JP5090672B2 - Waste disposal site, impermeable structure, and construction method for building a waste disposal site - Google Patents

Description

The present invention relates to a technology for constructing a waste disposal site.
More specifically, the present invention relates to a technique for constructing a water shielding structure on a concave surface for dumping waste.

  The waste disposal site has a concave surface provided by digging the ground or constructing a retaining wall. Waste is sequentially dumped into this concave surface.

By the way, in the waste disposal site, it is extremely important to prevent leachate generated by rainwater falling on the waste dumped in the concave surface from leaking from the concave surface to the external soil.
The most widely used technique for preventing leakage of leachate is to provide a water shielding layer that covers the entire concave surface. This water shielding layer is made by laying a water shielding sheet over the entire concave surface. Leakage water is prevented from leaking to the outside by laying a water-impervious sheet having a high water-impervious performance made of a synthetic resin impermeable sheet or a rubber impermeable sheet over the entire concave surface.
In particular, in recent years, since the demand for preventing leakage of leachate to the outside is increasing, a technique of using two sheets of the above-described water-impervious sheet in practical use has been put into practical use.

  However, even if a water shielding sheet is used, leachate leaks to the outside if sharp objects mixed in the waste damage the water shielding sheet. It is the same even when two sheets of water-impervious sheets are stacked.

  An object of the present invention is to improve the water shielding structure of a waste disposal site so that leakage of leachate can be prevented at a higher level.

The above-described problems are solved by the following invention.
The present invention is a case where a concave surface for dumping waste and a powder or granular material are formed on the concave surface to form a layer with a predetermined thickness, and the layer is impregnated with moisture. A waste disposal site comprising a swollen impermeable layer that is swollen to exhibit a impermeable function, and a impermeable layer having a water impermeable function formed on the swollen impermeable layer. .
This waste disposal site is formed in the form of a layer of a predetermined thickness on the concave surface in the form of powder or granules in addition to the water shielding layer, and the layer is impregnated with moisture. In this case, a swelling water-impervious layer is provided that swells to exhibit a water-impervious function. The swollen water-impervious layer is formed of a powdery substance or a granular substance, and exhibits a water-impervious function by sucking and swelling the impregnated moisture. Therefore, the swelling impermeable layer is less likely to leak leachate due to local breakage than the impermeable layer often composed of the impermeable sheet.
Therefore, according to this waste disposal site, the risk of leakage of leachate can be reduced.

The present invention is also a water-blocking structure for a waste disposal site formed on a target surface that is an arbitrary range of concave surfaces for dumping waste, wherein the concave surface is made of powder or granular material. A swollen impermeable layer that is formed so as to have a layer thickness of a predetermined thickness and that swells when the layer is impregnated with water and exhibits a water impermeable function, and the swollen impermeable layer And a water shielding layer having a water shielding function formed thereon.
This water-impervious structure can also reduce the risk of leakage of leachate, similar to the waste disposal site described above.

In the present invention, when the swollen impermeable layer swells, the swollen impermeable layer swells to such an extent that the swollen impermeable layer can be visually found from the front side of the impermeable layer. You may have the softness | flexibility of the grade which the done position swells.
When the water shielding layer is damaged, the swelling water shielding layer swells. Therefore, it is necessary to find it quickly and repair the damaged part.
When the swollen impermeable layer swells, the position where the swollen impermeable layer swelled to such an extent that the swollen impermeable layer can be visually detected from the front side of the impermeable layer (that is, the swollen impermeable layer swelled) In the case where a water shielding layer having such a degree of flexibility as to expand is adopted, it becomes possible to quickly find a breakage in the water shielding layer and repair the damaged portion quickly. Therefore, the risk of leakage of leachate can be reduced by employing such a water shielding layer.

The water shielding layer in the present invention is not particularly limited as long as it has a water shielding function, and its production method, material, etc. are not particularly limited. For example, the water-impervious layer may be a water-impervious sheet, or may be a solidified liquid resin sprayed on the surface of the swelling water-impervious layer. The water-impervious sheet is generally long, and laying it is disadvantageous in terms of labor and cost. Further, in general, the water shielding sheet is generally laid in the concave surface by being connected by fusing together adjacent ones in a state of being hung from the edge of the concave surface toward the bottom of the concave surface. However, the operation | work which hangs a water-impervious sheet | seat from the edge of the concave surface used as a high place when it sees from the bottom part of a concave surface, and connects adjacent things is not necessarily safe.
If the water-impervious layer is formed by spraying a liquid resin on the surface of the swollen impermeable layer and solidifying it, it takes less time than using a water-impervious sheet, and the safety of the work can be increased. .

  The swollen water-impervious layer in the present invention is formed as a layer of a predetermined thickness on the concave surface in a powdery or granular form, and swells when the layer is impregnated with moisture. The details are not limited as long as the water shielding function is exhibited. For example, the swollen water-impervious layer may be formed of bentonite, a highly water-absorbent resin (for example, SAP, which is a derivative of acrylic acid), or swollen rubber.

This invention also provides the construction method for constructing | assembling the waste disposal site which has a water-impervious structure in the target surface which is the arbitrary ranges among the concave surfaces for waste dumping. This construction method forms a water shielding structure on an existing concave surface.
In this construction method, a concave surface for waste disposal is constructed, and the target surface of the concave surface swells when moisture is impregnated in the gap between the planar first member and the second member. A swelled water-impervious member formed by arranging a powdery body or a granular material having a predetermined thickness to form a water-insulating function, and has a water-insulating function on the swollen water-insulated member Form a water shielding layer.
A waste disposal site having a water-impervious structure made by this construction method can also reduce the risk of leakage of leachate.
In this construction method, the entire surface of one side of the first member and the second member may be fixed to the target surface. If there is a gap between the concave surface and the first member in contact with the concave surface, or between the concave surface and the second member in contact with the concave surface, the swollen water-impervious member may be easily damaged, or leaching water may occur. In some cases, the leachate may spread over a wide range through the gap. If the entire surface of one side of the first member and the second member is fixed to the target surface, such a fear can be suppressed.
In the method of forming a water-impervious structure on an existing concave surface, an integral swollen water-impervious member formed by sandwiching a swollen water-impervious material between the first member and the second member can be used. Both the first member and the second member can be paper, non-woven fabric or woven fabric. The first member and the second member may be made of the same material or different materials. Moreover, while the adhesive is apply | coated to the whole surface of what is fixed to the said target surface among the 1st member and the 2nd member, the surface of the said 1st member or the said 2nd member to which the said adhesive was apply | coated Can be provided with a sheet-like cover material that can be easily removed. Of the first member and the second member in the swollen water-impervious member having a cover material and a pressure-sensitive adhesive, it is preferable that the second member to be coated with the pressure-sensitive adhesive is made of paper. This is because the surface that contacts the concave surface of the swelled water-impervious member can be made smoother by doing so, so that the adhesive with the adhesive to the concave surface of the swelled water-impervious member can be made stronger.
In this construction method, a swollen impermeable layer is formed by the swollen impermeable member, and a further impermeable layer can be formed thereon.

The present invention is also a waste disposal site having a water shielding structure on a target surface which is an arbitrary range of concave surfaces for dumping waste, and the target surface is made by placing concrete. We also provide a construction method for constructing what is said to be the surface. In this method, the concrete body and the water-impervious structure are formed together.
In this construction method, in the form for placing concrete for constructing the concrete body, when the placed concrete is hardened, a portion corresponding to the target surface is formed with a planar first member and A swollen water-impervious structure in which powders or granules that swell when they are impregnated with water and exhibit a water-blocking function are arranged in a gap between the second members so as to form a layer of a predetermined thickness By fixing the member, placing concrete in that state, and removing the formwork after the concrete is hardened, a concrete body in which the swelling water-impervious member is fixed to the target surface is constructed.
A waste disposal site having a water-impervious structure made by this construction method can also reduce the risk of leakage of leachate.
In addition, although this method can be used only on the concave surface, which is the surface of the concrete body formed by concrete, the concrete body and the water-impervious structure are formed together, so the concrete body is formed. Compared with the above-mentioned construction method that requires the formation of a swollen water-impervious layer after this, it is superior in terms of labor and safety.
In this construction method in which the concrete body and the water-impervious structure are formed together, an integral swollen water-impervious member formed by sandwiching a swollen water-impervious material between the first member and the second member can be used. Both the first member and the second member can be paper, non-woven fabric or woven fabric. The first member and the second member may be made of the same material or different materials. Of the first member and the second member, those not fixed to the mold are preferably made of non-woven fabric or woven fabric. When the first member and the second member that are not fixed to the mold are made of a non-woven fabric or a woven fabric, the placed concrete hardens in a state of entering the non-woven fabric or the woven fabric. This is because the member and the concrete body can be more firmly fixed.
In addition, since the swelling water-impervious member in this case is finally removed from the mold, it is not necessary to fix the entire surface of the first member or the second member to the mold.
In this construction method, a swollen impermeable layer is formed by the swollen impermeable member, and a further impermeable layer can be formed thereon.

  Hereinafter, preferred first and second embodiments of the present invention will be described in detail with reference to the drawings. In the description of both embodiments, the same reference numerals denote the same parts, and redundant explanations are omitted in some cases.

<< First Embodiment >>
In this embodiment, a construction method for constructing a waste disposal site having a water shielding structure by providing a water shielding structure on the concave surface 10 as shown in FIG. 1 will be described. The concave surface 10 is a portion where waste is dumped inside.

The waste disposal site in this embodiment includes a recess 11 made by digging the ground and a retaining wall 12 raised from one end of the recess. In this embodiment, the surface of the recess 11 is covered with concrete. The concave surface 10 described above is formed by the surface of the recess 11 and the surface of the retaining wall 12 connected in series from the surface of the recess 11.
The concave surface 10 may be made only by a concave portion dug down the ground, or may be made by surrounding the entire circumference with a retaining wall.

  In this embodiment, a water shielding structure is constructed on the entire surface of the concave surface 10. That is, in this embodiment, the entire surface of the concave surface 10 is a target surface as referred to in the present invention.

First, the swelling water-impervious member 20 as shown in FIG. In this embodiment, the swelling water-impervious member 20 is about 1 m square. But the magnitude | size and shape of the swelling impermeable member 20 are not this limitation.
The swollen water-impervious member 20 of this embodiment is configured such that a swollen impermeable material 22 is sandwiched between two sheets of paper 21. Although not limited to this, this paper 21 is kraft paper. The paper 21 may be coated with a water repellent material. In addition, the paper 21 in the swelling water-impervious member 20 can also be configured by other members such as a sheet or mat, for example, a nonwoven fabric.
The swollen water-impervious material 22 is formed by filling bentonite, a highly water-absorbent resin, or a swollen rubber powder or granular material between two sheets of paper 21. Although not restricted to this, the swelling water-impervious material 22 of this embodiment is a material in which a bentonite powder or granular material is filled between papers 21.
An adhesive (not shown) is applied to one of the two sheets of paper 21, and a film-like sheet 23 covering the adhesive is attached so as to be easily peeled off. In a state where the sheet 23 is peeled off, the surface of the paper 21 to which the adhesive has been applied is pressed against the concave surface 10 to fix the swelling water-impervious member 20 to the concave surface 10.
A layer formed by the swelling water-impervious material 22 included in each swelling water-impervious member 20 is a swollen impermeable layer according to the present invention.

Next, a water shielding layer is formed so as to cover the entire surface of the swelling water shielding member 20. The water-impervious layer can be formed by spreading a water-impervious sheet and connecting adjacent water-impervious sheets so as to be watertight, but in this embodiment, by solidifying the liquid resin dispersed in layers. A water shielding layer is to be formed.
The impermeable layer prevents leachate from flowing out of the concave surface 10, and in this embodiment, the water permeability coefficient is on the order of 10 ⁻⁹ cm / s or less. In this embodiment, although not necessarily limited to this, a polyware resin is used as the liquid resin. Polyware resins include aromatics (urethane mixed resins, pure polyware resins, modified urea resins, etc.) and aliphatics (modified reinforced urea resins, aliphatics and fatty resins), but they are water-impervious. If it is intended to increase, a fat-type one may be used.
The liquid resin may be sprayed by any method. In this embodiment, the polyware resin, which is a liquid resin, is dispersed by using a known two-component mixed spraying method. The two-component mixing spraying is a technique for spraying the polyware resin by spraying the surface of the swelling water-impervious member 20 such as the surface of the swelling water-impervious member 20 while mixing two types of stock solutions using a gun spray or the like. .
The thickness of the water shielding layer is preferably 0.5 mm or more from the viewpoint of ensuring the water shielding performance, but it is reasonable to set the thickness to 1.5 mm or more in consideration of the current national standards. In this embodiment, the liquid resin is sprayed so that the thickness of the water shielding layer is about 2.0 mm. The thickness of the water shielding layer can be controlled based on the weight of the dispersed liquid resin. In this embodiment, the thickness of the water shielding layer is about 2.0 mm, but this thickness can be appropriately selected within a range up to about 5.0 mm. The thickness of the water shielding layer is set to about 5.0 mm because, if the thickness of the water shielding layer is made thicker than that, the improvement in the water shielding performance is caused by the increase in the amount of the required liquid resin. This is because disadvantages are conspicuous.

When the liquid resin is solidified and the water-impervious layer is completed, the water-impervious structure of the waste disposal site is completed.
FIG. 3 shows an enlarged view of a part of the concave surface 10 of the completed waste disposal site, more specifically, a part of the surface of the retaining wall 12.
In FIG. 3, what is indicated by 30 is a water shielding layer.
In this waste disposal site, when the impermeable layer 30 is damaged, when the leachate reaches the swollen impermeable material 22 inside the swollen impermeable member 20 from the damaged portion of the impermeable layer 30, the swollen and impermeable layer 30 The water material 22 swells and exhibits a water shielding function. Accordingly, the leachate is unlikely to leak from the concave surface 10 to the outside.
Further, when the swollen impermeable material 22 swells, the water impervious layer 30 in this waste disposal site has a position where the swollen impermeable material 22 swells from the front side of the impermeable layer 30, for example, management of the waste disposal site. It has the flexibility which the position where the swelling water-impervious material 22 swells to such an extent that a person can find it visually. When the manager of the waste disposal site finds a bulge generated on the surface of the impermeable layer 30 based on the swelling of the swelling impermeable material 22, appropriate treatment such as repair of the impermeable layer 30 is performed on the site. Just do it. In addition, in order to give the above-described degree of flexibility to the water-impervious layer 30, the liquid resin sprayed for forming the water-impervious layer 30 in the present embodiment is the degree that the water-impervious layer 30 described above even after solidification. It has flexibility.

<< Second Embodiment >>
In the second embodiment, a waste disposal site is constructed as follows.
As in the case of the first embodiment, the waste disposal site according to the second embodiment includes a recess made by digging down the ground and a concrete retaining wall raised from one end of the recess. The point which the surface of the recessed part 11 of 2nd Embodiment is covered with concrete is the same as that of 1st Embodiment. The concave surface similar to the case of the first embodiment is formed by the surface of the concave portion and the surface of the retaining wall continuously connected from the surface of the concave portion. The waste disposal site of the second embodiment also has a water shielding structure as in the case of the first embodiment, and the water shielding structure of the concave portion of the concave surface is the same construction method as in the first embodiment. It is built with.
However, the water-impervious structure of the retaining wall portion of the second embodiment is not created after the retaining wall is constructed as in the case of the first embodiment. Made. The water-impervious structure in the second embodiment includes a swollen water-impervious layer and a water-impervious layer as in the case of the first embodiment. Of these, the swollen impermeable layer is a retaining wall in this embodiment. Made at the same time.

Since the water-impervious structure of the concave portion is made by the same construction method as in the first embodiment, the description of the construction method is omitted. Hereinafter, a method for making a retaining wall having a water-impervious structure will be described.
In constructing a retaining wall having a swollen impermeable layer, first, a mold 40 corresponding to the shape of the retaining wall is formed (FIG. 4A). The mold 40 is made by connecting a plurality of mold members 41.
Next, on the inner side of the part corresponding to the part of the concave surface of the retaining wall constructed later (the right side of the mold 40 in FIG. 4), the entire surface of the form 40 is formed. The swelling water-impervious member 20 is attached so as to cover (FIG. 4B). In this embodiment, the swelling water-impervious member 20 has a size of about 1 m square. But the magnitude | size and shape of the swelling impermeable member 20 are not this limitation.
As shown in FIG. 5, the swollen water-impervious member 20 of this embodiment is configured such that a swollen impermeable material 22 is sandwiched between two nonwoven fabrics 24. It should be noted that at least one of the two nonwoven fabrics 24 in the swelling water-impervious member 20 can be composed of other sheet-like or mat-like members, for example, woven fabric or paper.
As in the case of the first embodiment, the swollen water-impervious material 22 is formed by filling bentonite, a highly water-absorbent resin, a swollen rubber powder or granular material between two nonwoven fabrics 24. Although not restricted to this, the swelling water-impervious material 22 of the second embodiment is one in which a bentonite powder or granular material is filled between the nonwoven fabrics 24.
The swelling water-impervious member 20 may be attached to the mold 40 in any way, but in this embodiment, an adhesive is spot-applied to an appropriate place on one surface of the swollen impermeable member 20. The swollen impermeable member 20 is fixed to the mold 40 by pressing the surface of the swollen impermeable member 20 on which the adhesive is applied to the mold 40. The reason why the adhesive is not applied to the entire surface of one surface of the swollen water-impervious member 20 is that when the mold 40 to which the swollen impermeable member 20 is fixed later is removed, the mold 40 is removed from the swollen impermeable member 20. This is so that it can be easily removed.

Next, in this state, concrete 50 is placed between the molds 40 (FIG. 4C). And the concrete 50 is hardened as it is. The hardened concrete 50 becomes a retaining wall.
Next, when the concrete 50 is hardened, the mold 40 is removed (FIG. 4D). The concrete 50 placed between the molds 40 is hardened in a state where a part of the nonwoven fabric 24 constituting the swelling water-impervious member 20 enters the concrete 50 side. Is firmly fixed to the concrete 50. On the other hand, since the surface of the swelling water-impervious member 20 on the mold 40 side is only spot-fixed to the mold 40, the mold 40 can be easily removed.

Finally, a water shielding layer is formed so as to cover the entire surface of the swelling water shielding member 20 (FIG. 4E). The water-impervious layer 30 can be formed by spreading a water-impervious sheet and connecting adjacent water-impervious sheets so as to be water-tight, and, as in the case of the first embodiment, a liquid dispersed in a layered manner. You may form by solidifying resin. In the second embodiment, the latter is selected.
As described above, the retaining wall having the water shielding structure of the waste disposal site of the second embodiment is completed.
Even in the waste disposal site of the second embodiment, as in the case of the first embodiment, as a result of the breakage of the water shielding layer 30, leachate from the damaged portion of the water shielding layer 30 of the swelling water shielding member 20. When the internal swelling water shielding material 22 is reached, the swelling water shielding material 22 swells and exhibits a water shielding function. The same applies to the water shielding layer 30 formed on the surface of the retaining wall.

The sectional side view which shows an example of the concave surface where the waste disposal site of 1st Embodiment of this invention is constructed | assembled. The perspective view which shows the structure of the swelling water-impervious member used in the waste disposal site of 1st Embodiment. Sectional drawing of a part of waste disposal site of 1st Embodiment completed. The sectional side view which shows roughly the implementation procedure of the construction method for constructing the retaining wall of the waste disposal site of 2nd Embodiment of this invention. The perspective view which shows the structure of the swelling water-impervious member used in the waste disposal site of 2nd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Concave surface 20 Swelling water-impervious member 21 Paper 22 Swelling water-impervious material 23 Sheet 30 Water-impervious layer 40 Formwork 50 Concrete

Claims (10)

A concave surface for dumping waste,
It is formed so as to be a layer of a predetermined thickness on the concave surface with a powdery body or a granular body, and when the layer is impregnated with water, it swells and exhibits a water shielding function. A swollen impermeable layer,
A water shielding layer having a water shielding function formed on the swelling water shielding layer;
With
The water-impervious layer can be visually found that when the swollen impermeable layer swells, the position corresponding to the swollen impermeable layer is swollen,
Waste disposal site. A wastewater shielding structure for a waste disposal site formed on a target surface that is an arbitrary range of concave surfaces for dumping waste,
It is formed so as to be a layer of a predetermined thickness on the concave surface with a powdery body or a granular body, and when the layer is impregnated with water, it swells and exhibits a water shielding function. A swollen impermeable layer,
A water shielding layer having a water shielding function formed on the swelling water shielding layer;
With
The water-impervious layer can be visually found that when the swollen impermeable layer swells, the position corresponding to the swollen impermeable layer is swollen,
Impermeable structure. The swelling water-insulating layer is formed of bentonite, highly water-absorbing resin or swelling rubber,
The water shielding structure according to claim 2. The water shielding layer is a solidified liquid resin sprayed on the surface of the swelling water shielding layer.
The water shielding structure according to claim 2. A construction method for constructing a waste disposal site having a water-impervious structure on a target surface that is an arbitrary range of concave surfaces for dumping waste,
Constructing a concave surface for dumping waste,
Of the concave surface, the object surface, the gap between the planar first member and the second member, a powdery body or a granular body that swells when water is impregnated and exhibits a water shielding function Laying a swelling water-impervious member arranged in a layered form of a predetermined thickness,
Forming a water shielding layer having a water shielding function on the swelling water shielding member;
Is,
The water shield layer, when the swelling water-impervious member is swelled, the swelling water-impervious member shall be the ones that can be found visually that the swelled position corresponding to the swollen,
Construction method. Fixing the entire surface of one side of the first member and the second member to the target surface;
The construction method according to claim 5. A swelling water-impervious member used in the construction method according to claim 6,
The first member and the second member are paper, and adhesive is applied to the entire surface of those fixed to the target surface,
A sheet-like cover material that can be easily removed is provided on the surface of the first member or the second member to which the adhesive has been applied.
Swelled water-impervious member. A waste disposal site having a water-impervious structure on a target surface, which is an arbitrary range of concave surfaces for dumping waste, wherein the target surface is the surface of a concrete body made by placing concrete It is a construction method for building
Of the formwork for placing the concrete for constructing the concrete body, when the placed concrete is hardened, a portion corresponding to the target surface is provided with a planar first member and a second member. In the gap between them, fix a swelling water-impervious member formed by arranging a powdery or granular material that swells when it is impregnated with water to exert a water-shielding function, or a granular material in a layered shape of a predetermined thickness. ,
In that state, cast concrete.
By removing the formwork after concrete hardening,
Construct a concrete body with a swelling impermeable member fixed on the target surface,
Forming a water-impervious layer on the surface of the swelling water-impervious member fixed to the target surface of the concrete body;
Is,
The water shield layer, when the swelling water-impervious member is swelled, the swelling water-impervious member shall be the ones that can be found visually that the swelled position corresponding to the swollen,
Construction method. The first member and the second member are nonwoven fabric or woven fabric,
The construction method according to claim 8. The water-impervious layer is configured such that, when the swollen impermeable layer swells, an administrator of the waste disposal site can visually detect that the swollen position of the swollen impermeable layer is swollen.
The waste disposal site according to claim 1.

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