JP2006152649A - Soil bearing power testing device and soil bearing power testing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a soil bearing power testing deice and a soil bearing power testing method capable of reducing an accident such that a measuring device part collides with an obstacle in moving, while accurately measuring a settlement quantity of the ground. <P>SOLUTION: An expansion column 11 is installed toward an upper part from the inside in an intermediate cylinder body 2 installable on the end part side of a boom (d) of a moving body D, and is arranged in a head part of the expansion column 11 via an adjusting crown 18 composed of a projecting part 19 and a recessed part 20 so as to be capable of abutting on an under surface of a ceiling slab B of a caisson. An expansion operation means is arranged on the expansion column 11, and a lower cylinder body 21 is installed in a lower part of the intermediate cylinder body 2. A hydraulic jack 22 for an actual load is fitted to and inserted into this lower cylinder body 21. A loading plate 26 is installably installed in a soil bearing power testing position, and a length measuring machine 27 for measuring a settlement quantity of the loading plate 26, is directly installed between the lower cylinder body 21 and the loading plate 26. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention uses a ground strength test apparatus for testing the ground strength of a caisson support ground after excavating the ground at the bottom of the caisson working chamber and sinking the caisson, and the ground strength test apparatus. The present invention relates to a proof test method.

  As a conventional technique of this kind, a ground strength test apparatus, there is a technique described in Japanese Patent No. 2747896.

  FIG. 10 is a partially longitudinal front view showing an example of the ground strength test apparatus described in the above-mentioned patent publication.

  10 includes a strut pipe 42, a first mounting base 44, a pressure sensor 47, a hydraulic jack 50 for loading, a loading base 57, and a second mounting base. 58, a measuring rod 59 and a length meter 61, a camera (not shown) provided at a key point in the work room, a computer and a monitor (none of which are shown) arranged in an operation room installed on the ground or the like. ) And the like.

  A pipe camber 43 is integrally attached to the upper end of the support pipe 42.

  The first mounting base 44 is fixed to the lower end portion of the support pipe 42. The first mounting base 44 has an upper flange 45, a lower flange 46, and a side bracket (not shown).

  The pressure sensor 47 is attached to the lower surface of the lower flange 46.

  The hydraulic jack 50 is attached to the lower part of the pressure sensor 47 via flanges 48 and 49. The hydraulic jack 50 includes a piston 51 and a piston rod 52. The hydraulic jack 50 is connected to a hydraulic unit (not shown) via hydraulic hoses 53 and 54.

  The loading platform 57 is attached to the lower end portion of the piston rod 52 of the hydraulic jack 50 via a spreader 55 and a mounting plate 56.

  A plurality of the second mounting bases 58 are provided on the upper surface of the mounting plate 56 at equal intervals in the circumferential direction, and extend upward.

  The measuring rods 59 are arranged at equal intervals in the circumferential direction and are installed on the second mounting base 58.

  The length meter 61 is disposed corresponding to the measuring rod 59 and is installed on the upper flange 45 of the first mounting base 44 via a stand 60. The probe 62 of each length meter 61 is in contact with the upper surface of the measuring rod 59.

  The camera captures the scale of a measuring instrument such as a length meter 61 or the position or orientation of various members and sends the data to a computer or monitor.

  The computer stores the measurement data of the settlement amount of the loading table 57 by the length meter 61 sent from the camera and the loading load at that time, and calculates the relationship between the loading load and the settlement amount. It comes to memorize. Further, the computer takes in data relating to the positions and postures of various members sent from other cameras, calculates the control amount of the members, and controls the members via the control means.

  The monitor displays the position and posture of various members, the amount of settlement of the loading table 57, the relationship between the loading load and the amount of settlement.

  Thus, when using the ground strength test apparatus 41, the excavator is attached as follows instead of the excavation bucket.

  That is, the ground strength test apparatus 41 is connected to the jib of the excavator and the bucket operation jack (not illustrated) via a bracket (not illustrated) provided on the first mounting base 44 of the ground strength test apparatus 41. Removably attach.

  Then, the ground strength test apparatus 41 is carried toward the test position by the excavator while the hydraulic jack 50 is contracted, and the loading table 57 is placed on the ground strength test position G ′ determined in advance on the ground G. Then, the ground strength test apparatus 41 is set up substantially vertically. Next, the hydraulic jack 50 is operated to the extension side, and the pipe camber 43 attached to the upper end portion of the support pipe 42 is abutted against the lower surface of the caisson ceiling slab B, and the ground strength test apparatus 41 is set in a testable state. .

  When the ground strength test apparatus 41 is set in a use state, a vertical direction indicator (not shown) is attached to the support pipe 42, the vertical direction indicator is photographed by a camera, and an image photographed by the camera is taken as a computer. The image is processed and displayed on the monitor, and the ground strength test apparatus 41 is set up substantially vertically while viewing the image.

Subsequently, the hydraulic jack 50 is extended, a reaction force is applied to the ceiling slab B, a load is applied to the loading table 57, the loading table 57 is pushed into the ground strength test position G ′ on the ground G, and the loading table 57 at this time is loaded. Is measured by the length meter 61 through the measuring rod 59. Then, the scale of the length meter 61 is read by the camera, and the measurement data is sent to the computer, stored, and displayed on the monitor. Further, the computer calculates the relationship between the loaded load (kN / m ³ ) and the amount of settlement (m) and stores this.

The test operation described above is repeated until the amount of settlement of the loading platform 57 reaches 15 mm or the loading load exceeds the maximum ground pressure level expected at the site or the yield point, and the test results are loaded by a computer. Summarize and memorize weight-sinking curve. Then, a load applied at a certain subsidence amount is obtained from a load-subsidence amount curve created by a computer, and the ground coefficient Ks (kN / m ³ ) is calculated using the following equation (1).

  Also, in the above-mentioned patent publication, the strut pipe 42 is constituted by a double pipe by combining an outer pipe and an inner pipe, and a ground strength test apparatus equipped with a hydraulic jack for adjusting the pipe length inside these pipes. Is also described.

  By the way, the ground strength test apparatus 41 described in the above-mentioned patent gazette has the following problems to be improved.

(1) Since the support pipe 42 and the pipe camber 43 are integrated, when the ceiling slab B is inclined, it is difficult to install the ground strength test device 41 substantially vertically, and an accurate measurement result is obtained. I can't.
(2) Since the subsidence amount and the strain amount of the ground strength test apparatus 41 are not confirmed, the measurement value cannot be corrected and the measurement value is inaccurate.
(3) In the case of a type in which the support pipe 42 has a double structure of an outer pipe and an inner pipe and is extended and contracted by a hydraulic jack, the support pipe 42 is changed due to a change in hydraulic pressure and oil amount applied to the hydraulic jack for extending and retracting the support pipe 42. May expand and contract, and the measurement error may increase.
(4) When checking the verticality of the ground strength test apparatus 41, the verticality indicator cannot be confirmed by digital display because the vertical direction indicator is viewed while viewing the image reflected by the camera.
(5) The measuring rod 59 is installed on the second mounting table 58 attached to the loading table 57, and the length measuring device 61 is mounted on the measuring rod 59 so that the amount of settlement of the loading table 57 is measured. The measuring device portion becomes large, and there is a high risk that the measuring device portion collides with an obstacle or the like when the ground strength test device 41 moves and is damaged.
(6) When the ground strength test apparatus 41 was attached to and removed from the caisson excavator, the work environment was poor because of high-pressure work.
(7) As described above, high-pressure work occurs, so that the working time is greatly limited, especially at a large depth, and the construction period becomes long and the cost becomes high.
(8) Conventionally, since the hydraulic jack 50 and the loading platform 57 are fixedly connected to the pressure sensor 47, the pressure sensor 47 is damaged and the measurement accuracy is hindered. In particular, when moving in an inclined state at the time of setting, a load such as the hydraulic jack 50 acts on the pressure sensor 47, and a bending moment or an offset load is applied, which may damage the pressure sensor 47.

  The present invention has been made in view of the above circumstances, and the object of the present invention is to accurately measure the amount of ground subsidence, and there are many accidents in which the measuring device collides with an obstacle or the like during movement. An object of the present invention is to provide a ground strength test apparatus.

  Another object of the present invention is to provide a ground strength test apparatus that can more accurately measure the amount of ground subsidence.

  Another object of the present invention is to provide a ground strength test apparatus that can be installed more accurately and quickly in the vertical direction.

  Furthermore, another object of the present invention is to provide a ground strength test method capable of more accurately and easily measuring the amount of ground subsidence.

  In order to achieve the above object, the invention of claim 1 is the invention of claim 1, wherein the movable body D is provided with a removable intermediate cylindrical body 2, and the intermediate cylindrical body 2 is provided with a retractable telescopic column 11. The head of the telescopic column 11 is provided with an abutting tool that presses the ceiling slab B in a rotatable manner, a lower cylinder 21 is attached to the lower part of the intermediate cylinder 2, and a loading jack 22 is installed in the lower cylinder 21. , A load plate 26 is attached to the lower portion of the load jack 22 described above, and a length measuring device 27 for measuring the amount of settlement of the load plate 26 is attached to the lower cylindrical body 21. Test equipment.

  According to a second aspect of the present invention, in the ground strength test apparatus according to the first aspect, a reaction force portion 21a is provided at an upper portion of the lower cylindrical body 21, and the load jack 22 and the reaction force portion 21a are provided between A pressure sensor 25 is provided.

  According to a third aspect of the present invention, in the earth strength test apparatus according to the first or second aspect, the internal thread 12 formed on the upper outer cylinder 10 attached to the intermediate cylinder 2 is used as the expansion / contraction means for the expansion / contraction column 11. And a male screw 13 provided on the telescopic column 11 and screwed to the female screw 12; and a drive motor 15 for rotating the telescopic column 11 forward and backward.

  According to a fourth aspect of the present invention, in the ground strength test apparatus according to any one of the first to third aspects, an inclinometer 29 is attached to the intermediate cylinder 2, and the inclinometer 29 is connected to the digital tilt display device 35. In addition, the digital inclination display device 35 is configured to be able to correct the inclination of the entire earth strength test apparatus.

  According to a fifth aspect of the present invention, in the ground strength test apparatus according to any one of the first to fourth aspects, the contact tool is an adjustment comprising a convex portion 19 and a concave portion 20 on the head of the telescopic column 11. The crown 18 is structured to be disposed so as to be able to contact the lower surface of the ceiling slab B.

  The invention of claim 6 is a ground strength test method for performing a ground strength test by remote control using the moving body D, wherein the ground strength test position G ′ of the caisson work room A is leveled with a bucket, Sand is spread on the bucket, the moving body D is moved to the lower lock E, the pressure inside the lower lock E is adjusted to atmospheric pressure, a ground strength test device is attached to the moving body D, and the lower lock E internal pressure is adjusted to approximately the same pressure as the caisson working chamber A internal pressure, the moving body D is moved to the ground strength test position G ′, and the ground strength test apparatus is connected to the ground strength test position G ′ and the ceiling. The ground strength test method is characterized in that the ground strength of the ground G is measured by installing the slab B substantially vertically and applying a load to the ground G with a loading jack.

  A seventh aspect of the invention is the ground strength test method according to the sixth aspect, wherein the ground strength test apparatus 1 according to any one of claims 1 to 5 is used as the ground strength test apparatus. .

  In the invention according to the first aspect of the present invention, the movable body D is provided with the removable intermediate cylinder 2, the intermediate cylinder 2 is provided with the extendable telescopic column 11, and the head of the extendable column 11 can be rotated. The contact tool for pressing the ceiling slab B is provided on the head of the telescopic slab B. Further, according to claim 5, the contact tool is provided with an adjustment crown 18 including a convex portion 19 and a concave portion 20 on the head of the telescopic column 11. Since the structure is attached so as to be able to come into contact with the lower surface, even if the lower surface of the ceiling slab B is slightly inclined or uneven, these defects can be absorbed by the contact tool, The entire test apparatus can be installed substantially vertically. Therefore, measurement errors due to the ground strength test apparatus being installed in an inclined state do not occur, and the amount of settlement of the ground G can be accurately measured.

  In the first aspect of the present invention, the lower cylinder 21 is attached to the lower part of the intermediate cylinder 2, the loading jack 22 is fitted into the lower cylinder 21, and the loading plate 26 is attached to the lower part of the loading jack 22. Since the length measuring device 27 for measuring the amount of settlement of the loading plate 26 is attached to the lower cylindrical body 21, the measuring device portion including the length measuring device 27 can be compactly assembled. There is also an effect that accidents such as collision with obstacles can be reduced. Further, since the length measuring device 27 is attached to the outside of the lower cylindrical body 21 and the measuring needle 28 is directly brought into contact with the loading plate 26 for measurement, the measuring needle of the length measuring device 27 is loaded even when the ground is inclined. Therefore, reliable measurement can be performed.

  In the second aspect of the present invention, the reaction force portion 21a is provided on the upper portion of the lower cylindrical body 21, and the pressure sensor 25 is provided between the loading jack 22 and the reaction force portion 21a. As a result, since the loading jack 22 and the pressure sensor 25 are held in the lower cylinder 21, there is no positional displacement between them, and the load of the loading jack 22 can be held by the lower cylinder 21 and the loading jack 22. Can be transmitted to the pressure sensor 25, the measurement accuracy can be improved, and damage to the pressure sensor 25 can be prevented.

  In the invention according to claim 3 of the present invention, the expansion / contraction operation means of the expansion / contraction column 11 is provided in the expansion / contraction column 11 and the internal thread 12 formed in the upper cylindrical body 10 attached to the intermediate cylinder 2. Since the drive motor 15 for screwing the male screw 13 and rotating the telescopic column 11 forward / reversely is provided, the hydraulic pressure and oil that cannot be avoided by the type of conventional technology in which the column pipe is expanded and contracted by a hydraulic jack. The error of the measurement value caused by the expansion and contraction of the support pipe due to the fluctuation of the amount can be eliminated, and therefore, the subsidence amount of the ground G can be measured more accurately.

  In the invention according to claim 4 of the present invention, an inclinometer 29 is attached to the intermediate cylinder 2, the inclinometer 29 is connected to a digital tilt display device 35, and the digital tilt display device 35 is monitored while monitoring the ground. Since the inclination of the entire proof stress test apparatus is corrected, the vertical degree can be confirmed by digital display, and the entire proof stress test apparatus can be installed in the vertical direction more accurately and quickly.

  The invention according to claim 6 of the present invention is a ground strength test method for performing a ground strength test by remote control using the moving body D, wherein the ground strength test position G ′ of the caisson working chamber A is set as a bucket. Leveling, leveling the sand with a bucket and leveling, moving the moving body D to the lower lock E, adjusting the pressure inside the lower lock E to atmospheric pressure, attaching a ground strength test device to the moving body D, The pressure inside the lock E is adjusted to approximately the same pressure as inside the caisson working chamber A, the moving body D is moved to the ground strength test position G ′, and the ground strength test device is placed between the ground strength test position G ′ and the ceiling slab B. It is installed substantially vertically and a load is applied to the ground G by the loading jack 22. Therefore, according to the sixth aspect of the present invention, when the ground strength test apparatus 1 is attached to and removed from the moving body D, work under high atmospheric pressure can be avoided. In addition to having an effect that can be freed from difficult work, work time can be shortened because work time is not limited even at deep work.

  Furthermore, since the ground strength test apparatus 1 according to any one of claims 1 to 5 is used as the ground strength test apparatus, the invention according to claim 7 of the present invention is described in each of the first to fifth aspects. The invention has the effects that can be achieved.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a longitudinal side view showing an embodiment of the ground strength test apparatus of the present invention, and FIG. 2 is an enlarged sectional view taken along line II-II in FIG.

  The ground strength test apparatus 1 according to the embodiment shown in FIGS. 1 and 2 includes an intermediate cylinder 2, a bracket 7 for mounting the ground strength test apparatus 1 on a moving body D, an upper outer cylinder 10, and a telescopic cylinder. 11, the adjusting crown 18, the joining structure of the telescopic cylinder 11 and the adjusting crown 18, the telescopic operating means for the telescopic cylinder, the lower cylinder 21, the hydraulic jack 22 for loading, the pressure sensor 25, and the loading A plate 26, a length measuring device 27, an inclinometer 29 and the like are provided. Further, the ground strength test apparatus 1 includes a hydraulic unit 30, a cockpit 33, a computer 34 and a digital tilt display device 35 installed in the cockpit 33.

  The moving body D is obtained by improving a part of the excavator by exchanging a bucket attached to the tip of the boom of the caisson excavator with a bracket.

  The intermediate cylinder 2 is formed with a slit 3 that is long in the vertical direction. In addition, a guide member 4 that is long in the vertical direction is provided inside the intermediate cylinder 2. An upper plate 5 is attached to the intermediate cylinder 2. Further, a plurality of reinforcing plates 6 are attached to the outer periphery of the intermediate cylinder 2 at a predetermined interval in the circumferential direction.

  The bracket 7 is provided on one side of the intermediate cylinder 2. As shown in FIG. 1, the bracket 7 is attached to the end of the boom d of the moving body D via the mounting pin 8, and is inserted into the hoisting cylinder e <b> 1 of the moving body D via the other mounting pin 9. The ground strength test apparatus 1 is detachably mounted on the moving body D through the mounting structure.

  The upper outer cylinder 10 is integrally mounted on the upper plate 5 of the intermediate cylinder 2. An internal thread 12 is formed inside the upper outer cylinder 10.

  The telescopic cylinder 11 is mounted from the inside of the intermediate cylinder 2 to the upper part through the inside of the upper outer cylinder 10. On the outer periphery of the telescopic cylinder 11, a male screw 13 that engages with the female screw 12 is provided.

  A drive motor 15 for a telescopic cylinder is installed inside the intermediate cylinder 2 via a motor mount 14. The motor mounting base 14 is disposed in the intermediate cylinder 2 so as to be movable in parallel in the vertical direction along the guide member 4 that is long in the vertical direction. The telescopic cylinder 11 is connected to the rotary shaft 16 of the drive motor 15 so as to rotate together with the rotary shaft 16. The drive motor 15 is connected to the hydraulic unit 30 via the hydraulic pipes 17a and 17b, and can rotate forward and backward.

  A female screw 12 formed on the upper outer cylinder 10, a male screw 13 provided on the telescopic cylinder 11, a means for moving the motor mounting base 14 in the vertical direction along the guide member 4, and a drive motor 15 that rotates forward and backward. Thus, an expansion / contraction operation means for extending / contracting the expansion / contraction column 11 in the vertical direction is configured.

  The adjustment crown 18 is separated from the telescopic cylinder 11. The adjustment crown 18 is attached by a wire or a chain (both not shown) so as not to fall from the telescopic cylinder 11.

  A convex arc 19 is provided at the upper end of the telescopic cylinder 11. On the other hand, a concave arc 20 is formed on the lower surface of the adjustment crown 18. The convex portion 19 and the concave portion 20 constitute a joint structure of the telescopic cylinder 11 and the adjustment crown 18. In this joint structure, when the earth bearing test apparatus 1 is set up, when the adjustment crown 18 is brought into contact with the lower surface of the ceiling slab B, the convex portion 19 and the concave portion 20 are joined to each other, and the lower surface of the ceiling slab B is inclined. The unevenness is absorbed, and the ground strength test apparatus 1 can be installed substantially vertically. In addition, the recessed part 20 may be formed in the upper end part of the expansion-contraction column 11, and the convex part 19 may be provided in the lower surface of the adjustment crown 18. FIG.

  The lower cylinder 21 is integrally attached to the lower part of the intermediate cylinder 2. The lower cylinder 21 holds a cylinder of a hydraulic jack 22 for loading.

  A loading rod 23 projects from the lower end of the hydraulic jack 22. The hydraulic jack 22 is connected to the hydraulic unit 30 via hydraulic pipes 24a and 24b and is slid.

  The pressure sensor 25 is installed on the jack head chamber side in the lower cylindrical body 21. That is, the pressure sensor 25 is provided between the reaction force portion 21 a that is the bottom surface of the lower cylindrical body 21 and the hydraulic jack 22. This pressure sensor 25 detects the load of the hydraulic jack 22 and sends it to the computer 34 instead of an electric signal.

  The loading plate 26 is suspended from the lower plate 21 ′ of the lower cylindrical body 21 by a wire or a chain (both not shown). The loading plate 26 is applied with a load by the hydraulic jack 22 via the rod 23 and is pushed into the ground strength test position G ′ on the ground G during the ground strength test. The mounting method of the loading plate 26 and the hydraulic jack 22 may be either a fixed type as in the present embodiment or a movable type such as a chain or a pin. When the measurement ground is flat, a fixed type may be used, but a movable type is preferable for an inclined ground or an uneven ground.

  A plurality of the length measuring devices 27 are arranged in the circumferential direction, and are respectively fixed to the outer periphery of the lower cylindrical body 21 with a magnet or the like. Each length measuring device 27 is provided with a measuring needle 28 downward. Each measuring needle 28 is in direct contact with the upper surface of the loading plate 26 during the earth bearing test, measures the amount of settlement of the loading plate 26, and converts the measured value into an electric signal and sends it to the computer 34. When a micrometer is used for the length measuring device 27, the scale of the micrometer is read by a box camera and the read value is sent to the computer 34.

  The inclinometer 29 is installed on the upper surface of the upper plate 5 of the intermediate cylinder 2. The inclinometer 29 measures the inclination of the ground strength test apparatus 1 when the ground strength test apparatus 1 is set up between the ground strength test position G ′ on the ground G and the lower surface of the ceiling slab B, and the measured value is electrically measured. It is sent to the digital tilt display device 35 instead of the signal.

  The hydraulic unit 30 is usually mounted on the rear side of the moving body D. The hydraulic unit 30 is connected with a drive motor 15 for a telescopic cylinder and a hydraulic jack 22 for loading in relation to the earth strength test apparatus 1. The drive motor 15 is connected to the hydraulic unit 30 via hydraulic hoses 17 a and 17 b and a direction switching valve 31. The hydraulic jack 22 is connected to the hydraulic unit 30 via hydraulic pipes 24 a and 24 b and a direction switching valve 32.

  The cockpit 33 is installed on the ground or / and on the upper slab.

  The computer 34 is installed in the cockpit 33. Then, in relation to the ground strength test apparatus 1, the computer 34 captures and stores at least the detected load value from the pressure sensor 25, and sinks the loading plate 26 at the ground strength test position G ′ from the length measuring device 27. The measured value is taken in and stored, and the ground strength of the ground G is calculated.

  The digital inclination display device 35 takes in the inclination direction and the inclination angle of the ground strength test apparatus 1 from the inclinometer 29 and digitally displays them.

  Next, a method for mounting and removing the ground strength test apparatus 1 from the moving body D in this embodiment and a ground strength test method performed using the ground strength test apparatus 1 will be described.

  FIG. 3 is a flowchart of a method of mounting and removing the ground strength test apparatus from the moving body D, and a ground strength test method performed using the ground strength test apparatus. FIG. 4 is an explanatory diagram of a mounting work of the ground strength test apparatus. 5 is an explanatory diagram of the ground strength test state, FIG. 6 is a diagram showing in detail the ground strength test by the ground strength test apparatus according to one embodiment of the present invention, and FIG. 7A is a test of the ground strength test method of the present invention. FIG. 7B is an explanatory diagram showing the relationship between the amount of ground subsidence and other values in the ground strength test.

First, in the embodiment shown in FIG. 3, prior to the execution of the bearing capacity test, the preparation phase 100, placed in advance measures the specific strain amount h ₂ with respect to the load of the ground proof testing device 1 to be actually used. The strain amount h ₂ of the ground strength test apparatus 1 is obtained by measuring the strain amount h ₂ at that time by adding a load when actually performing the ground strength test to the ground strength test apparatus 1.

  Then, in process 101, a flooring ground is created at the ground strength test position G '. In order to create this flooring ground, the bottom ground of the work room A of the caisson is excavated by the moving body D, the caisson is submerged to a predetermined depth, and then the ground strength test position G ′ is set by the moving body D. Dig a little. The moving body D is collected in the lower lock E, the sand previously stored in the lower lock E is loaded into the bucket, the moving body D is moved to the ground strength test position G ′, and the transported sand is tested for the ground strength. Lay down at position G ', leveling and rolling. The sand to be spread may be transported from the ground to the work room via a material lock or manlock using a sand bucket (for soil excavation of ground excavated soil) or the like.

  Next, the moving body D is recovered in the lower lock E in the process 102. When collecting the moving body D in the lower lock E, the slide hatch F provided at the lower part of the lower lock E is opened, and the moving body D is pulled up through the slide hatch F. Next, the slide hatch F is closed. The opening and closing of the slide hatch F and the lifting operation of the moving body D are all performed by remote operation.

  As described above, after the slide hatch F provided at the lower part of the lower lock E is closed and the inside of the lower lock E is sealed, the inside of the lower lock E is decompressed to atmospheric pressure in the process 103.

  After the pressure in the lower lock E is reduced to atmospheric pressure, an operator enters the lower lock E in process 104, removes the excavation bucket of the moving body D, and installs the ground strength test apparatus 1 instead. In this process 104, the excavation bucket is removed from the moving body D, and the replacement work for mounting the earth strength test apparatus 1 is performed in the lower lock E under atmospheric pressure. Since the operation time is not limited, the exchanging work from the excavation bucket to the earth strength test apparatus 1 can be performed efficiently.

  After the ground strength test apparatus 1 is mounted on the moving body D, the operator leaves the atmospheric pressure chamber M from the lower lock E in the process 105. Next, the pressure door N is closed, and the inside of the lower lock E is increased to almost the atmospheric pressure in the work chamber A.

  After increasing the pressure in the lower lock E, the slide hatch F provided at the lower portion of the lower lock E is opened in the process 106, and the ground strength test apparatus 1 is moved into the work chamber A together with the moving body D. The body D is handed over to the traveling rail C laid on the lower surface of the ceiling slab B, and then the slide hatch F is closed. When the movable body D and the earth strength test apparatus 1 are moved to the work chamber A, the telescopic cylinder 11 and the rod 23 of the hydraulic jack 22 are contracted. Further, in this process 106, the moving body D and the ground strength test apparatus 1 are moved to the working room A, the moving body D is transferred to the traveling rail I, and the slide hatch F is opened and closed by remote control.

  Next, in process 107, the ground strength test apparatus 1 is moved onto the ground strength test position G 'by the moving body D. Next, the earth strength test apparatus 1 is set up with the loading plate 26 facing downward. Then, the hydraulic pressure is sent from the hydraulic unit 30 to the drive motor 15 through the hydraulic hose 17a of the drive motor 15, the drive motor 15 is rotated in the forward direction, and the telescopic cylinder 11 is extended by the screw action of the female screw 12 and the male screw 13. The adjustment crown 18 is brought into contact with the lower surface of the ceiling slab B. At this time, the inclination direction and the inclination angle of the earth strength test apparatus 1 are measured by the inclinometer 29, and the measured values are sent to the digital inclination display device 35 for digital display. Then, in the cockpit 33, the operator confirms the tilt direction and tilt angle displayed on the digital tilt display device 35, operates the boom d of the moving body D, and between the ground strength test position G ′ and the ceiling slab B. The earth strength test apparatus 1 is installed in As described above, in the ground strength test apparatus 1, the tilt direction and the tilt angle of the ground strength test apparatus 1 are measured by the inclinometer 29, and the measured values are sent to the digital tilt display device 35. Since the tilt direction and the tilt angle are digitally displayed, the operator can easily stand the ground strength test apparatus 1 substantially vertically while viewing the data. Moreover, in this earth strength test apparatus 1, since the upper end part of the expansion-contraction column 11 and the lower surface of the adjustment crown 18 are joined via the convex part 19 and the recessed part 20, joining by this convex part 19 and the recessed part 20 is carried out. By the structure, the inclination and unevenness of the ceiling slab B can be absorbed, and the ground strength test apparatus 1 can be easily installed substantially vertically as shown in FIG.

  The control of the drive motor 15 in the process 107 and the control of the boom d of the moving body D for correcting the ground strength test apparatus 1 substantially vertically are performed by remote operation.

  Subsequently, in the process 108, the ground strength test is performed by using the ground strength test apparatus 1 installed substantially vertically between the ground strength test position G 'on the ground G and the lower surface of the ceiling slab B. In order to perform such a ground strength test, the lower end portion of the measuring needle 28 of the length measuring device 27 is brought into contact with the loading plate 26 that is in contact with the ground strength test position G ′, and an initial measurement of the amount of settlement of the loading plate 26 is performed. Set the value to 0. Next, from the state shown in FIG. 6 and FIG. 7A, the hydraulic pressure is supplied from the hydraulic unit 30 to the jack head chamber side in the lower cylindrical body 21 through the hydraulic pipe 24a, and the hydraulic jack 22 is pushed down. A load is applied to the loading plate 26 via 23, and the loading plate 26 is pushed into the ground strength test position G ′ to sink. Then, in the first earth strength test, a predetermined load is applied to the loading plate 26 while detecting the loading load with the pressure sensor 25 installed in the lower cylindrical body 21, as shown in FIG. 7B. In addition, when the amount of settlement of the loading plate 26 is measured by the length measuring device 27 and a micrometer is used for the length measuring device 27, the scale as a measurement value of the micrometer is read by the Kannai camera, and the read value is read. Send to computer 34.

By the way, as is clear from the relationship between the values indicating the ground strength test state in FIG. 7B, the ground subsidence amount h is given by the following equation 2.
[Equation 2]
h = (h ₁ −h ₀ ) −h ₂
Each value of Equation 2 is as follows.
h ₀ : Initial value
h ₁ : Measurement value of length measuring device (= h + h ₂ )
h ₂ : Strain amount with respect to the load of the device obtained in advance

Here, as described above in this embodiment, by setting the initial value h ₀ to 0. Further, the strain amount h ₂ of the ground proof testing apparatus 1, since the previously measured during the preparation phase 100, a previously value. Therefore, the computer 34 calculates the subsidence amount h of the ground G from the measured value h ₁ of the subsidence amount of the loading plate 26 by the length measuring device 27. Thereby, the settlement amount h of the true ground G can be obtained easily and accurately.

Further, in this process 108, the load applied to the loading plate 26 is increased step by step, the amount of settlement of the loading plate 26 at that time is measured, and the amount of settlement h of the ground G reaches 15 mm as in the prior art. The test is repeated until the applied load exceeds the magnitude of the maximum ground pressure expected at the site or the yield point, and the test results are compiled into a loaded load-settlement curve by the computer 34 and stored. Then, the load applied at a certain subsidence amount is obtained from the above-described load-subsidence amount curve created by the computer 34, and the ground coefficient Ks (kN / m ³ ) is calculated using the above equation (1).

  When the intended ground strength test is completed, the moving body D and the ground strength test apparatus 1 are collected in the lower lock E in the process 109, and the excavation bucket is replaced with the boom d of the mobile body D instead of the ground strength test apparatus 1. And finish all work. In this process 109, when the moving body D and the ground strength test apparatus 1 are recovered to the lower lock E, the hydraulic pressure is sent from the hydraulic unit 30 to the rod side chamber of the lower cylindrical body 21 through the hydraulic pipe 24b on the return side. Then, the rod 23 of the hydraulic jack 22 is contracted. Further, hydraulic pressure is supplied from the same hydraulic unit 30 to the drive motor 15 through the hydraulic hose 17b on the return side, the drive motor 15 is rotated in the reverse direction, and the telescopic cylinder 11 is reduced by the screw action of the female screw 12 and the male screw 13. Let Next, the ground strength test device 1 is removed from between the ground strength test position G ′ and the ceiling slab B, and the ground strength test device 1 is carried below the lower lock E by the moving body D while being slightly tilted. Then, the slide hatch F is opened, and the moving body D and the ground strength test apparatus 1 are pulled up together in the lower lock E and collected. Next, the slide hatch F is closed, and the inside of the lower lock E is reduced to atmospheric pressure. Thereafter, an operator enters the lower lock E, removes the ground strength test device 1 from the moving body D, the boom d, and the rod e of the hoisting cylinder, and mounts the excavation bucket instead. Next, the worker leaves the lower lock E.

  Subsequently, when excavating the ground G at the bottom of the work chamber A, after the pressure in the lower lock E is increased to the atmospheric pressure in the work chamber A, the slide hatch F is opened, and the movable body is moved from the lower lock E to the work chamber A. D is sent out, the movable body D is suspended on the traveling rail C, the movable body D is traveled along the traveling rail C, and the ground G is excavated by the excavation bucket.

  In this embodiment, the length measuring device 27 is directly attached to the lower cylindrical body 21, that is, without using various members as in the prior art. Therefore, the measuring device including the length measuring device 27 is compact. Can be summarized. Therefore, when dropping the movable body D and the earth strength test apparatus 1 together from the lower lock E into the work chamber A, when carrying the work room A, or when recovering from the work chamber A into the lower lock E, etc. During the movement, it is possible to reduce the number of accidents in which the measuring device part collides with an obstacle or the like.

  Conventionally, since a jack or a loading plate is fixedly connected to the pressure sensor, the pressure sensor may be damaged, measurement accuracy may be hindered, and the pressure sensor may be damaged. On the other hand, in the present invention, the loading jack 22 is fitted and fixed to the lower cylindrical body 21, and the pressure sensor 25 is in contact between the loading jack 22 and the reaction force portion 21a. For this reason, since the load such as the loading jack 22 is held by the lower cylindrical body 21, the pressure sensor 25 is not subjected to a bending moment or an unbalanced load as in the conventional case, and there is no possibility of damaging the pressure sensor 25. Highly accurate measurement is possible.

  Further, in the present invention, the length measuring device 27 is fixed to the outside of the lower cylindrical body 21, and the measurement needle 28 is directly brought into contact with the loading plate 26 for measurement. Enables measurement. Further, since the measurement needle 28 is directly brought into contact with the loading plate 26 for measurement, the measurement needle 28 is not detached from the loading plate 26 even when the ground is inclined, and reliable measurement can be performed.

  A present Example shows the specific example for attaching the loading board 26, and the mode of attachment is shown in FIG. In this embodiment, components that are the same as or the same as those of the first embodiment described above are denoted by the same reference numerals, and the description thereof is omitted. In this embodiment, the loading plate 26 can swing with respect to the lower cylindrical body 21. For this reason, the guide part 70 is provided in the present Example. The guide unit 70 includes a guide bar 71, a support fitting 72, and a chain 75.

  In this embodiment, the guide rod 71 of the guide portion 70 is fixed to the upper surface of the loading plate 26 by welding or the like. Two or more guide bars 71 are provided. On the other hand, a support fitting 72 is fixed to the lower cylindrical body 21 corresponding to the guide rod 71. A through hole 72 a for allowing the guide rod 71 to pass is formed in the support metal 72. The diameter of the through hole 72a is large enough to fit the guide rod 71, and there is a gap in the through hole 72a through which the guide rod 71 is passed. For this reason, even if the support ground is inclined and the loading plate 26 is inclined, the lower cylindrical body 21 is structured to be swingable with respect to the loading plate 26.

  The loading plate 26 is suspended from the lower cylindrical body 21 by a chain 75 or the like so that the loading plate 26 does not fall when the earth strength test apparatus is moved. During the earth bearing test, the loading plate 26 is pressed so that the rod 23 of the hydraulic jack 22 follows the guide rod 71.

  A present Example shows the other specific example for attaching the loading board 26, and the mode of attachment is shown in FIG. In this embodiment, components that are the same as or the same as those in the first and second embodiments described above are denoted by the same reference numerals, and the description thereof is omitted. In the present embodiment, similarly to the second embodiment, the loading plate 26 can swing with respect to the lower cylindrical body 21. For this purpose, in this embodiment, an attachment portion 80 is provided. The attachment portion 80 includes a rod cover 81, a bracket 82, and a bolt 83.

  In this embodiment, a male screw 23 a is provided on the outer periphery of the rod 23, and a female screw 81 a that is in screw contact with the male screw 23 a is provided on the inner periphery of the rod cover 81. The rod cover 81 is screwed to the rod 23 of the hydraulic jack 22 by the male screw 23a and the female screw 81a.

  The bracket 82 is fixed to the loading plate 26 by welding or the like, and the bracket 82 has a plurality of bolt holes 82a. On the other hand, the rod cover 81 is provided with a female screw 81b so as to face the bolt hole 82a. With the bolt hole 82 a of the bracket 82, the female screw 81 b of the rod cover 81, and the bolt 83, the loading plate 26 is swingably locked to the rod 23 by the bolt 83 through the bolt hole 82 a of the bracket 82. Yes. The outer diameter of the bolt hole 82a of the bracket 82 is large enough to fit the bolt 83, and there is a gap in the bolt hole 82a through which the bolt 83 is passed. For this reason, even if the supporting ground is inclined and the loading plate 26 is inclined, the lower cylindrical body 21 to which the hydraulic jack 22 is attached has a structure that can swing with respect to the loading plate 26.

  In this embodiment, the rod cover 81 is provided with two female screws 81a for attaching to the bolt 83. In addition, the rod cover 81 and the loading plate 26 before the ground strength test may be in contact with each other or may be separated from each other due to the gap generated in the bolt hole 82a of the bracket 82. During the earth strength test, the rod 23 of the hydraulic jack 22 presses the loading plate 26.

  Each example has been described above. In each of the embodiments described above, the moving body D is a caisson excavator. However, the moving body includes a construction machine such as a breaker that breaks the caisson blade. In each of the above-described embodiments, the described load jack is the hydraulic jack 22, but the loading jack includes a pneumatic, electric, or screw-type journal jack.

It is a vertical side view which shows one Example of this invention earth strength test apparatus. It is the II-II line cutting | disconnection expanded sectional view of FIG. It is the flowchart of the mounting method and removal method to the mobile body of the ground strength test apparatus in one Example of this invention, and the ground strength test method performed using this ground strength test apparatus. It is explanatory drawing of the mounting | wearing operation | work of the ground strength test apparatus of this invention. It is explanatory drawing of the ground strength test state by the ground strength test apparatus. It is a figure which shows the detail of the ground strength test by the ground strength test apparatus. FIG. 7A is an explanatory diagram of a state before the test of the ground strength test method according to the present invention, and FIG. 7B is an explanatory diagram showing the relationship between the amount of ground subsidence and other values in the ground strength test. . It is explanatory drawing for demonstrating attachment of a loading board. It is explanatory drawing for demonstrating attachment of a loading board. It is a partial longitudinal cross-sectional front view which shows an example of the conventional earth strength test apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ground strength test apparatus 2 Intermediate cylinder 7 Bracket which attaches ground strength test apparatus to the boom of a moving body 10 Upper outer cylinder 11 Telescopic cylinder 12 Female screw 13 Male screw 15 Drive motor 16 Rotating shaft 17a, 17b Hydraulic hose 18 Adjustment crown 19 Convex Part 20 Recess 21 Lower cylinder 21a Reaction part 22 Hydraulic jack 23 Rod 23a Male screw 24a, 24b Hydraulic pipe 25 Pressure sensor 26 Loading plate 27 Measuring instrument 28 Measuring needle 29 Inclinometer 30 Fluid Pressure unit 33 Cockpit 34 Computer 35 Digital tilt display device 70 Guide portion 71 Guide rod 72 Support bracket 72a Through hole 75 Chain 80 Mounting portion 81 Rod cover 81a, 81b Female thread 82 Bracket 82a Bolt hole 83 Bolt A Work chamber B Ceiling slab D Mobile body d Mobile body G E Lower lock G Ground at the bottom of the work room G 'Ground test position M Atmospheric pressure room N Pressure door

Claims (7)

The movable body (D) is provided with a removable intermediate cylinder (2),
The intermediate cylinder (2) is provided with a telescopic column (11) that is telescopic,
The head of the telescopic column (11) is provided with a contact tool that presses the ceiling slab (B) rotatably,
A lower cylinder (21) is attached to the lower part of the intermediate cylinder (2),
A loading jack (22) is inserted into the lower cylindrical body (21),
A loading plate (26) is attached to the lower portion of the load jack (22) described above,
A ground strength test apparatus, wherein a length measuring device (27) for measuring the amount of settlement of the load plate (26) is attached to the lower cylindrical body (21).   A reaction force portion (21a) is provided at the upper portion of the lower cylindrical body (21), and a pressure sensor (25) is provided between the load jack (22) and the reaction force portion (21a). The ground strength test apparatus according to claim 1.   The telescopic operation means of the telescopic column (11) is provided in the internal thread (12) formed in the upper outer cylinder (10) attached to the intermediate cylinder (2), the telescopic column (11) and The male screw (13) screwed into the female screw (12) and a drive motor (15) for rotating the telescopic column (11) forward and backward are provided. Earth resistance test equipment.   An inclinometer (29) is attached to the intermediate cylinder (2), the inclinometer (29) is connected to a digital tilt display device (35), and the entire earth resistance test device is connected through the digital tilt display device (35). The ground strength test apparatus according to any one of claims 1 to 3, wherein the inclination can be corrected.   The contact tool has an adjustment crown (18) composed of a convex portion (19) and a concave portion (20) arranged on the head of the telescopic column (11) so as to be able to contact the lower surface of the ceiling slab (B). The ground strength test apparatus according to any one of claims 1 to 4, wherein the ground strength test apparatus is a structure to be used. A ground strength test method for performing a ground strength test by remote control using a moving object (D),
Level the ground strength test position (G ') of the caisson work room (A) with a bucket,
Spread sand with the bucket at the leveling position,
Moving the movable body (D) to the lower lock (E);
Adjusting the pressure in the lower lock (E) to atmospheric pressure,
A ground strength test device is attached to the moving body (D),
Adjusting the pressure in the lower lock (E) to be substantially the same as the pressure in the caisson working chamber (A),
Moving the movable body (D) to the ground strength test position (G ′);
The earth strength test apparatus is installed substantially vertically between the earth strength test position (G ′) and the ceiling slab (B),
A ground strength test method for measuring the ground strength of the ground (G) by applying a load to the ground (G) with a jack for loading.   The ground strength test apparatus according to claim 6, wherein the ground strength test apparatus (1) according to any one of claims 1 to 5 is used as the ground strength test apparatus.

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