JP2774416B2 - Lightweight embankment method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lightweight embankment method.

[0002]

2. Description of the Related Art Conventionally, when the foundation ground at an embankment construction site is soft or has a risk of landslide, embankment is constructed after various countermeasure methods such as ground improvement are performed.

Recently, a method (EPS method) of laminating lightweight styrofoam blocks as embankment material has also been implemented.

[0004]

However, it takes a lot of construction time and cost to take countermeasures such as ground improvement.

[0005] In the method of laminating styrofoam blocks (EPS method), there are problems such as the necessity of accurate ground shaping, the necessity of construction of concrete slabs, the necessity of brazing material, and the dissolution in petroleum. Was.

[0006]

Accordingly, in the present invention, a permeable layer is formed on a leveled embankment construction site, and a urethane foaming stock solution is foamed on the permeable layer to form a urethane foam layer. A lightweight embankment that does not dissolve in petroleum oils, and is filled with a certain thickness of earth and sand on the surface of the urethane foam layer to form an embankment. .

Further, in the present invention, urethane is mixed with an aggregate to form a urethane foam layer. As the aggregate, various foamed resin pieces, various plastic pieces, tire pieces, wood pieces,
The use of at least one of concrete lumps, asphalt lumps, pumice stones, and crushed stones, the provision of a reinforcing material in the urethane foam layer, and the provision of a styrofoam block in the urethane foam layer Also have features.

[0008]

[Function] The embankment is constructed according to the following procedure.

[0009] Excavation of the embankment construction site as necessary,
Level the ground.

A water permeable layer is formed on the leveled embankment construction site, and a urethane foaming stock solution is foamed on site on the water permeable layer to form a urethane foam layer having a predetermined height.

[0011] Earth and sand of a certain thickness are piled on the surface of the urethane foam layer to form an embankment surface layer.

In this manner, a lightweight embankment can be easily constructed.

At this time, by mixing the urethane with the aggregate to form the urethane foam layer, the amount of the expensive urethane used can be reduced and the strength can be increased. At least one of various foamed resin pieces, various plastic pieces, tire pieces, wood pieces, concrete lumps, asphalt lumps, pumice stones, crushed stones, and the like can be used.

Further, when a reinforcing material is provided in the urethane foam layer, the embankment can be made stronger.

When a lightweight material such as a styrofoam block is provided in the urethane foam layer, the amount of expensive urethane used can be greatly reduced while ensuring the lightness of the embankment.

[0016]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a construction flow diagram of a lightweight embankment A as a first embodiment of a flat ground embankment of the lightweight embankment method according to the present invention. The lightweight embankment construction method will be described with reference to the construction flow diagram. I do.

As shown in FIG. 1A, an embankment construction site G is excavated and leveled as required.

As shown in FIG. 1B, a permeable layer 1 is formed by forming a sand layer having a certain thickness or laying a permeable sheet on the ground-filled embankment construction site G.

As shown in FIG. 1 (c), the urethane foaming stock solution is jetted and injected onto the water-permeable layer 1 by a urethane jetting device / injecting device M and foamed to form a urethane foam layer 2 having a constant height. .

As shown in FIGS. 1 (d) and (e), the urethane foam layers 2 having a constant height are sequentially laminated and foamed in a stepwise manner and integrated to form an integrated urethane foam layer 2 having a predetermined height. I do.

As shown in FIG. 1F, earth and sand are piled on the surface of the urethane foam layer 2 to a certain thickness to form an embankment surface layer 3.

In this way, a lightweight embankment A can be constructed.

Here, the urethane foam forming the urethane foam layer 2 is (1) lightweight, (2) workability, (3) filling property,
(4) composite structure, (5) self-sustainability, (6) water resistance, (7) strength properties, (8) water permeability / absorption properties, (9) heat resistance, (10) chemical resistance,
(11) It has the following characteristics with respect to shock absorption.

(1) Lightweight The unit volume weight is 25-50 kg / m ³ (can be set arbitrarily by mixing the stock solution) and ultra-light (about 1/50 of earth and sand / concrete)
This is effective in solving the problem of soft ground subsidence and insufficient bearing capacity.

(2) Workability The undiluted solution is pumped by a hose and foamed 20 to 40 times, so that embankment with urethane foam can be formed. With small equipment, small amount of materials,
A large amount of construction is possible in a short time, and the workability is very good. Easy ground formation at the construction site and good workability.

(3) Fillability The urethane foaming stock solution is foamed several tens times and then hardened, so that it can be easily filled and molded even if the ground has irregularities.

(4) Composite Structure The foamed urethane is excellent in self-adhesiveness, and it adheres to and solidifies with an object, so that it can be integrated as a composite structure. Further, since the reinforcing steel reinforcing material can be easily incorporated, it is possible to form a stronger structure.

(5) Self-sustainability When the urethane stock solution is brought into contact with the cured urethane foam and then newly foamed, they are bonded and integrated with each other to form a continuous mass (lump) without weak lines, and used as a self-standing structure. it can.

(6) Water resistance The foam is a foam containing closed cells and is chemically stable, so that it is not deteriorated by water.

(7) Strength properties A foamed urethane foamed 30 to 40 times, has a uniaxial compressive strength of about 2 kgf / cm ² , and can form a foam having a higher strength by blending. The strength required for the embankment material is sufficient. It is.

(8) Water Permeability In the case of a closed-cell foam, there is no water permeability.

(9) Heat resistance At 80 ° C. or lower, there is no problem in normal use.

(10) Chemical resistance Generally, it has resistance to acids and alkalis and does not dissolve in gasoline or kerosene.

(11) Shock Absorbing Property It has good shock absorbing property.

Further, by forming an urethane foam layer 2 by mixing an aggregate with urethane, the amount of expensive urethane used can be reduced and the strength can be increased.

At this time, as the aggregate, styrene foam pieces, various plastic pieces, tire pieces, wood pieces and the like, which are industrial wastes, can be effectively used, and concrete lumps, asphalt lumps, pumice stones, crushed stones and the like can be used. At least one of them may be used.

FIG. 2 is a construction flow diagram of a lightweight embankment A as a second embodiment according to the present invention. The lightweight embankment method will be described with reference to the construction flowchart.

As shown in FIG. 2A, the embankment construction site G is excavated as necessary and leveled.

As shown in FIG. 2B, a permeable layer 1 is formed by forming a sand layer of a certain thickness or laying a permeable sheet on the leveled embankment construction site G.

As shown in FIG. 2 (c), after arranging a reinforcing bar or the like as a reinforcing material 4 in a frame, a hard urethane stock solution is jetted onto the permeable layer 1 by a urethane jetting device / injecting device (not shown). Inject and foam to form a urethane foam layer 2 having a certain height.

As shown in FIG. 2D and FIG. 2E, the urethane foam layers 2 having a fixed height are sequentially laminated and foamed in a stepwise manner and integrated to form an integrated urethane foam layer 2 having a predetermined height. .

As shown in FIG. 2F, earth and sand are piled on the surface of the urethane foam layer 2 to a certain thickness to form an embankment surface layer 3.

In this way, by arranging a reinforcing bar or the like as the reinforcing material 4 in the urethane foam layer 2, the strength of the lightweight embankment A can be increased.

At this time, the reinforcing material 4 may be a reinforcing bar, a wire mesh,
Mesh, various types of civil engineering sheets, glass fibers, organic fibers, and the like can be used.

FIG. 3 is a construction flow chart of a lightweight embankment A as a third embodiment according to the present invention. The lightweight embankment method will be described with reference to this construction flow chart.

As shown in FIG. 3A, the embankment construction site G is excavated and leveled as required.

As shown in FIG. 3 (b), a water layer 1 is formed by forming a sand layer having a certain thickness or laying a water permeable sheet on the leveled embankment construction site G.

As shown in FIG. 3C, a plurality of styrofoam blocks 5 are placed on the permeable layer 1 in a stepwise manner.
A urethane stock solution is jetted and injected around and above the styrofoam 5 by a urethane jetting / injecting device (not shown), foamed and bonded and integrated, and a urethane foam layer 2 enclosing a styrofoam block 5 having a fixed height. To form

As shown in FIG. 3 (d), the urethane foam layer 2 enclosing the styrofoam block 5 having a fixed height is sequentially laminated and foamed in a stepwise manner and integrated, and the integrated styrofoam block 5 having a predetermined height is included. The urethane foam layer 2 to be formed is formed.

As shown in FIG. 3E, earth and sand are piled up to a certain thickness on the surface of the urethane foam layer 2 to form an embankment surface layer 3.

In this way, the use of expensive urethane can be greatly reduced while maintaining the lightness and integration of the lightweight embankment A.

At this time, the styrofoam block has a unit weight of about 0.02 g / cm ^{3, which} is very light (about 1/100 of earth and sand / concrete), is self-supporting, can be stacked manually, and has good workability. .

[0054]

According to the present invention, the following effects can be obtained.

The urethane foaming stock solution can be foamed on site to form a urethane foam layer that occupies most of the embankment, so that the construction can be performed quickly and easily and the weight of the embankment can be significantly reduced. it can. Due to this weight reduction, various countermeasure methods such as ground improvement are not required even when the foundation ground is soft and there is a risk of slipping, and the construction period and construction cost can be reduced. In addition, the urethane foam stock solution has a water-permeable layer on the embankment construction site formed in advance and foams on the water-permeable layer, so the urethane foam layer itself has no water permeability, but drainage from the foundation ground It can be made good through the permeable layer, promoting the soil compaction effect and increasing the strength of the foundation ground.

Since urethane foam is a structure that is integrated and adhered to the shape of the construction site, it can be easily formed into the ground, and is required for the construction of concrete floor slabs required for the method of laminating styrofoam blocks (EPS method), and for the binding of braces. Is unnecessary, and the workability is good.

Further, no countermeasures against petroleum are required, and the workability is good.

As the urethane foam, one having an appropriate density and strength can be arbitrarily used according to the use of each part, and further, they can be continuously integrated.

By mixing the aggregate with the urethane, a composite and integrated urethane foam mixed layer can be formed. As a result, the amount of expensive urethane used can be reduced, and a urethane foam mixture having an appropriate density and strength can be selected and used according to the use of each part.

In the above, at least one of various foamed resin pieces, various plastic pieces, tire pieces, wood pieces, concrete lumps, asphalt lumps, pumice stones, crushed stones and the like can be used as the aggregate. We can utilize waste.

In the urethane foam layer, reinforcing materials such as reinforcing bars, wire meshes, meshes, various types of civil engineering sheets, glass fibers, organic fibers, and the like can be easily provided, and the strength can be increased.

Since a lightweight body such as a styrofoam block can be arranged in the urethane foam layer and integrated into a composite, the amount of expensive urethane foam to be used can be significantly reduced while ensuring the lightness of the embankment. Thus, the construction cost can be reduced.

[Brief description of the drawings]

FIG. 1 is a construction flow diagram as a first embodiment of a lightweight embankment method according to the present invention.

FIG. 2 is a construction flow diagram as a second embodiment.

FIG. 3 is a construction flowchart as a third embodiment.

[Explanation of symbols]

 A Lightweight embankment 1 Water-permeable layer 2 Urethane foam layer 3 Embankment surface layer 4 Reinforcement material 5 Lightweight material such as styrene foam block

Continuation of the front page (56) References JP-A-62-197512 (JP, A) JP-A-62-268414 (JP, A) JP-A-4-106218 (JP, A) (58) Fields investigated (Int) .Cl. ⁶ , DB name) E02D 3/00 101 E02D 17/18

Claims (5)

(57) [Claims] 1. A permeable layer is formed on a molded embankment construction site.
Then, a urethane foaming undiluted solution is foamed on the water-permeable layer to form a urethane foam layer, and earth and sand of a certain thickness are piled on the surface of the urethane foam layer to form an embankment containing the urethane foam layer. A lightweight embankment method. 2. The lightweight embankment method according to claim 1, wherein an aggregate is mixed with urethane to form a urethane foam layer. 3. An aggregate comprising at least one of various foamed resin pieces, various plastic pieces, tire pieces, wood pieces, concrete lumps, asphalt lumps, pumice stones, and crushed stones. Item 2. The lightweight embankment method according to item 2. 4. The lightweight embankment method according to claim 1, wherein a reinforcing material is provided in the urethane foam layer. 5. The lightweight embankment method according to claim 1, wherein a styrofoam block is provided in the urethane foam layer.