JP6832047B2 - Method of measuring the filling status of the steel plate concrete structure and method of constructing the steel plate concrete structure - Google Patents

Description

The present invention relates to a steel plate concrete structure in which concrete or grout material is filled and a steel plate is driven into the upper surface, a method for measuring a filling state of concrete or grout material, and a method for constructing a steel plate concrete structure.

Conventionally, a seismic isolation device is mounted on a seismic isolation foundation made of reinforced concrete. In this case, it is necessary to drive a base plate for attaching the seismic isolation device into the concrete of the seismic isolation foundation.
The seismic isolation foundation is constructed by the following procedure. That is, the reinforcement of the seismic isolation foundation is arranged, and then the formwork is built along the outer peripheral side surface of the seismic isolation foundation. Next, the base plate is installed on the reinforcing bar. In this state, concrete is press-fitted into the formwork through the central opening of the base plate.

Here, the filling rate of concrete is generally required to be about 90 to 95%. The concrete filling factor is the ratio of the area of the smooth portion where no bubbles (recesses) are formed to the surface area of the concrete on the lower surface of the base plate. This is because a large vertical load acts on the base plate from the seismic isolation device, and if the concrete filling rate is low, this vertical load cannot be transmitted to the seismic isolation foundation.

In order to solve this problem, for example, the following methods have been proposed.
First, Patent Document 1 proposes a filling condition measurement method in which ultrasonic waves are applied to the concrete before the concrete placed on the seismic isolation foundation is hardened, and the condition of the concrete is determined by the measured waveform change. Has been done.

Secondly, in Patent Document 2, a space to be filled is provided between the seismic isolation foundation and the base plate, and the hydraulic slurry is injected and filled into the space to be filled from the hydraulic slurry injection pipe to obtain the hydraulic slurry. A method of increasing the filling rate of the hydraulic composition by curing has been proposed.

Thirdly, Patent Document 3 proposes a grout filling method for the lower part of the base plate for a seismic isolation device. In this grout filling method, a grout is placed in a hole provided in the center of the base plate, and the grout material is filled in the gap from the upper end of the grout to the lower part of the base plate. According to this proposal, by injecting the grout material with the tip of the grout rohto installed below the lower surface of the base plate, it is possible to fill the grout while preventing air from being entrained.

Fourth, a method has been proposed in which a concrete press-fitting experiment is performed using a full-scale test piece before the construction of the seismic isolation foundation.
Specifically, after press-fitting the concrete of the test piece, the base plate is removed. Then, a recess which is an air bubble is formed in a part of the concrete surface which is the lower surface of the base plate. Therefore, the concrete surface is photographed, and the area of the recess is calculated by image processing this image to calculate the concrete filling rate.

In this case, when an image of the concrete surface is taken, it is difficult to distinguish between the smooth portion and the recess, so the recess is manually colored. This makes it easier to recognize the recesses in the image of the concrete surface, and the concrete filling rate can be calculated with high accuracy.

Japanese Unexamined Patent Publication No. 2004-53376 JP-A-2010-242332 Japanese Unexamined Patent Publication No. 2000-240073

However, in the first to third methods, it is difficult to grasp the concrete filling rate with high accuracy. Further, in the fourth method, since the concave portion on the concrete surface is manually colored, there is a problem that it takes a lot of work.

An object of the present invention is to provide a method for measuring a filling status of a steel plate concrete structure and a method for constructing a steel plate concrete structure, which can grasp the filling rate of concrete or grout material with high accuracy while reducing work labor. ..

In order to realize a solid steel plate concrete structure, the present inventors include a method for measuring the filling status of a steel plate concrete structure, which can confirm the degree of solidity of the steel plate concrete structure in a short time even with a small number of people. We have invented a method for constructing a steel plate concrete structure using this filling condition measurement method.
In the method for measuring the filling state of the steel plate concrete structure of the present invention, the concave portion formed on the concrete surface from which the steel plate has been removed is not colored with paint or the like, but granules are sprayed on the concrete surface and stay in the concave portion. The projected area of the granular material is calculated to obtain the concrete filling rate.
Further, in the method for constructing the steel plate concrete structure of the present invention, first, a test piece is constructed so that the filling rate obtained by the filling state measuring method of the present invention for the test piece exceeds a predetermined threshold value. After deciding the mix of concrete or grout material, the work is carried out.

The method for measuring the filling status of a steel plate concrete structure according to the first invention is a steel plate concrete structure (for example, seismic isolation described later) in which concrete or grout material is filled and a steel plate (for example, a base plate 20 described later) is driven into the upper surface. This is a method of measuring the filling state of the foundation 1), in which a granular material (for example, a granular material 50 described later) is sprayed on the upper surface (for example, the base plate support surface 45 described later) from which the steel plate of the steel plate concrete structure has been removed. A step (for example, step S4 described later) and a step of removing the granular material located in a portion other than the recess (for example, the recess 46 described later) formed on the upper surface of the steel plate concrete structure (for example). Step S5) described later and a step of calculating the projected area of the granules staying in the recess and calculating the filling rate of concrete or grout material in the steel plate concrete structure (for example, steps S6 and S7 described later). It is characterized by having.

According to the present invention, since the granular material stays only in the concave portion, the area of the concave portion can be easily obtained by obtaining the projected area of the granular material. Therefore, the filling rate of concrete or grout material can be obtained with high accuracy by obtaining the ratio of the area of the upper surface of the steel plate concrete structure other than the recess to the area of the upper surface of the steel plate concrete structure.

Further, since it is not necessary to manually color the concave portion on the upper surface of the concrete as in the conventional case, the labor can be reduced. Further, even if a small number of people work, the concave portion on the upper surface of the steel plate concrete structure and the substantially smooth portion other than the concave portion can be easily identified in a short time. In addition, the filling rate of the steel plate concrete structure can be quantitatively confirmed by quantifying the void portion represented by the recess on the upper surface of the steel plate concrete structure and the substantially smooth portion.
When determining the projected area of the granules, the projected area of the granules may be obtained by photographing the upper surface of the structure from which the steel plate has been removed and performing image processing on the photographed image.

The method for measuring the filling state of the steel plate concrete structure of the second invention is characterized in that the granules have transparency.

According to the present invention, by using the transparent granules, the granules remaining in the recesses are arranged so as to overlap each other in the depth direction of the recesses, and the depth of the recesses depends on the shade of color of the granules. Can be easily estimated.

The method for constructing a steel plate concrete structure of the present invention is a method for constructing a steel plate concrete structure, in which a test body of a steel plate concrete structure (for example, a test body 40 described later) is prepared by blending a predetermined concrete or grout material. A step of determining the filling rate of the test piece by constructing and using the above-mentioned method for measuring the filling status of the steel plate concrete structure (for example, steps S1 to S8 described later) and the determined filling rate exceed a predetermined threshold value. In the case of the case, it is characterized by including a step of carrying out a steel plate concrete structure (for example, steps S9 and S10 described later) by blending the concrete or grout material used for the test body.

According to the present invention, a test piece of a steel plate concrete structure is constructed in advance by test construction, and concrete or concrete is used so that the filling rate obtained by the filling state measuring method for the test piece exceeds a predetermined threshold value. Determine the grout mix. A solid steel plate concrete structure can be constructed by carrying out the work with the concrete or grout material of the determined composition.

According to the present invention, it is possible to reduce the labor and to grasp the filling rate of the concrete or grout material constituting the steel plate concrete structure with high accuracy in a short time even with a small number of people. In addition, a solid steel plate concrete structure can be constructed with a high filling rate.

It is a vertical sectional view of the seismic isolation foundation to which the construction method of the steel plate concrete structure which concerns on a reference example is applied. It is a flowchart of the method of constructing a seismic isolation foundation by the method of constructing a steel plate concrete structure. It is explanatory drawing of the construction method of a seismic isolation foundation (No. 1, concrete placing situation). It is explanatory drawing of the construction method of the seismic isolation foundation (the second, the schematic view of the concrete upper surface). It is explanatory drawing of the construction method of the seismic isolation foundation (the third, the spraying situation of a granular material). It is explanatory drawing of the construction method of the seismic isolation foundation (the fourth, the brushing situation of a granular material). It is explanatory drawing (use example of a transparent granular material) of the construction method of the seismic isolation foundation which concerns on 1st Embodiment. It is explanatory drawing (use example of the thermoplastic resin granular material) of the construction method of the seismic isolation foundation which concerns on 2nd Embodiment.

The present invention is a method for measuring the filling status of concrete for a steel plate concrete structure filled under a seismic isolation foundation, and a method for constructing a steel plate concrete structure using the filling status measuring method.
In the filling status measurement method, granules are sprayed on the upper surface of the steel plate concrete structure from which the steel plate has been removed, and the projected area of the granules remaining in the recesses formed on the upper surface is calculated to obtain concrete or concrete in the steel plate concrete structure. There is a reference example (FIGS. 1 to 6) for determining the filling rate of the grout material. In addition, the first embodiment (FIG. 7), which is different from the reference example in that a transparent granular material is used, and the second embodiment (FIG. 8), which is different from the reference example in that a thermoplastic resin granular material is used. , There is.
Further, in the formulation referred to in the present specification, the compounding strength, the water-cement ratio, the unit water amount, the admixture amount, the unit cement amount, etc. are determined, and the admixture material, the fine aggregate, the coarse aggregate amount, etc. are determined. It is defined as a compounding design to achieve the performance required for concrete, etc.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of the following embodiments, the same components will be designated by the same reference numerals, and the description thereof will be omitted or simplified.
[ Reference example ]
FIG. 1 is a vertical sectional view of a seismic isolation foundation 1 as a steel plate concrete structure to which the method for constructing a steel plate concrete structure according to the reference example of the present invention is applied.
The seismic isolation foundation 1 is used for a seismic isolation structure in which the building 3 is supported by the foundation 2 via the seismic isolation device 10. The seismic isolation foundation 1 is provided on the foundation 2, and the seismic isolation device 10 is installed on the seismic isolation foundation 1.

The seismic isolation device 10 includes a lower flange 11, a laminated rubber 12 provided on the lower flange 11, and an upper flange 13 provided on the laminated rubber 12.
The laminated rubber 12 is made by alternately laminating steel plates and rubber.
The upper and lower flanges 11 and 13 are provided with bolt insertion holes 14 and 15 for inserting bolts at predetermined intervals along the peripheral edge portion.

The seismic isolation foundation 1 is a reinforced concrete structure filled with concrete, and a base plate 20 as a rectangular steel plate is driven into the upper surface of the seismic isolation foundation 1. Through holes 21 for placing concrete are formed in the central portion of the base plate 20, and female screws 22 are provided at predetermined intervals in an annular shape centered on the through holes 21 at the peripheral edge of the base plate 20. Has been done.
Further, a base plate 30 is driven into the lower surface of the building 3, and the base plate 30 has substantially the same structure as the base plate 20.

The lower flange 11 of the seismic isolation device described above is placed on the base plate 20. In this state, the bolt 16 is inserted into the bolt insertion hole 14 of the lower flange 11, and the bolt 16 is tightened and fixed to the female screw 22 of the base plate 20. As a result, the seismic isolation device 10 is joined to the seismic isolation foundation 1.

Further, the flange 13 on the upper side of the seismic isolation device has the same structure as the flange 11, and is fixed to the base plate 30 by bolts 17.

Since a large load is applied to the seismic isolation foundation 1 through the base plate 20, the concrete filling rate of the seismic isolation foundation 1 is generally required to be about 90 to 95% as described above.

Therefore, before the construction of the seismic isolation foundation 1, a full-scale test body of the seismic isolation foundation 1 is test-constructed, and the concrete filling state of this test body is measured to determine pass / fail. Here, the concrete filling rate is targeted at 95% or more, and 90% or more is judged to be acceptable. Further, the maximum permissible maximum air gap diameter that can be permissible is set to 80 mm or less.
If the concrete filling condition of the test body 40 is acceptable, the seismic isolation foundation 1 is carried out by using the concrete preparation and casting method used for the test body 40.

Hereinafter, a procedure for measuring the concrete filling state of the test body 40 and constructing the seismic isolation foundation 1 by the implementation work will be described with reference to the flowchart of FIG.
Similar to the seismic isolation foundation 1, the test body 40 is a reinforced concrete structure filled with concrete, and a base plate 20 as a steel plate for attaching a seismic isolation device is driven into the upper surface of the test body 40. ..

In step S1, reinforcement is arranged on the test body 40, and the outer formwork 41 is built along the outer peripheral side surface of the test body 40. Here, the height position of the upper end of the outer form 41 is set higher than the height position of the base plate 20 by about 10 cm.
In step S2, the base plate 20 is installed on the reinforcing bars arranged, and the inner formwork 42 is built.

In step S3, as shown in FIG. 3, the concrete casting pipe 43 is connected to the through hole 21 in the center of the base plate 20, and the concrete is press-fitted into the inside of the outer formwork 41 through the concrete casting pipe 43. Since the height position of the upper end of the outer form 41 is about 10 cm higher than that of the base plate 20, concrete is placed on the lower surface of the base plate 20 until it can be confirmed that the concrete to be press-fitted overflows from the top end of the outer form 41. Press in.

In step S4, the base plate 20 is removed after the concrete has hardened. Then, as shown in FIG. 4, a portion of the concrete upper surface 44 that is located directly below the base plate 20 and supports the base plate 20 (hereinafter, the base plate support surface 45) is exposed. The base plate support surface 45 is substantially smooth, but a recess 46 (indicated by diagonal lines in FIG. 4), which is a bubble, is partially formed.

Therefore, as shown in FIG. 5, a colored resin substantially spherical granular body 50 is sprayed on the base plate support surface 45. The granules are made of glass or resin, for example, and have a diameter of about 2 to 5 mm.
In step S5, as shown in FIG. 6, the base plate support surface 45 is swept with the brush 60 to remove the granular material 50 located in a portion other than the recess 46.

In step S6, the area of the recess 46 is calculated.
Specifically, since the recess 46 is colored by accumulating the granular material 50, the base plate support surface 45 is photographed with a camera or the like, and the photographed image is taken into the software of the personal computer and image-processed to obtain the granular material. The projected area of the portion colored with 50 is calculated and used as the area of the recess 46.

In step S7, the concrete filling rate is calculated.
Specifically, the area of the base plate support surface 45 is calculated by performing image processing on the captured image. Next, the area of the base plate support surface 45 other than the recess 46 (that is, the value obtained by subtracting the area of the recess 46 from the area of the base plate support surface 45) divided by the area of the base plate support surface 45 is the value of the concrete. Calculated as the filling rate.

In step S8, the average depth of the recess 46 is calculated.
Specifically, the granules 50 accumulated in the recess 46 are sucked by a suction device (not shown), the volume of the sucked granules 50 is measured, and the measured volume is divided by the area of the recess 46 to obtain a value. Calculated as the average depth of the recess 46.

In step S9, it is determined whether or not the concrete filling rate is 90% or more, which is a predetermined threshold value. If this determination is Yes, the process proceeds to step S10, and if this determination is No, the process proceeds to step S11.
In step S10, since the concrete mixing and placing method used in the test construction was good, a plurality of seismic isolation foundations 1 are constructed by the implementation work by the concrete mixing and placing method this time.
In step S11, since the concrete mixing and casting method used in the test construction was not good, at least one of the concrete mixing and casting methods was changed to return to step S1, and the test construction was performed again. In this way, good concrete preparation and selection of concrete casting method are performed. Specifically, in order to improve the concrete filling rate, the concrete composition design at the time of test construction is used as the base, and the slump flow value is mainly adjusted to ensure the fluidity of concrete, and new test construction is carried out. Make the preparation for. In the case of grout material, the flow is mainly adjusted by the amount of water.

According to this reference example , there are the following effects.
(1) Since the granular material 50 stays only in the recess 46, the area of the recess 46 can be easily obtained by obtaining the projected area of the granular body 50. Therefore, the concrete filling rate can be obtained with high accuracy by obtaining the ratio of the area of the base plate support surface 45 other than the recess 46 to the area of the base plate support surface 45 of the test body 40 of the seismic isolation foundation. .. Further, since it is not necessary to manually color the concave portion 46 of the base plate support surface 45 as in the conventional case, the labor can be reduced.

(2) The average depth of the recess 46 can be easily calculated by collecting the granules 50 remaining in the recess 46 and dividing the volume of the collected granules 50 by the area of the recess 46. Further, the cost can be reduced by reusing the granules 50 collected by suction.

(3) After calculating the filling rate of the test body 40 of the seismic isolation foundation 1 by the test construction, the filling rate was compared with a preset threshold value, and a good concrete preparation and casting method was selected. Therefore, it is possible to construct the seismic isolation foundation 1 having a stable and high filling rate with little variation depending on the construction conditions. In addition, by conducting test construction on a plurality of specifications and recording the construction results, the specifications of the work to be carried out can be determined in a short time.

First Embodiment
FIG. 7 is an explanatory diagram of a procedure for measuring the concrete filling status of the test body 40 by the filling status measuring method according to the first embodiment of the present invention.
The present embodiment differs from the reference example in that the granular material 50A is colored and has transparency.
In this embodiment, as shown in FIG. 7, the color changes according to the depth of the recess 46. That is, the deep part of the recess 46 becomes darker in color, and the shallow part becomes lighter in color.

According to this embodiment, in addition to the above-mentioned effect (1), there are the following effects.
(4) By using the transparent granular material 50A, the depth of the recess 46 can be easily visually confirmed based on the shade of color of the recess 46.

[ Second Embodiment]
FIG. 8 is an explanatory diagram of a procedure for measuring the concrete filling status of the test body 40 by the filling status measuring method according to the second embodiment of the present invention.
In the present embodiment, as shown in FIG. 8, a point granulate 50B is a disc-shaped thermoplastic resin colored diameter of about 5mm is different from the reference example.
In the present embodiment, when calculating the area of the recess 46, the granular body 50B in the recess 46 is melted by applying hot air to fill the recess 46, and in this state, the base plate support surface 45 is used by a camera or the like. A photograph is taken, the photographed image is image-processed, and the projected area of the portion colored by the granular body 50 is calculated as the area of the recess 46.

According to this embodiment, in addition to the above-mentioned effect (1), there are the following effects.
(5) Since the granular material 50B has a disk shape having a diameter of about 5 mm, the granular material 50B does not enter the recess 46 having a diameter of less than 5 mm. Therefore, the area can be obtained only for the recess 46 having a diameter of 5 mm or more, which is large to some extent.
Further, since the granular material 50B is melted with hot air to fill the recess 46, the area of the recess 46 can be calculated with higher accuracy.

The present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the range in which the object of the present invention can be achieved are included in the present invention.
For example, the above-described embodiment targets the seismic isolation foundation 1 in which concrete is filled under the steel plate, but is not limited to this, and is not limited to this, and is a concrete-filled steel pipe column having a concrete joint surface and a diaphragm (stiffening plate). Is also applicable.

1 ... Seismic isolation foundation (steel plate concrete structure) 2 ... Foundation 3 ... Building 10 ... Seismic isolation device 11 ... Flange 12 ... Laminated rubber 13 ... Flange 14 ... Bolt insertion hole 15 ... Bolt insertion hole 16 ... Bolt 17 ... Bolt 20 ... Base plate (steel plate) 21 ... Through hole 22 ... Female screw 30 ... Base plate 40 ... Specimen 41 ... Outer formwork 42 ... Inner formwork 43 ... Concrete casting piping 44 ... Concrete upper surface 45 ... Base plate support surface 46 ... Recesses 50, 50A, 50B ... Granules 60 ... Brush

Claims (3)

It is a method of measuring the filling status of a steel plate concrete structure in which concrete or grout material is filled and a steel plate is driven into the upper surface.
A step of spraying colored and transparent granules on the upper surface of the concrete body without coloring the upper surface of the concrete body from which the steel plate of the steel plate concrete structure has been removed.
Removing the one located in those該Ko Nkuri top which is formed in portions other than the concave portion of the bets body of the granulate,
A method for measuring a filling state of a steel plate concrete structure, which comprises a step of calculating a projected area of granules staying in the recess and calculating a filling rate of concrete or grout material in the steel plate concrete structure. .. It is a method of measuring the filling status of a steel plate concrete structure in which concrete or grout material is filled and a steel plate is driven into the upper surface.
A step of spraying a granular material of a thermoplastic resin on the upper surface of the concrete body without coloring the upper surface of the concrete body from which the steel plate of the steel plate concrete structure has been removed.
A step to enrich the removal of those located in those該Ko Nkuri top which is formed in portions other than the concave portion of the bets body of the granules and, the recess is dissolved by applying a hot air to granulate in the recess ,
A method for measuring a filling state of a steel plate concrete structure, which comprises a step of calculating a projected area of granules staying in the recess and calculating a filling rate of concrete or grout material in the steel plate concrete structure. .. It is a method of constructing a steel plate concrete structure.
A test piece of a steel plate concrete structure is constructed by blending a predetermined concrete or grout material, and the filling rate of the test piece is obtained by using the method for measuring the filling status of the steel plate concrete structure according to claim 1 or 2. Process and
When the obtained filling rate exceeds a predetermined threshold value, the steel plate concrete structure comprises a step of carrying out a steel plate concrete structure by blending the concrete or grout material used for the test body. How to build a body.