JP2004211523A - Geological survey equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide geological survey equipment capable of measuring a static penetration resistance of a ground in an underground layer and, at the same time, surely sampling a ground specimen. <P>SOLUTION: The geological survey equipment 1 is equipped with a penetration rod 3 wherein a sampling section 2 for sampling the ground specimen is provided and a sounding testing screw point 4 put on the front end of the penetration rod 3. The sampling section 2 is equipped with a pocket for storing the ground specimen and a lid body 21 closing an opening section of the pocket, the screw point 4 is penetrated into the ground to maintain a state for the lid body 21 to close the opening section to the rotation in the direction of the forward rotation forming a hole, and the lid body 21 is so constituted that it can open the opening section by friction with the inner circumferential surface of the hole to the rotation in the direction of the reverse rotation. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a geological survey device for collecting a ground sample.
[0002]
[Prior art]
When constructing a building, a geological survey is generally performed by drilling, but recently, a simple geological survey is also performed on a detached house. In the case of a detached house, a Swedish sounding test method (Japanese Industrial Standard A1221) is the most widely used survey method. This can be investigated up to an inexpensive and somewhat hard ground (up to an N value of about 20). However, in this method, the soil sample cannot be sampled only by judging the strength of the ground by penetrating the screw at the tip.
[0003]
In recent detached houses, it has become necessary to design the stability of the building after construction in more detail. This has been caused by the revision of the Building Standards Law and an increase in building disputes. When making detailed ground determinations, it cannot be said that determining the ground depth alone is sufficient, and it is necessary to sample soil samples to determine whether the water content is high and to determine the water quality of the water (eg, , Alkalinity or acidity).
[0004]
As a conventional soil sampler, a soil sampler described in Patent Document 1 is exemplified. This device has a structure in which a number of sampling units are connected in cascade, a cone is attached to the distal end, and a penetrating rod is connected to a proximal end. The sampling unit 80 has an outer diameter substantially equal to the diameter of the hole formed by the cone penetration test of the ground. As shown in FIG. 14, the sampling unit 80 is provided with a storage space 81 for the soil sample, and a window 82 as an opening of the storage space 81 is provided with a blade 83 for shaving the soil sample. Is provided. The blade 83 is provided so as to cover most of the window 82 and the blade edge 83a projects slightly outward.
[0005]
[Patent Document 1]
JP-A-11-140858
[0006]
[Problems to be solved by the invention]
However, since the conventional soil sampling device has a window 82 in which the accommodation space 81 for accommodating the soil sample is always open, it can be inserted into or removed from a hole formed in the ground. In addition, there is a problem that a soil sample having a depth other than the intended purpose enters the accommodation space 81.
[0007]
In addition, if sampling is performed after conducting a Swedish sounding test, the test rod must be pulled out once at the sampling position, and the sampling device must be pushed back into the hole to perform the work. There is a problem that is up.
[0008]
It is conceivable that the sampling unit 80 may be adopted as a penetrating rod of the Swedish sounding test apparatus so that the sounding test and the sampling may be completed in one process. When the sampling unit 80 is rotated during the sounding test, a soil sample of an unintended depth enters the accommodation space 81 from the window 82 that is always open. There is a problem. In addition, the sampling unit 80 has a problem that since the cutting edge 83a protrudes outward, the resistance during rotation increases, which adversely affects the sounding test.
[0009]
An object of the present invention is to solve the above problems and to provide a geological survey device capable of reliably collecting a ground sample at a target depth.
[0010]
Further, an object of the present invention is to solve the above-mentioned problems and to provide a geological survey device capable of measuring a static penetration resistance of the ground in an underground layer and reliably collecting a ground sample at a desired depth. It is in.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, a geological survey device of the present invention is a geological survey device including a penetration rod provided with a sampling unit for sampling a ground sample, wherein the sampling unit accommodates the ground sample. A concave portion, and a lid closing the opening of the concave portion, and the lid closes the opening for rotation in the forward rotation direction, which is one rotation direction about the axis of the penetrating rod. The state is maintained, and the lid is configured to open the opening by friction with the inner peripheral surface of the hole with respect to rotation in the reverse rotation direction.
[0012]
Further, the geological survey device of the present invention is a geological survey device including a penetrating rod provided with a sampling unit for sampling a ground sample, and a screw point for a sounding test attached to a tip of the penetrating rod. The sampling unit includes a concave portion that accommodates the ground sample, and a lid that closes an opening of the concave portion, and the screw point penetrates into the ground to form a hole to prevent rotation in a forward rotation direction. Is configured such that the lid keeps the state in which the opening is closed, and the lid opens the opening due to friction with the inner peripheral surface of the hole against rotation in the reverse rotation direction. ing.
[0013]
In this document, the ground sample includes a liquid such as water in addition to a soil sample such as soil, mud, sand, gravel, and stone.
[0014]
On the outer peripheral surface of the penetrating rod, a mounting portion of the lid body that is relatively depressed from the periphery is formed, and a normal rotation direction side of the mounting portion is a positive rotation of the lid body. The cover is suddenly depressed so as to cover the side part, and the reverse rotation direction side of the mounted portion is gently depressed so as not to cover the reverse rotation side of the lid. Is illustrated.
[0015]
The mode in which the lid opens the opening is not particularly limited, but the following mode is exemplified.
(1) A mode in which the opening is opened by removing the whole from the penetrating rod. In this aspect, the penetrating rod is configured to have a configuration in which a projection for shaving a soil sample appears at or around the opening when the lid is separated.
(2) A mode in which the opening is opened when the reverse rotation direction side is separated from the penetration rod and opened. In this embodiment, the lid is configured to be opened until it is turned upside down, and a convex portion for cutting a soil sample is provided on the back surface.
[0016]
In addition, the lid is illustrated as an example in which the reverse rotation direction side is easily separated. Although this configuration is not particularly limited, the following embodiments are exemplified.
(A) A mode in which the forward rotation direction side of the lid is attached to a penetrating rod, and the reverse rotation direction side is not attached. Here, “attachment” is not particularly limited, but may be an aspect attached by a fitting structure, an aspect attached by applying an adhesive, an aspect attached by an adhesive tape, or a hinge in which one piece is fixed to a penetrating rod. And the like, which are openably and closably attached.
(B) A mode in which the opposite rotation direction side of the lid is lifted from the outer peripheral surface of the penetrating rod.
(C) An embodiment in which a convex portion facing the reverse rotation direction is provided on the lid.
(D) An embodiment in which two or more of the above (a) to (c) are combined.
[0017]
Further, in the above-mentioned geological survey device, at the time of sampling the ground sample, the head is attached between the head mounted on the base end side of the penetrating rod and the head turning around the head, and the rotation of the head turning is performed. An embodiment provided with an eccentric adapter for eccentricizing the central axis of the penetrating rod with respect to the axis will be exemplified.
[0018]
A mode in which a liquid sampling medium for impregnating and sampling a liquid as a ground sample is inserted into the concave portion of the sampling section is exemplified.
[0019]
The liquid collection medium is not particularly limited, and examples thereof include a nonwoven fabric, a felt, a cloth, and a sponge.
[0020]
An example in which a test medium for examining the liquid quality of the liquid is inserted into the concave portion of the sampling section together with the liquid collection medium is exemplified.
[0021]
The test medium is not particularly limited, and examples of the paper medium include litmus test paper and various pH test papers for measuring pH. The test medium may be made of a material other than paper.
[0022]
An example in which the penetration rod is formed with a spiral groove wound in a direction to be screwed into a hole formed in the ground by the rotation in the forward rotation direction. This “direction of screwing into the hole formed in the ground by the rotation in the forward rotation direction” is the same as the spiral of the screw point when the screw point is provided.
[0023]
The groove exemplifies a mode in which the tip end portion of the penetrating rod is formed so as to be recessed stepwise with respect to the outer peripheral surface of the penetrating rod. This “penetration rod tip side” is the same side as the screw point side when the screw point is provided.
[0024]
The groove exemplifies a mode in which the proximal end portion of the penetrating rod is formed so as to be gradually depressed with respect to the outer peripheral surface of the penetrating rod. This “protruding rod base end side” is the same side as the counter screw point side when the screw point is provided.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
1 to 8 show a geological survey device 1 according to a first embodiment of the present invention. As shown in FIG. 1, the apparatus 1 includes a penetrating rod 3 provided with a sampling unit 2 for sampling a ground sample, a screw point 4 for sounding test attached to a tip of the penetrating rod 3, 3 is provided with a joiner 5 as a head mounted on the base end side, and an eccentric adapter 6 mounted on the joiner 5. In this example, a sounding test embodied for a Swedish sounding test will be described. In this example, the rotation direction in which the screw point 4 penetrates the ground to form a hole is referred to as “forward rotation direction”, and the opposite direction is referred to as “reverse rotation direction”.
[0026]
The penetrating rod 3 has a plurality of rod pieces 10 shown in FIGS. 2 and 3 connected in cascade, and in this example, all the sampling units 2 are provided in the same direction. In the Swedish sounding test, since it is not necessary to rotate in the reverse rotation direction, each rod piece 10 is usually connected with a screw tightened by rotation in the forward rotation direction, but in the geological survey device 1 of the present invention, Since the soil sample is sampled by reverse rotation after penetration, they are connected to each other so that they cannot rotate relative to each other. The connecting structure is not particularly limited, but as shown in FIG. 4, in this example, a substantially prismatic convex portion 11 is provided on one end surface of each rod piece 10 in the longitudinal direction, and the convex portion 11 is provided on the other end surface. There is provided a recess 12 into which 11 fits. A hole 13 is formed in the convex portion 11 and the concave portion 12 so as to penetrate the two when the two are fitted. A pin 14 is inserted into the hole 13 and both sides of the hole 13 are A pin 14 is prevented from coming off by attaching an elastic band 15 formed in a C-shape so as to close it. The concave side end portion 10a of the rod piece 10 to which the elastic band 15 is attached is reduced in diameter, and the outer peripheral surface of the rod piece 10 and the outer peripheral surface of the elastic band 15 are substantially flat without the step when the elastic band 15 is attached. It is designed to be flush. On the inner peripheral surface of the elastic band 15, a pair of convex portions 15a (only one of them may be fitted) that fits into the opening of the hole 13 for preventing the elastic band 15 from rotating is formed. As shown in FIG. 5, a pair of engaged holes 15b for engaging the engaging claws 16a of the pliers 16 for removing the elastic band 15 is provided on the outer peripheral surface of the elastic band 15. I have. In this example, the connection structure between the screw point 4 or the joiner 5 and the rod pieces 10 is also the same as the connection structure between the rod pieces 10.
[0027]
The rod piece 10 of this example is formed to have a length of 0.5 m, and the sampling unit 2 is provided at the center in the length direction. Therefore, when the rod pieces 10 are connected, the penetrating rod 3 is in a state in which the sampling unit 2 is provided every 0.5 m. Although the interval between the sampling units 2 is not particularly limited, it is exemplified that the sampling units 2 are provided at one or more locations where the length of the penetrating rod 3 is about 1.0 m as in this example.
[0028]
The sampling section 2 includes a pocket 20 serving as a concave portion for storing a ground sample in the underground layer, and a lid 21 for closing an opening 20 a of the pocket 20.
[0029]
The pocket 20 is formed by a vertically long concave hole formed in the peripheral surface of the rod piece 10. The pocket 20 is recessed obliquely downward. This prevents the collected soil sample from falling off at the time of withdrawal after sampling, and enables the water in the ground to be collected.
[0030]
The lid 21 is for preventing the soil sample from entering the pocket 20 during the penetration test, and is made of resin such as plastic in this example. The lid 21 is mounted on a mounting portion 22 formed on the outer peripheral surface of the penetrating rod 3. The mounted portion 22 is relatively depressed relative to the surroundings, and when mounted on the mounted portion 22, the lid 21 does not protrude outward from the outer peripheral surface of the penetrating rod 3 in a sectional view. It has become. The forward rotation direction side of the mounted portion 22 is suddenly recessed so as to cover the side portion of the cover 21 on the forward rotation direction side, thereby forming a step portion 22a, and the penetrating rod 3 rotates forward. The lid 21 is prevented from detaching due to the resistance of the inner peripheral surface W of the hole when rotating in the direction. Further, the reverse rotation direction side of the mounted portion 22 is gently recessed so as not to cover the side portion of the lid 21 on the reverse rotation direction side, and when the penetrating rod 3 is rotated in the reverse rotation direction. The reverse rotation direction side of the lid 21 is separated by the resistance of the inner peripheral surface W of the hole. In addition, a blade 23 as a convex portion facing in the same direction is provided on a side edge portion of the cover 21 in the reverse rotation direction, and the blade 23 is attached to the surface of the mounting portion 22 in a state where the cover 21 is mounted. From a little floating. Thereby, when the penetrating rod 3 is rotated in the reverse rotation direction, the resistance of the inner peripheral surface W of the hole is easily received, the lid 21 is easily separated in the reverse rotation direction, and the soil sample is removed by the blade 23. I try to sharpen it.
[0031]
The mounting structure of the lid 21 is not particularly limited, but in this example, mounting holes 25 are provided above and below the pocket 20 of the mounted portion 22 on the positive rotation direction side. A pair of upper and lower pins 26 to be fitted are provided, and the pins 26 are inserted into the mounting holes 25 for mounting. The lid 21 keeps the state in which the opening 20a is closed for rotation in the forward rotation direction (see FIG. 8A), and the inner periphery of the hole for rotation in the reverse rotation direction. The opening 20a is opened by partly opening from the opening 20a due to friction with the surface W (see FIG. 8B).
[0032]
The screw point 4 is a well-known one used for a Swedish sounding test, and is made of a special steel having high wear resistance.
[0033]
As shown in FIG. 6, the joiner 5 includes a connecting portion 30 connected to the rod piece 10 and a rotatable member 31 extending in a radial direction of the penetrating rod 3 attached to an upper end of the connecting portion 30. A positioning hole 31 a is provided on the upper surface of the rotated member 31 at a position concentric with the central axis of the penetrating rod 3. The joiner 5 is directly rotated by a joiner turning 32 as a head turning during a sounding test, and is rotated via an eccentric adapter 6 during a sampling test. The lower surface of the joiner turn 32 includes a positioning pin 33 that penetrates into the positioning hole 31a of the rotated member 31 and a contact pin 34 that abuts on both side surfaces of the rotated member 31 to transmit the rotational force. .
[0034]
The eccentric adapter 6 is interposed between the joiner 5 and the joiner whirl 32 at the time of sampling the ground sample, and eccentricizes the center axis of the penetration rod 3 with respect to the rotation axis of the joiner whirl 32. Specifically, the eccentric adapter 6 has a concave portion 35 on the lower surface side thereof into which the rotatable member 31 of the joiner 5 can penetrate, and an eccentric positioning hole 36 on the upper surface side into which the positioning pin 33 of the joiner turn 32 is fitted. The eccentric positioning hole 36 is provided at a position shifted from the central axis of the penetrating rod 3 as shown in FIGS. For this reason, when the joiner 5 is turned by the joiner turning 32 via the eccentric adapter 6, the penetrating rod 3 rotates in a substantially conical shape with the screw point 4 at the apex, and the sampling unit 2 is securely placed on the inner peripheral surface W of the hole. The opening 21 a is reliably opened by the lid 21 so that the ground sample is collected in the pocket 20.
[0035]
Next, a method of using the geological survey device 1 of the present invention will be described. First, a Swedish sounding test is performed by rotating the penetrating rod 3 in the forward rotation direction by the joiner turning 32. Then, the penetration rod 3 is penetrated to the test completion depth. Next, the eccentric adapter 6 is interposed between the joiner 5 and the joiner turn 32, and the penetrating rod 3 is rotated in the reverse rotation direction. Then, the lid 21 is opened, and the ground sample is collected in the pockets 20 provided every 0.5 m in depth. When the sampling is completed, the test is completed by pulling the penetrating rod 3 upward as it is. When the eccentric adapter 6 is not interposed, the penetrating rod 3 may be rotated in a state where the center of the penetrating rod 3 is brought close to the inner peripheral surface W of the hole.
[0036]
According to the geological survey device 1 of the present invention configured as described above, since the penetration section 3 is provided with the sampling section 2 for sampling the ground sample, the ground section is not pulled out after the sounding test is completed. A sample can be easily collected. Therefore, the working efficiency can be greatly improved as compared with the case where the sounding test and the sampling are separately performed.
[0037]
In addition, the sampling unit 2 includes a pocket 20 for storing a ground sample, and a lid 21 for closing the opening 20a of the pocket 20, and the rotation in the forward rotation direction in which the screw point 4 penetrates the ground. The lid 21 maintains the state that the opening 20a is closed, and the lid 21 is configured to open the opening 20a by friction with the inner peripheral surface W of the hole against rotation in the reverse rotation direction. Therefore, it is possible to prevent a soil sample having an undesired depth from entering the pocket 20 during the sounding test, and to reliably collect a soil sample having a desired depth.
[0038]
Further, the lid 21 is provided with a blade 23 facing the same direction at the side edge in the reverse rotation direction, and the blade 23 is slightly floated from the surface of the mounted portion 22 in a state where the lid 21 is mounted. Therefore, when the penetrating rod 3 is rotated in the reverse rotation direction, the reverse rotation direction side of the lid 21 can be easily separated by receiving the resistance of the inner peripheral surface W of the hole. Moreover, when the lid 21 is away from the reverse rotation direction, the blade 23 cuts the soil sample, so that the ground sample can be efficiently collected in the pocket 20.
[0039]
In addition, since the eccentric adapter 6 is provided for eccentricizing the central axis of the penetrating rod 3 with respect to the rotation axis of the joiner rotation 32, the sampling unit 2 (particularly in the reverse rotation direction) is inserted into the hole when sampling the ground sample. The lid 21 is reliably brought into contact with the peripheral surface W, so that the lid 21 reliably opens the opening 20 a and the ground sample can be reliably collected in the pocket 20.
[0040]
Next, FIG. 9 shows a geological survey device according to a second embodiment of the present invention. The geological survey device of the present embodiment is different from the first embodiment in the configuration of the lid 41, and the rest is common to the first embodiment. Therefore, the same parts as those in the first embodiment will be denoted by the same reference numerals, and redundant description will be omitted (hereinafter, the same applies to other embodiments).
[0041]
The lid 41 of the present embodiment is provided with a main body 42 made of an elastic metal mesh having a fine mesh so as not to allow most soil samples to pass therethrough, and a pair of upper and lower pins 43 fitted into the mounting holes 25. . In this example, the pin 43 is made of resin, and is fixed to the main body 42 by welding. Further, the reverse rotation direction side of the lid 41 is slightly floated from the surface of the mounted portion 22 in a state where the lid 41 is mounted, and the penetrating rod 3 is rotated in the reverse rotation direction. In this case, the resistance of the inner peripheral surface W of the hole is easily received so that the reverse rotation direction side of the lid 41 is easily separated. Then, the lid 41 maintains a state in which the opening 20a is closed for rotation in the forward rotation direction (see FIG. 9A), and the inner peripheral surface W of the hole is rotated when rotated in the reverse rotation direction. When the resistance is received, the soil sample is opened until it is turned upside down, and the soil sample is cut at the edge and the back surface (see FIG. 9B), whereby the ground sample can be efficiently collected in the pocket 20. .
[0042]
According to this embodiment, the same effect as that of the first embodiment can be obtained.
[0043]
Next, FIGS. 10 and 11 show a geological survey device according to a third embodiment of the invention. The geological survey device of the present embodiment is different from the first embodiment in the configuration of the lid 51, and the rest is common to the first embodiment.
[0044]
As shown in FIG. 10, the lid 51 of the present embodiment is formed by applying an adhesive 53 to the back surface of a base material 52 such as a thin plate or a sheet made of a resin such as plastic. No adhesive 53 is provided on the reverse rotation direction side of the back surface of the lid 51, and the penetration rod 3 is peeled off by the resistance of the inner circumferential surface W of the hole when the penetration rod 3 is rotated in the reverse rotation direction. Making it easier. The same structure as that of the lid 51 can also be realized by, for example, folding back the hard tape in the reverse rotation direction side to the back side. On the back surface of the lid 51, a projection 54 for cutting a soil sample is provided. Then, the lid 51 keeps the state in which the opening 20a is closed for rotation in the forward rotation direction (see FIG. 10A), and the inner peripheral surface W of the hole is rotated when rotating in the reverse rotation direction. Upon receiving the resistance, the soil sample is opened until it is turned upside down, and the soil sample is cut by the convex portion 54 provided on the back surface thereof (see FIG. 10B). Can be collected.
[0045]
FIG. 11 shows a modification of the lid 51 of the present embodiment.
(1) The lid 55 shown in FIG. 11A includes a lid piece 56 made of metal or hard resin for closing the opening 20a, and a hard tape 57 for attaching the lid piece 56 to the mounting portion 22. ing. The reverse rotation direction side of the tape 57 is folded back (the folded portion 57b) so that the adhesive 57a does not contact the mounted portion 22. As a result, as shown by a two-dot chain line in FIG. Then, when the penetration rod 3 rotates in the reverse rotation direction and receives the resistance of the inner peripheral surface W of the hole, the lid 55 is opened and the soil sample is cut off at the edge of the lid piece 56.
[0046]
(2) The lid 58 shown in FIG. 11 (b) has a hinge 59 in which one piece 59a is fixed to the opening 20a in the forward rotation direction by welding or a screw and the other piece 59b is rotatable. And a hard tape 57 adhered from above the hinge 59 so as to close the opening 20a. The other piece 59b of the hinge 59 is rotatable to a position shown by a two-dot chain line in the same figure, and in this state, about 5 to 15% of the diameter of the penetrating rod 3 from the outer peripheral surface of the penetrating rod 3. It is designed to protrude. Further, on the reverse rotation direction side of the tape 57, a folded portion 57b similar to the above-described modified example (1) is formed. Then, when the penetration rod 3 rotates in the reverse rotation direction and receives the resistance of the inner peripheral surface W of the hole, the lid 58 opens and the soil sample is cut off at the edge of the other piece 59b of the hinge 59. .
[0047]
In addition, in the above modified examples (1) and (2), instead of the hard tape 57, paper, cloth (woven fabric), or non-woven fabric coated with an adhesive can be used. In addition, in the above-described modified examples (1) and (2), the opposite rotation direction sides of the lids 55 and 58 are not attached to the attached portion 22, but are attached with the adhesive 57a next to the folded portion 57b. You may do so.
[0048]
According to this embodiment, the same effect as that of the first embodiment can be obtained.
[0049]
Next, FIG. 12 shows a geological survey device 60 according to a fourth embodiment of the present invention. The geological survey device 60 of the present embodiment is different from the first embodiment in that the liquid sampling medium 61 and the test paper 62 are inserted into the pockets 20 of the sampling unit 2, and the other embodiments are the same as those of the first embodiment. And in common.
[0050]
The liquid sampling medium 61 is used for sampling by impregnating groundwater as a ground sample or moisture in the ground, and is made of a nonwoven fabric in this example. The shape of the liquid collection medium 61 is not particularly limited, but in the present example, as shown in FIG. Further, the shape of the liquid collection medium 61 is not particularly limited, but in this example, the liquid collection medium 61 is formed slightly larger than the opening of the pocket 20 so as not to fall out of the pocket 20 during the geological survey, and is pushed into the pocket 20. To be used in
[0051]
The test paper 62 is for investigating the liquid quality of water (in this example, pH measurement), and is provided in the pocket 20 together with the liquid collection medium 61. The method of providing the test paper 62 is not particularly limited. However, the test paper 62 is sandwiched between the inner surface of the pocket 20 and the outer surface of the liquid collecting medium as shown in FIG. 12A, or is divided and formed as shown in FIG. An example is shown in which the liquid collection medium 61 is sandwiched between divided pieces 61a, 61a.
[0052]
Next, a method of using the geological survey device 60 of the present embodiment will be described. For example, the sampling unit 2 of every other penetration rod 3 (can be changed as appropriate, and may be two or more) (that is, 1.0 m At intervals), the liquid sampling medium 61 and the test paper 62 are inserted, and the lid is attached. The sampling unit 2 in which the liquid sampling medium 61 and the test paper 62 are not inserted is the same as in the first embodiment. Then, a geological survey is performed as in the first embodiment. Then, a ground sample at a depth of 1.0 m can be sampled in the same manner as in the first embodiment, and groundwater or moisture in the ground at a depth of 1.0 m is impregnated into the liquid sampling medium 61 and the test paper 62. Can be done. Then, the liquid sampling medium 61 and the test paper 62 are taken out from the pocket 20, and the water quality can be immediately determined based on the reaction state of the test paper 62. Further, the water impregnated in the liquid collection medium 61 can be separately investigated in detail.
[0053]
According to the present invention, in addition to the effects of the first embodiment, since the liquid collecting medium 61 is inserted into the pocket 20, it is possible to reliably collect the liquid by impregnating the groundwater or the moisture in the ground.
[0054]
Further, since the test paper 62 is inserted into the pocket 20 together with the liquid collection medium 61, the water quality can be determined immediately after the completion of the sampling test.
[0055]
Next, FIG. 13 shows a geological survey device 70 according to a fifth embodiment of the present invention. The geological survey device 70 of the present embodiment is different from the first embodiment in that a spiral groove 71 is formed in the penetrating rod 3, and the rest is common to the first embodiment.
[0056]
The groove 71 extends in a spiral shape wound in the same direction as the spiral of the screw point (the direction of screwing into the hole formed in the ground by the rotation in the normal rotation direction), and in this example, both ends of the rod piece Side. The end 71 a of the groove 71 on the screw point side (tip side of the penetrating rod) is formed so as to be recessed stepwise with respect to the outer peripheral surface of the penetrating rod 3. The end 71 b of the groove 71 on the side opposite to the screw point (the base end side of the penetrating rod) is formed so as to be gradually recessed with respect to the outer peripheral surface of the penetrating rod 3.
[0057]
The method of using the geological survey device 70 of the present embodiment is almost the same as that of the first embodiment, except that the groove 71 operates as follows. First, even if the soil sample enters the groove during the sounding test, since the groove 71 is wound in the same direction as the spiral of the screw point, the penetration rod 3 penetrates into the ground with the rotation in the forward rotation direction. On the other hand, the soil sample is sent relatively to the screw point side. The end 71b of the groove 71 on the side opposite to the screw point is formed so as to be gently depressed with respect to the outer peripheral surface of the penetration rod 3, so that the groove 71 is smoothly discharged from the end 71b. On the other hand, at the time of sampling, when the penetrating rod 3 is rotated in the reverse rotation direction while being pressed against the inner peripheral surface W of the hole, the soil sample is scraped off by the groove 71 and enters the groove. Moreover, the soil sample is relatively sent to the screw point side by the rotation of the penetrating rod 3 in the reverse rotation direction, but the screw point side end 71 a of the groove 71 is stepped with respect to the outer peripheral surface of the penetrating rod 3. Since it is formed so as to be depressed, a soil sample is reliably collected at the end portion 71a.
[0058]
According to the present invention, in addition to the effect of the first embodiment, the above effect can be obtained by the spiral groove 71 wound in the same direction as the spiral of the screw point 4.
[0059]
15 to 18 show a geological survey device 100 according to a sixth embodiment of the present invention. The geological survey device 100 of the present embodiment inserts into a hole 101 formed in the ground in advance and samples a ground sample. The following points are different from the first embodiment, and the others are the first embodiment. And in common. In this example, the "forward rotation direction", which is one rotation direction about the axis of the penetrating rod 103, is set in the direction of the arrow in FIG. 17A, and the "reverse rotation direction" that is the opposite direction is the same. It is set in the direction of the arrow in FIG.
[0060]
As shown in FIG. 15, the apparatus 100 includes a penetrating rod 103 provided with a sampling unit 2 for sampling a ground sample, a substantially cone-shaped cone 104 attached to the tip of the penetrating rod 103, and a penetrating rod 103. A handle 105 is provided on the base end side, and a guide member 106 is provided at an opening of a hole 101 formed in the ground. In addition, instead of the cone 104, another protrusion may be appropriately mounted on the distal end side of the penetrating rod 103, or a screw point for a sounding test may be mounted. You can also.
[0061]
The penetrating rod 103 of the present example has a plurality of rod pieces 110 shown in FIG. 16 connected in cascade. Each rod piece 110 is connected by a male screw 111 and a female screw 112 that are tightened by rotation in the reverse rotation direction. Thereby, when sampling the ground sample by rotating the penetrating rod 103 backward in the hole, each rod piece 110 is prevented from coming off.
[0062]
The rod piece 110 includes an engaged portion 115 formed of a pair of flat portions formed at a back-to-back position with respect to the center axis, an identification number 116 for identifying the rod piece 110, and a guide member 106. And a sampling section 2 for inserting a pin 117 for locking the pin 117. The engaged portion 115 is for engaging a tool such as a wrench for tightening and removing the screws 111 and 112 by rotating the rod piece 110. The length of the rod piece 110 of this example excluding the male screw 111 is 1 m. When the rod piece 110 is connected, the penetrating rod 103 is in a state where the sampling unit 2 is provided every 1 m.
[0063]
A drain hole 119 communicating with the outer peripheral surface of the penetrating rod 103 is formed in the pocket 20 of the sampling unit 2, and discharges excess liquid when the ground sample contains a large amount of liquid (water or the like). It is supposed to.
[0064]
In this example, the lid 121 that covers the opening 20a of the sampling unit 2 is formed of a metal plate that is formed so as to be fitted to the mounted portion 22 of the penetration rod 103. The forward rotation direction side edge of the lid 121 is connected to the outer peripheral surface of the penetrating rod 103 with an adhesive tape 122, so that the reverse rotation side of the lid 121 can be opened and closed. Accordingly, the lid 121 keeps the state in which the opening 20a is closed with respect to the rotation in the forward rotation direction as shown in FIG. 17A, and moves in the reverse rotation direction as shown in FIG. The lid 121 is configured to open the opening 20a due to friction with the inner peripheral surface W of the hole with respect to the rotation of. The pressure-sensitive adhesive tape 122 is not particularly limited. However, if the base material has firm stickiness and elasticity, the lid 121 can be prevented from opening and closing without tightness. In this example, since the lid 121 is attached to the penetrating rod 103 with the adhesive tape 122, even if the inner peripheral surface W of the hole 101 has a hard part such as a rock and the lid 121 is caught, the adhesive tape 122 is The lid 121 is torn and comes off the penetration rod 103. Therefore, it is possible to prevent the penetration rod 103 from being damaged and prevent the penetration rod 103 from being pulled out of the hole 101.
[0065]
The guide member 106 has a guide hole 125 for guiding the penetrating rod 103, and an annular convex portion 126 is provided at a peripheral portion of the guide hole 125. A notch 126a is formed in the annular convex portion 126 at a position symmetrical with respect to the center axis of the guide hole 125, and a pin 117 for locking the rod piece 110 is locked here.
[0066]
Next, a method of using the geological survey device 100 of the present invention will be described. In this example, it is assumed that the hole 101 by a sounding test or the like is formed in the ground in advance. In this example, it is assumed that the penetrating rod 103 includes five rod pieces 110.
(1) The guide member 106 is disposed on the ground so that the hole 101 and the center of the guide hole 125 coincide.
(2) The cone 104 is attached to the distal end side of the first rod piece 110, and the rod piece 110 is inserted into the hole 101 via the guide hole 125 of the guide member 106. At this time, as shown in FIG. 17 (a), when the insertion is performed while being rotated little by little in the forward rotation direction, the lid 121 does not open during the insertion, and the ground sample having an unintended depth is sampled during the insertion. It can be reliably prevented from entering the part 2.
(3) The pin 117 is inserted into the pin hole 118 of the first rod piece 110, and the first rod piece 110 is locked to the guide member 106 as shown in FIG. In this state, the second rod piece 110 is connected to the upper end side of the first rod piece 110. The pin 117 is pulled out from the pin hole 118 of the first rod piece 110, and the second rod piece 110 is inserted into the hole 101.
(4) The above (3) is repeated for the third to fifth rod pieces 110.
(5) The handle 105 is attached to the upper end of the fifth rod piece 110, and the penetrating rod 103 is rotated in the reverse rotation direction while the peripheral surface of the penetrating rod 103 is in contact with the inner peripheral surface W of the hole 101. . Then, as shown in FIG. 17B, the lid 121 is opened to open the opening 20 a, and the ground sample is shaved by the reverse rotation side edge of the lid 121 and collected in the pocket 20. Next, the cover 121 is closed by slightly rotating the penetration rod 103 in the forward rotation direction. Next, the handle 105 is removed from the penetration rod 103.
(6) The procedure of (3) and (4) is reversed, and the penetrating rod 103 is pulled out from the hole 101 while removing the upper rod pieces 110 one by one. At this time, when pulling out while rotating the penetrating rod 103 little by little in the forward rotation direction side, the lid 121 does not open during the pulling out, and the ground sample having an unintended depth enters the sampling section during the pulling out. It can be reliably prevented. This completes the work.
[0067]
According to the geological survey device 100 of the present invention configured as described above, the lid 121 keeps the state that the opening 20a is closed with respect to the rotation in the normal rotation direction as in the first embodiment, Since the lid 121 is configured to open the opening 20a by friction with the inner peripheral surface W of the hole 101 with respect to rotation in the reverse rotation direction, reverse rotation is performed only when a ground sample is collected. Thereby, it is possible to prevent a ground sample having an unintended depth from entering the sampling unit 2 while the penetration rod 103 is being inserted into the hole 101 or being pulled out from the hole 101, and the desired depth can be prevented. Ground samples can be collected reliably.
[0068]
Note that the present invention is not limited to the above-described embodiment, and may be embodied with appropriate modifications without departing from the spirit of the invention, for example, as described below.
(1) The mounting structure of the lids 21, 41, 51, 121 is appropriately changed. For example, a structure in which the projections are slightly smaller than the range of the opening 20a of the pocket 20 on the back side of the lids 21 and 41 may be attached to the opening 20a.
(2) To increase or decrease the arrangement interval of the sampling unit 2 as appropriate.
(3) The shapes of the pocket 20 and the lid are appropriately changed.
(4) The lids 21, 41, and 51 are configured so as to open the opening 20a by being entirely separated from the opening 20a. In this case, if the penetrating rod 3 is configured such that a projection for shaving the soil sample appears at or around the opening 20a when the lids 21, 41, 51 are separated, the soil sample is efficiently collected in the pocket 20. It is preferred because it can In the embodiment, the step 22a of the mounted portion 22 corresponds to the convex portion.
(6) In the first to fourth and sixth embodiments, the groove 71 of the fifth embodiment is provided instead of the sampling unit 2 provided on the penetrating rod 3.
(7) Applying the changes of the second to fifth embodiments to the geological survey device 1 of the first embodiment to the geological survey device 100 of the sixth embodiment.
[0069]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to the geological survey apparatus of Claim 1 of this invention, the outstanding effect that the ground sample of the target depth can be reliably collected is produced.
[0070]
Further, according to the geological survey device according to claim 2 of the present invention, the excellent effect that the static penetration resistance of the ground in the underground layer can be measured and the ground sample at the target depth can be reliably collected. To play.
[0071]
The above effects can also be obtained by the geological survey device according to claims 3 to 14 of the present invention.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a geological survey device according to a first embodiment of the present invention.
FIG. 2 is a front view of a rod piece constituting a penetration rod of the geological survey device.
FIG. 3 is a side view of the rod piece.
FIG. 4 is a view showing a method of connecting the rod pieces.
FIG. 5 is a sectional view taken along line VV of FIG. 1;
FIG. 6 is a perspective view showing how to use the eccentric adapter of the geological survey device.
FIG. 7 is a plan view showing a state where an eccentric adapter is attached to a joiner of the penetrating rod.
FIG. 8 is a sectional view taken along line VIII-VIII of FIG. 1 in a use state.
FIG. 9 is a sectional view similar to FIG. 8, showing a geological survey device according to a second embodiment of the present invention.
FIG. 10 is a sectional view similar to FIG. 8, showing a geological survey device according to a third embodiment of the present invention.
FIG. 11 is a diagram showing a modified example of the geological survey device.
FIG. 12 is a perspective view showing a sampling unit of a geological survey device according to a fourth embodiment of the present invention.
FIG. 13 is a front view of a rod piece of the geological survey device according to the fifth embodiment of the present invention.
FIG. 14 is a cross-sectional view showing an accommodation space for a ground sample in a conventional ground sample sampling apparatus.
FIG. 15 is an overall configuration diagram of a geological survey device according to a sixth embodiment of the present invention.
FIG. 16 is a front view of a rod piece constituting a penetration rod of the geological survey device.
17 is a sectional view taken along line XVII-XVII in FIG. 15 in a state of use.
FIG. 18 is a perspective view showing how to use the device.
[Explanation of symbols]
1 Geological survey device
2 Sampling unit
3 Penetrating rod
4 screw points
5 Joiner
6 Eccentric adapter
20 pockets
20a opening
21 Lid
22 Mounting part
22a Step
23 blades
32 Joiner
41 Lid
51 Lid
54 convex
55 Lid
58 Lid
60 Geological survey device
61 Liquid sampling medium
62 test paper
70 Geological Survey Equipment
71 groove
71a screw point side end
71b Non-Screw Point Side End
100 geological survey device
101 holes
103 Penetrating rod
104 cones
105 handle
106 Guide member
110 Rod Piece
121 lid
122 adhesive tape
Inner circumferential surface of W hole

Claims (14)

A geological survey device comprising a penetrating rod provided with a sampling unit for sampling a ground sample,
The sampling unit includes a concave portion that accommodates the ground sample, and a lid that closes an opening of the concave portion,
For rotation in the forward rotation direction, which is one rotation direction about the axis of the penetrating rod, the lid keeps the state in which the opening is closed, and for rotation in the reverse rotation direction, A geological survey apparatus configured such that the lid opens the opening by friction with an inner peripheral surface of the hole. A geological survey device including a penetration rod provided with a sampling unit for sampling a ground sample, and a screw point for a sounding test attached to a tip of the penetration rod,
The sampling unit includes a concave portion that accommodates the ground sample, and a lid that closes an opening of the concave portion, and the screw point penetrates into the ground to form a hole to rotate in a forward rotation direction. The lid maintains the state that the opening is closed, and the lid is configured to open the opening by friction with the inner peripheral surface of the hole against rotation in the reverse rotation direction. Geological survey equipment. On the outer peripheral surface of the penetrating rod, a mounting portion of the lid body that is relatively depressed from the periphery is formed,
The forward rotation direction side of the mounted portion is suddenly depressed so as to cover a side portion of the lid body on the forward rotation direction side,
The geological survey device according to claim 1, wherein a reverse rotation direction side of the mounted portion is gently depressed so as not to cover a side portion of the lid body on the reverse rotation direction side. The geological survey device according to any one of claims 1 to 3, wherein the lid is configured to open the opening by being entirely separated from the penetrating rod. The geological survey device according to claim 4, wherein the penetrating rod is configured such that when the lid is separated, a convex portion for shaving a soil sample appears at or around the opening. The geological survey device according to any one of claims 1 to 3, wherein the lid is configured to open the opening by opening the opposite rotation direction side away from the penetration rod. The geological survey device according to claim 6, wherein the lid is configured to open until it is turned over, and a convex portion for cutting a soil sample is provided on a back surface. The geological survey device according to any one of claims 4 to 7, wherein the lid is configured such that the reverse rotation direction side is easily separated. At the time of sampling a ground sample, the head is mounted between the head mounted on the base end side of the penetrating rod and the head turning that turns the head, and the center of the penetrating rod is rotated with respect to the rotation axis of the head turning. The geological survey device according to any one of claims 1 to 8, further comprising: an eccentric adapter for eccentricizing a shaft. The geological survey device according to any one of claims 1 to 9, wherein a liquid sampling medium for impregnating and sampling a liquid as a ground sample is inserted into the concave portion of the sampling unit. The geological survey device according to claim 10, wherein a test medium for examining the liquid quality of the liquid is inserted into the concave portion of the sampling unit together with the liquid collection medium. The geology according to any one of claims 1 to 11, wherein the penetration rod is formed with a spiral groove wound in a direction to be screwed into a hole formed in the ground by the rotation in the forward rotation direction. Survey equipment. 13. The geological survey device according to claim 12, wherein the groove is formed such that a tip end portion of the penetrating rod is recessed stepwise with respect to an outer peripheral surface of the penetrating rod. 14. The geological survey device according to claim 12, wherein the groove is formed such that a proximal end portion of the penetrating rod is gently depressed with respect to an outer peripheral surface of the penetrating rod.

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