JP3221101U - Unconsolidated sampling device - Google Patents

Abstract

The present invention provides an unconsolidated sampling device capable of simply and safely performing operation with ease and being able to reliably collect an unconsolidated sample at any position in a wellbore.
A sample collecting unit 10 is provided at the upper part of a tank part 3 capable of containing an unconsolidated sample 300, and a sample discharging unit 20 is provided at a lower part thereof. The piston 13 is movable in the vertical direction and biased downward by the spring member 15 and connected to the wire member 19. When the wire member is pulled upward, the piston rises and the sampling port 12 is opened, and the inside of the tank is The unconsolidated sample in the wellbore 200 can be collected. In the body portion 21 of the sample discharge unit 20, the piston 23 which is movable in the left-right direction and connected to the handle 28 is accommodated. When the handle is pulled rightward, the piston moves rightward. The discharge port 21a is opened to discharge the unconsolidated sample in the tank portion.
[Selected figure] Figure 2

Description

  The present invention relates to an apparatus for collecting an unconsolidated sample in a wellbore in a prefabricated pile embedding method.

  As pre-made pile embedding methods, a number of pre-boring methods and middle digging methods have been proposed. And when excavating the wellbore in those construction methods, there is a case that the extremity portion is excavated and excavated to build a rooted portion, but in any case, the rooting fluid is injected to the extremity portion of the wellbore Then, it mixes with excavated earth and sand and forms a root cement by solidifying it. Then, in the pre-boring method, the circumferential fixing liquid is poured into the pile peripheral portion, mixed with excavated soil, and soil cement is formed and solidified to fix the prefabricated pile to the ground.

  In recent years, a high bearing capacity construction method to obtain large bearing capacity by using prefabricated piles has spread, and as a result, the bearing capacity increases, and as a result, the construction quality is secured. Interest is growing. Therefore, the strength confirmation of the root consolidation part etc. by collecting the unconsolidated sample before the soil cement solidifies in the in-situ, the root consolidation part etc by collecting the consolidated sample which the soil cement solidified by core boring The strength confirmation of is conducted.

  However, if it is necessary to drill the soil cement that has solidified to the collection point when collecting consolidated samples of the pile perimeter fixed part by core boring, it took a lot of time and cost for the sampling operation . In addition, when collecting consolidated samples of the root consolidation part in the drilled hole where a long pile length is to be embedded, the guide pipe for drilling whose tip is clogged is solidified before the soil cement solidifies. Since it is necessary to insert in the inside of the pile body, the collection operation of the consolidated sample is expensive and complicated.

  Therefore, it is easier to collect the unconsolidated sample before the soil cement is solidified and to check the strength, rather than to collect the solidified sample from which the soil cement is solidified. Many collection devices have been proposed for collecting consolidated samples.

JP, 2017-179855, A JP 2012-237192 A

  However, as in the case of Patent Document 1 described above, in the case where the sampling mechanism of the sampling device for the unconsolidated sample performs the opening and closing of the sampling port by hydraulic pressure, the connection portion of the hydraulic piping installed on the drilling rod is disconnected. Not only can the hydraulic oil flow out and collection of the unconsolidated sample can not be performed, but there is also the possibility that environmental pollution and deterioration of the working environment may occur.

  In addition, as in Patent Document 2 described above, the collecting mechanism of the device for collecting the unconsolidated sample is a mechanical type that opens and closes the collection port by a mechanical structure, and the intake port of the collection tank is opened by the operation of the operation rod. In the case of the structure which is squeezed or clogged, the operation is difficult because the operation of the operating rod is required to be finely adjusted, and the structure is complicated, so that the mechanism adjustment is also required.

  The present invention is intended to solve the above-mentioned conventional problems, and it is simple in structure, easy to operate and safe, and can not be completely consolidated at any position (depth) in the wellbore. An object of the present invention is to provide an unconsolidated sampling device capable of sampling a sample.

  In order to achieve the above object, the invention according to claim 1 comprises a tank unit capable of containing an unconsolidated sample, a rod connecting unit provided in the tank unit and connectable to a rotating rod, and the tank unit. An unconsolidated sampling device comprising at least one sampling unit provided and capable of collecting an unconsolidated sample and at least one sample discharge unit capable of discharging an unconsolidated sample, wherein the tank portion is a bottom plate portion And the upper lid for sealing the upper end of the housing, and the sampling unit is closed at the upper end and has an opening at the lower end, and at least one collection on the side A substantially cylindrical body portion having a mouth, a piston portion capable of moving inside the body portion and being capable of closing the collection port, and a position capable of closing the collection port inside the body portion Said piston part A spring member biased downward, a wire member connected to the piston portion and capable of pulling up the piston portion, and the inside of the body portion and the inside of the tank portion communicate with each other through the opening portion The sample discharge unit has a substantially cylindrical body portion having one end closed, an outlet provided at the other end, and an inlet formed on the side, and the inside of the body can be moved. It has a piston portion capable of closing the discharge port, and a handle portion connected to the piston portion and capable of moving the piston portion, and the inside of the body portion and the inside of the tank portion are connected via the inflow port. It is characterized in that it is in communication.

  The invention according to claim 2 is characterized in that the longitudinal direction of the body portion of the sampling unit and the central axis of the rod connecting portion are substantially parallel.

  In the invention according to claim 3, a plurality of small tanks are formed inside the tank, and each of the small tanks is provided with at least one sampling unit and one sample discharging unit. The interiors of the respective small tank portions communicate with the interiors of the body portion of the sampling unit via the opening portion, and through the interiors of the body portion of the sample discharge unit and the inflow port. It is characterized in that it is in communication.

  From the above, according to the invention of claim 1, since the structure is simple and there is no need to adjust the mechanism, the unconsolidated sample can be easily and safely taken out and discharged. An unconsolidated sample can be collected at any position of the root consolidation portion and the pile peripheral fixing portion. In addition, when collecting an unconsolidated sample, visually check the state in which the wire member has been pulled upward or pulled back downward to grasp the open / close state of the collection port though it is indirect. Can ensure the collection of unconsolidated samples. Moreover, since the structure is simple, the unconsolidated sampling device itself after use can be easily cleaned.

  In addition, by providing a plurality of sampling units or sampling ports, it is possible to collect an unconsolidated sample in a shorter time and more reliably. Further, by providing a plurality of sample discharge units, the collected unconsolidated sample can be reliably discharged in a short time.

  According to the second aspect of the present invention, since the longitudinal direction of the body of the sampling unit and the central axis of the rod connecting portion are substantially parallel, the wire member is disposed so as to be substantially parallel to the rotating rod. It is possible to smoothly move the piston portion up and down. As a result, since the opening and closing of the collection port can be smoothly performed, the unconsolidated sample can be reliably collected at a more accurate (desired) position.

  Moreover, according to the invention concerning Claim 3, while being able to extract a separate unconsolidated sample inside each small tank part, the unconsolidated sample accommodated in the inside of each small tank part is separated separately While being able to reduce the collection labor when collecting an unconsolidated sample at a plurality of positions in the rooting portion and the pile periphery fixing portion, it is possible to shorten the collection operation time.

It is a fragmentary sectional view of an unconsolidated sampling device concerning a 1st embodiment of the present invention. It is an unconsolidated sampling phase diagram of an unconsolidated sampling device according to a first embodiment of the present invention. It is an unconsolidated sample discharge | release state figure of the unconsolidated sampling apparatus which concerns on 1st Embodiment of this invention. It is a fragmentary sectional view of the unconsolidated sampling device concerning a 2nd embodiment of the present invention. It is a fragmentary sectional view of the unconsolidated sampling device concerning a 3rd embodiment of the present invention. It is a fragmentary sectional view of the unconsolidated sampling device concerning a 4th embodiment of the present invention. FIG. 1 is an excavated state diagram of a wellbore using an unconsolidated sampling device according to a first embodiment of the present invention. It is a use phase figure at the time of unconsolidated sampling of an unconsolidated sampling device concerning a 1st embodiment of the present invention. It is a use phase figure at the time of unconsolidated sample discharge of the unconsolidated sampling device concerning a 1st embodiment of the present invention. It is another use condition figure at the time of unconsolidated sample discharge of the unconsolidated sampling device concerning a 1st embodiment of the present invention.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Although the embodiment will be described in detail below, the present invention is not limited to this. In addition, while attaching the identical mark concerning the identical component in each figure, it abbreviates concerning the explanation. First, the unconsolidated sampling device 1 according to the first embodiment will be described. As shown in FIG. 1, the tank unit 3 provided with the rod connecting unit 2, the sampling unit 10, and the sample discharge unit 20. Have.

  The tank unit 3 is composed of an upper cover 4 and a storage unit 5. The upper lid portion 4 is a thin, substantially circular plate-like member, and is fixed to the upper end portion of the housing portion 5 by a bolt or the like to seal the housing portion 5. A rod connecting portion 2 connectable to the tip of the rotating rod 101 is provided substantially at the center of the upper lid 4. The rod connecting portion 2 is provided such that its central axis is substantially perpendicular to the upper lid 4.

  Further, a substantially circular through hole 6 is formed in the vicinity of the outer peripheral edge of the upper cover 4. The sampling unit 10 is provided at the position of the through hole 6 on the upper cover 4, and the longitudinal direction of the body 11 is substantially perpendicular to the upper cover 4 and the central axis of the rod connecting portion 2. It is fixed so as to be parallel to it.

  The body portion 11 of the sampling unit 10 is substantially cylindrical and the upper end portion is closed by the top plate portion 11a, while the lower end portion is opened and the opening portion 11b is provided. Since the inner diameter of the body portion 11 is larger than the inner diameter of the through hole 6, the entire through hole 6 is covered by the body portion 11.

  Therefore, the inside of the body 11 and the inside of the tank 3 communicate with each other through the opening 11 b and the through hole 6. In the vicinity of the lower end portion of the side surface of the body portion 11, a substantially circular shaped collection port 12 for collecting the unconsolidated sample 300 into the inside of the tank portion 3 is formed.

  A substantially cylindrical piston portion 13 having an outer diameter substantially the same as or slightly smaller than the inner diameter of the body portion 11 is accommodated in the body portion 11, and the piston portion 13 moves up and down in the body portion 11. It is possible. The rubber packings 14 and 14 extending continuously in the circumferential direction are provided in the vicinity of the upper end and the lower end of the side surface of the piston 13, and the rubber packing 14 is in contact with the inner side of the body 11. The rubber packing 14 is in a state in which the gap between the inner side surface 11 and the side surface of the piston portion 13 is closed.

  The outer diameter of the piston portion 13 is larger than the inner diameter of the through hole 6 formed in the upper lid portion 4, and the vertical length of the piston portion 13 is a sampling port formed in the body portion 11. It is formed to be longer than the inner diameter of 12.

  A spring member 15 is accommodated in a space between the upper end surface 13a of the piston portion 13 and the top plate portion 11a of the body portion 11, and the spring member 15 biases the piston portion 13 downward. It is in the state. Therefore, the piston portion 13 in the normal state is located at the lowermost position in contact with the upper lid portion 4 of the tank portion 3 in the body portion 11, and closes the opening 11b of the body portion 11 and the collection port 12, And the entry of the unconsolidated sample 300 into the torso portion 11. Further, at the same time, the piston portion 13 also closes the through hole 6 formed in the upper lid portion 4.

  Further, the piston portion 13 is provided with a rod portion 16 extending upward from the approximate center of the upper end surface 13a. The rod portion 16 is inserted into the insertion hole 18 formed substantially at the center of the top plate portion 11 a of the body portion 11, and the upper end portion 16 a of the rod portion 16 protrudes upward from the top plate portion 11 a of the body portion 11 And is connected to the wire member 19.

  From the above structure, by operating the wire member 19, the vertical movement of the piston portion 13 is possible. Specifically, by pulling the wire member 19 upward, as shown in FIG. 2, the rod portion 16 connected to the wire member 19 is pulled upward while being guided to the insertion hole 18, and accordingly the rod portion The piston portion 13 fixed to the lower end portion 16 b of 16 is also pulled upward in the body portion 11.

  As a result, the opening 11 b of the body 11, the collection opening 12 and the through hole 6 of the upper lid 4 closed by the piston 13 are opened, so that the outside of the unconsolidated sampling device 1 and the tank The interior of the part 3 is in communication. Therefore, the unconsolidated sample 300 present in the vicinity of the sampling port 12 of the sampling unit 10 in the drilling hole 200 can flow into the tank portion 3 through the sampling port 12, the opening 11 b and the through hole 6. The unconsolidated sample 300 can be accommodated in the tank portion 3.

  At this time, the spring member 15 accommodated in the body portion 11 of the sampling unit 10 is contracted by the upward movement of the piston portion 13.

  At the same time when the unconsolidated sample 300 flows into the tank portion 3, the air present in the tank portion 3 passes through the through hole 6 of the upper lid portion 4, the opening portion 11 b of the body portion 11 and the sampling port 12. It is discharged out of the consolidated sampling device 1.

    On the other hand, when the wire member 19 pulled up is released, the spring member 15 is returned to the extended state by the restoring force of the spring member 15, so that the piston portion 13 is pushed downward by the spring member 15 inside the body portion 11. The wire member 19 connected to the rod portion 16 fixed to the piston portion 13 is pulled back downward while returning to the lowermost position contacting the upper lid portion 4 of the tank portion 3. Therefore, the piston 13 closes the opening 11 b of the body 11, the collection port 12 and the through hole 6 of the upper lid 4 again, and the inflow of the non-solidified sample 300 into the tank 3 is blocked.

  In addition, since the longitudinal direction of the body portion 11 of the sampling unit 10, the central axis of the rod connecting portion 2 and the central axis of the rotating rod 101 coupled thereto are substantially parallel, the unconsolidated sampling device 1 is used. Even in the case of lowering the drilling hole 200 to a deep position, the wire member 19 is operated along the rotating rod 101 so as to be substantially parallel to the rotating rod 101, so that the wire member 19 can be operated smoothly. As a result, the piston 13 can be smoothly moved in the vertical direction in the body 11. Therefore, the unconsolidated sample 300 can be reliably accommodated in the tank portion 3 at a desired position in the drilling hole 200.

  The housing portion 5 is a substantially cylindrical member having a bottom plate portion 5a, and the upper end portion thereof is open, and the unsolidified sample 300 can be housed therein. Further, on the bottom plate portion 5a, a sample discharge unit 20 extending along the radial direction of the bottom plate portion 5a is provided.

  The sample discharge unit 20 has a substantially cylindrical body portion 21, and both ends thereof project from the tank portion 3. And while the one end part of the fuselage | body part 21 is opened and the discharge port 21a is provided, the other end part is obstruct | occluded by the end plate part 21b. A substantially circular inflow port 22 is formed in a portion of the side surface of the body portion 21 located in the tank portion 3. Therefore, the inside of the body 21 and the inside of the tank 3 are in communication with each other through the inlet 22.

  A substantially cylindrical piston portion 23 having an outer diameter substantially the same as or slightly smaller than the inner diameter of the body portion 21 is accommodated in the body portion 21, and the piston portion 23 is accommodated in the body portion 21 (first embodiment In the configuration, it is movable in the left and right direction). Rubber packings 24 and 24 extending continuously in the circumferential direction are provided in the vicinity of the left and right end parts of the side surface of the piston part 23, and the rubber packing 24 is in contact with the inner side surface of the body part 21. The gap between the inner side surface and the side surface of the piston portion 23 is closed by the rubber packing 24. The length in the left-right direction of the piston portion 13 is longer than the inner diameter of the inflow port 22 formed in the body portion 21.

  Therefore, normally, as shown in FIG. 1, the piston portion 23 is located in the body portion 21 at the position where the inflow port 22 is formed, and the inflow port 22 is blocked and housed in the tank portion 3. The penetration of the unconsolidated sample 300 into the body portion 21 is prevented. Further, the piston portion 23 is also in a state of closing the discharge port 21a of the body portion 21 at the same time.

  Further, the piston portion 23 is provided with a rod portion 25 extending rightward from the approximate center of the right end face 23a. The rod portion 25 is inserted into the insertion hole 26 formed substantially at the center of the end plate portion 21 b of the body portion 21, and the right end portion 25 a of the rod portion 25 protrudes to the right from the end plate portion 21 b of the body portion 21. At the same time, the handle portion 28 is provided at the right end 25a.

  By the above-mentioned structure, by operating the handle portion 28, the lateral movement of the piston portion 23 is possible. Specifically, by pulling the handle portion 28 in the right direction, as shown in FIG. 3, the rod portion 25 connected to the handle portion 28 is drawn out from the body portion 21 while being guided by the insertion hole 26, and the right direction Along with that, the piston portion 23 fixed to the left end 25b of the rod portion 26 also moves in the right direction in the body portion 21.

  As a result, the inflow port 22 and the discharge port 21a of the body portion 21 closed by the piston portion 23 are opened, so that the outside of the unconsolidated sampling device 1 and the inside of the tank portion 3 communicate with each other. It becomes a state. Therefore, the unconsolidated sample 300 accommodated in the tank unit 3 can be discharged to the outside of the tank unit 3 through the inflow port 22 and the discharge port 21a.

  Then, after discharging the unconsolidated sample 300 in the tank portion 3, the rod portion 25 connected to the handle portion 28 is guided to the insertion hole 26 by pushing the handle portion 28 in the left direction. In order to move in the left direction while being pushed into the portion 21, the piston portion 23 fixed to the left end portion 25 b of the rod portion 26 also moves in the left direction in the body portion 21 and the inlet 22 in the opened state And, the discharge port 21a is closed again by the piston portion 23.

  Note that when the unconsolidated sample 300 is stored in the tank portion 3, as shown in FIG. 1 and FIG. 1, the unconsolidated sample 300 does not intrude into the storage portion 5 from the discharge port 21 a of the body portion 21 of the sample discharge unit 20. As shown in FIG. 2, the discharge port 21 a is closed by the cap 29. On the other hand, when discharging the unconsolidated sample 300 stored in the tank unit 3, as shown in FIG. 3, it is easy to discharge the unconsolidated sample 300 into the unconsolidated sample collection box 104 described later. Remove the cap 29 from the discharge port 21a, and attach a L-shaped tubular discharge plug 30 instead.

  As described above, the unconsolidated sampling device 1 according to the first embodiment has a simple structure and does not require adjustment of its mechanism in particular, so that the operation of collecting and discharging the unconsolidated sample 300 is easy and It can be done safely. In addition, collection of the unconsolidated sample 300 can be performed at an arbitrary position (depth) such as a root consolidation portion or a pile peripheral fixing portion in the drilling hole.

  Also, by visually confirming the state of the wire member 19 (the state of being pulled upward or the state of being pulled back downward) from the above, although it is indirect, the state of the sampling port 12 (opened state or blocking) The unconsolidated sample 300 can be reliably stored in the tank portion 3 at an arbitrary position.

  Further, since the structure is simple, the unconsolidated sampling device 1 itself after being used for collecting the unconsolidated sample 300 can be easily washed.

  By the way, in the unconsolidated sampling device 1 according to the first embodiment, as shown in FIG. 1, the sampling unit 10 is provided on the upper cover 4 but in the second embodiment shown in FIG. As in the unconsolidated sampling device 1A, the sampling unit 10 is provided with the tank via the substantially cylindrical connecting portion 31 provided in the upper part of the storage portion 5 of the tank portion 3 and curved upward in an arc shape. It may be connected to the part 3. At this time, the inside of the sampling unit 10 is in communication with the inside of the tank unit 3.

  In the case of the above structure, when the unconsolidated sample 300 flows into the tank portion 3 from the sampling port 12 of the sampling unit 10 through the connecting portion 31, as in the first embodiment, the inside of the tank portion 3 simultaneously. It is necessary that the air present in the container 5 is discharged to the outside of the unconsolidated sampling device 1A through the through hole 6 of the housing portion 5, the connection portion 31, the opening 11b of the body portion 11 and the sampling port 12. Therefore, it is desirable that the connecting portion 31 be connected in the vicinity of the upper end portion of the storage portion 5 so that most of the air in the tank portion 3 can be discharged.

  Further, as shown in FIG. 4, a funnel-shaped member 32 may be provided above the sample discharge unit 20 so as to narrow downward. Specifically, the entire peripheral edge portion of the upper end portion of the funnel-shaped member 32 contacts the inner side surface of the storage portion 5 of the tank portion 3, and the entire peripheral edge portion of the lower end portion of the opening 32a provided in the funnel-shaped member 32 and the sample It fixes in the state which contact | connected the whole peripheral part of the inflow port 22 of the discharge unit 20 in contact. With such a structure, the unconsolidated sample 300 contained in the tank portion 3 can be reliably guided into the body portion 21 of the sample discharge unit 20.

  In the first embodiment, only one sampling unit 10 for collecting the unconsolidated sample 300 is provided in the tank unit 3, but the unconsolidated sample 300 flows into the tank unit 3. Unconsolidated sampling device 1B according to the third embodiment shown in FIG. 5 in order to facilitate the process (the air in the tank portion 3 is easily discharged to the outside) and to reliably sample the unconsolidated sample 300 in a short time As in the above, two (or more) sampling units 10 may be provided in the tank unit 3.

  Further, in the first embodiment, only one sampling port 12 is formed on the side surface of the body portion 11 of the sampling unit 10, but the unconsolidated sample 300 can easily flow into the tank portion 3 (tank portion A plurality of sampling ports 12 may be formed on the side surface of the body portion 11 in order to ensure that the air in 3 is easily discharged to the outside and the unconsolidated sample 300 can be reliably collected in a short time (not shown) ). In that case, the heights of the collection ports 12 are substantially aligned so that all the collection ports 12 are closed by the normal piston section 13 located at the lowermost position in the body section 11 Is desirable.

  Further, in the first embodiment, only one sample discharge unit 20 for discharging the unconsolidated sample 300 accommodated in the tank unit 3 to the outside of the tank unit 3 is provided in the tank unit 3. In order to reliably discharge the unconsolidated sample 300 in a short time, a plurality of sample discharge units 20 may be provided in the tank unit 3 (not shown).

  Further, as in the unconsolidated sampling device 1C according to the fourth embodiment shown in FIG. 6, the inside of the tank portion 3 is completely divided longitudinally by the partition wall 5b, so that the tank portion 3 is divided into two small tank portions 3a. And 3b, and in each of the small tank portions 3a and 3b, at least the sampling unit 10 and the sample discharge unit 20, as in the unconsolidated sampling device 1 according to the first embodiment shown in FIG. It is good also as a state provided one each.

  According to the above-described structure, it is possible to accommodate separate unconsolidated samples 300 in the respective small tank parts 3a and 3b, and to combine the unconsolidated samples 300 accommodated in the respective small tank parts 3a and 3b. It can be discharged separately.

  Accordingly, when it is desired to collect the soil cement 300a which is the unconsolidated sample 300 of the rooted portion and the soil cement 300b which is the unconsolidated sample 300 of the fixed portion of the pile in the drilled hole 200, the soil is fixed at the rooted portion. After the cement 300a is collected and housed in one small tank portion 3a (3b), the pile peripherals are continuously taken without pulling up the unconsolidated sampling device 1C to the ground to discharge the soil cement 300a stored. The soil cement 300b can be collected at the fixed part and accommodated in the other small tank part 3b (3a). Therefore, while being able to reduce the collection effort at the time of collecting the unconsolidated sample 300 in two places, collection operation time can be shortened.

  In the unconsolidated sampling device 1C according to the fourth embodiment shown in FIG. 6, the inside of the tank portion 3 is divided into two, but it may be divided into three or more. In the unconsolidated sampling device 1C, the inside of the tank portion 3 is vertically divided by the partition wall 5b, but the inside of the tank portion 3 may be horizontally divided by the partition wall 5b (shown in FIG. ). In that case, the sampling unit 10 is provided in each of the small tank portions formed by division in the same manner as, for example, the unconsolidated sampling device 1A according to the second embodiment shown in FIG. A sample discharge unit 20 is provided in the same manner as the unconsolidated sampling device 1 according to one embodiment.

  Next, a method of collecting the unconsolidated sample 300 using the unconsolidated sampling device 1 according to the first embodiment will be specifically described. First, as shown in FIG. 7, the drilling device 102 is connected to the tip of the rotary rod 101 of the drilling machine 100 to dig the drilling hole 200 of a predetermined depth on the ground 201. After excavating, while pouring the rooting fluid into the tip of the drilled hole 200, the rotary rod 101 is repeated up and down, mixed with the rooting fluid and excavated soil and stirred to form the soil cement 300a while forming the soil cement 300a. Build.

  Thereafter, while injecting the pile peripheral fixing solution, the rotary rod 101 is repeated up and down, mixed with the pile peripheral fixing solution and the excavated soil, and stirred to form the soil cement 300 b and build the pile peripheral fixing portion. Then, the rotary rod 101 is pulled up from the drilling hole 200, the drilling device 102 connected to the tip of the rotating rod 101 is removed, and the unconsolidated sampling device 1 is connected instead. Then, the rotating rod 101 is removed from the drilling machine 100, and instead, the rotating rod 101 is suspended by the crane 103.

  At this time, as shown in FIG. 1, the piston portion 13 in the sampling unit 10 is positioned at the lowermost position in the body portion 11, so the through hole 6 in the upper cover 4 of the unconsolidated sampling device 1 The opening 11 b of the body portion 11 and the sampling port 12 in the sampling unit 10 are closed by the piston portion 13. Further, the inlet 22 and the outlet 21 a of the body 21 in the sample discharge unit 20 are closed by the piston 23. Further, the discharge port 21 a is also closed by the cap 29.

  Then, as shown in FIG. 8, the unconsolidated sampling device 1 is lowered by the crane 103 to a position where it is desired to extract the unconsolidated sample 300 (the soil cements 300 a and 300 b before solidification) in the drilled hole 200. At this time, the wire member 19 is disposed along the rotary rod 101 so as to be substantially parallel to the rotary rod 101 while extending from the sampling unit 10 to the ground (ground 201), and one end 19a thereof is drilled 200 Is held by the operator 202 standing by at the ground 201 in the vicinity, and the wire member 19 is kept operable.

  Next, when the unconsolidated sampling device 1 reaches the position where it is desired to extract the unconsolidated sample 300, the descent of the unconsolidated sampling device 1 by the crane 103 is stopped. Then, in order to collect the unconsolidated sample 300, the operator 202 performs an operation such as pulling the wire member 19, and as shown in FIG. 2, the wire member 19 is pulled upward and the state is maintained for a while.

  Thereby, the piston portion 13 is also pulled upward in the body portion 11, and the through hole 6 in the upper lid portion 4, the opening 11b of the body portion 11 in the sampling unit 10 and the extraction port 12 are opened and the state is maintained. Therefore, the unconsolidated sample 300 present in the vicinity of the sampling port 12 of the sampling unit 10 in the drilled hole 200 can flow into the tank unit 3, and the unconsolidated sample 300 can be accommodated in the tank unit 3.

  Then, after a sufficient amount of unconsolidated sample 300 is accommodated in the tank portion 3, the wire member 19 pulled up by the operation of the operator 202 is released. By doing this, the piston portion 13 returns to the lowermost position in the body portion 11 by the restoring force of the spring member 15, and the through hole 6 in the upper lid portion 4 and the opening 11b of the body portion 11 in the sampling unit 10 Since the collection port 12 returns to the state of being blocked by the piston portion 13, the inflow of the unconsolidated sample 300 into the tank portion 3 can be blocked.

  Next, as shown in FIG. 9, the rotating rod 101 and the unconsolidated sampling device 1 are pulled up from the drilled hole 200 by the crane 103, and the truth of the unconsolidated sample collection box 104 for recovering the unconsolidated sample 300. Move up to the top. At this time, the cap 29 is removed from the discharge port 21a of the body 21 of the sample discharge unit 20, and instead, the discharge plug 30 is attached.

  Then, as shown in FIGS. 3 and 9, when the operator 202 pulls the handle portion 28 in the right direction, the inflow port 22 and the discharge of the body 21 in the sample discharge unit 20 blocked by the piston 23 are discharged. The outlet 21 a is opened, and the unconsolidated sample 300 stored in the tank unit 3 is discharged to the outside of the tank unit 3, thereby recovering the unconsolidated sample 300 in the unconsolidated sample collection box 104.

  The unconsolidated sampling device 1A according to the second embodiment shown in FIG. 4, the unconsolidated sampling device 1B according to the third embodiment shown in FIG. 5, and the unconsolidated sampling device according to the fourth embodiment shown in FIG. The method of collecting the unconsolidated sample 300 by the consolidating sampling device 1C is substantially the same as in the case of the unconsolidated sampling device 1 according to the first embodiment, and the operator 202 pulls the wire member 19 upward. Thus, the unconsolidated sample 300 can be stored in the tank part 3 (3a, 3b), and by releasing the wire member 19 pulled up upward, the nonsolidified substance in the tank part 3 (3a, 3b) The inflow of the consolidated sample 300 can be blocked.

  Further, by pulling the handle portion 28 and pulling out the rod portion 25 from the body portion 21, the unconsolidated sample 300 contained in the tank portion 3 (3a, 3b) is discharged out of the tank portion 3 (3a, 3b) It can be done. In addition, after discharging the unconsolidated sample 300 in the tank portion 3 (3a, 3b), the handle portion 28 is pushed in to push the rod portion 25 into the body portion 21, whereby the inflow port 22 and the discharge portion of the body portion 21 are discharged. The outlet 21 a is closed by the piston portion 23.

  When the unconsolidated sample 300 is collected in the drilled hole 200 already excavated and filled with the unconsolidated sample 300, it is shown in FIG. 10 instead of the rotating rod 101 shown in FIG. Even if the unconsolidated sampling device 1 etc. is connected to the tip of such a dedicated sampling rod 105 and the sampling rod 105 is suspended by the crane 103, the unconsolidated sample 300 is collected Good.

1, 1A, 1B, 1C unconsolidated sampling device 24 rubber packing 2 rod connecting portion 25 rod portion 3 tank portion 25a right end portion 3a, 3b small tank portion 25b left end portion 4 upper lid portion 26 insertion hole 5 accommodating portion 28 handle portion 5a Bottom plate portion 29 Cap 5b Partition wall 30 Ejection plug 6 Through hole 31 Connecting portion 10 Sample collection unit 32 Funnel-like member 11 Body portion 32a Opening portion 11a Top plate portion 100 Excavator 11b Opening portion 101 Rotary rod 12 Collection port 102 Excavation Device 13 Piston part 103 Crane 13a Upper end face 104 Unconsolidated sample collection box 14 Rubber packing 105 Rod for sampling only 15 Spring member 200 Excavation hole 16 Rod part 201 Ground 16a Top end 202 Operator 16b Bottom end 300, 300a, 300b Not Solidification sample 18 insertion hole 19 wire member 2 Sample discharge unit 21 the body portion 21a discharge port 21b end plate portion 22 the inlet 23 the piston portion 23a right end face

Claims (3)

  A tank unit capable of containing an unconsolidated sample, a rod connecting part provided in the tank unit and connectable to a rotating rod, and at least one sampling unit provided in the tank unit capable of collecting an unconsolidated sample And an unconsolidated sampling device having at least one sample discharge unit capable of discharging an unconsolidated sample, wherein the tank portion includes a substantially cylindrical housing portion provided with a bottom plate portion and an upper end portion of the housing portion. A substantially cylindrical body portion having an upper lid portion for sealing, the sampling unit having an upper end portion closed, an opening portion provided at a lower end portion, and at least one collection port formed on a side surface; A piston portion capable of moving the inside of the body and closing the collection port, a spring member biasing the piston portion downward to a position where the collection port can be closed inside the body portion, the piston portion And connected A wire member capable of pulling up the piston portion, the inside of the body portion and the inside of the tank portion are in communication with each other through the opening portion, and one end portion of the sample discharging unit is closed A substantially cylindrical body portion having an outlet at its other end and an inlet formed at its side, a piston portion which can move inside the body and can close the outlet, and the piston portion Unconsolidated sampling characterized in that it has a handle portion connected to the piston portion and capable of moving the piston portion, and the inside of the body portion and the inside of the tank portion communicate with each other through the inflow port. apparatus.   The unconsolidated sampling device according to claim 1, wherein a longitudinal direction of the body portion of the sampling unit and a central axis of the rod connecting portion are substantially parallel.   A plurality of small tanks are formed inside the tank, each small tank is provided with at least one sampling unit and one sample discharge unit, and the inside of each small tank is The inside of the body portion of the sampling unit is in communication with the inside of the body through the opening, and the inside of the body portion of the sample discharge unit is in communication through the inflow port. An unconsolidated sampling device according to claim 1 or 2.

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