JP2004346649A - Performance evaluation method for mixed soil - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain basic data by preparing a test piece with soil and a hardening material mixed using a miniaturized agitating apparatus in constructing a soil cement column. <P>SOLUTION: A preparing apparatus 1 for use in preparing the test piece of the soil cement column prepares the test piece by storing the soil and hardener in a cylindrical container 10 and mixing and agitating them while lowering and inserting the agitating apparatus 20. The container 10 is constituted to be dividable in a prescribed position in a height direction, and a partition plate is inserted in a joint part of each cylindrical body before a mixture is solidified. A plurality of samples of round slice shape are thereby obtained to prepare a test piece used for a compression test or to cope with a test of a solidified state such as a pin penetration test. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for evaluating the performance of a solidified soil by preparing a specimen under actual conditions for a soil cement column constructed by mixing soil and hardener.
[0002]
[Prior art]
Conventionally, when constructing a structure such as a house or other small-scale building, conditions such as the strength of the ground at the construction site were investigated, and it was determined that the ground could not support the structure. In some cases, construction is being carried out to increase its bearing capacity. In order to increase the supporting capacity of the ground, means such as placing a pile or the like and performing columnar ground improvement are generally used. In the columnar ground improvement method, a hole having a predetermined diameter is excavated using an excavator such as an earth auger, and a hardened material such as cement milk is mixed into the excavated soil to form the soil and the hardened material. A mixed and hardened soil cement column is constructed (for example, see Patent Document 1).
[0003]
[Patent Document 1]
JP 2002-235322 A
[Problems to be solved by the invention]
However, since a soil cement column as a cast-in-place pile constructed as described above is deeply constructed in the ground, there is a problem that the actual strength of the column and the like cannot be easily checked. . Therefore, in order to confirm the solidification state and strength of the column, after constructing the soil cement column, pull it out using a jack or the like, perform processing such as cutting any part of the column, and perform a test piece. May be collected and a compression test performed. However, pulling out and testing columns actually constructed on site is expensive because of the cost of the tests.Therefore, only when developing new technologies or building the foundations of particularly important buildings, etc. Available methods. In order to solve the problems described above, there is no equipment that can mix soil and hardening material immediately in response to the construction site, and there is no method that can easily measure the solidification state, and the development of a simple test method is desired. is the current situation.
[0005]
An object of the present invention is to provide an apparatus that can mix soil and a hardening material in accordance with an actual site, and a test method that can easily confirm the properties of the improved soil.
[0006]
[Means for Solving the Problems]
The present invention relates to a method for evaluating the performance of mixed treated soil, and the invention of claim 1 is directed to a mixing container having an opening on an upper surface for accommodating soil and a hardening material; Using a shaping device provided with a stirrer for mixing the materials and a driving device for lowering the stirrer at a constant speed while rotating the stirrer, preparing a specimen of the mixed treated soil inside the mixing container. It is used to evaluate the mixing state and strength of the soil and the hardening material.
[0007]
The invention according to claim 2 is characterized in that the mixing container is configured by combining a plurality of cylindrical portions that can be divided into a plurality of slices, and after the mixed treated soil is created in the container, the mixing container is provided between the dividable cylindrical portions. A test piece corresponding to each cylindrical portion is made divisible by inserting a plate-shaped object into the tube, and is provided for an arbitrary test.
[0008]
According to a third aspect of the present invention, as the stirrer, a miniaturized device that is assumed to be used in the field is used, and the mixing state of the soil and the hardening material in a test piece created by a stirrer having an arbitrary configuration. And / or measurement of strength.
[0009]
According to a fourth aspect of the present invention, in the molding apparatus used for preparing the specimen, a means for engaging a stirrer with a support shaft provided with a vertical movement means is provided, and an engagement portion of the support shaft is provided in an engagement portion of the support shaft. When the shaft is rotated in the lowering direction, the locked state can be maintained, and by rotating the shaft in the upward direction, the locking with the stirring device is released, and the lower end of the container is The method is characterized in that the support shaft is pulled up while the stirring device is left, and the evaluation is performed using the upper specimen in the container.
[0010]
By using the apparatus configured as described above, it is possible to prepare a specimen in a laboratory using a miniaturized stirrer that can be applied to the site, and to make the characteristics of the soil cement column immediately And can be easily evaluated. Further, in the apparatus for preparing the specimen, since the soil at the construction site of the column can be mixed with the hardening material, an accurate basic sample can be obtained. The specimen for evaluating the characteristics of the soil cement column can be processed into an arbitrary shape such as a test piece state or a round section state, so that the evaluation using a plurality of methods can be easily performed. .
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described according to the illustrated example. The example shown in FIGS. 1 to 3 describes the configuration of an apparatus for preparing a specimen by mixing soil and a hardening material, and a forming apparatus 1 is a substantially large-diameter support leg member combined with a steel frame. 2, a support shaft 6 provided with screws for moving up and down at a predetermined pitch by being fitted to a screw engaging portion 3 provided on an upper portion of the support leg member 2, and being attached to and detached from a lower portion of the support shaft 6. It is provided in combination with a stirrer 20 to be attached as possible. At a position corresponding to the stirring device, a cylindrical mixing container 10 having an upper opening was positioned, and the stirring device 20 was rotated inside the mixing container 10 and inserted into the mixing container 10. The ingredients are mixed and agitated. A handle member 5 is provided above the support shaft 6, and the support shaft 6 can be moved up and down by rotating it by hand.
[0012]
It is to be noted that by using a means for screw-engaging the support shaft 6 with the screw engaging portion 3, a constant penetration speed can be obtained. For example, the handle member 5 is rotated once. Thus, the support shaft 6 can be moved up and down by 7 mm. An attaching / detaching portion 7 is provided at a lower end portion of the support shaft 6, an upper end portion of the stirring device 20 is engaged with the attaching / detaching portion 7, and an operation of lowering the support shaft 6 is performed. When the rotation is reversed, the detachable portion 7 is detached from the locking portion of the stirring device 20.
[0013]
The mixing container 10 has a configuration as shown in FIG. 3, and connects the bottomed lower cylindrical portion 11, the short middle cylindrical portion 13, and the upper cylindrical portion 15 via the connection portions 12, 14, respectively. Thus, one cylindrical container is formed. Further, as shown in FIG. 3A, inside the mixing container 10, guides 16 and 16a for preventing co-rotation are provided in the longitudinal direction, and the anti-co-rotation blades provided for the stirring device 20 are provided. Both ends are inserted into the co-rotation prevention guide 16 to guide the stirrer 20 when moving it up and down.
[0014]
As the stirrer 20 used when preparing a test specimen with the molding apparatus 1, one having a configuration as described in FIGS. 4 to 7 is used. The stirrer described below constitutes a main device that has been conventionally used in a small size, and the stirrer 20A in FIG. 4 uses the device disclosed in JP-A-2002-235322. ing. Further, the stirrer 20B shown in FIG. 5 describes a general known example of a stirrer without a co-rotation preventing means. Further, the stirrer 20C in FIG. 6 is described as an example in which one co-rotation prevention guide 16 is provided, and the stirrer 20D in FIG. 7 is described as an example in which two co-rotation prevention guides 16 are provided. .
[0015]
The stirrer 20A is provided with stirring blades 22 to 24 at predetermined intervals on the upper and lower sides and the intermediate portion of the support shaft 21, and the stirring blades 22 to 24 are supported inside the mixing vessel 10. It is configured so as to be rotatable by the shaft 21. Further, between the middle wing 23 and the lower wing 24, a co-rotation prevention wing 25 is provided via a shaft supporting member 26 that allows free rotation with respect to the support shaft 21. The anti-corotating blades 25 are used as guides for lowering the stirrer 20A by inserting both ends of the anti-corotating guide 16 into the anti-corotating guide 16 provided in the mixing container 10, respectively. Then, by rotating the support shaft 21 by the support shaft 6, the mixed material accommodated in the mixing container 10 is gradually lowered in accordance with the pitch of the support shaft 6 while being stirred by the stirring blade.
[0016]
In the stirring device 20A, by rotating the support shaft 21, the co-rotation prevention blade 25 acts as a resistance member against the stirring action of the stirring blades 22 to 24, and the mixed material rotates co-rotating inside the container. To promote the mixing / stirring action. In addition to the stirring action, a planetary gear-shaped planetary rotator 27 provided on the lower wing 24 comes into contact with a shaft support member 26 of the co-rotation prevention wing 25 at an engagement portion 28 to follow the rotation of the lower wing 24. By rotating at a high speed, the action of stirring the mixed material can be more effectively promoted.
[0017]
The stirrer 20B shown in FIG. 5 is provided with three-stage stirring blades 22 to 24 at predetermined intervals above and below the support shaft 21. It is illustrated. Further, the stirrer 20C of FIG. 6 is configured such that one anti-corotating wing 25 is provided between the middle wing 23 and the lower wing 24, and the stirrer 20D shown in FIG. The anti-corotating wings 25, 25a are respectively arranged between the wings. In the stirrers 20C and 20D provided with the co-rotation prevention blades, the resistance action of the co-rotation prevention blades is given to the stirring action of the stirring blades, so that the effect of mixing the soil and the hardening material can be exhibited well. It is assumed.
[0018]
Each of the four types of stirrers 20A to 20D is referred to as a type A to D described below, but various stirrers are provided at the lower end of the support shaft 6 in FIG. And used for mixing and stirring the soil and the hardening material as the mixed material in the mixing container 10. In each of the above embodiments, the length (height) of the support shaft 21 of the stirrer is 260 mm, and the stirring blades 22 to 24 attached to the support shaft have a length of 194 mm, and protrude from the inner surface of the mixing vessel 10. So that it does not come into contact with the co-rotation prevention guide 16. Further, among the three-stage stirring blades, the lower blade 24 is provided with a thickness of 12 mm and a width of 38 mm at a predetermined angle, and the other two stirring blades 22 and 23 have a thickness of 9 mm and a width of 9 mm. Is attached to the support shaft 21 at a predetermined angle with a tilt of 32 mm.
[0019]
As shown in FIG. 3, the mixing container 10 used for stirring the mixed material by inserting the respective stirring devices into the inside is configured to have an outer diameter of 270 mm, and is provided on both sides of the inner surface thereof. By setting the length of the anti-corotating blade 25 for inserting the both ends to the slit of the co-rotating preventing guide 16 to be 254 mm, the mixing container is held in a state in which the anti-corotating blade 25 is not rotatable. 10 to be able to move up and down along a co-rotation prevention guide. In each of the above embodiments, the stirring blades 22 to 24 provided in the stirring device have a length of 194 mm and are configured so as not to abut against the co-rotation prevention guide 16 protruding from the inner surface of the mixing container 10. Further, of the three-stage stirring blades, the lower blade 24 is provided with a thickness of 12 mm and a width of 38 mm at a predetermined angle, and the other two stirring blades 22 and 23 have a thickness of 9 mm. , Having a width of 32 mm, are attached to the support shaft 21 at a predetermined angle.
[0020]
As shown in FIG. 3, the mixing container 10 is a combination of 33 members overlapped with each other, and each of the lower cylindrical portion 11, the middle cylindrical portion 13, and the upper cylindrical portion 15 is 300 mm, It is configured to be 60 mm and 140 mm, and each cylinder is provided so as to be separable via connection portions 12 and 14, respectively. When a specimen is prepared using the mixing container 10, the three members are fixed via a connecting portion, and the mixed material inserted therein is stirred by a stirrer. Then, the support shaft 6 is pulled up, the stirring device 20 is left in the lower cylindrical portion 11, and a partition plate is inserted above and below the middle cylindrical portion 13 to be divided into three cylindrical test pieces. The remaining portion of the specimen left in the lower cylindrical portion 11 may be taken out of the stirring device before solidification, and the remaining mixture may be discarded.
[0021]
Next, a procedure for preparing a specimen will be described. Using the molding apparatus 1 configured as described above, the mixed material inserted into the mixing container 10 is mixed and agitated to prepare a specimen, and a test on the produced specimen will be described below. As the mixed material used in this embodiment, Kasaoka clay is used. The clay as the mixed material has the following physical properties.
Moisture content (%) 55,
Density of soil particles (g / cm ³ ) 2.77,
Liquid limit ωL (%) 60.3,
Plastic limit ωp (%) 17.65,
Particle size characteristics (%) [Clay 70, Silt 27, Sand 3,
When preparing a specimen using the raw materials, first, a pipe 8 having a surface coated with a release material is disposed at the center of the mixing container 10, and Kasaoka clay as a mixed material is placed in the mixing container 10. To a predetermined height. The inside of the pipe 8 was filled with cement milk (W / C = 60%) (8 kg of cement and 4.8 kg of water), and then the pipe was pulled out. Thereafter, as shown in FIGS. 1 and 2, the stirrer 20 is attached to the support shaft 6 and the mixture is stirred while rotating the stirrer at a constant penetration speed, so that the upper surface of the mixture is higher than the upper surface of the upper cylinder 15 by 30 mm. The material was filled so that
[0022]
When the lower part of the stirring device 20 reaches the bottom of the mixing container 10, the support shaft 6 is rotated in the reverse direction to disconnect the stirring device 20 via the attaching / detaching portion 7, and the stirring device 20 is left in the lower cylindrical portion 11. Until then, only the support shaft 6 was pulled up. Then, after removing the bolts of the connection portions 12 and 14 above and below the middle cylinder portion 13, stainless steel plates were inserted above and below the middle cylinder portion 13 to divide the specimen into three parts. With respect to the three divided parts, the test piece held in the upper cylindrical part 15 at the top was immediately inserted with a pipe having a diameter of 30 mm and a length of 60 mm from above, and a test piece was collected and cured. After 4 weeks, the specimen was subjected to a uniaxial compression test. In addition, a pin penetration test was performed on the specimen accommodated in the middle cylinder portion 13 from the upper surface thereof after a curing period of four weeks. At the time of the pin penetration test, a toothpick was used, the penetration depth was 5 mm, and the penetration test was performed at a mesh interval of 10 mm.
[0023]
(Uniaxial compression test of extracted core)
FIG. 8 shows data obtained by performing a uniaxial compression test on a test piece obtained from a portion corresponding to the upper cylindrical portion 15 in a test piece molded using the mixing container 10. In this test data, using each of the types A to D of the stirrer, the state of the strength distribution in a test piece obtained by preparing a test piece, from the results of this test, A ... C ... B = D. That is, in the test using the four types of stirring devices, it was found that the mixing state of the soil and the hardening material was greatly different depending on the shape and structure of the stirring device.
[0024]
(Pin penetration test)
Of the specimens mixed in the mixing container 10, the results of the pin penetration test performed on the specimen housed in the middle cylinder portion 13 from the upper surface thereof after a curing period of four weeks after the curing period. , Shown in FIGS. In the figure, the places where the pin penetrated 5 mm or more are indicated by circles, and the places where the pins did not penetrate are indicated by crosses. Further, a portion without a mark in a central portion of the test piece indicates a region which is a hollow portion at the time of molding. From the results as shown in FIGS. 9 to 12, when the best types are arranged in order, it becomes C... A... B... D. The region corresponds to the position of the outermost edge of the stirring blade. That is, in the types A and C, it can be seen that the soil and the hardening material are well mixed in the portion stirred by the stirring blade. On the other hand, in the examples using the B and D type stirring devices of FIGS. 10 and 12, it was found that the strength of the soil cement column could not be improved due to the small number of high strength portions.
[0025]
(Other tests)
Phenolphthalein test: Using the specimen used in the pin penetration test, phenolphthalein as a reagent was applied on the upper surface thereof, and the state of pin penetration was observed. In this test, the dispersion state of the cement milk can also be observed by the red tint of the reagent. As a result of the test, when arranged in the order of the type in which the red response is clear, the result is A ... C ... B ... D as compared with the examples of FIGS. 9 to 12, and a result slightly different from the result of the pin penetration test is obtained. Was done.
[0026]
Unsolidified portion removal test: The unsolidified portion of the specimen used in the pin penetration test and the phenolphthalein test was scraped off with a finger, and the remaining solidified portion was observed. As a result of the observation, the type A was cleaner than the type C, but the size of the solidified portion was C> A. Therefore, it is difficult to give a superiority or inferiority between the two types of test specimens, and it may be considered that they are almost equal. Therefore, when the results are compared in the order of type, A ... C ... B = D, and results almost similar to the results of the pin penetration test shown in FIGS. 9 to 12 can be obtained.
As described above, FIG. 9 showing the results of the pin penetration test and the phenolphthalein test and the removal test of the unsolidified portion were able to obtain substantially the same results. By performing the test, the solidification state of the soil cement column can be easily observed.
[0027]
As can be seen from the results of the test, when a soil cement column as a cast-in-place pile is constructed at a building site of a building, in order to properly design the strength of the column, the molding apparatus 1 is formed using soil at the construction site. Thus, necessary data can be obtained by preparing a specimen. Therefore, a highly reliable cast-in-place pile can be designed by previously confirming the mixing ratio of the soil and hardening material in the test room and obtaining the data in accordance with the soil properties at the site. Also, as can be seen from the above experiment, the structure of the stirrer, that is, the arrangement relationship of the mixing / stirring blades, the presence or absence of the co-rotation prevention blades, the arrangement relationship of the auxiliary planetary stirring member, and the conditions such as its shape and structure Thereby, the mixed state of the soil and the hardening material can be confirmed using the specimen.
[0028]
Therefore, when constructing a soil cement column (cast-in-place pile) in order to support the foundation of a house or the like, the test specimen is created using the soil at the construction site of the construction, and the data of the test results is used. be able to. Therefore, it is possible to design an optimum column in accordance with the weight of the building to be constructed on the foundation ground on which the construction work is performed, the strength of the ground, and the conditions such as the overlapping state of the soil and stratum. In addition, the results of the above tests revealed that the shape and structure of the stirrer used in the construction of the column greatly affected the strength of the column. When developing a stirrer with a new configuration that can perform better functions, it is also necessary to use a specimen created in the laboratory to measure the strength of the column, the mixing state of soil and hardener, and other data. Confirmation can be performed in advance.
[0029]
In the above-mentioned molding apparatus 1, a test piece was prepared only by pushing (lowering) the support shaft 6 when stirring the material in the container using the stirring apparatus 20. It is needless to say that, when agitating in the container by using, the mixing / stirring action may be performed by the operation of pulling up the stirring device. Then, using any locking means, such as removing the stirring member from the container after pulling up the stirring member without automatically removing the shape of the locking portion for attaching the stirring container to the support shaft by reversing the support shaft. Can be dealt with. In the operation of moving the stirrer up and down, an attempt to improve the stirring state is a construction method used at a general column construction site, so that a specimen more suited to the construction condition at the site is used. It can be created.
[0030]
【The invention's effect】
By using the apparatus configured as described above, it is possible to prepare a specimen in a laboratory using a miniaturized stirrer that can be applied to the site, and to make the characteristics of the soil cement column immediately And can be easily evaluated. Further, in the apparatus for preparing the specimen, since the soil at the construction site of the column can be mixed with the hardening material, an accurate basic sample can be obtained. The specimen for evaluating the characteristics of the soil cement column can be processed into an arbitrary shape such as a test piece state or a round section state, so that the evaluation using a plurality of methods can be easily performed. .
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a configuration of a specimen preparation apparatus of the present invention.
FIG. 2 is an explanatory diagram of a relationship between a stirring device and a support shaft.
FIGS. 3A and 3B are explanatory diagrams of a configuration of a mixing container, wherein FIG. 3A is a cross-sectional view and FIG. 3B is a plan view.
FIG. 4 is an explanatory diagram showing a configuration of an A-type stirring device.
FIG. 5 is an explanatory diagram showing a configuration of a B-type stirring device.
FIG. 6 is an explanatory diagram showing a configuration of a C-type stirring device.
FIG. 7 is an explanatory diagram showing a configuration of a D-type stirring device.
FIG. 8 is a graph showing the results of a uniaxial compression test.
FIG. 9 is an explanatory diagram of a result of a pin penetration test in an A type device.
FIG. 10 is an explanatory diagram of a result of a pin penetration test in a B-type device.
FIG. 11 is an explanatory diagram of a result of a pin penetration test in a C type device.
FIG. 12 is an explanatory diagram of a result of a pin penetration test in a D-type device.
[Explanation of symbols]
1 molding device, 2 support leg member, 3 screw engaging portion,
5 handle member, 6 support shaft, 7 detachable part,
8 injection pipe, 10 mixing vessel, 11 lower cylinder,
13 Medium cylinder part, 15 Upper cylinder part, 16 Guide for co-rotation prevention,
20 stirrer, 21 spindle, 22 upper wing, 23 middle wing,
24 lower wing, 25 co-rotating wing, 26 shaft support member,
27 planetary rotator, 28 contact part.

Claims (4)

A mixing container having an opening on the top surface for storing soil and hardening material,
A stirrer that mixes the soil and hardening material inside the mixing container,
Using a molding device provided with a driving device that descends at a constant speed while rotating the stirring device,
A method for evaluating the performance of a mixed soil, comprising preparing a specimen of the mixed soil in the mixing vessel and evaluating the mixed state and strength of the soil and the hardening material. The mixing container is configured by combining a plurality of cylindrical portions that can be divided into a plurality of slices,
After creating the mixed treated soil in the container, insert a plate-like thing between the dividable cylinders, and allow the specimen corresponding to each cylinder to be divided,
The performance evaluation method of the mixed treated soil according to claim 1, wherein the method is provided for an optional test. As the stirring device, a device that is assumed to be used in the field and is downsized,
The performance evaluation of the mixed treated soil according to claim 1 or 2, wherein the evaluation of the mixed state of the soil and the hardening material and / or the measurement of the strength are performed on the test specimen prepared by the stirring device having an arbitrary configuration. Method. The molding apparatus used to create the specimen, provided with a means for engaging a stirrer with a support shaft provided with a vertical movement means,
The engaging portion of the support shaft can maintain a locked state when rotating in the direction of lowering the shaft, and by rotating in the direction of raising the shaft, the lock with the stirring device is released. Make up,
The performance evaluation method of the mixed treated soil according to claim 3, wherein the support shaft is pulled up with the stirring device left at a lower end portion of the container, and the evaluation is performed using a specimen at an upper portion in the container.

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