JP2010521602A - Honeycomb reinforcement for soil particle restraint - Google Patents

Abstract

[PROBLEMS] To provide a high hydraulic conductivity, a high frictional force with aggregates, a reduction in the amount of raw materials used, a low manufacturing cost, easy root rooting, and a dispersion of loads acting on compressive loads. Providing a honeycomb-shaped reinforcing material for restraining soil particles, which has advantages such as stabilization of the ground by preventing deformation.
A honeycomb reinforcing material for restraining soil particles according to the present invention forms a net-like sheet having a mesh of a certain size while a transverse reinforcing thread and a longitudinal reinforcing thread intersect, and the sheet is fixed in the width direction. After the fusion splicing at the intervals, a number of honeycomb cell networks are formed by pulling in one direction.
[Selection] Figure 3

Description

  The present invention relates to a honeycomb-like reinforcing material for restraining soil particles used for environmental protection of slopes and revetments, or for the formation of foundations such as retaining walls, retaining walls, road base layers and the like. More specifically, by forming a net-like sheet having a mesh of a certain size while the transverse reinforcing thread and the longitudinal reinforcing thread intersect, the sheet is fusion-bonded in the width direction, so that the hydraulic conductivity is high and the aggregate. The frictional force is high, the amount of raw materials used is reduced, the manufacturing cost is low, the roots are easy to settle, the load acting on the compression load is dispersed and the deformation is prevented, and the ground is stabilized. The present invention relates to a honeycomb-like reinforcing material for restraining soil particles, which has advantages such as realizing

  In general, slopes and revetments are susceptible to erosion and collapse due to rainfall and running water, and soft ground is a ground that deforms due to its supporting capacity of the foundation ground being smaller than the load of the structure. For such slopes and revetments, when building a dike, slope protection reinforcements must be installed to prevent erosion and collapse of the slope, and when embankments or roads are implemented on soft ground Therefore, it is necessary to install a reinforced structure so as to increase the supporting force of the ground and prevent subsidence of the ground.

  As shown in FIG. 1, the conventional structure of such a slope-protecting reinforcing material has a belt-like sheet 100 made of a high-density polyethylene material and having a predetermined length. Then, the honeycomb-shaped reinforcing material for constraining soil particles formed into a cell-like net by pulling.

  Referring to FIG. 2, after producing the honeycomb-shaped reinforcing material for restraining soil particles of FIG. 1, an operator using a punching machine in order to increase the hydraulic conductivity of the sheet 100 in the subsequent process on the site. A honeycomb reinforcing material for constraining soil particles having a structure for forming the through hole 200 was used.

  However, the conventional soft ground reinforcement has a low water permeability coefficient, low frictional force with the filler, requires expensive equipment during production, is expensive to manufacture, is not easy to root, and is compressed. There is a problem that the ground is deformed due to distortion of the sheet during loading.

  Therefore, the present invention is for solving the above-described problems, and the object of the present invention is to form a net-like sheet having a mesh of a certain size while the transverse reinforcing yarn and the longitudinal reinforcing yarn intersect. , This sheet is formed by fusion splicing in the width direction, has a high water permeability coefficient, high frictional force with aggregates, reduces the amount of raw materials used, lowers manufacturing costs, and facilitates root attachment The object of the present invention is to provide a honeycomb-shaped reinforcing material for restraining soil particles, which has advantages such as the stabilization of the ground is realized by dispersing the load acting upon the compressive load and preventing the deformation.

  In order to achieve the above object, the present invention forms a net-like sheet having a mesh of a certain size while the transverse reinforcing yarn and the longitudinal reinforcing yarn intersect, and this sheet is fused at a certain interval in the width direction. After connection, a honeycomb reinforcing material for restraining soil particles is provided, which is formed by pulling in one direction to form a large number of honeycomb-shaped cell nets.

  The honeycomb-shaped reinforcing material for restraining soil particles according to the present invention described above forms a net-like sheet having a mesh of a certain size while the transverse reinforcing yarn and the longitudinal reinforcing yarn intersect, and the sheet is fused in the width direction. It is formed by connecting, has a high hydraulic conductivity, high frictional force with aggregates, reduces the amount of raw materials used, lowers manufacturing costs, facilitates root entrapping, and acts on compressive loads This is a useful invention that has the advantage that the stabilization of the ground is realized by dispersing the load to be distributed and preventing deformation.

It is a perspective view which shows the reinforcement material which consists of the conventional high density polyethylene. It is a perspective view which shows the reinforcement material which consists of the conventional high density polyethylene. It is a perspective view which shows the honeycomb-shaped reinforcement material for earth particle restraint which concerns on this invention. It is a partial excerpt perspective view which shows the structure of the cell-like cell net | network part which forms the honeycomb-shaped reinforcement material for earth particle restraint which concerns on this invention. It is a partial extract front view which shows the structure of the sheet | seat which forms the honeycomb-shaped cell net part which concerns on this invention. It is a graph which shows the displacement-shearing force with respect to normal stress using the reinforcement material which consists of the conventional high density polyethylene. It is a graph which shows a normal stress-maximum shear stress curve using the reinforcing material which consists of the conventional high density polyethylene. It is a graph which shows the displacement-shearing force with respect to normal stress using the honeycomb-shaped reinforcement material for earth particle restraint which concerns on this invention. It is a graph which shows a normal stress-maximum shear stress curve using the honeycomb-shaped reinforcement material for earth particle restraint which concerns on this invention.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 3 is a perspective view showing a honeycomb-shaped reinforcing material for restraining soil particles according to the present invention, and FIG. 4 is a partial view showing a structure of a honeycomb-shaped cell network portion forming the honeycomb-shaped reinforcing material for restraining soil particles according to the present invention. FIG. 5 is a partially extracted front view showing the structure of a sheet forming the honeycomb cell network according to the present invention.

  As shown in FIGS. 3 and 5, the honeycomb-shaped reinforcing material 1 for restraining soil particles according to the present invention has a certain size while the transverse reinforcing yarn 10 and the longitudinal reinforcing yarn 20 made of polyethylene having a predetermined length intersect each other. A net-like sheet 40 having a large number of meshes 30 may be formed, and the crossing pattern of the transverse reinforcing yarns 10 and the longitudinal reinforcing yarns 20 may be formed into a shape of +, x, or * as necessary.

  When the sheet 40 is formed, the adjacent sheet 40 is fusion-bonded at a constant interval in the width direction of the sheet. At this time, the fusion is performed by ultrasonic welding, hot melt welding, hot wedge welding, hot air welding, or the like.

  When fusing again with another adjacent sheet while fusing at a fixed interval, fusing is performed at the intermediate part between the already fused parts so that the fused parts do not overlap.

  When a large number of the fused sheets 40 are stacked as described above, a large number of honeycomb cell networks 50 are formed by pulling the sheets in one direction.

  As described above, when a large number of sheets are fused at regular intervals to form the cell-like cell network part 50, the space of the cell network part 50 is filled with aggregates such as sand, earth, and gravel. Then, since a very large number of meshes are uniformly formed on the entire surface of the sheet without a separate subsequent process, the friction characteristics are increased, and the conventional honeycomb-shaped reinforcing material for restraining soil particles using a general belt-shaped sheet is used. There are advantages such as a material saving effect and weight reduction effect of 20% or more, and easy root survival.

  Experiments were carried out by a large shear test method on the soil-restrained honeycomb-shaped reinforcing material 1 of the present invention having the structure described above and the conventional slope protecting reinforcing material made of a high-density polyethylene material as shown in FIG. went. The experimental results are shown in the following table.

Experimental method: Large shear test method Experimental condition: Upper part-weathered soil
Lower part-Reinforcement made of high-density polyethylene

Experimental method: Large shear test method Experimental condition: Upper part-weathered soil
Lower part-honeycomb reinforcing material for restraining soil particles of the present invention

  As shown in Table 1, the graph showing the displacement-shear force against the normal stress and the graph showing the normal stress-maximum shear stress curve using the conventional high-density polyethylene reinforcing material are shown in FIGS. Is shown in Correspondingly, as shown in Table 2, the graph showing the displacement-shear force with respect to normal stress and the normal stress-maximum shear stress curve are shown using the honeycomb-shaped reinforcing material for restraining soil particles according to the present invention. The graphs are shown in FIGS. 8 and 9.

  Here, the honeycomb-shaped reinforcing material for restraining soil particles according to the present invention has about 50% higher frictional properties and about 9 times higher adhesive strength than when a conventional reinforcing material made of high-density polyethylene is used. I understand.

  As shown in FIG. 3, the ends in the width direction, that is, the ends of the horizontal reinforcing yarn 10 and the vertical reinforcing yarn 20 protrude sharply, so that the ends of the horizontal reinforcing yarn 10 and the vertical reinforcing yarn 20 bite into the ground and are fixed. The force and frictional force are increased, and the soil-like constraining honeycomb reinforcing material 1 of the present invention is fixed and installed more stably.

DESCRIPTION OF SYMBOLS 1 Honeycomb reinforcement material for earth particle restraint 10 Horizontal reinforcement thread 20 Longitudinal reinforcement thread 30 Mesh 40 Sheet 50 Cell mesh part

Claims (4)

In the honeycomb reinforcing material for soil particle restraint,
By forming a mesh-like sheet having a mesh of a certain size while the transverse reinforcing thread and the longitudinal reinforcing thread intersect, the sheet is fused and connected at a certain interval in the width direction, and then pulled in one direction to A honeycomb-shaped reinforcing material for restraining soil particles, characterized by forming a honeycomb-shaped cell network portion.   2. The honeycomb reinforcing material for restraining soil particles according to claim 1, wherein an intersecting pattern of the horizontal reinforcing yarn and the vertical reinforcing yarn is selected from shapes of +, ×, and *.   The soil particle constraining according to claim 1, wherein the fusion is performed by any one method selected from ultrasonic welding, hot melt welding, hot wedge welding, and hot air welding. Honeycomb reinforcement. 2. The honeycomb-shaped reinforcing material for restraining soil particles according to claim 1, wherein an end portion in the width direction of the sheet is sharply formed by an end portion of the horizontal reinforcing yarn and the vertical reinforcing yarn.

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