JP6853771B2 - Embankment structure and embankment construction method - Google Patents

Description

The present disclosure relates to an embankment structure and an embankment construction method.

Conventionally, railroad tracks, that is, embankments constructed by raising earth and sand on the ground in order to pass the track higher than the ground, have been widely used, but when the ground itself is soft, it is on the ground. A technique has been proposed in which a cement-improved gravel slab is laid on the cement-improved gravel slab and an embankment is constructed on the cement-improved gravel slab (see, for example, Patent Document 1).

FIG. 3 is a schematic cross-sectional view of a conventional embankment structure.

In the figure, 91 is a ground such as soft ground, and 92 is a cement-improved gravel slab laid on the surface of the ground 91. The cement-improved gravel slab 92 includes cement-improved gravel 92a, which is a type of cement-improved soil obtained by mixing crushed stone and cement having an adjusted particle size, and geogrid 92b embedded in the cement-improved gravel 92a. And. In the example shown in the figure, the geogrid 92b is arranged to form two layers. Then, an embankment 93 made of high-quality earth and sand is constructed on the cement-improved gravel slab 92. The track is usually constructed on the upper surface of the embankment 93 with a roadbed such as an asphalt roadbed, ballast is laid on the roadbed, and the track is laid on the pillows arranged on the ballast.

Japanese Unexamined Patent Publication No. 2011-220108

However, although the above-mentioned conventional technique is extremely effective when constructing a new embankment, when reconstructing an embankment that has collapsed due to heavy rain or an earthquake, a long time, enormous labor, and a large amount of cost are required. This will hinder the early restoration of the railway.

Normally, the embankment such as the damaged railway embankment needs to be restored at an early stage, so it is constructed by stacking multiple large sandbags called tonpacks. However, since the soil filled in the sandbags is generally locally generated soil with low strength and rigidity, it is possible to use locally generated soil with low strength and rigidity in areas where railroad loads directly act, such as directly under the track or above the embankment. Deformation and track subsidence may occur after resumption of service. Therefore, the part of the embankment on which the railroad load directly acts is constructed as in the past without using sandbags, which requires a long time and enormous labor. Furthermore, although conventional embankments are constructed from high-quality earth and sand, it is difficult to obtain good-quality earth and sand around the disaster site, and even if it can be obtained, it will reach the disaster site. It is difficult to bring in.

Here, by solving the problems of the conventional technique and laying a cement-improved gravel slab on the constructed embankment, the embankment structure has high strength and can be easily constructed in a short time. And to provide a method of embankment construction.

Therefore, the embankment structure includes an embankment constructed on the ground and a cement-improved gravel slab laid on the embankment, which includes a cement-improved gravel and a geogrid. ..

In other embankment structures, the geogrid is a flat grid-like reinforcing material made of a polymer material, which is embedded in the cement-improved gravel.

In yet another embankment structure, the embankment further comprises a plurality of sandbags.

In still other embankment structures, the sandbags further include collapsed soil that made up the collapsed embankment and locally generated soil that is the earth and sand around the collapsed embankment.

In still another embankment structure, the embankment is constructed by heaping up earth and sand .

In still other embankment structures, the embankment further includes collapsed soil that constituted the collapsed embankment and locally generated soil that is the earth and sand around the collapsed embankment.

In yet another embankment structure, a trackbed is laid directly on the upper surface of the cement-improved gravel slab.

In the embankment construction method, an embankment is constructed on the ground, and a cement-improved gravel slab containing cement-improved gravel and geogrid is laid on the embankment.

According to the present disclosure, a cement-improved gravel slab is laid on the constructed embankment. As a result, an embankment structure having high strength can be easily constructed in a short time.

It is a schematic cross-sectional view of the embankment structure in the 1st Embodiment. It is a schematic cross-sectional view of the embankment structure in the 2nd Embodiment. It is a schematic cross-sectional view of the conventional embankment structure.

Hereinafter, the present embodiment will be described in detail with reference to the drawings.

FIG. 1 is a schematic cross-sectional view of the embankment structure according to the first embodiment.

In the figure, reference numeral 31 denotes a supporting ground as a ground for supporting the embankment structure in the present embodiment, and is, for example, a soft ground, but the ground is not necessarily limited thereto, and may be a strong ground. .. Here, for convenience of explanation, it is assumed that the supporting ground 31 is a soft ground affected by heavy rain or an earthquake.

Reference numeral 21 denotes an embankment constructed on the supporting ground 31. The embankment 21 extends in a direction perpendicular to the screen shown in the figure, and may be used for supporting a road or as a river embankment, for example. It may be used for any purpose, but here, for convenience of explanation, it is assumed that it is used to support a railroad track, that is, a track. Further, the embankment 21 may be newly constructed, but here, for convenience of explanation, it is assumed that the embankment that has collapsed due to heavy rain or an earthquake is restored at an early stage. Therefore, the embankment 21 is constructed by stacking a plurality of large sandbags 22 called ton packs. Specifically, the entire embankment 21 is constructed by stacking sandbags 22.

The sandbag 22 is, for example, about 1000 [kg] of earth and sand in a bag-shaped packaging material having a large square or cylindrical shape of about 1 [m] × 1 [m] × 1 [m]. It is packed with. The bag-shaped packaging material is called a flexible container bag, and is composed of a sheet and a belt woven with durable chemical fibers such as polyethylene and polypropylene. The sandbag 22 does not necessarily have to be a ton pack, and is a smaller one, for example, a small bag-shaped packaging material packed with about 15 to 20 [kg] of earth and sand. May be good.

In addition, the earth and sand in the sandbag 22 is from high-quality earth and sand, for example, earth and sand corresponding to the first type construction occurrence soil or the second type construction occurrence soil specified by the Ordinance of the Ministry of Land, Infrastructure, Transport and Tourism, and the flat plate loading test (JIS A 1215). It is desirable that the obtained earth and sand has a K ₃₀ value of 70 to 110 [MN / m ³ ] or more, but it does not necessarily have to be good quality earth and sand, and any kind of earth and sand may be used, for example. It may be the collapsed soil that constituted the collapsed embankment, or the local soil that is the earth and sand around the collapsed embankment.

In the example shown in the figure, the entire embankment 21 is composed of the stacked sandbags 22, but only a part of the embankment 21 (for example, only the parts on both sides) is composed of the sandbags 22 and other parts. The portion may be composed of earth and sand, crushed stone, or the like.

Further, reference numeral 10 denotes a cement-improved gravel slab laid on the embankment 21. The cement-improved gravel slab 10 is a cement-improved gravel soil 12 which is a kind of cement-improved soil obtained by mixing crushed stone and cement having an adjusted particle size in the earth and sand, and a geogrid 11 embedded in the cement-improved gravel soil 12. It is a flat thick plate-like composite material that extends in the direction perpendicular to the screen in the figure. The cement-improved gravel 12 is obtained by adding a ^{small amount of cement (usually 50 to 80 [kg / m 3} ]) to a particle size-adjusted crushed stone (usually M-40 grain crushed stone) and stabilizing it. By sufficiently stirring and compacting, the material has higher strength and deformation characteristics as compared with ordinary gravel material (see, for example, Non-Patent Document 1). Further, the geogrid 11 is a flat grid-like reinforcing material made of a polymer material widely used for reinforced soil structures, and is a reinforcing material having high tensile strength. In the example shown in the figure, the geogrid 11 is arranged so as to form two layers, but the geogrid 11 may be arranged so as to form one layer. It may be arranged so as to form three or more layers. The cement-improved gravel slab 10 having such a structure has high bending rigidity and toughness because the geogrid 11 bears the tensile force generated inside the member and the cement-improved gravel 12 bears the compressive force.
Kenji Watanabe, "Method of constructing embankment on soft ground using cement-improved gravel soil", Civil engineering construction, Vol. 50, No. 7, pp. 17-21, July 2009

The cement-improved gravel slab 10 also has an excellent water-shielding effect. Without the addition of cement, i.e., while the permeability of tills that do not cement improvement of about 10 ^-2 [m / s], tills where the cement improved, i.e., permeability of cement improved tills 10 ^- It has been confirmed that it is about ⁶ to 10 ^{-9 [m / s].} In other words, it has been confirmed that the water permeability coefficient of gravel soil is significantly reduced by improving cement, and the water-impervious effect is greatly improved. Therefore, since the water supplied to the upper surface of the cement-improved gravel slab 10 due to rainfall or the like hardly permeates the cement-improved gravel slab 10, the embankment 21 located below the cement-improved gravel slab 10 does not absorb the water. As a result, the embankment 21 can be reliably prevented from being deformed or collapsed.

Further, it is desirable that the upper surface of the cement-improved gravel slab 10 is a flat surface. As a result, it is possible to directly lay a track bed such as a track concrete of a slab track or a track bed ballast of a ballast track on the upper surface of the cement-improved gravel slab 10 without constructing a roadbed. Therefore, it is not necessary to construct a roadbed such as a concrete roadbed for a slab track or an asphalt roadbed for a ballast track, so that the workability of the track is improved.

Further, since the cement-improved gravel slab 10 has high rigidity and is hard to be deformed, vibration is hard to be transmitted to the member under the cement-improved gravel slab 10, that is, it has a seismic isolation effect (see, for example, Non-Patent Document 1). Therefore, the load of the train passing through the track laid on the cement-improved gravel slab 10, that is, the railroad load is difficult to be transmitted to the embankment 21 located under the cement-improved gravel slab 10, and the embankment 21 has a plurality of embankments 22. Even if it is constructed by stacking individual pieces, or if the earth and sand in the earthen slab 22 is not of good quality, the embankment 21 will not be deformed or collapsed.

In the present embodiment, the directions of upper, lower, left, right, front, rear, etc. used to explain the configuration and operation of each part of the cement-improved gravel slab 10, embankment 21, and supporting ground 31 are shown. The expression is relative rather than absolute, and is appropriate when each part of the cement-improved gravel slab 10, embankment 21, and supporting ground 31 is in the posture shown in the figure, but the posture changes. If so, it should be changed and interpreted according to the change in posture.

As described above, the embankment structure in the present embodiment is the embankment 21 constructed on the supporting ground 31 and the cement-improved gravel slab 10 laid on the embankment 21, and the cement-improved gravel 12 and the geogrid. It is provided with a cement-improved embankment slab 10 including 11. Further, the embankment construction method includes a step of constructing an embankment 21 on the supporting ground 31 and laying a cement-improved gravel slab 10 containing the cement-improved gravel soil 12 and the geogrid 11 on the embankment 21. As a result, although it has a simple structure, it can exhibit high strength and can be easily constructed in a short time. Further, since the water supplied to the embankment structure from above does not permeate the cement-improved gravel slab 10, the embankment 21 does not absorb the water, and the vibration and impact applied to the embankment structure from above. Since the load such as the above is not directly transmitted to the embankment 21, the embankment 21 is not deformed or collapsed.

Further, in the present embodiment, the geogrid 11 is a flat grid-like reinforcing material made of a polymer material, and is embedded in the cement-improved gravel soil 12. Therefore, the cement-improved gravel slab 10 has high rigidity and does not deform even when subjected to a large load.

Further, in the present embodiment, the embankment 21 includes a plurality of sandbags 22. Therefore, the embankment 21 can be constructed by stacking the sandbags 22, and the embankment structure can be easily constructed in a short time.

Further, in the present embodiment, the sandbag 22 contains poor quality earth and sand. Therefore, for example, even in the case of restoring the damaged embankment structure, the embankment 21 can be easily obtained and the embankment 21 can be constructed, so that the embankment structure can be easily constructed in a short time. it can. Further, the moisture supplied to the embankment structure from above does not permeate the cement-improved gravel slab 10, and the load applied to the embankment structure from above is not directly transmitted to the embankment 21, so that the embankment 22 constituting the embankment 21 Even if it contains poor quality earth and sand, the embankment 21 will not be deformed or collapsed.

Further, in the present embodiment, the track bed is laid directly on the upper surface of the cement-improved gravel slab 10. Therefore, since it is not necessary to construct the roadbed, the trackbed can be easily laid in a short time.

Next, the second embodiment will be described. For those having the same structure as that of the first embodiment, the description thereof will be omitted by assigning the same reference numerals. Further, the description of the same operation and the same effect as that of the first embodiment will be omitted.

FIG. 2 is a schematic cross-sectional view of the embankment structure according to the second embodiment.

In the present embodiment, the embankment 21 is not constructed by stacking a plurality of sandbags 22 as in the first embodiment, but is constructed by stacking sandbags, and includes the sandbags 22. It is not. The earth and sand for constructing the embankment 21 is preferably good quality earth and sand like the earth and sand packed in the sandbag 22 in the first embodiment, but it does not necessarily have to be good quality earth and sand. The soil may be of lower quality than usual.

Further, it is desirable that the upper surface of the cement-improved gravel slab 10 is a flat surface as in the first embodiment. As a result, the trackbed can be laid directly on the upper surface of the cement-improved gravel slab 10 without constructing a roadbed. Therefore, since it is not necessary to construct the roadbed, the workability of the track is improved.

Since the configuration of other points is the same as that of the first embodiment, the description thereof will be omitted. Further, the actions and effects of other points are the same as those in the first embodiment, and thus the description thereof will be omitted.

As described above, in the present embodiment, the embankment 21 does not include the sandbag 22. In addition, the embankment 21 contains earth and sand of poor quality. Therefore, for example, even in the case of restoring the damaged embankment structure, the embankment 21 can be easily obtained and the embankment 21 can be constructed, so that the embankment structure can be easily constructed in a short time. it can. Further, the moisture supplied to the embankment structure from above does not permeate the cement-improved gravel slab 10, and the load applied to the embankment structure from above is not directly transmitted to the embankment 21, so that the earth and sand constituting the embankment 21 is of good quality. Even if this is not the case, the embankment 21 will not be deformed or collapsed.

It should be noted that the disclosure herein describes features relating to preferred and exemplary embodiments. Various other embodiments, modifications and modifications within the scope and purpose of the claims attached herein can be naturally conceived by those skilled in the art by reviewing the disclosure of the present specification. is there.

The present disclosure can be applied to embankment structures and embankment construction methods.

10 Cement-improved gravel slab 11 Geogrid 12 Cement-improved gravel 21 Embankment 22 Sandbag 31 Supporting ground

Claims (8)

The embankment built on the ground and
An embankment structure which is a cement-improved gravel slab laid on the embankment and includes a cement-improved gravel slab including a cement-improved gravel and a geogrid. The embankment structure according to claim 1, wherein the geogrid is a flat grid-like reinforcing material made of a polymer material and is embedded in the cement-improved gravel. The embankment structure according to claim 1 or 2, wherein the embankment includes a plurality of sandbags. The sandbag is the embankment structure according to claim 3, which includes the collapsed soil that constitutes the collapsed embankment and the locally generated soil that is the earth and sand around the collapsed embankment. The embankment structure according to claim 1 or 2, wherein the embankment is constructed by heaping up earth and sand. The embankment structure according to claim 5, wherein the embankment includes the collapsed soil that constitutes the collapsed embankment and the locally generated soil that is the earth and sand around the collapsed embankment. The embankment structure according to any one of claims 1 to 6, wherein the trackbed is laid directly on the upper surface of the cement-improved gravel slab. Build an embankment on the ground,
A method for constructing an embankment, which comprises laying a cement-improved gravel slab containing a cement-improved gravel and a geogrid on the embankment.

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