JP7475316B2 - Ground reinforcement structure and ground reinforcement method - Google Patents

Description

Article 30, paragraph 2 of the Patent Act applies. Posted on the website (June 30, 2021) https://confit.atlas.jp/guide/event/jgs56/subject/13-7-4-01/advanced

The present invention relates to a ground reinforcement structure and a ground reinforcement method for reinforcing the ground that supports a structure.

Conventionally, the following two measures have been mainly taken when the ground strength supporting buildings, bridge abutments, piers, retaining walls, embankments, and other structures is insufficient.
(1) Pile foundation work, in which piles are placed in the ground and structures are supported by the piles. (2) Ground improvement work, in which improvement materials are used to increase the strength of the ground and support structures. Both of these methods require large machinery, and are difficult to carry out on slopes in mountainous areas, in valleys, or in small areas in urban areas. In addition, there are some types of ground to which these methods cannot be applied.

Incidentally, the root pile method is widely known as one method for reinforcing and stabilizing cut slopes, natural ground, embankments, etc., in which holes drilled in the ground are filled with filler material, reinforcing material is inserted into the holes, and the filler material is solidified to form piles.
The root pile method involves casting reinforcement materials with a very small diameter (φ200 mm or less) using a small boring machine, and is particularly used in construction in small work sites.

In the case of the conventional reinforcement method using the root pile method, it is common to provide an anchoring member at the head of the pile and bury it in the structure, as shown in Figure 5.
The ground reinforcement method for structures using the root pile method has the following limitations:
(1) Pile foundations are required to bear all of the forces acting on a structure, but extremely small diameter reinforcement materials (φ200 or less) have low bending rigidity and are not suitable for use as pile foundations.
(2) The pile head and the structure are rigidly connected and a bending moment acts on the reinforcement material, but since the reinforcement material has low bending rigidity, there is a risk of deformation or breakage.

The present invention aims to provide a ground structure and a ground reinforcement method that can reduce the support burden of a structure placed on reinforcing materials while achieving high support performance.
Furthermore, the present invention has an object to provide a ground reinforcement structure and a ground reinforcement method that enable reinforcement to be performed using small diameter piles that can be constructed using small machines.

The present invention, made to achieve the above-mentioned object, is a ground reinforcement structure that reinforces the ground beneath a structure, and comprises a plurality of reinforcing materials each consisting of a reinforcing core material that penetrates into the ground and has its surroundings solidified with filling material, and a pressure receiving body connected to the upper part of the reinforcing core material, and a stress transfer layer consisting of granular backfill material such as sandy soil, crushed stone, improved soil, lightweight embankment material, etc. directly below the bottom surface of the structure, the pressure receiving body is disposed within the stress transfer layer, the upper part of the reinforcing core material penetrates the pressure receiving body, fastening members are fixed to the penetrating reinforcing core material above and below the pressure receiving body, a spherical washer with a spherical surface facing the pressure receiving body is provided between the fastening member and the pressure receiving body, and a flexible washer having flexibility is provided between the spherical washer and the fastening member .

The ground reinforcement method of the present invention comprises a step of excavating the ground surface, a reinforcing material placement step of penetrating a small-diameter reinforcing core material into the ground and solidifying the surrounding area with filling material and connecting a pressure -receiving body to the upper part of the reinforcing core material, and a stress-transfer layer construction step of backfilling the upper surface of the excavated ground with granular backfill material such as sandy soil, crushed stone, improved soil, lightweight embankment material or the like to bury the pressure-receiving body and construct a stress-transfer layer , wherein the upper part of the reinforcing core material penetrates the pressure-receiving body, and fastening members are fixed to the penetrating reinforcing core material above and below the pressure-receiving body, a spherical washer with a spherical surface facing the pressure-receiving body is provided between the fastening member and the pressure-receiving body, and a flexible washer having flexibility is provided between the spherical washer and the fastening member.

The present invention provides at least one of the following advantages by solving the above-mentioned problems.
(1) The load of the structure is transmitted to the reinforcement material and the underlying ground via the stress transfer layer, and is shared between the reinforcement material and the underlying ground to support the structure, making it possible to support even large structures.
(2) The reinforcement materials can be installed using smaller machines than those used for pile foundation construction and ground improvement work, making it possible to install them on slopes in mountainous areas, in valleys, and in small sites in urban areas.
(3) Structures can be supported even on ground where pile foundations or ground improvement works cannot be applied.

An explanatory diagram of the ground reinforcement structure of the present invention (1) 1 is a perspective view of a reinforcing core material and a pressure-receiving body of a reinforcing material according to the present invention; Explanatory diagram of the reinforcing material of the present invention (2) Explanatory diagram of the ground reinforcement structure of the present invention (2) Illustration of the conventional root pile construction method

The following describes an embodiment of the present invention with reference to the drawings.

[1] Ground Reinforcement Structure <1> Overall Configuration The ground reinforcement structure of the present invention reinforces the ground supporting a structure 1, thereby stably supporting the structure 1.
The ground reinforcement structure of the present invention has a plurality of reinforcing members 2 disposed in the lower part of a structure 1. Also, a stress transfer layer 3 is provided in the lower part of the bottom surface 11 on which the reinforcing members 2 are disposed (FIG. 1).
In this embodiment, the structure 1 is a sabo dam, but the ground reinforcement structure of the present invention is not limited to this and can be applied to various structures such as buildings, bridge abutments and piers, retaining walls, etc.

<2> Reinforcement material The reinforcement material 2 is constructed by inserting a reinforcing core material 21 into a hole drilled in the ground by a boring machine, filling the hole with a filler material, and hardening it. Boring machines are smaller than the machines used for pile foundation construction and ground improvement work, and can be used on slopes in mountainous areas, in valleys, and in narrow sites in urban areas.
The reinforcing core material 21 is a rod material such as a deformed steel bar, a PC steel bar, or a hollow pipe, whose outer periphery is formed into a male thread shape and which can be joined to form one or more rods into a long length. When joining hollow pipes, a fitting method using a coupler can also be used. In addition to the male thread shape, the outer periphery of the reinforcing core material 21 may have continuous projections or independent depressions/projections to increase adhesion with the filler.
A pressure-receiving body 22 is provided on the upper part of the reinforcing core material 21 .
The filler fills the holes and hardens to integrate the reinforcing core material 21 with the surrounding ground. The filler is a solidifying agent such as cement milk or mortar, and is preferably mixed with an expansive material, and is configured to expand within the holes when hardened.
The reinforcing core material 21 is caused to reach the supporting layer under the ground and is fixed by peripheral friction via the filler. However, if the reinforcing core material 21 can be fixed by peripheral friction, it may not reach the supporting layer.

<3> Pressure-receiving body The pressure-receiving body 22 is a plate-shaped member that transmits the applied force to the reinforcing core material 21 (Fig. 2). In this embodiment, the plate has an octagonal outer periphery and has a lattice formed inside, but the shape is not limited to this and may be circular, rectangular or other polygonal plate-shaped, top-shaped, conical or pyramidal, and the shape is selected according to the applied stress. The material of the pressure-receiving body 22 may be concrete, steel, resin, wood, or other material, and is selected according to the applied stress and construction conditions.
The standard dimensions of the pressure receiving body 22 are 0.3 m to 1.5 m.
A plurality of reinforcing members 2 are arranged, but they are arranged so that the pressure-receiving bodies 22 of adjacent reinforcing members 2 do not come into contact with each other, and it is preferable to keep an interval of 0.5 to 2.0 m between them.

The pressure receiver 22 has a through hole in the center, and the through hole penetrates the upper part of the reinforcing core material 21 (FIG. 3).
Fastening members 221a, b are fixed to the reinforcing core 21 above and below the pressure-receiving body 22. The fastening members 221a, b are screwed into male threads on the outer circumferential surface of the reinforcing core 21. When the reinforcing core 21 is a hollow pipe, an attachment is attached to the male threads, and the pressure-receiving body 22 is fixed and clamped by the attachment.
Spherical washers 222a, b and flexible washers 223a, b are provided between the fastening members 221a, b and the pressure-receiving body 22, respectively, to clamp the pressure-receiving body 22 from above and below, thereby connecting the pressure-receiving body 22 to the reinforcing core material 21.
The spherical washers 222a and 222b are washers whose surfaces in contact with the pressure receiving body 22 are spherical.
Since there is a gap between the through hole of the pressure-receiving body 22 and the reinforcing core material 21, and the spherical washers 222a, b in contact with the pressure-receiving body 22 are spherical, when a force other than the axial direction of the reinforcing core material 21 acts on the pressure-receiving body 22, the spherical washers 222a, b and the flexible washers 223a, b act as hinges, the pressure-receiving body 22 tilts relative to the reinforcing core material 21, and only axial stress is transmitted to the reinforcing core material 21.
Alternatively, instead of using the spherical washers 222a, b, the pressure-receiving body 22 may be sandwiched from above and below by flexible washers 223a, b, and the pressure-receiving body 22 may be configured to be inclined relative to the reinforcing core material 21 due to the flexibility of the flexible washers 223a, b.

<4> Stress transfer layer Backfill material is filled in on the pressure-receiving body 22 connected to the reinforcing core material 21 to form the stress transfer layer 3. In order to construct the structure 1 on the stress transfer layer 3, the stress transfer layer 3 is located between the bottom surface 11 of the structure 1 and the ground that has penetrated the pressure-receiving body 22 and the reinforcing core material 21 (FIG. 4).
The backfill material that forms the stress transfer layer 3 is a granular material such as crushed stone, sandy soil, improved soil, lightweight embankment material, etc., and is a material that has a shear strength sufficiently higher than that of the ground surrounding the reinforcing material 2, and does not prevent the pressure-receiving body 22 from inclining relative to the reinforcing core material 21.
The stress transfer layer 3 transfers the stress acting from the structure 1 to the reinforcing core material 21 and the ground, and the material of the backfill material and the thickness of the stress transfer layer 3 are selected depending on the specifications of the structure 1, the allowable displacement, and the construction conditions, to control the efficiency of transmission of the acting stress.

The reinforcing material 2 transmits the acting force transmitted by the pressure-receiving body 22 in the stress-transmitting layer 3 to the supporting layer below the ground. At this time, the pressure-receiving body 22 is inclined relative to the reinforcing core material 21, and only the axial force is transmitted to the reinforcing core material 21. Therefore, even if the reinforcing material 2 has an extremely small diameter of φ200 or less, it will not be damaged by bending.
In addition, not only the reinforcing material 2 but also the stress transfer layer 3 transmits force to the underlying ground, and the support of the structure 1 is shared between the reinforcing material 2 and the underlying ground, so that even a large structure 1 can be supported.
Structures can be supported even on ground where pile foundations or ground improvement works cannot be applied.

1 Structure, 11 Bottom surface, 2 Reinforcing material, 21 Reinforcing core material, 22 Pressure-receiving body, 221 Fastening member, 222 Spherical washer, 223 Flexible washer, 3 Stress transfer layer

Claims (3)

A ground reinforcement structure that reinforces the ground under a structure,
The reinforcing material includes a reinforcing core material that penetrates into the ground and is solidified around the reinforcing core material by a filling material, and a pressure-receiving body that is connected to the upper part of the reinforcing core material.
A stress transfer layer made of granular backfill material such as sandy soil, crushed stone, improved soil, lightweight embankment material, etc. is provided directly under the bottom surface of the structure,
The pressure-receiving body is disposed within the stress transfer layer ;
The upper portion of the reinforcing core penetrates the pressure-receiving body,
Fastening members are fixed to the penetrating reinforcing core material above and below the pressure-receiving body,
a spherical washer having a spherical surface on the pressure-receiving body side is provided between the fastening member and the pressure-receiving body,
A flexible washer having flexibility is provided between the spherical washer and the fastening member .
Ground reinforcement structure. The upper portion of the reinforcing core penetrates the pressure-receiving body,
Fastening members are fixed to the penetrating reinforcing core material above and below the pressure-receiving body,
A flexible washer having flexibility is provided between the fastening member and the pressure-receiving body.
The ground reinforcement structure according to claim 1. excavating a surface of the ground;
a reinforcing material placement process for inserting a small-diameter reinforcing core material into the ground, solidifying the surrounding area with a filler, and connecting a pressure-receiving body to an upper portion of the reinforcing core material;
a stress transfer layer construction process for backfilling the top surface of the excavated ground with granular backfill material such as sandy soil, crushed stone, improved soil, lightweight embankment material , etc., and burying a pressure receiver to construct a stress transfer layer ;
The upper portion of the reinforcing core penetrates the pressure-receiving body,
Fastening members are fixed to the penetrating reinforcing core material above and below the pressure-receiving body,
a spherical washer having a spherical surface on the pressure-receiving body side is provided between the fastening member and the pressure-receiving body,
a flexible washer having flexibility is provided between the spherical washer and the fastening member;
Ground reinforcement method.

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