacement meter that measures the displacement of the core and the rod. As data for this, it is possible to measure the displacement of the core or the displacement of the rod and the advancement and retraction of the rod. In addition, the core displacement (displacement of the core tip) or the core entry length that has entered the core barrel can be grasped in real time, so the core collection status can be confirmed while the core is being collected, It is also possible to determine the accuracy of.

  Further, according to the core collection method, the accuracy of the collected core can be determined.

It is a partial longitudinal cross-sectional view which shows a core collection apparatus. It is the II-II line end view of FIG. It is a schematic diagram which shows a boring apparatus. It is a front view which shows a rod. It is a partial longitudinal cross-sectional view which shows the state before connection of a core collection apparatus, a rod body, and a cable body. FIG. 6 is an end view taken along line VI-VI in FIG. 5. It is a partial longitudinal cross-sectional view which expands and shows the 1st rotation connector periphery. It is a front view which expands and shows the 2nd rotation connector periphery. It is a partial longitudinal cross-sectional view which shows the mode of the extraction | collection of the core by a boring apparatus.

Hereinafter, a core collection device, a boring device, and a core collection method according to an embodiment of the present invention will be described.
1 and 2 show a core collection device 1 according to an embodiment of the present invention. The core collecting device 1 includes a core barrel 3 and a first displacement meter 40.

  The core barrel 3 is a so-called double core barrel, and includes an outer tube 10 and an inner tube 20.

  The outer tube 10 includes an outer tube main body 12, an outer tube head 14, and a bit 16. The outer tube body 12 has a tubular shape. The outer tube head 14 is attached to the upper end of the outer tube body 12 and closes the upper opening of the outer tube body 12. One end of a rod 50 (rod body 52), which will be described later, is connected to the outer tube head. The rod 50 connected to the outer tube head 14 is coaxial with the outer tube main body 12. The outer tube head 14 and the rod 50 are detachable by a male screw provided on one side and a female screw provided on the other side. The outer tube head 14 is provided with a first guiding channel 32 through which the fluid F flows, and connects a second guiding channel 34 described later and the inside of the rod 50. The bit 16 is for excavating the ground G, and has an annular shape and is attached to the tip (lower end) of the outer tube main body 12. The outer tube 10 rotates as the rod 50 rotates.

  The inner tube 20 includes an inner tube main body 21 and an inner tube head 23. The inner tube main body 21 is tubular in shape. The inner tube main body 21 is coaxial with the outer tube main body 12 and maintains a distance from the outer tube 10 in order to provide a second guide channel 34 that is a channel through which the fluid F flows. Are arranged in the outer tube 10. The space inside the inner pipe main body 21 is a core collecting unit 22 from which the core C cut out from the ground G is collected. The fluid F that has sequentially flowed through the rod 50, the first guide channel 32, and the second guide channel 34 is discharged from the lower end of the core barrel 3. The first guide channel 32 and the second guide channel 34 correspond to the guide channel 30. The inner tube head 23 is attached to the upper end of the inner tube body 21 and closes the upper opening of the inner tube body 21. The inner tube head 23 is suspended from the outer tube head 14 via a connecting rod 24. The inner pipe head 23 is connected to the connecting rod 24 via a bearing 25. Therefore, the inner tube 20 does not rotate with the rotation of the rod 50 and the outer tube 10.

  The core barrel 3 may be other than a double core barrel such as a single core barrel.

  The first displacement meter 40 is for measuring the displacement of the core C entering the core collection unit 22, and is attached to the upper side of the inner tube main body 21. Here, the displacement of the core C means the displacement of the core C entering the inside of the inner tube main body 21 in the vertical direction (direction parallel to the axis of the inner tube main body 21).

  In the present embodiment, as the first displacement meter 40, a wire displacement meter that detects the advance / retreat of the wire 41 with a potentiometer is used. The wire 41 advances and retreats in the vertical direction (a direction parallel to the axis of the inner tube main body 21) inside the inner tube main body 21.

  The first displacement meter 40 includes a contact portion 42 at the tip of the wire 41 in order to ensure that the wire 41 follows the displacement of the core C entering the inside of the inner tube main body 21. The contact part 42 includes a contact part main body 43, a pressing part 44, and an anti-slip part 45. The contact portion main body 43 is a cylindrical shape having a slightly smaller diameter than the inner tube main body 21 and is made of metal. The contact portion main body 43 is arranged coaxially with the inner pipe main body 21 inside the inner pipe main body 21. The pressing portion 44 is a plate or sheet made of rubber or resin, the contact portion 42 presses the inner surface of the inner tube main body 21, and the contact portion 42 moves in the axial direction inside the inner tube main body 21. It is provided in the side periphery of the contact part main body 43 so that it may become possible. The anti-slip portion 45 is a plate or sheet made of rubber or resin, and is provided on the lower surface of the contact portion main body 43. The contact portion 42 moves in the vertical direction when a predetermined external force is applied in the vertical direction.

In the first displacement meter 40, when the core C enters the core sampling part 22, the tip end surface (upper end face) of the core C comes into contact with the contact part 42, and the contact part 42 is pushed up by the core C. The wire 41 is retracted. Thereby, the first displacement meter 40 measures the displacement of the front end surface (upper end surface) of the core C as the displacement of the core C.
When the contact portion 42 is pushed up by the core C by pressing the inner tube main body 21, the contact portion 42 also functions as a resistance to the core C. Therefore, the disturbance of the core C is suppressed, and a high-quality core C can be collected. . Further, by providing the contact portion 42 with the anti-slip portion 45, the disturbance of the upper end of the core C can be further suppressed, so that a higher quality core C can be collected.

  A water absorbing material 46 such as a polymer water absorbing material may be disposed on the contact portion 42. If it does in this way, since the water absorption material 46 absorbs fluids, such as the water which approachs into the core collection part 22, the damage of the 1st displacement meter 40 by a fluid can be prevented.

  The first displacement meter 40 may be any device as long as it can measure the displacement of the core C entering the core collection unit 22, such as a laser displacement meter. Further, the contact part 42 may be provided only with the contact part main body 43.

  Next, a boring apparatus according to an embodiment of the present invention will be described. FIG. 3 shows a boring device. The boring device includes the core collecting device 1, the rod 50, the boring device main body 70, the storage unit 80, the water supply channel 82, the first transmission unit, the information processing device 130, and the second displacement meter 140. And a second transmission unit. Regarding the core collection device 1, the description of the above part is omitted.

The rod 50 is formed by connecting a plurality of rod bodies 52 in the longitudinal direction. As shown in FIGS. 4 and 5, the rod body 52 is tubular and has a male screw 54 at one end and a female screw 56 that can be fastened to the male screw 54 at the other end. The rod body 52 is connected by fastening the male screw 54 of one rod body 52 to the female screw 56 of the other rod body 52.
The boring device can extend the length of the rod 50 and increase the depth of excavation by adding the rod body 52 to the rod 50.
The rod 50 may be composed of a single rod body 52.

  The core collecting device 1 is connected to the lower end of the rod 50.

  Inside the rod body 52, a cable fixing portion 60 for fixing a cable body 92 described later is provided. As shown in FIG. 6, the cable fixing portion 60 includes an outer frame portion 62, a fixing portion 64, and a support portion 66. The outer frame portion 62 has an annular shape, and is fixed to the rod body 52 with its outer peripheral surface being in contact with the inner surface of the rod body 52. The fixing portion 64 is located at the center of the outer frame portion 62 and is connected to the outer frame portion 62 by a plurality of support portions 66. The fixing portion 64 is provided with a through hole 67 through which the cable body 92 is passed. In the cable fixing portion 60, a portion surrounded by the outer frame portion 62, the support portion 66, and the fixing portion 64 is a space (hole). Due to this space, the fluid F flows in the rod body 52 without being blocked by the cable fixing portion 60.

  The boring device main body 70 supports the rod 50 so that its axis is substantially parallel to the vertical direction. The boring device main body 70 includes a drive device 72 that rotates the rod 50 about its axis and advances and retracts in the vertical direction (the axial direction of the rod 50).

The storage unit 80 stores fluid F such as water therein. The interior of the reservoir 80 is connected to the interior of the rod 50 by a water supply channel 82. The water supply path 82 is connected to the upper end of the rod 50 via a swivel 83 so as not to rotate with the rotation of the rod 50. The water supply path 82 is provided with a pump 84 as an advection device for advancing the fluid F.
The fluid F in the reservoir 80 is discharged from the tip (lower end) of the core barrel 3 by the pump 84 through the water supply channel 82, the rod 50, and the conduit 30 of the core collection device 1.

  The first transmission unit is for transmitting the measurement signal measured by the first displacement meter 40 to the information processing apparatus 130. The first transmission unit may be wired or wireless, but in the present embodiment, the first transmission unit includes a wired cable 90, the first rotary connector 100, and the second rotary connector 110. Has been.

The cable 90 is configured by connecting a plurality of cable bodies 92 capable of transmitting a displacement meter measurement signal. The cable body 92 is provided in the core collecting device 1 and all the rod bodies 52. The cable body 92 is also provided on the outside of the rod 50 on the ground as a connection between the cable 90 of the rod body 52 and the information processing apparatus 130. Of the cable bodies 92, those connected to adjacent cable bodies 92 are provided with connecting portions 94 for detachably connecting the cable bodies 92 at both ends or one end thereof. When connecting the rod 50 (rod body 52) and the core collecting device 1 or when connecting the rod bodies 52 to each other, the connection is made by connecting the connecting portions 94 of the cable bodies 92 provided in these.
Note that the cable bodies 92 included in the rod bodies 52 may not be included in all the rod bodies 52 but may be included in some of the rod bodies 52.
In the following description, the cable 90 refers to a cable in which a plurality of cable bodies 92 are connected, or a cable that is provided with a rotary connector.

There are two cable bodies 92 provided in the core collecting device 1. These cable bodies 92 are connected via the first rotary connector 100. One of these cable bodies 92 has one end (lower end) connected to the first displacement meter 40 and the other end (upper end) connected to the first rotary connector 100. The other is connected to the first rotary connector 100 at one end (lower end), from which the cable hole 36 for passing the cable 90 provided in the inner tube head 23, the connecting rod 24 and the outer tube head 14, and the cable hole The other end (upper end) of the outer pipe 10 is connected to the cable body 92 of the rod body 52. The other cable body 92 is passed through the through hole 67 of the cable fixing portion 60 fixed to the first guide passage 32 of the outer tube 10, and is pressed or adhered to the through hole 67, and is attached to the outer tube 10. It is fixed. The other cable body 92 is also fixed to the cable hole 36 by a cable fixing portion 60 or a bearing as required. The other cable body 92 is provided with a connection portion 94 at the other end, and is connected by connecting the connection portion 94 to the cable body 92 of the rod body 52 coupled to the core collecting device 1. The length of the other cable body 92 is such that the connecting portion 94 can be brought out of the outer tube head 14.
In a predetermined portion of the cable hole 36, a sealing material is filled in a gap between the cable hole 36 and the cable body 92 so that the fluid F does not flow from the first guide channel 32 of the outer tube 10.

  The cable body 92 provided in each rod body 52 is passed through the through hole 67 of the cable fixing portion 60 provided therein, and is pressed or adhered to the through hole 67 to be fixed to the rod body 52. The cable body 92 provided in each rod body 52 is longer than each rod body 52, and the connecting portions 94, 94 at both ends thereof can be brought out from each opening of the rod body 52.

  Among the cable bodies 92 provided in the rod body 52, the cable body 92 located on the uppermost side is provided in the rod body 52 located on the ground. The cable body 92 includes a connecting portion 94 at one end (lower end), and is connected by connecting the adjacent lower cable body 92 and the connecting portion 94 to each other. The other end (upper end) of the cable body 92 is connected to the second rotary connector 110.

  The cable body 92 disposed on the outside of the rod 50 has one end connected to the second rotary connector 110 and the other end connected to the information processing device 130.

  Among the cable bodies 92, the one fixed to the core collection device 1 or the rod body 52 rotates with the rotation of the rod 50.

  The first rotating connector 100 is a connector for electrically connecting a rotating body and a non-rotating body. The first rotary connector 100 uses a so-called slip ring, and includes a ring portion 101 and a brush portion 104 as shown in FIG.

  The ring part 101 of the first rotary connector 100 includes an annular ring part main body 102 and a metal annular ring 103 provided on the outer periphery of the ring part main body 102. The ring portion 101 of the first rotary connector 100 is connected to the cable body 92 of the rod body 52 of the cable body 92 provided in the core collecting device 1. The cable body 92 is fixed in the hollow portion. The ring 103 of the ring portion 101 is electrically connected to the cable body 92. The ring portion 101 of the first rotary connector 100 rotates with the rotation of the rod 50 together with the fixed cable body 92.

  The brush portion 104 of the first rotary connector 100 includes a brush portion main body 105 and a metal brush 106 provided on the brush portion main body 105. The brush 106 is in contact with the ring 103 of the ring unit 101. The brush 106 of the brush unit 104 and the first displacement meter 40 are electrically connected by the cable body 92 as described above. The brush portion 104 of the first rotary connector 100, the first displacement meter 40, and the cable body 92 connecting them do not rotate with the rotation of the rod 50.

  The boring device includes a cable body 92 provided in the core collecting device 1 by including the first rotary connector 100, and a cable body 92 (cable 90) that rotates as the rod 50 rotates, and a cable that does not rotate. The body 92 (cable 90) can be electrically connected without being twisted as the rod 50 rotates.

  In addition, when the core barrel 3 of the core collecting apparatus 1 is a single core barrel, the core barrel 3 and the first displacement meter 40 provided to the core barrel 3 rotate as the rod 50 rotates, so the first rotary connector 100 is unnecessary. is there. In this case, the first displacement meter 40 can be directly connected to the cable body 92 provided in the rod body 52 coupled to the core collecting device 1 with a single cable body 92.

  The second rotary connector 110 is the same as the first rotary connector 100, and includes a ring part 111 and a brush part 114 as shown in FIG.

  The ring portion 111 of the second rotary connector 110 is fixed to the rod body 52 provided with the cable body 92 located on the uppermost side with the rod body 52 being passed through the hollow portion of the ring body 112. . Further, the ring 113 of the ring part 111 is electrically connected to one end of the cable body 92 located on the uppermost side. The ring portion 111 of the second rotary connector 110 rotates as the rod 50 rotates.

  In the brush portion 114 of the second rotary connector 110, the brush 116 provided on the brush portion main body 115 is in contact with the ring 113 of the ring portion 111. The brush 116 of the brush unit 114 and the information processing device 130 are electrically connected by the cable body 92 located outside the rod 50 as described above. The brush portion 114 of the second rotary connector 110 and the cable body 92 connected thereto do not rotate as the rod 50 rotates.

  The boring device includes the second rotating connector 110, so that the boring device 1 and the rod body 52 are provided with a cable body 92 (cable 90) that rotates as the rod 50 rotates, and the outside of the rod body 52. The cable body 92 (cable 90) that does not rotate with the rotation of the rod body 52 can be electrically connected without being twisted with the rotation of the rod 50.

  As described above, the boring device includes the cable 90, the first rotary connector 100, and the second rotary connector 110, so that the cable 90 is not twisted as the rod 50 rotates. A measurement signal measured by one displacement meter 40 can be transmitted to the information processing apparatus 130. Moreover, since the boring apparatus is provided with the cable body 92 for every rod body 52, when performing the connection of the rod 50 (rod body 52) and the core collection | recovery apparatus 1, or the connection of the rod bodies 52, these are carried out. The connection and the connection between the cable bodies 92 can be easily performed in a short time.

  In addition, since the fluid F flows in the rod 50 or the first water conduit, the cable body 92 including the connecting portion 94, the first rotary connector 100, and the second rotary connector 110 are waterproof. preferable.

  The information processing apparatus 130 stores a measurement signal measured by a displacement meter as displacement data or processes the displacement data. The information processing apparatus 130 includes a data collection unit 132 and an information processing unit 134.

  The data collection unit 132 performs AD conversion on the measurement signal of the displacement meter and stores it as displacement data for every predetermined time, or displays or outputs it. The data collection unit 132 is electrically connected to the brush 116 of the brush unit 114 of the second rotary connector 110 by a cable body 92 located outside the rod 50. The data collection unit 132 is electrically connected to the information processing unit 134 through the cable body 92. As the data collection unit 132, for example, a data logger can be used.

The information processing unit 134 stores and processes displacement data. The information processing unit 134 includes a control unit including a CPU and a memory, a communication unit that transmits and receives a measurement signal of the displacement meter or data processed by the displacement meter, an output unit such as a display and a printer, a storage unit such as a hard disk, and a keyboard. And an input unit such as a mouse, and these components are connected by a bus or the like. As the information processing unit 134, for example, a personal computer can be used.
The information processing unit 134 includes a processing unit that processes displacement data of the displacement meter under the control of the control unit as a functional configuration.

  The information processing apparatus 130 may be any apparatus as long as it stores, displays, or outputs displacement data by AD-converting at least a displacement meter measurement signal.

The second displacement meter 140 is for measuring the vertical displacement of the rod 50. As the second displacement meter 140, a wire displacement meter is used in the present embodiment, similarly to the first displacement meter 40. The second displacement meter 140 is attached to the boring device main body 70 so as to be positioned near the rod body 52 that is on the ground.
A portion of the rod body 52 located below the second displacement meter 140 is provided with a wire fixing portion 144. The wire fixing portion 144 includes a non-rotating portion that does not rotate as the rod 50 rotates. For example, a bearing or the like can be used for the wire fixing portion 144.
In the second displacement meter 140, the tip of the wire 142 is attached to the non-rotating portion of the wire fixing portion 144, and the wire 142 is advanced and retracted in the vertical direction.
With such a configuration, the second displacement meter 140 is prevented from rotating as the rod 50 rotates.

  In the boring device, since the second displacement meter 140 does not rotate with the rotation of the rod 50, the displacement of the rotating rod 50 in the vertical direction does not twist or entangle the wire 142. Accurate measurement is possible.

  The second displacement meter 140 may be any device that can measure the displacement of the rod 50, such as a laser displacement meter.

  The second transmission unit is for transmitting the measurement signal measured by the second displacement meter 140 to the information processing apparatus 130 (data collection unit 132). The second transmission unit may be wired or wireless, but in the present embodiment, a cable 150 (cable body 152) that is wired is used as in the first transmission unit.

  Next, a core collection method using the boring apparatus will be described. When using the boring device, the contact portion 42 provided in the first displacement meter 40 is arranged so that its bottom surface (slip prevention portion 45) is substantially the same height as the lower end of the inner pipe body 21 as an initial position. deep. As a result, the first displacement meter 40 can measure the entry length of the core C with reference to the lower end of the inner pipe main body 21. The reference position of the displacement of the rod 50 measured by the second displacement meter 140 is the position of the tip of the wire 142 at the start of core collection.

  Next, the boring device main body 70 is driven to lower (advance and retreat) while rotating the rod 50. As a result, the core collecting device 1 descends while rotating the outer tube 10 having the bit 16 to excavate the ground G, and collects the core C in the core collecting unit 22 of the inner tube main body 21 (see FIG. 9). ). When the ground G is hard, in order to cool the bit 16, the fluid F is supplied from the storage unit 80 to the core collecting device 1 and excavated while discharging the fluid F from the tip of the core barrel 3. When the collection of the core C in the predetermined section is completed, the rod 50 is raised, the core collection device 1 is pulled up to the ground, and the core C collected by the core collection unit 22 is collected. If necessary, the core collection device 1 is returned to the excavation hole, and the excavation, the collection of the core C, and the recovery of the core C are performed again. A series of actions such as excavation, collection of the core C, and collection of the core C are repeated until the core C having a predetermined depth is collected. When the excavation depth becomes deep and the length of the rod 50 becomes insufficient in the sampling operation of the core C, the rod body 52 and the cable body provided for the rod body 52 are separately added to the rod 50 and the cable 90 provided for the boring device. 92 are connected or connected by the above method, and the rod 50 and the cable 90 are extended.

  When the core C is sampled, the first displacement meter 40 measures the vertical displacement of the tip (upper end) of the core C entering the core sampling unit 22. The second displacement meter 140 measures the forward / backward displacement of the rod 50.

  The measurement signals measured by the first displacement meter 40 and the second displacement meter 140 are transmitted to the information processing device 130, AD-converted by the data collection unit 132 of the information processing device 130, and as displacement data for every predetermined time. It is stored in the data collection unit 132.

  As shown below, the processing unit of the information processing unit 134 obtains the advance / retreat distance of the rod 50 at the time of core collection and the approach length of the core C collected by the core collection unit 22 based on the stored displacement data. Or you can compare them.

  The advancing / retreating distance of the rod 50 is obtained by calculating the difference between the displacement data measured by the second displacement meter 140 and the value at the start of core collection and the value at the completion of core collection or the absolute value of this difference. It is done. The advance / retreat distance of the rod 50 is a positive value.

  The entry length of the core C is the difference between the value at the start of core collection, that is, the value at the time when the contact portion 42 is in the initial position, and the value at the completion of core collection among the displacement data of the first displacement meter 40 It is obtained by calculating the absolute value of the difference. The entry length of the core C is a positive value.

Regarding the comparison of the advance / retreat distance of the rod 50 and the approach length of the core C, the difference between the advance / retreat distance of the rod 50 and the approach length of the core C or the absolute value of this difference is obtained, and the obtained value is compared with the threshold value. To do. The obtained value and threshold value are positive values.
When the obtained value is smaller than the threshold value, the core C having the same length as the advance / retreat distance of the rod 50 is collected in the core collection unit 22, so the collected core C accurately reflects the actual ground G. It can be judged that there is a high possibility that
On the contrary, when the obtained value is larger than the threshold value, the core C having the length corresponding to the advance / retreat distance of the rod 50 is not collected in the core collecting unit 22 because of the gap in the ground G. It can be determined that there is a high possibility that the core C does not accurately reflect the actual ground G.

  According to the core sampling device 1 and the boring device including the core sampling device 1, the accuracy of the sampled core C is determined by including a displacement meter that measures the displacement of the core C or a displacement meter that measures the displacement of the rod 50. As data, the displacement of the core C or the displacement of the rod 50 and the advance / retreat of the rod 50 can be measured. In addition, it is possible to grasp the displacement (displacement of the tip) and the entry length of the core C that has entered the inner pipe body 21 (core barrel 3) in real time. It is also possible to determine the accuracy of the collected core C.

  Moreover, when transmitting the measurement signal measured with the displacement meter with the cable 90, the core sampling device 1 and the boring device including the same transmit the measurement signal without twisting the cable 90 by providing the rotary connector. can do.

  Further, the core collecting device 1 and the boring device including the core collecting device 1 are provided with a cable body 92 for each rod body 52 when the rod 50 is composed of a plurality of rod bodies 52, thereby extending the rod 50 and the cable 90. Can be easily performed in a short time.

  Further, according to the core collection method, the accuracy of the collected core C can be determined.

DESCRIPTION OF SYMBOLS 1 Core sampling device 3 Core barrel 10 Outer tube 12 Outer tube main body 14 Outer tube head 16 Bit 20 Inner tube 21 Inner tube body 22 Core sampling part 23 Inner tube head 24 Connecting rod 25 Bearing 30 Guide channel 32 First guide channel 34 Second guiding channel 36 Cable hole 40 First displacement meter 41 Wire 42 Contact portion 43 Contact portion main body 44 Pressing portion 45 Non-slip portion 46 Water absorbing material 50 Rod 52 Rod body 54 Male screw 56 Female screw 60 Cable fixing portion 62 Outer frame portion 64 Fixed portion 66 Support portion 67 Through hole 70 Boring device main body 72 Drive device 80 Storage portion 82 Water supply path 83 Swivel 84 Pump 90 Cable (first transmission portion)
92 Cable body 94 Connection portion 100 First rotation connector 101 Ring portion 102 Ring portion main body 103 Ring 104 Brush portion 105 Brush portion main body 106 Brush 110 Second rotation connector 111 Ring portion 112 Ring portion main body 113 Ring 114 Brush portion 115 Brush Main unit 116 Brush 130 Information processing device 132 Data collection unit 134 Information processing unit 140 Second displacement meter 142 Wire 144 Wire fixing unit 150 Cable (second transmission unit)
152 Cable body C Core F Fluid G Ground

Claims (4)

A tubular core barrel that is detachable from one end of the rod of the boring device and has a core collecting part for collecting the core of the ground,
A first displacement meter that measures the displacement of the core that enters the core sampling unit,
The first displacement meter is a wire-type displacement meter in which a wire advances and retreats in a direction substantially parallel to the axis of the core barrel in the core sampling unit, and includes a contact portion with which the core contacts the tip of the wire,
A core collecting device comprising a water absorbing material on the contact portion. A boring device capable of transmitting a measurement signal measured by a displacement meter to an information processing device,
The rod,
A core having a tubular core barrel connected to one end of the rod and having a core collecting part for collecting the core of the ground, and a first displacement meter for measuring the displacement of the core entering the core collecting part A collection device;
A boring device body that rotates the rod about its axis and advances and retreats in the axial direction;
A second displacement meter for measuring the forward and backward displacement of the rod;
A first transmitter for transmitting the measurement signal of the first displacement meter to the information processing device;
A second transmitter for transmitting the measurement signal of the second displacement meter to the information processing device,
The core barrel is connected to one end of the rod, a tubular outer tube, and the outer tube is coaxially arranged in the outer tube so as to be non-rotating with respect to the outer tube. A double core barrel connected and having a tubular inner tube whose inside is the core collection part,
The first displacement meter is provided in the inner pipe,
The rod is tubular and has a space inside;
The first transmission unit includes a cable, a first rotary connector that electrically connects the rotating body and the non-rotating body, and a second rotary connector that electrically connects the rotating body and the non-rotating body. With
One end of the cable is connected to the first displacement meter, extends outside the rod through the core barrel and the rod, and the other end can be connected to the information processing device.
Some of the cables are fixed to both or one of the core barrel and the rod, and rotate with the rotation of the rod.
Cables other than the part of the cables include those that connect to the first displacement meter that does not rotate with the rotation of the rod and those that can connect to the information processing apparatus that does not rotate with the rotation of the rod. And
A cable connected to the part of the cable and the first displacement meter is connected via the first rotary connector;
The boring apparatus, wherein the part of the cables and a cable connectable to the information processing apparatus are connected via the second rotary connector. A boring device capable of transmitting a measurement signal measured by a displacement meter to an information processing device,
The rod,
A core having a tubular core barrel connected to one end of the rod and having a core collecting part for collecting the core of the ground, and a first displacement meter for measuring the displacement of the core entering the core collecting part A collection device;
A boring device body that rotates the rod about its axis and advances and retreats in the axial direction;
A second displacement meter for measuring the forward and backward displacement of the rod;
A first transmitter for transmitting the measurement signal of the first displacement meter to the information processing device;
A second transmitter for transmitting the measurement signal of the second displacement meter to the information processing device,
The first displacement meter is a wire-type displacement meter in which a wire advances and retreats in a direction substantially parallel to the axis of the core barrel in the core sampling unit, and includes a contact portion with which the core contacts the tip of the wire,
A boring device comprising a water absorbing material on the contact portion. Connected to one end of the rod of the boring device, inside rotate and advance and retract Koabareru tubular having a coring portion which is a space for collecting the ground core, while the core was collected in the coring portion, adopted the core Measuring the displacement of the core entering the take-up portion and the forward / backward displacement of the rod at the time of collecting the core;
Obtaining an entry length of the core that has entered the core sampling part from the displacement of the core; and
Obtaining the advance / retreat distance of the rod from the advance / retreat displacement of the rod;
And a step of comparing an approach length of the core and a length of the advance / retreat distance of the rod.

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