JP6695562B1 - Impermeable side wall structure, bottom slab / side wall structure and impermeable side wall construction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water-impervious side wall structure, a bottom slab / side wall structure, and a water-impervious side wall construction method, which are superior in terms of water impermeability and strength, etc., while easily forming high-quality holding concrete. SOLUTION: The impermeable side wall structure includes a side wall skeleton 7, a side wall impermeable work layer 15 inside the side wall skeleton body 7, a side wall holding concrete 9 for protecting it, and a plurality of side wall holding concrete 9 in a lateral direction so as to cover the side wall holding concrete 9. A plurality of deck plates 17 arranged in rows and H-shaped steel columns 18 arranged between adjacent rows of the deck plates 17 are provided. One flange portion 20 of each H-shaped steel column 18 is embedded inside the side wall holding concrete 9, and the inner surface of the other flange portion 21 is on the surface opposite to the side wall impermeable construction layer 15 of the corresponding deck plate 17. Abutting. The side wall impermeable layer 15 has an FRP waterproof layer on the side of the side wall skeleton, and a water impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the holding concrete 9. [Selection diagram] Figure 1

Description

  The present invention relates to a water-impervious side wall structure, a bottom slab / side wall structure and a water-impervious side wall construction method suitable for constructing a final disposal site for landfilling waste.

  At the final disposal site for landfilling waste, it is necessary to take measures to prevent the leachate generated from the landfilled waste from leaking to the outside. As such measures, conventionally, a water barrier structure including a water barrier and an FRP waterproof layer is provided on the wall surface of a landfill section constructed of concrete (see, for example, Patent Document 1). .. The water-blocking work is configured by laminating a water-blocking sheet and a protective mat that protects the sheet, for example.

  In the method of constructing a water-impervious side wall structure disclosed in Patent Document 1, first, an outer RC wall of the side wall is formed, and an inner side wall impervious structure divided vertically by a predetermined dimension is formed inside the lowermost part thereof. The lowest part of the divided parts of the body is adhered, and concrete is placed on the part except the upper edge of the divided part. As a result, the lowermost part of the inner RC wall (holding concrete) of the side wall is formed. Then, the remaining portion above the bottom is formed.

  When forming the remaining part, the part adjacent to the upper part of the already formed lower part is bonded to the outer RC wall, and the upper edge of the lower part and the upper part The lower edge is welded and the upper divided portion is added. Then, with respect to the added divided portion, concrete is poured while leaving the upper edge of the divided portion, and the portion of the inner RC wall corresponding to the added divided portion is the lower inner RC wall portion. It is formed integrally.

  The water-impervious side wall structure is constructed by repeating the process for each divided portion until the inner RC wall reaches the height of the outer RC wall.

JP, 2017-104837, A

  However, according to the construction method of Patent Document 1, a plywood or steel plate face material fixed at two upper and lower points is used as the formwork when placing the pressing concrete in each divided step. In order to resist the lateral pressure applied to the face material and ensure the flatness, an excessively stiffening material and a process for mounting and removing the material are required. On the other hand, in order to avoid this, if the side pressure is not increased during compaction at the time of pouring concrete, a defective portion may occur due to insufficient compaction.

  In addition, the in-side-wall water-impervious structure includes an FRP waterproof layer provided on the inner surface of the outer RC wall, and an impermeable work layer provided between the FRP waterproof layer and the inner RC wall. Considering the strength and seismic performance, it is considered that there is room to adopt a material with excellent water impermeability in relation to the holding concrete.

  In view of the problems of the prior art, an object of the present invention is to easily form a high-quality holding concrete, and to provide a water-impervious side wall structure, a bottom slab / side wall structure, and an impervious water barrier that are more excellent in terms of water impermeability and strength. It is to provide a sidewall construction method.

The water-impervious side wall structure of the present invention is
A sidewall impermeable sidewall structure comprising: a sidewall skeleton, a sidewall impervious layer formed on an inner surface of the sidewall skeleton, and a holding concrete that protects the sidewall impervious layer,
A plurality of deck plates arranged in a plurality of rows in the left-right direction so as to cover the side opposite to the side wall impermeable work layer of the holding concrete;
An H-shaped steel column arranged between each adjacent row of the deck plates,
One flange portion of each H-shaped steel column is embedded inside the holding concrete, and the inner surface of the other flange portion is the side wall impermeable work layer at the corresponding one edge portion in the left-right direction of the deck plate. It is in contact with the opposite surface,
The sidewall impervious layer has an FRP waterproof layer on the side of the sidewall skeleton, and an impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the holding concrete. To do.

  According to the present invention, a side wall water blocking layer is formed on the inner surface of the side wall skeleton, a plurality of H-shaped steel columns are erected along the side wall skeleton, and a deck plate is arranged between each adjacent H-shaped steel columns, By placing concrete between the side wall impermeable construction layer and the deck plate, the impermeable side wall structure can be easily formed as one having high-quality holding concrete.

  Further, since the side wall frame, the FRP waterproof layer, the side wall water blocking layer, and the holding concrete are arranged in this order, and the holding concrete is inserted between the corrugated grooves of the deck plate, the water blocking side wall structure It is possible to improve the water impermeability, strength, etc.

The bottom slab / side wall structure of the present invention is
A bottom slab / side wall structure that constitutes a side wall and a side wall of a waste disposal site with a water barrier,
A lower RC portion that is a lower reinforced concrete portion of the bottom slab and a first portion that integrally configures a side wall skeleton that is a reinforced concrete portion outside the side wall;
A second part integrally forming an upper RC part which is a reinforced concrete part on the upper side of the bottom plate and a holding concrete on the inner side of the side wall;
A bottom slab impervious layer provided between the lower RC portion and the upper RC portion,
A side wall impermeable work layer provided between the side wall skeleton and the holding concrete,
On the surface of the holding concrete opposite to the side wall impermeable construction layer, a plurality of deck plates forming a plurality of rows in the left-right direction are arranged so as to cover the surface,
H-shaped steel columns are arranged between adjacent rows of the deck plate,
One flange portion of each H-shaped steel column is embedded inside the holding concrete, and the inner surface of the other flange portion corresponds to the side wall impermeable work layer at one end of the corresponding deck plate in the left-right direction. It is in contact with the opposite surface,
The bottom plate water-blocking layer has an FRP waterproof layer on the lower RC portion side, and a water-blocking layer formed of a liquid water-blocking material between the FRP waterproof layer and the upper RC layer,
The sidewall impervious layer has an FRP waterproof layer on the side of the sidewall skeleton, and an impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the holding concrete. To do.

  According to the present invention, a side wall water blocking layer is formed on the inner surface of the side wall skeleton, a plurality of H-shaped steel columns are erected along the side wall skeleton, and a deck plate is arranged between each adjacent H-shaped steel columns, By placing concrete between the side wall water blocking layer and the deck plate, the side wall structure of the bottom slab / side wall structure can be easily formed as one having high-quality holding concrete.

  Further, since the side wall frame, the FRP waterproof layer, the side wall water blocking layer, and the holding concrete are arranged in this order, and the holding concrete enters between the corrugated grooves of the deck plate, the water blocking side wall structure It is possible to improve the water impermeability, strength, and the like.

  In the present invention, the FRP waterproof layer is preferably provided by a one-ply or two-ply construction method. According to this, the FRP waterproof layer can be simply and effectively applied.

  In the present invention, it is preferable that the water-impermeable layer has a thickness of 3 mm or more, and that the liquid impermeable material contains polyurea, polyurethane, or rubber asphalt. According to this, since the relatively flexible water-impervious layer is interposed between the hard side wall skeleton and the FRP waterproof layer on both sides and the holding concrete, it is possible to improve the water impermeability of the side wall structure and the resistance to an earthquake or the like. it can. The same applies to the slab structure.

  In the present invention, it is preferable to have a protective elastic layer between the water-impervious layer and the pressing concrete. According to this, the impermeable layer can be effectively protected from the holding concrete.

  In the present invention, lower end portions of the plurality of H-shaped steel columns are respectively supported by fixing plates embedded in the second portion and fixed with root winding concrete, and upper end portions thereof are fixed to the side wall frame body. Is preferred.

  According to this, the lower end portion and the upper end portion of the H-shaped steel column are securely fixed and supported by the side wall frame body and the upper side RC portion and the lower side RC portion, and between the side wall water blocking work layer and the deck plate. The concrete can be placed without any trouble.

  In the present invention, it is preferable that one flange portion of the H-shaped steel column is provided with a shear connector projecting into the holding concrete from a surface of the H-shaped steel column on the side of the side wall impermeable construction layer. According to this, the connection between the holding concrete and the H-shaped steel column can be strengthened.

The method of constructing a water-impervious sidewall of the present invention is
A method of constructing a water-impervious side wall comprising a side wall skeleton, a side wall impermeable work layer provided inside the side wall skeleton, and a holding concrete that protects the side wall impermeable work layer,
Inside the side wall structure, a water blocking layer construction step of constructing the sidewall water blocking layer,
A plurality of H-shaped steel columns along the side-wall skeleton at positions separated by a predetermined distance from the side-wall skeleton, and H-shaped steel column standing steps of erected at a predetermined interval in a posture in which the flange surface is along the side-wall skeleton;
A reinforcing step for reinforcing the presser concrete,
One deck plate having a predetermined vertical dimension and a horizontal dimension corresponding to the predetermined interval is provided between the adjacent H-shaped steel columns, and the side wall shields on the left and right edge portions of the deck plate are provided. A deck plate arranging step of arranging so that the surface on the side opposite to the hydraulic layer contacts the inner surface of the flange portion on the side opposite to the side wall impermeable layer of the H-shaped steel column;
The deck plate of the holding concrete by placing concrete between the side wall water blocking layer installed in the water blocking layer construction step and the deck plate arranged in the deck plate arranging step. And a pressing portion forming step of forming a portion corresponding to
After performing the water impermeable layer construction step, the H-shaped steel column erection step, and the reinforcement step, the deck plate arrangement is performed from the lower portion of the side wall skeleton until the holding concrete is formed at a predetermined height. The step and the step of forming the pressing portion are repeated.

  According to the present invention, since the pressing concrete is formed to a predetermined height by repeating the deck plate arranging step and the pressing portion forming step, excessive stiffening material or It is not necessary to install and remove it, and the concrete to be placed can be compacted without worrying about the increase in lateral pressure. Therefore, the water-impervious side wall structure of the present invention can be easily constructed.

It is a sectional view of the bottom slab and side wall structure of the final disposal site concerning one embodiment of the present invention. It is the II-II sectional view taken on the line of FIG. 1, and has shown a part of side wall structure. FIG. 2 is a bar arrangement diagram of a root-wrapping concrete portion that fixes a base end portion of an H-shaped steel column of the bottom slab / side wall structure of FIG. 1. FIG. 4 is a plan view showing a fixing plate that is embedded in the root-wound concrete portion of FIG. 3 and supports a lower end of an H-shaped steel column. It is sectional drawing of the upper end part of the side wall structure in the bottom slab / side wall structure of FIG. It is sectional drawing which shows a mode seen from the upper side when fixing the upper end part of an H-shaped steel column to a side wall structure. It is a figure which shows a mode that a deck plate is arrange | positioned between H type steel columns in the corner | angular part of the bottom slab / side wall structure of FIG. It is a flowchart which shows the procedure of constructing the bottom slab / side wall structure of FIG. It is a flowchart which shows the construction procedure of the bottom plate impermeable construction layer and the side wall impermeable construction layer in the flowchart of FIG.

  Embodiments of the present invention will be described below with reference to the drawings. As shown in FIG. 1, the bottom slab / side wall structure 1 of the embodiment is a bottom slab 2 that is impermeable to water and a side wall (impermeable side wall) as a water impermeable side wall structure at the final disposal site of waste. 3 and 3.

  The bottom slab / side wall structure 1 includes a first portion 4 and a second portion 5. The first portion 4 integrally configures a lower RC portion 6 which is a lower reinforced concrete portion of the bottom slab 2 and a side wall skeleton 7 which is an outer reinforced concrete portion of the side wall 3. The second portion 5 integrally configures an upper RC portion 8 which is an upper reinforced concrete portion of the bottom slab 2 and a side wall holding concrete 9 inside the side wall 3.

  The lower RC portion 6 is provided on the foundation concrete 11 cast on the ground improvement layer 10. A concave groove 12 closed by the lower surface of the lower RC portion 6 is formed at an appropriate position between the lower RC portion 6 and the base concrete 11. A perforated pipe 13 for collecting water is buried in the groove 12 by using single-grain crushed stone. The perforated pipe 13 is used for discharging and detecting leachate or the like from the wastes input to the final disposal site.

  Between the lower RC portion 6 and the upper RC portion 8 of the bottom slab 2, a bottom slab impermeable layer 14 is provided. A side wall impermeable layer 15 is provided between the side wall body 7 of the side wall 3 and the side wall pressing concrete 9 inside thereof. The bottom plate impermeable work layer 14 and the side wall impermeable work layer 15 are constructed by the procedure shown in FIG. 9 described later.

  The upper RC portion 8 and the side wall retaining concrete 9 function as retaining concrete for protecting the bottom slab impermeable construction layer 14 and the side wall impermeable construction layer 15, respectively. A soft FRP waterproof 16 is applied to the outer surface of the side wall body 7. A vinyl ester color top is applied on the FRP waterproof 16.

  As shown in FIGS. 1 and 2, on the surface of the side wall pressing concrete 9 opposite to the side wall water blocking layer 15, a plurality of deck plates 17 are arranged in a plurality of rows in the left-right direction so as to cover the surface. To be done. As the deck plate 17, for example, a galvanized U-shaped deck having a thickness of 2.3 mm can be used.

  An H-shaped steel column 18 is arranged between adjacent rows of the deck plate 17. As the H-shaped steel column 18, for example, one having a dimension of H-200 × 200 × 8 × 12 and subjected to hot dip galvanization can be used. In the side wall holding concrete 9, for example, a wall reinforcing bar 19 of D13- @ 200W coated with epoxy resin is arranged. The intersecting portions of the wall reinforcing bar arrangements 19 are bound by a galvanized binding wire. The side wall holding concrete 9 is formed by pouring fiber reinforced concrete at a height of 1000 mm.

  The size of one deck plate 17 in the vertical and horizontal directions (vertical and horizontal directions) is set to about 1000 × 1500 mm in accordance with the arrangement interval of the H-shaped steel columns 18 and the placing height of the side wall holding concrete 9. It is also possible to use two deck plates each having a shorter vertical dimension, partly overlap each other so that the vertical dimension is about 1000 mm, and construct the deck plate 17 for one sheet by the two sheets.

  One flange portion 20 of each H-shaped steel column 18 is embedded inside the sidewall pressing concrete 9, and the inner surface of the other flange portion 21 has sidewall water impermeability at one end of the corresponding deck plate 17 in the left-right direction. It is in contact with the surface opposite to the work layer 15.

  The lower end of each H-shaped steel column 18 is supported by a fixing plate 22 as shown in FIG. 4 which is embedded in the second portion 5 as shown in FIGS. On the other hand, as shown in FIGS. 5 and 6, the upper end of each H-shaped steel column 18 is attached to the side wall structure 7 via a gusset plate 25 having a reinforcing plate 24 embedded in the side wall holding concrete 9 and a base plate 26. Fixed.

  A shear connector 27 is provided on one of the flanges 20 of the H-shaped steel column 18 so as to project into the side wall holding concrete 9 from the side surface of the side wall impermeable construction layer 15.

  In the corner portion of the side wall pressing concrete 9, as shown in FIG. 7, two chevron steels 28 are formed on the outer surface of the other flange portion 21 of the corner H-shaped steel column 18 so as to form a U-shape when viewed in cross section. Fixed. As a result, even at the corners, the adjacent deck plates 17 can be supported at a right angle without any trouble.

  As shown in FIG. 5, the upper end of the side wall 3 is higher than the upper end of the H-shaped steel column 18. The raised portion 29 projects from the side wall pressing concrete 9 on the upper end surface of the H-shaped steel column 18 so as to be substantially flush with the outer surface of the other flange portion 21 of the H-shaped steel column 18. Further, in the raised portion 29, reinforcing bars 30 are provided from the side wall frame 7 to the side wall holding concrete 9.

  A roof structure 31 and a catwalk 32 at the final disposal site are provided on the upper end surface of the side wall 3 composed of the side wall frame 7 and the side wall pressing concrete 9.

  A permeable water repellent layer 37 is provided from the entire upper surface of the upper RC portion 8 of the bottom slab 2 to the side surface of the root-wrapping concrete 23 and the exposed portion of the upper surface. Bentonite mixed soil 33 having a thickness of about 300 mm is spread on the permeable water repellent layer 37 to ensure a higher degree of water impermeability against leachate. On the bentonite mixed soil 33, dust-crushed crushed stone 34 mixed with powdered crushed stone is spread with a thickness of about 200 mm.

  The slab / sidewall structure 1 can be constructed according to the procedure shown in the flowchart of FIG. 8. That is, first, in step S1, the lower RC portion 6 of the bottom slab 2 and the side wall frame 7 of the side wall 3 are integrally formed of reinforced concrete.

  Next, in step S2, the bottom slab impervious layer 14 is provided on the upper side of the lower RC portion 6 according to the procedure of FIG. 9 described later. Next, in step S3, the side wall impermeable construction layer 15 is provided inside the side wall skeleton 7 according to the procedure of FIG.

  Next, in step S4, a plurality of H-shaped steel columns 18 are formed along the side wall skeleton 7 at positions separated from the side wall skeleton 7 by a predetermined distance in consideration of the thickness of the side wall pressing concrete 9, and the flange surfaces thereof are the side wall skeletons 7. Along the vertical posture, standings are performed at a predetermined interval D, for example, at intervals of 1500 mm (H-shaped steel column standing step).

  As shown in FIG. 3 and FIG. 4, this upright supports the base end portion of the H-shaped steel column 18 with the fixing plate 22 on the lower RC portion 6, and the upper end portion of the H-shaped steel column 18 as shown in FIG. As described above, it is performed by fixing to the side wall body 7.

  Next, in step S5, the upper RC portion 8 and the side wall pressing concrete 9 are reinforced (reinforcement process). The reinforcements include reinforcements of a portion of the root-wrapping concrete 23 as shown in FIG. 3 and reinforcements of the beam portion 36 including the reinforcement. Then, this bar arrangement is suitable for integrally forming the upper RC portion 8 and the side wall holding concrete 9. In addition, as shown in FIG. 5, the reinforcements of the side wall pressing concrete 9 and the side wall skeleton 7 at the upper end portion 29 straddle both upper end portions so that the upper end portions can be firmly coupled. Be seen.

  Next, in step S6, the deck plates 17 having the above-described vertical and horizontal dimensions are arranged one by one between the adjacent H-shaped steel columns 18 (deck plate arrangement step). At this time, if step S6 is the first time, the deck plates 17 are arranged one by one at the bottom of each of the H-shaped steel columns 18. After the first time, the deck plate 17 is arranged on the previously arranged deck plate 17.

  At this time, the arrangement of each deck plate 17 is such that the surfaces of the left and right edge portions of the deck plate 17 opposite to the side wall impermeable construction layer 15 are flange portions of the H-shaped steel columns 18 opposite to the wall impermeable construction layer 15. It is performed so as to contact the inner surface of 21 (see FIG. 7).

  In order to arrange in this way, as shown in FIG. 2, the resin is provided between the inner surface of the flange portion 20 of the H-shaped steel column 18 on the wall impermeable construction layer 15 side and the surface of the deck plate 17 facing this. A manufactured camber 35 is arranged. That is, the deck plate 17 is fixed to the H-shaped steel column 18 by the resin camber 35.

  Next, in step S7, concrete is placed between the wall water-blocking layer 15 and the deck plate 17 arranged in step S6 (holding portion forming step).

  When step S7 is the first time, at the same time as this step, concrete is also placed on the reinforcement portion of the beam portion 36 and on the bottom slab impermeable construction layer 14. As a result, the upper RC portion 8 of the bottom slab 2 and the lowermost portion of the side wall pressing concrete 9 of the side wall 3 are formed. The beam portion 36 is included in this portion.

  The above steps S6 and S7 are repeated until the side wall pressing concrete 9 which is formed stepwise upward by repeating these steps reaches the height of the side wall skeleton 7 in step S8. Done.

  When it is determined in step 8 that the height of the side wall skeleton 7 has almost been reached, in step S9, the upper end portion 29 of the side wall pressing concrete 9 is formed by pouring concrete to construct the bottom slab / side wall structure 1. Is completed.

  The reason why the side wall pressing concrete 9 is formed by placing the fiber reinforced concrete every 1000 mm as described above is as follows. That is, after the strength of the cast concrete on the lower side is developed and the fixing strength of the H-shaped steel column 18 against this is ensured, by placing the concrete on the upper side, the (horizontal direction of the H-shaped steel column 18 is The amount of deflection can be kept to a minimum. Then, by repeating this, it is possible to suppress the entrapment of the side wall holding concrete 9 as a whole.

  The reason for using the deck plate 17 is as follows. That is, the fiber reinforced concrete cast in situ and the deck plate 17 are not completely integrated. This has an effect that hair cracks of cast-in-place concrete do not affect the surface layer. As a result, the difference in behavior (temperature change, seismic force, etc.) of each layer of the side wall frame 7, the side wall impermeable layer 15, the cast-in-place concrete (side wall holding concrete 9), and the deck plate 17 is absorbed to some extent between the layers, and the side wall is absorbed. The risk of structural damage can be reduced. Further, when the deck plate 17 is damaged, the minimum unit (for example, about 1.5 m × 1.0 m) can be replaced or repaired.

  FIG. 9 shows a procedure for applying the bottom slab impervious layer 14 formed in step S2 and the sidewall impermeable layer 15 formed in step S3 of FIG. That is, first, the surface of the RC skeleton (the lower RC portion 6, the side wall skeleton 7) is subjected to polishing / graining treatment (step S21). This process is performed for the purpose of ensuring the adhesive strength of FRP waterproofing described later.

Next, a primer treatment is performed on the surface that has been subjected to the polishing and roughening treatment (step S22). As the primer, for example, one containing RP primer, RP primer additive, and RP primer cement (0.2 kg / m ² or more) is used. As the RP primer, a one-component moisture-curing urethane resin-based primer is used. As the RP primer additive, an adhesive force retention additive is used. As the cement for RP primer, a cement exclusively for RP primer is used. It is preferable to use a urethane resin-based primer.

Next, FRP waterproofing (FRP waterproofing layer) is applied (step S23). The FRP waterproofing construction may be performed by any one of a single-ply construction method and a double-ply construction method. In the case of single layer (1 ply construction method), 0.4 kg / m ² of RP # 1500 (corrosion-resistant vinyl ester resin), 1.07 m / m ² of glass mat # 450 (chopped strand mat), and 1.6 kg / m ² RP # 1500 (corrosion resistant vinyl ester resin) is applied in this order.

In the case of double (2 ply construction method), 0.4 kg / m ² of RP # 1500 (corrosion resistant vinyl ester resin), 1.07 m / m ² of glass mat # 380 (chopped strand mat), 1.4 kg / M ² of RP # 1500 (corrosion resistant vinyl ester resin), 1.07 m / m ² of glass mat # 380 (chopped strand mat), and 1.4 kg / m ² of RP # 1500 (corrosion resistant vinyl ester resin). Build in order.

  Next, surface treatment of FRP waterproofing is performed (step S24). That is, sanding polishing and acetone wipe cleaning are performed for the purpose of deburring and smoothing.

Next, a top coat process for protecting the FRP waterproofing is performed (step S25). For this treatment, 0.4 kg / m ² of RP color (corrosion resistant vinyl ester resin / colored gray and resin containing paraffin wax) is used. The color can be transparent or colored. In the case of the bottom slab impermeable layer 14, a cement-based noncombustible material is further sprayed.

  Next, a surface treatment is performed for the purpose of securing the adhesive force (step S26). Sanding polishing and acetone wipe cleaning are used for this treatment.

Next, a primer treatment on the FRP surface is performed (step S27). For this treatment, 0.15 kg / m ² of interlayer primer J (two-component reaction-curable urethane resin-based intermediary primer) is used.

Next, the liquid impermeable material is sprayed so as to have a thickness of 3 mm or more to provide an impermeable layer (step S28). As the liquid water-blocking material, for example, polyurea-based resin, polyurethane-based or rubber asphalt-based resin can be used. For example, as the polyurea resin, it is possible to use 2.0 kg / m ² of PM-5000 (two-component ultra-fast curing type polyurea resin waterproof material JIS-A-6021 urethane rubber high strength type).

  Next, a protective elastic paint is applied to form a protective elastic layer (step S29). That is, a waterproof epoxy cross-linked moisture-permeable emulsion filler (for example, DAN filler EPO (trade name) manufactured by Nippon Paint Co., Ltd.) is applied to a thickness of 2 mm or more, or an ultra-high weather resistance ultra-low contamination aqueous two-component inorganic material. A paint (for example, Applaud Chesterer II (trade name) manufactured by Nippon Paint Co., Ltd.) is applied to a thickness of 2 mm or more.

  When it is determined in step 30 that the bottom slab impermeable construction layer 14 is to be constructed, two protective mats having a thickness of 20 mm are further laid (step S31). As a result, the construction of the bottom slab impermeable work layer 14 or the side wall impermeable work layer 15 is completed.

  Although the embodiment of the present invention has been described above, the present invention is not limited to this. For example, steps S3 to S5 in FIG. 8 may be performed by changing the order. In addition, the present invention provides a waste material other than mercury-containing waste, such as radioactive waste, as long as it is a disposal site for waste materials such as mercury-containing waste that requires a high level of waterproofing / water-shielding and strong landfill areas. It can be preferably applied to the disposal site of. Further, not only the final disposal of waste, but also the disposal of radioactive waste can be applied to the intermediate disposal site.

  DESCRIPTION OF SYMBOLS 1 ... Bottom plate / side wall structure, 2 ... Bottom plate, 3 ... Side wall, 4 ... First part, 5 ... Second part, 6 ... Lower RC part, 7 ... Side wall frame, 8 ... Upper RC part, 9 ... Side wall presser Concrete, 10 ... Ground improvement layer, 11 ... Base concrete, 12 ... Recessed groove, 13 ... Perforated pipe, 14 ... Bottom slab impervious layer, 15 ... Sidewall impervious layer, 16 ... FRP waterproof, 17 ... Deck plate, 18 ... H-shaped steel column, 19 ... Wall reinforcing bar arrangement, 20 ... Flange portion, 21 ... Flange portion, 22 ... Anchoring plate, 23 ... Negori concrete, 24 ... Reinforcing plate, 25 ... Gusset plate, 26 ... Base plate, 27 ... Shear connector, 28 ... Angle steel, 29 ... Elevated part, 30 ... Reinforcing bar, 31 ... Roof structure, 32 ... Catwalk, 33 ... Bentonite mixed soil, 34 ... Dust mixed crushed stone, 35 ... Resin camber, 36 ... Beam part, 37 ... Permeable water repellent layer.

Claims (8)

A sidewall impermeable sidewall structure comprising: a sidewall skeleton, a sidewall impervious layer formed on an inner surface of the sidewall skeleton, and a holding concrete that protects the sidewall impervious layer,
A plurality of deck plates arranged in a plurality of rows in the left-right direction so as to cover the side opposite to the side wall impermeable work layer of the holding concrete;
An H-shaped steel column arranged between each adjacent row of the deck plates,
One flange portion of each H-shaped steel column is embedded inside the holding concrete, and the inner surface of the other flange portion is the side wall impermeable work layer at the corresponding one edge portion in the left-right direction of the deck plate. It is in contact with the opposite surface,
The sidewall impervious layer has an FRP waterproof layer on the side of the sidewall skeleton, and an impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the holding concrete. Impermeable side wall structure. A bottom slab / side wall structure that constitutes a side wall and a side wall of a waste disposal site with a water barrier,
A lower RC portion that is a lower reinforced concrete portion of the bottom slab and a first portion that integrally configures a side wall skeleton that is a reinforced concrete portion outside the side wall;
A second part integrally forming an upper RC part which is a reinforced concrete part on the upper side of the bottom plate and a holding concrete on the inner side of the side wall;
A bottom slab impervious layer provided between the lower RC portion and the upper RC portion,
A side wall impermeable work layer provided between the side wall skeleton and the holding concrete,
On the surface of the holding concrete opposite to the side wall impermeable construction layer, a plurality of deck plates forming a plurality of rows in the left-right direction are arranged so as to cover the surface,
H-shaped steel columns are arranged between adjacent rows of the deck plate,
One flange portion of each H-shaped steel column is embedded inside the holding concrete, and the inner surface of the other flange portion is the side wall impermeable work layer at the corresponding one edge portion in the left-right direction of the deck plate. It is in contact with the opposite surface,
The bottom slab impervious layer has an FRP waterproof layer on the lower RC portion side, and includes an impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the upper RC layer,
The sidewall impervious layer has an FRP waterproof layer on the side of the sidewall skeleton, and an impermeable layer formed of a liquid impermeable material between the FRP waterproof layer and the holding concrete. Bottom plate / side wall structure that does.   The structure according to claim 1 or 2, wherein the FRP waterproof layer is provided by a one-ply or two-ply construction method. The thickness of the impermeable layer is 3 mm or more,
The structure according to any one of claims 1 to 3, wherein a material containing polyurea, polyurethane, or rubber asphalt is used as the liquid impermeable material.   The structure according to any one of claims 1 to 4, further comprising a protective elastic layer between the water-impervious layer and the pressing concrete.   The lower end portions of the plurality of H-shaped steel columns are respectively supported by fixing plates embedded in the second portion and fixed with root-wound concrete, and the upper end portions are fixed to the side wall frame. The structure according to claim 2.   7. A shear connector protruding into the holding concrete from a surface of the H-shaped steel column on one side of the side wall impermeable construction layer is provided on one flange portion of the H-shaped steel column. The structure described in. A method of constructing a water-impervious side wall comprising a side wall skeleton, a side wall impermeable work layer provided inside the side wall skeleton, and a holding concrete that protects the side wall impermeable work layer,
Inside the side wall structure, a water blocking layer construction step of constructing the sidewall water blocking layer,
A plurality of H-shaped steel columns along the side-wall skeleton at positions separated by a predetermined distance from the side-wall skeleton, and H-shaped steel column standing steps of erected at a predetermined interval in a posture in which the flange surface is along the side-wall skeleton;
A reinforcing step for reinforcing the presser concrete,
One deck plate having a predetermined vertical dimension and a horizontal dimension corresponding to the predetermined interval is provided between the adjacent H-shaped steel columns, and the side wall shields on the left and right edge portions of the deck plate are provided. A deck plate arranging step of arranging so that the surface on the side opposite to the hydraulic layer contacts the inner surface of the flange portion on the side opposite to the side wall impermeable layer of the H-shaped steel column;
The deck plate of the holding concrete by placing concrete between the side wall water blocking layer installed in the water blocking layer construction step and the deck plate arranged in the deck plate arranging step. And a pressing portion forming step of forming a portion corresponding to
After performing the water impermeable layer construction step, the H-shaped steel column erection step, and the reinforcement step, the deck plate arrangement is performed from the lower portion of the side wall skeleton until the holding concrete is formed at a predetermined height. A method of constructing a water-impervious side wall, which comprises repeating the step and the step of forming the holding portion.

Images