JP2019173394A - Honeycomb structure - Google Patents

Abstract

To provide a honeycomb structure that hardly leaks and has excellent followability to repeated loads or the like.SOLUTION: The present invention is a honeycomb structure 10 in which a filling material 6, ... is filled in a honeycomb-shaped three-dimensional reinforcing material 1 in which a plurality of honeycomb-shaped cells 5, ... are formed by strip materials 2, ... made of a plurality of strip-shaped resin sheets. And the filling material becomes cement improved gravel soil in which cement is added to crushed stone. By using the cement improved gravel soil in this way, crushed stones are bonded to each other by cement after filling, and it is possible to suppress the outflow from the cell even under the influence of rainfall, groundwater, or the like.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a honeycomb structure that is disposed as a retaining wall or a slope protection work on a surface layer of embankment or cut, or as a foundation of a structure.

  As disclosed in Patent Documents 1-3, a structure in which a granule such as sand, earth and sand, or crushed stone is filled in a void of a cell formed in a honeycomb shape to form a retaining wall or a slope surface protector. The body is known.

  On the other hand, it is not easy to flow out of the cell like a granular material, but it is also possible to use a material that is filled as a fluid such as concrete, mortar, or soil mortar and solidifies after filling. Is described.

  Here, when filling granular materials, such as sand, earth and sand, or a crushed stone, there are few restrictions on work, it is excellent in workability, and there is an advantage that the slope can be greened by vegetation.

  On the other hand, when filling concrete or the like that is filled as a fluid and solidified by drying, there is no risk of outflow from the cell, and there is an advantage that the slope can be covered with a strong integrated structure.

Japanese Utility Model Publication No. 6-67545 Japanese Patent No. 6192763 Japanese Patent No. 6186031

  However, in the case of filling granular materials such as earth and sand, the earth and sand filled in the cell may flow out due to the influence of long-term use, rainfall or infiltrated groundwater. And when earth and sand etc. flow out, there exists a possibility that settlement may arise or a slope may collapse.

  On the other hand, when concrete or the like is solidified and hardened, cracks may occur on the surface due to repeated loading, repeated daily or yearly changes in temperature, and the appearance may be impaired.

  Accordingly, an object of the present invention is to provide a honeycomb structure that is less likely to flow out and that has excellent followability to repeated loads and the like.

  In order to achieve the above object, the honeycomb structure of the present invention includes a honeycomb solid reinforcing material in which a plurality of honeycomb-shaped cells are formed by a strip material made of a plurality of long pieces of resin or fiber sheet. In which the filling material is cement-impregnated gravel soil obtained by adding cement to crushed stone.

  The honeycomb structure of the present invention configured as described above is used as a filling material for a honeycomb-shaped three-dimensional reinforcing material in which honeycomb-shaped cells are formed by a strip material composed of a plurality of long pieces of resin or fiber sheets. Use cement-modified gravel with added cement.

  For this reason, crushed stones are bonded to each other by cement after filling, and it is possible to suppress the outflow from the cell even under the influence of rainfall or groundwater. In addition, unlike concrete that has once been mixed with a large amount of water, the degree of adhesion between crushed stones is low, so that a structure with excellent followability to repeated loads can be obtained.

It is a perspective view for demonstrating the structure of the honeycomb structure of this Embodiment. It is a perspective view explaining the state before expansion | deployment of a honeycomb-shaped solid reinforcement material. It is a perspective view explaining the state after expansion | deployment of a honeycomb-shaped solid reinforcing material. It is sectional drawing explaining the structure of the retaining wall by which the honeycomb structure is arrange | positioned in the front. It is sectional drawing explaining the structure of the slope protection work in which the honeycomb structure is arrange | positioned on the slope.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a configuration of a honeycomb structure 10 described in the present embodiment. As shown in FIGS. 4 and 5, the honeycomb structure 10 is provided as a retaining wall 10A or a slope protection work 10B.

  That is, the honeycomb structure 10 is disposed so as to cover the side surface of the embankment, the excavation surface of the cut, and the like. As an arrangement method, there are a method of stacking on the side of the embankment and a method of laying as a surface layer of a slope (slope).

  As shown in FIG. 1, the honeycomb structure 10 of the present embodiment includes a plurality of honeycomb-shaped cells 5,... By a strip material 2,. It is mainly composed of the formed honeycomb three-dimensional reinforcing material 1 and the filling materials 6 filled in the cells 5,.

  As the strip material 2, a strip material (sheet shape) formed of a resin material such as high-density polyethylene can be used. As shown in FIGS. 2 and 3, a plurality of strip-shaped strip materials 2,... The binding sites 4 are alternately bonded to the side.

  When the bundle of strip materials 2,... Bonded in this way is expanded in the direction of the arrow shown in FIG. 2 (the thickness direction of the strip material 2), a plurality of honeycomb-shaped cells 5,. Will be formed.

  In short, the adjacent strip members 2 and 2 formed in a wavy shape are provided with a coupling portion 4 at a place where the valley and the mountain contact each other, and the space in the rhombic shape in plan view where the mountain and the valley are separated and opposed to each other is a cell. 5

  The strip material 2 can be provided with holes 3 for discharging water accumulated in the cells 5. The size and shape of the hole 3 may be anything and can be arbitrarily set within a range in which the desired strength of the strip material 2 can be maintained.

  Further, the arrangement in the case of providing a plurality of holes 3,... May be a series arrangement or a staggered arrangement. FIG. 1 shows a strip material 2A having no holes in the forefront, and the strip material 2 in which a plurality of holes 3,.

  The bonding site 4 between the strip materials 2 and 2 can be provided by, for example, applying heat welding or ultrasonic welding to the stacked strip materials 2 and 2. Moreover, the coupling | bond part 4 can also be provided by screwing in a tapping screw. Furthermore, the binding site 4 can be provided by bundling with a resin band or the like using the hole 3 of the strip material 2.

  Then, the filling materials 6,... Are filled into the cells 5,. In the honeycomb structure 10 of the present embodiment, the filling material 6 becomes a cement improved gravel soil in which cement is added to crushed stone.

  Cement-modified gravel is produced, for example, by adding a small amount of cement to particle size-adjusted crushed stone. The particle size-adjusted crushed stone is a coarse aggregate obtained by pulverizing rocks after crushing with a crusher or the like to obtain a particle size distribution having a size suitable for the intended use. JIS A5001 M-40 (particle size range 0-40 mm), M-30 (particle size range 0-30 mm), M-25 (particle size range 0-25 mm), etc., which collected relatively large crushed stones can be used.

The strength of cement-improved gravel soil can be increased by using high-quality particle-size crushed stone. Examples of the particle size-adjusted crushed stone include granulated crushed stone A (specific gravity G _s = 2.71, uniformity coefficient U _c = 12.1, average particle diameter D ₅₀ = 0.54 mm), granulated crushed stone B (specific gravity G _s = 3.03, uniformity coefficient U _c = 32.3, average particle diameter D ₅₀ = 0.14 mm) can be used.

The amount of cement added to the cement-improved gravel soil may be as small as 0.4-0.8 kN / m ³ or 2.0-4.0% by weight. For example, in the case of granulated crushed stone A, cement-modified gravel soil with a weight percentage (weight ratio) of 2.5% -2.8% (0.678 kN / m ³ -0.758 kN / m ³ ) Can be used. On the other hand, in the case of granulated crushed stone B, cement-impregnated gravel soil having a weight% (weight ratio) of about 2.5% (0.758 kN / m ³ ) can be used.

  As the cement to be added, ordinary Portland cement or the like can be used. The cement-improved gravel soil can be easily produced by simply stirring the crushed stone and cement with a backhoe or the like.

  In addition, the cement-impregnated gravel soil can be increased in strength stably by thoroughly mixing and dispersing the cement uniformly. Therefore, the cement-modified gravel soil may be stirred using a mixer or the like.

  The cement-improved gravel soil produced by adding cement to particle size-adjusted crushed stone can gradually increase the strength with the passage of time (long-term curing). Further, deformation due to repeated loading can be suppressed.

  Furthermore, by filling the cells 5 of the honeycomb-shaped three-dimensional reinforcing material 1 serving as a tensile member with cement-impregnated gravel soil as a filling material 6, it can be expected that the toughness performance against bending deformation is improved by the tension of the strip material 2. In addition, it is possible to exhibit resistance characteristics that hardly cause the deformation even with respect to bending deformation due to repeated loading.

  FIG. 4 is a cross-sectional view showing a configuration in which a retaining wall 10A serving as a honeycomb structure is provided on the front surface of the back embankment 7A. That is, when constructing the retaining wall 10A that covers the surface of the back embankment 7A, for example, the honeycomb-shaped three-dimensional reinforcing material 1 that has three rows in the depth direction is arranged at the lowest level.

  Then, in the pit near the construction site, the crushed stone and the cement are adjusted with a backhoe to produce a cement-improved gravel soil. The produced cement-improved gravel soil is filled into the cells 5 of the bottom three-dimensional honeycomb reinforcing material 1 as the filling material 6 using a backhoe or the like.

  On the first-stage honeycomb structure thus constructed, the second-stage honeycomb-shaped three-dimensional reinforcing material 1 is stacked, and the cells 5 are filled with the filling material 6 in the same manner as in the first stage. Go. Then, by repeating such work, a stair-shaped retaining wall 10A is constructed.

  On the other hand, FIG. 5 is a cross-sectional view showing a configuration in which the slope protection work 10B that becomes the honeycomb structure is provided on the slope of the excavated natural ground 7B. That is, when constructing the slope protection work 10B that covers the slope of the natural ground 7B, the honeycomb three-dimensional reinforcing material 1 is laid so as to be one layer on the surface layer, for example.

  The honeycomb three-dimensional reinforcing material 1 laid on the slope is fixed to the slope by anchoring anchor pins 8,... Driven into the natural ground 7B. Then, the cells 5 of the honeycomb-shaped three-dimensional reinforcing material 1 are filled with cement-improved gravel soil as a filling material 6.

  The cement-impregnated gravel soil filled in the cell 5 as the filling material 6 is blocked by the hardened cement between the crushed stones and has reduced water permeability. Therefore, when applied as a slope protection work 10B, High surface layer.

Next, the operation of the honeycomb structure 10 of the present embodiment will be described.
The honeycomb structure 10 of the present embodiment configured as described above has a honeycomb three-dimensional reinforcement in which honeycomb cells 5,... Are formed by strip materials 2,. As the filling material 6 for the material 1, cement-improved gravel soil in which cement is added to a particle-size-controlled crushed stone is used.

  Cement-improved gravel soil is bonded to the crushed stone by cement after filling, and can be prevented from flowing out of the cell 5 even under the influence of rainfall or groundwater. For example, when the retaining wall 10A or the slope protection work 10B is used, even if rain is blown directly, or groundwater that has permeated through the back embankment 7A or the ground mountain 7B flows down, the crushed stones will fall apart. Without spillage. As a result, the occurrence of subsidence can be prevented.

  On the other hand, when a concrete layer is constructed by once filling a cell with concrete mixed with a large amount of water and mixed, strong integrity is exhibited when the concrete hardens by drying. However, for example, when a large repeated load acts on the back embankment 7A due to the passage of a train or the like, the back embankment 7A and the strong concrete layer have a large difference in rigidity, so that the amount of deformation is different, and cracks may occur on the surface. This crack is not a big problem structurally, but it is detrimental to aesthetics.

  On the other hand, when cement improved gravel soil is used for the filling material 6 as in the honeycomb structure 10 of the present embodiment, the ground such as the back embankment 7A and the ground pile 7B becomes close to rigidity and can easily follow the deformation. Become. That is, since the degree of adhesion between crushed stones is lower than that of concrete, it has excellent followability to repeated loads.

  In particular, cement-impregnated gravel soil, when crushed stone and cement are mixed, has almost no adhesive force and can be handled in the same way as earth and sand. By the work, the cells 5,... Can be filled. Moreover, when filling cement improvement gravel soil as the filling material 6, since it is not necessary to perform the compacting operation | work, it can construct efficiently.

  After filling, the cement undergoes a hydration reaction due to surrounding moisture, rainfall, or infiltrated groundwater, and the strength gradually increases. That is, since the strength of the cement-improved gravel soil increases after becoming familiar with the back embankment 7A and the ground pile 7B due to the initial load loading or the like, it is possible to exhibit excellent resistance characteristics against subsequent repeated loading. .

  In addition, the surface of the cement-improved gravel soil mixed with crushed stone and a small amount of cement is prone to minute cracks even after repeated daily and yearly temperature changes due to solar radiation and temperature, or when it receives rainfall. Since it does not become a smooth surface, even if it cracks, it will not spoil the beauty.

  The embodiment of the present invention has been described in detail above with reference to the drawings. However, the specific configuration is not limited to this embodiment, and design changes that do not depart from the gist of the present invention are not limited to this embodiment. Included in the invention.

  For example, in the above-described embodiment, the case where the strip-shaped strip material 2 is used has been described. However, the present invention is not limited to this, and a strip-shaped strip material having at least one side wall of the cell 5 is used. I just need it.

  Moreover, in the said embodiment, although the honeycomb structure used as the retaining wall 10A or the slope protection work 10B was demonstrated, it is not limited to this, Support ground, such as a foundation of a structure, a foundation ground, and embankment, The honeycomb structure 10 can be arranged for a roadbed or the like.

  Furthermore, in the above-described embodiment, the case where the cement-improved gravel clay is produced from the particle size-adjusted crushed stone is described. However, the present invention is not limited to this, and the cement produced by adding a small amount of cement to ordinary crushed stone or the like. Improved gravel soil can also be used as a filling material.

DESCRIPTION OF SYMBOLS 10 Honeycomb structure 1 Honeycomb-shaped solid reinforcement 2,2A Strip material 5 Cell 6 Filling material 10A Retaining wall (honeycomb structure)
10B Slope protection work (honeycomb structure)

Claims (2)

A honeycomb structure in which a filling material is filled in a honeycomb-shaped three-dimensional reinforcing material in which a plurality of honeycomb-shaped cells are formed by a strip material composed of a plurality of long pieces of resin or fiber sheet,
The honeycomb structure according to claim 1, wherein the filling material is cement improved gravel soil in which cement is added to crushed stone. The honeycomb structure according to claim 1, wherein the crushed stone is a particle size-adjusted crushed stone, and the amount of cement added is 0.4-0.8 kN / m ³ or 2.0-4.0 wt%.