JP2015077540A - Bottom slab structure of final disposal site - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bottom slab structure of a final disposal site that can surely prevent leakage of retained water from the inside of the final disposal site and infiltration of groundwater into the inside.SOLUTION: A bottom slab structure 20 which closes a bottom of a final disposal site is composed of a first crushed stone layer 21 installed on the ground GR, a first waterproof unit 22, a second crushed stone layer 23, a second waterproof unit 24, and a protective sand layer 25 in this order from the ground GR side. Each of the first and second waterproof units 22, 24 is formed by laminating a water-impervious sheet 22b and a protective mat 22a. The first crushed stone layer 21 is provided with a water collecting perforated pipe 26 for water discharge that collects and discharges groundwater. The second crushed stone layer 23 is provided with a water collecting perforated pipe 27 for inspection that collects water inside the final disposal site.

Description

  The present invention relates to a bottom slab structure of a final disposal site where a banking material containing inorganic waste is buried as a compacted body.

  Conventionally, as the bottom plate structure of this type of final disposal site, there is one described in Patent Document 1 filed by the applicant of the present application. The bottom plate structure of the final disposal site has a structure in which the bottom of the final disposal site is covered with a water shielding sheet and drainage pipes are provided above and below it.

  Among these drainage pipes, the drainage pipe on the upper side of the water-impervious sheet is for collecting rainwater that has fallen in the open type (without roof) final disposal site, This drain pipe is for verifying that the retained water including rainwater is not leaking from the inside of the final disposal site.

Japanese Patent No. 4317260

  Here, the applicant of the present application conducted a further diligent test study, and in the final disposal site, particularly in the final disposal site constructed in an area where there is a lot of groundwater, the leakage of retained water from the inside of the final disposal site and the underground water into the interior. We studied to prevent intrusion and achieve higher levels of safety performance.

  The present invention has been made in view of the above points, and provides a bottom plate structure of a final disposal site that can reliably prevent leakage of retained water from the inside of the final disposal site and ingress of groundwater into the interior. For the purpose.

  In order to achieve the above object, the bottom plate structure of the final disposal site of the present invention is a bottom plate structure of the final disposal site that fills the embankment material containing inorganic waste as a compacted body, and is erected on the outer periphery of the final disposal site. And a bottom slab structure that closes the bottom of the final disposal site surrounded by the vertical wall, the bottom slab structure, in order from the ground side, a first crushed stone layer provided on the ground, It consists of a first waterproof unit, a second crushed stone layer, a second waterproof unit, and a protective sand layer. The first waterproof unit and the second waterproof unit are composed of a waterproof sheet and a waterproof sheet. A protective mat that covers and protects the surface is formed, and the first crushed stone layer is provided with a perforated drainage water collecting pipe for collecting and discharging groundwater, and the second crushed stone layer is It is characterized by having a perforated water collection pipe for collecting water inside the disposal site.

  As described above, in the bottom slab structure of the final disposal site of the present invention, the waterproof unit is formed of the waterproof sheet and the protective mat that protects the waterproof sheet, and the load applied to the waterproof unit by the crushed stone layer or the protective sand layer is applied. Since it is dispersed and reduced, the water shielding sheet is not damaged. For this reason, the waterproof unit reliably prevents leakage of retained water from the inside of the final disposal site.

  Further, an inspection water collecting pipe is provided on the upper side of the first waterproof unit. Therefore, by monitoring the water collecting pipe for inspection, it is possible to reliably determine the presence or absence of water leakage from the final disposal site.

  Furthermore, a drainage water collecting pipe for discharging groundwater is provided below the first waterproof unit. Therefore, by discharging the groundwater from the drainage water collecting pipe, it is possible to prevent the groundwater from entering from the lower side of the bottom plate structure into the final disposal site.

  Therefore, according to the bottom slab structure of the final disposal site of the present invention, it is possible to reliably prevent leakage of retained water from the inside and intrusion of groundwater into the interior even in a final disposal site constructed in an area with a lot of groundwater. it can.

  Moreover, in the bottom slab structure of the final disposal site of this invention, it is preferable that a 1st crushed stone layer has a convex part which protrudes in the ground side, and the drainage water collecting pipe is provided in the convex part.

  Thus, if the 1st crushed stone layer has the convex part which protrudes in the ground side, ie, if a recessed part is formed on the ground, the groundwater which springed up from the ground side will be the 1st crushed stone layer on the ground. , The water concentrates in the concave portion and is discharged from the drainage water collecting pipe disposed in the concave portion. As a result, the groundwater is more easily discharged, so that the intrusion of groundwater into the final disposal site can be more reliably prevented.

  Moreover, in the bottom slab structure of the final disposal site of the present invention, the second crushed stone layer is formed of a plurality of layers and a third waterproof unit disposed between the plurality of layers, and the third waterproof unit is It is preferable that the water-impervious sheet and a protective mat that covers and protects the surface of the water-impervious sheet are laminated.

  In this way, if the second crushed stone layer is formed of a plurality of layers and the third waterproof unit is disposed between the plurality of layers, the first waterproof unit and the second waterproof unit are temporarily provided. Even if it is damaged, the third waterproof unit can prevent leakage of retained water from the inside of the final disposal site and infiltration of groundwater into the inside.

  In the bottom plate structure of the final disposal site of the present invention, the vertical wall has a fourth waterproof unit that covers the inner surface of the vertical wall and a urethane layer that covers the surface of the fourth waterproof unit. The fourth waterproof unit is formed by laminating a waterproof sheet and a protective mat that covers and protects the surface of the waterproof sheet, and the urethane layer is made of urethane and urethane that covers the surface of the fourth waterproof unit. Preferably, the first waterproof unit and the second waterproof unit are connected to the fourth waterproof unit. The non-combustible spray body is sprayed on the surface.

  If the urethane layer is coated on the surface of the fourth waterproof unit, the urethane layer serves as a buffer, so that the fourth waterproof unit can be prevented from being damaged. Moreover, since the surface side of the fourth waterproof unit is in a cured state, when the protective mat or the water shielding sheet constituting the fourth waterproof unit is damaged, the damaged part is partially torn. Become. Therefore, the damaged part can be visually identified, and a quick repair treatment or the like is possible.

  Further, the first waterproof unit that separates the inside and the outside of the final disposal site and the second waterproof unit that covers the second crushed stone layer are connected to the fourth waterproof unit that covers the inner surface of the vertical wall in this way. In this way, it is possible to more reliably prevent water from entering and leaking.

  As a result, leakage of retained water from the inside of the final disposal site and entry of groundwater into the inside can be prevented more reliably.

  Further, in the bottom slab structure of the final disposal site of the present invention, a foundation retaining wall disposed on the vertical wall support and a roof portion supported by the upper end of the foundation retaining wall and covering the entire upper part of the final disposal site. It is preferable to provide.

  In this way, if the final disposal site is a closed type final disposal site with a roof, there will be no intrusion of rainwater from directly above the final disposal site. Can be prevented.

Sectional drawing which shows the structure of a final disposal site. Sectional drawing which shows the structure of the bottom plate structure in the final disposal site of FIG. 1, a vertical wall, and a vertical wall support body. The schematic diagram which shows arrangement | positioning of the drainage water collecting pipe in the final disposal site of FIG. The schematic diagram which shows arrangement | positioning of the water collecting pipe for a test | inspection in the final disposal site of FIG. Sectional drawing which shows the structure of the peripheral part waterproof structure in the final disposal site of FIG. 1, a vertical wall, and a vertical wall support body.

  Hereinafter, with reference to FIGS. 1-5, embodiment of the final disposal site provided with the bottom plate structure of the final disposal site of this invention is described.

  As shown in FIG. 1, the final disposal site of the present embodiment digs down on the ground surface GL, and forms a landfill space on the ground GR for reclaiming the embankment material containing inorganic waste as a compacted body. Yes.

  The final disposal site includes a vertical wall 10 erected on the outer periphery thereof, a bottom plate structure 20 that closes the bottom of the final disposal site surrounded by the vertical wall 10, and a vertical wall support that supports the vertical wall 10. 30, a peripheral waterproof structure 40 provided in the peripheral part of the final disposal site building, a roof 50 covering the entire upper part of the landfill space, and an approach path 60 from the outside to the inside of the final disposal site. .

  First, the vertical wall 10 erected on the outer periphery of the final disposal site will be described. The vertical wall 10 is a structure made of reinforced concrete composed of steel materials (for example, H steel) erected on the ground GR and concrete filling between the steel materials. In addition, the vertical wall 10 may use a structure formed of a wire-like grid or the like in addition to such a reinforced concrete structure.

  As shown in FIG. 2, the vertical wall 10 includes a vertical wall waterproof unit 11 (fourth waterproof unit) that covers the inner surface of the vertical wall 10 and a urethane layer 12 that covers the surface of the vertical wall waterproof unit 11. Have.

  The vertical wall waterproof unit 11 is formed by laminating two sets of a protective mat 11a and a water shielding sheet 11b protected by the protective mat 11a.

  The urethane layer 12 is formed of urethane 12a sprayed on the surface of the vertical wall waterproof unit 11 and non-combustible spraying material 12b sprayed on the surface of the urethane 12a.

  As described above, since the urethane layer 12 covers the surface of the vertical wall waterproof unit 11, the urethane layer 12 serves as a buffer, and damage to the vertical wall waterproof unit 11 can be prevented. Moreover, when the surface side of the vertical wall waterproof unit 11 is cured and the protective mat 11a and the water shielding sheet 11b forming the vertical wall waterproof unit 11 are damaged, the damaged part is partially torn. become. Therefore, the damaged part can be visually identified, and a quick repair treatment or the like is possible.

  Next, the bottom slab structure 20 that closes the bottom of the final disposal site will be described. As shown in FIG. 2, the bottom plate structure 20 includes, in order from the ground GR side, a first crushed stone layer 21 provided on the ground GR, a first waterproof unit 22, a second crushed stone layer 23, 2 waterproof unit 24 and protective sand layer 25.

  The first crushed stone layer 21 is provided with a perforated drainage water collecting pipe 26 that collects and discharges groundwater. The second crushed stone layer 23 is provided with a perforated water collection pipe 27 for collecting water inside the final disposal site.

  The first crushed stone layer 21 is formed of crushed stone laid on the ground GR. Moreover, the 1st crushed stone layer 21 has the convex part 21a which protrudes in the ground GR side in the position where the drainage water collecting pipe 26 is arrange | positioned. That is, the ground GR has a recess formed at a position where the drainage water collecting pipe 26 is disposed.

  The first waterproof unit 22 is formed of two protective mats 22a and a water shielding sheet 22b protected by being disposed so as to be sandwiched between the protective mats 22a. Further, the end portion of the first waterproof unit 22 is connected to the lower end portion of the vertical wall waterproof unit 11 covering the inner surface of the vertical wall 10 by a process such as welding to form a connection portion 28a.

  The second crushed stone layer 23 is formed by laminating a first layer 23a, a partition waterproof unit 23b (third waterproof unit), and a second layer 23c in order from the ground GR side. The first layer 23a and the second layer 23c are formed by laying crushed stone. Similarly to the first waterproof unit 22, the partition waterproof unit 23b is formed of a water shielding sheet and a protective mat for protecting the waterproof sheet. Moreover, the edge part of the waterproof unit 23b for division is connected to the vertical wall waterproof unit 11 by processes, such as welding, and the connection part 28b is formed.

  Similar to the first waterproof unit 22, the second waterproof unit 24 is formed of a water shielding sheet and a protective mat that protects it. The end of the second waterproof unit 24 is connected to the vertical wall waterproof unit 11 by a process such as welding to form a connection portion 28c.

  The protective sand layer 25 is formed of protective sand laid on the second waterproof unit 24, that is, the entire bottom of the final disposal site.

  As shown in FIG. 3, the drainage water collecting pipe 26 is arranged in a mesh shape on the ground GR where the final disposal site is constructed, that is, in the first crushed stone layer 21. Groundwater that springs up from the ground GR is discharged from the drainage basin 26a provided at the outer peripheral position to the outside of the final disposal site through the drainage water collecting pipe 26.

  As shown in FIG. 4, the water collecting pipe 27 for inspection is arranged in a mesh pattern on the first waterproof unit 22, that is, in the first layer 23 a that is the lowermost layer of the second crushed stone layer 23. By monitoring the water detection pipe 27a provided at the outer peripheral position of the water collecting pipe 27 for inspection, it is possible to reliably determine the presence or absence of water leakage from the inside of the final disposal site.

  Thus, in the bottom slab structure 20, the waterproof units 22, 23 b and 24 are all protected by the crushed stone layers 21, 23 a and 23 c and the protective sand layer 25.

  Therefore, since the load applied to the waterproof units 22, 23b, 24 is dispersed and reduced by the crushed stone layers 21, 23a, 23c and the protective sand layer 25, in any case, the waterproof units 22, 23b, 24 No damage will occur.

  Even if a special situation such as subsidence occurs in a part of the ground where the final disposal site was constructed, even if one of the waterproof units 22, 23b, 24 is damaged, The other waterproof units 22, 23 b, 24 reliably prevent leakage of retained water from the inside of the final disposal site and intrusion of groundwater into the inside.

  In the bottom slab structure 20, the first crushed stone layer 21 is disposed on the ground GR side of the first waterproof unit 22, and the convex portion 21a of the first crushed stone layer 21, that is, the concave portion of the ground GR. The drainage water collecting pipe 26 is disposed.

  Therefore, the groundwater that has springed up from the ground GR side is blocked by the first waterproof unit 22, passes through the inside of the first crushed stone layer on the ground GR, and on the ground GR on which the convex portion 21a is formed. It concentrates in a recessed part and is discharged | emitted from the drainage water collecting pipe 26 arrange | positioned at the recessed part.

  Further, in the bottom slab structure 20, the waterproof units 22, 23b, 24 constituting the bottom slab structure 20 are connected to the vertical wall waterproof unit 11 by a process such as welding.

  Therefore, water intrusion or leakage from between the waterproof units 22, 23b, 24 constituting the bottom slab structure 20 and the vertical wall waterproof unit 11 is reliably prevented.

  Therefore, in the final disposal site of this embodiment, the bottom plate structure having such a bottom plate structure 20 is formed, so that even in the final disposal site constructed in an area where there is a lot of groundwater, the retained water from the inside. It is possible to reliably prevent water leakage and groundwater intrusion into the interior.

  Next, the vertical wall support 30 that supports the vertical wall 10 will be described. As shown in FIG. 1, the vertical wall support 30 is configured by disposing impermeable improved soil around the entire final disposal site so as to support the vertical wall 10 on the outside of the vertical wall 10. ing.

  Further, the vertical wall support 30 is formed so that its outer periphery expands toward the ground surface. Specifically, as shown in FIG. 2, the vertical wall support 30 has an outer peripheral surface that expands in a stepped manner with a tapered surface 31 and a horizontal surface 32.

  Next, the peripheral waterproof structure 40 provided in the peripheral part of the final disposal site building will be described. As shown in FIG. 5, the peripheral waterproof structure 40 includes a foundation retaining wall 41 disposed on the vertical wall support 30, a drainage groove 42 provided on the outer peripheral side of the foundation retaining wall 41, and a foundation support. Peripheral waterproof unit 43 disposed so as to cover the area from the side surface of wall 41 to drain groove 42 and the outer peripheral surface of drain groove 42, and the peripheral waterproof unit in the area from foundation retaining wall 41 to drain groove 42 43 and a peripheral crushed stone layer 44 disposed on 43.

  Further, the region from the foundation retaining wall 41 to the drainage groove 42 is inclined from the foundation retaining wall 41 toward the drainage groove. On the other hand, a soil 70 in which azaleas and the like are planted is provided on the outer peripheral side of the drainage groove 42.

  The foundation retaining wall 41 is an inverted T-shaped member, and a groove portion 41a is formed on the side surface on the outer peripheral side of the portion extending above the center portion. In addition, a water repellent finish is applied to a region above the groove 41a on the outer peripheral surface by applying a water repellent.

  The drainage groove 42 includes a U-shaped side groove 421, a pedestal 422 disposed under the side groove 421, and a basic crushed stone layer 423 disposed under the pedestal 422.

  The side groove 421 is formed of porous concrete on the side portion and has a permeation portion 421a through which water passes.

  The peripheral waterproof unit 43 includes a first unit 431 that covers a part of the outer peripheral side wall of the foundation retaining wall 41 and an inner peripheral surface of the groove 41a, and a second unit that covers an area from the foundation retaining wall 41 to the drainage groove 42. 432, a flat bar 433 for fixing the first unit 431, and a urethane layer 434 covering the first unit 431 and the flat bar 433.

  The first unit 431 is formed by stacking two sets of a protective mat 431a and a water shielding sheet 431b.

  The second unit 432 is formed of two protective mats 432a and a water shielding sheet 432b protected by being disposed so as to be sandwiched between the protective mats 432a. Further, the end of the second unit 432 is connected to the end of the first unit 431.

  The flat bar 433 is disposed inside the groove 41a of the foundation retaining wall 41, and is disposed so as to fix and protect the end of the first unit 431.

  The urethane layer 434 fills the groove 41a of the foundation retaining wall 41, and the urethane 434a sprayed on the surfaces of the first unit 431 and the flat bar 433, and the non-combustible material sprayed on the surface of the urethane 434a. It is formed of a spray material 434b.

  The peripheral crushed stone layer 44 is formed by laying crushed stone. As for the edge part by the side of the foundation retaining wall 41 of the peripheral part crushed stone layer 44, the upper surface is located above the formation position of the groove part 41a of the foundation retaining wall 41, and the lower surface is located below the formation position of the groove part 41a. . That is, the peripheral portion crushed stone layer 44 has a thickness in which the upper surface embeds the groove 41 a of the foundation retaining wall 41. On the other hand, the end of the peripheral crushed stone layer 44 on the drainage groove 42 side has an upper surface positioned substantially at the same height as the upper surface of the side groove 421 of the drainage groove 42, and a lower surface is the upper end of the formation position of the penetration portion 421 a of the side groove 421. It is located below the part.

  As described above, in the peripheral waterproof structure 40, the outer peripheral side wall of the foundation retaining wall 41 and a part of the inner peripheral surface of the groove 41a, the region from the foundation retaining wall 41 to the drain groove 42, and the drain groove 42 The outer peripheral surface is covered with the peripheral waterproof unit 43. Further, the region from the foundation retaining wall 41 to the drainage groove 42 is inclined from the foundation retaining wall 41 toward the drainage groove 42. Further, the permeation portion 421a of the side groove 421 of the drainage groove 42 is formed of porous concrete that allows water to pass therethrough, and the upper end portion of the permeation portion 421a is located above the lower surface of the peripheral crushed stone layer 44. Yes.

  Therefore, the rainwater or the like that has fallen in the periphery of the final disposal site is blocked by the peripheral waterproof unit 43, passes through the peripheral crushed stone layer 44, and is collected from the infiltration portion 421a to the inside of the drainage groove 42. It is discharged outside the final disposal site. As a result, rainwater or the like that has fallen on the periphery of the final disposal site does not even reach the vertical wall support 30 and does not enter the inside from the side of the final disposal site.

  Of the rainwater that has fallen in the area on the outer peripheral side of the drainage groove 42, the rainwater that has flowed to the final disposal site flows on the surface of the soil 70 where azaleas are planted, and the vicinity of the final disposal site. In the same manner as rainwater that has fallen on the section, the water is discharged to the outside of the final disposal site via the drainage groove 42.

  Further, in the peripheral waterproof structure 40, the peripheral waterproof unit 43 is formed by the water shielding sheets 431 b and 432 b and the protective mats 431 a and 432 a that protect the water shielding sheets 431 b and 432 b, and on the periphery thereof A partial crushed stone layer 44 is disposed.

  Therefore, since the load applied to the peripheral waterproof unit 43 is dispersed and reduced by the peripheral crushed stone layer 44, the peripheral waterproof unit 43 is not damaged.

  Further, in the peripheral waterproof structure 40, the end of the peripheral waterproof unit 43 on the side of the foundation retaining wall 41, that is, the end of the first unit 431 opposite to the connection with the second unit 432 side, Inside the groove 41 a on the side surface of the foundation retaining wall 41, it is fixed by a flat bar 433 and covered with a urethane layer 434. Further, the region where the groove 41 a is formed is filled with the peripheral crushed stone layer 44.

  Therefore, since the edge part of the peripheral part waterproof unit 43 does not peel off from the foundation retaining wall 41, rainwater or the like may enter the inside of the final disposal site from the joint between the foundation retaining wall 41 and the peripheral waterproof unit 43. Absent.

  In the peripheral waterproof structure 40, the peripheral waterproof structure 40 is subjected to a water repellent process by applying a water repellent agent to a region above the groove 41 a on the outer peripheral surface of the foundation retaining wall 41. Has been.

  Therefore, the outer peripheral surface of the foundation retaining wall 41 is subjected to waterproofing in all areas by the water repellent finish and the peripheral waterproof unit 43, so that the final disposal is performed from the side of the foundation retaining wall 41. Rainwater does not enter the inside of the site.

  Therefore, in the final disposal site of the present embodiment, by forming such a peripheral waterproof structure including the peripheral waterproof structure 40, it is possible to reliably prevent the intrusion of rainwater from the side to the inside. Can be done.

  Next, the roof 50 that covers the entire upper portion of the landfill space will be described. As shown in FIG. 1, the roof portion 50 includes a plurality of support columns 51 erected on the upper end surface of the foundation retaining wall 41 of the peripheral waterproof structure 40, and the entire portion directly above the final disposal site supported by the support columns 51. And a roof 52 covering the.

  As described above, since the closed-type final disposal site with the roof 50 is used, the intrusion of rainwater from directly above the final disposal site is eliminated. To be prevented. The roof portion 50 is not necessarily provided, and may be an open final disposal site where the roof portion 50 is not provided.

  Next, the approach path 60 from the outside to the inside of the final disposal site will be described. As shown in FIG. 1, the approach path 60 is an approach path for carrying waste to be landfilled from the outside of the final disposal site into the site by a trailer or a dump truck, and has a predetermined inclination angle (for example, 10 %) Is provided along the vertical wall 10 (illustration of the off-site carry-in path is omitted).

  Although the illustrated embodiment has been described above, the present invention is not limited to such a form.

  For example, in the above embodiment, the vertical wall waterproof unit 11 and the first unit 431 of the peripheral waterproof unit 43 are formed by stacking two sets of protective mats 11a and 431a and water shielding sheets 11b and 431b. However, these waterproof units may be formed of only one set of protective mats and water shielding sheets, or may be formed by stacking three or more sets.

  Moreover, in the said embodiment, the 2nd crushed stone layer 23 is formed by laminating | stacking the 1st layer 23a, the waterproof unit 23b for division, and the 2nd layer 23c in order from the ground GR side. However, the second crushed stone layer may be formed of one layer, or may be formed of three or more layers and a waterproof unit disposed therebetween.

  In the above embodiment, the first waterproof unit 22, the second waterproof unit 24, and the second unit 432 of the peripheral waterproof unit 43 include two protective mats 22a and 432a and protective mats 22a and 432a. It is formed with the water shielding sheets 22b and 432b protected by being arranged so as to be sandwiched between the two. However, these waterproof units may be formed by laminating a large number of waterproof sheets and protective mats as long as the waterproof sheet is sandwiched between protective mats.

  In the above embodiment, the permeation part 421a of the U-shaped side groove 421 of the drainage groove 42 of the peripheral waterproof structure 40 is formed of porous concrete. However, the permeation portion may be configured so that rainwater permeates from the side of the side groove. For example, the side wall portion may be formed of ordinary concrete, and the drain holes may be provided at equal intervals.

DESCRIPTION OF SYMBOLS 10 ... Vertical wall, 11 ... Vertical wall waterproof unit (4th waterproof unit), 11a ... Protective mat, 11b ... Water shielding sheet, 12 ... Urethane layer, 12a ... Urethane, 12b ... Spraying material, 20 ... Bottom plate structure, 21 ... 1st crushed stone layer, 21a ... Projection, 22 ... 1st waterproof unit, 22a ... Protective mat, 22b ... Water shielding sheet, 23 ... 2nd crushed stone layer, 23a ... 1st layer, 23b ... For division Waterproof unit (third waterproof unit), 23c ... second layer, 24 ... second waterproof unit, 25 ... protective sand layer, 26 ... drainage water collecting pipe, 26a ... water collecting tank, 27 ... testing water collecting pipe, 27a Test pipe, 28a, 28b, 28c ... Connection part, 30 ... Vertical wall support, 31 ... Tapered surface, 32 ... Horizontal surface, 40 ... Peripheral waterproof structure, 41 ... Base retaining wall, 41a ... Groove part, 42 ... Drainage groove, 421 ... lateral groove, 421a Penetration unit, 422 ... pedestal, 423 ... basic crushed stone layer, 43 ... peripheral portion waterproof unit, 431 ... first unit,
431a ... Protective mat, 431b ... Water shielding sheet, 432 ... Second unit, 432a ... Protective mat, 432b ... Water shielding sheet, 433 ... Flat bar, 434 ... Urethane layer, 434a ... Urethane, 434b ... Spraying material, 44 ... Partial crushed stone layer, 50 ... roof part, 51 ... support pillar, 52 ... roof, 60 ... approach path, 70 ... soil, GL ... ground surface, GR ... ground.

In order to achieve the above object, the bottom plate structure of the final disposal site of the present invention is a bottom plate of a final disposal site in which a filling material containing inorganic waste is buried in a landfill space formed by digging into the ground surface as a compacted body. A vertical wall standing on the outer periphery of the final disposal site, and a bottom plate structure that closes the bottom of the final disposal site surrounded by the vertical wall , and the vertical wall has a lower end on the ground It has a vertical wall waterproof unit that is erected by burying and covers the inner surface, and the bottom plate structure, in order from the ground side, a first crushed stone layer provided on the ground, a first waterproof unit, It is composed of a second crushed stone layer, a second waterproof unit, and a protective sand layer. The first waterproof unit , the second waterproof unit, and the vertical wall waterproof unit include a water shielding sheet and a surface of the water shielding sheet. And a protective mat that covers and protects The crushed stone layer is provided with a perforated drainage water collecting pipe that collects and discharges groundwater, and the second crushed stone layer is equipped with a perforated water collecting pipe for collecting water inside the final disposal site. The first waterproof unit and the vertical wall waterproof unit are connected between the first crushed stone layer and the second crushed stone layer, and the second waterproof unit and the vertical wall waterproof unit are the second It is connected between the crushed stone layer and the protective sand layer .

As described above, in the bottom slab structure of the final disposal site of the present invention, the waterproof unit is formed of the waterproof sheet and the protective mat that protects the waterproof sheet, and the load applied to the waterproof unit by the crushed stone layer or the protective sand layer is applied. Since it is dispersed and reduced, the water shielding sheet is not damaged. In addition, the first waterproof unit and the vertical wall waterproof unit are connected between the first crushed stone layer and the second crushed stone layer, and the second waterproof unit and the vertical wall waterproof unit are the second crushed stone. There is a connection between the layer and the protective sand layer. For this reason, the waterproof unit reliably prevents leakage of retained water from the inside of the final disposal site and intrusion of groundwater into the inside .

Further, in the bottom plate structure of the final disposal site of the present invention, the vertical wall has a urethane layer covering the surface of the vertical wall waterproof unit, urethane layer, urethane and urethane coating the surface of the vertical wall waterproofing unit It is preferable to form with the nonflammable spray body sprayed on the surface.

If the urethane layer is coated on the surface of the vertical wall waterproof unit, the urethane layer serves as a buffer, so that the vertical wall waterproof unit can be prevented from being damaged. Moreover, since the surface side of the vertical wall waterproof unit is in a cured state, when the protective mat or the water shielding sheet constituting the vertical wall waterproof unit is damaged, the damaged portion is partially torn. Therefore, the damaged part can be visually identified, and a quick repair treatment or the like is possible.

Further, in the bottom slab structure of the final disposal site of the present invention, a vertical wall support configured to support the vertical wall outside the vertical wall, and a foundation retaining wall disposed on the vertical wall support, The roof part is preferably supported by the upper end of the foundation retaining wall and covers the entire upper part of the final disposal site.

Further, as shown in FIG. 2, the vertical wall 10 includes a vertical wall waterproof unit 11 that covers the inner surface thereof, and a urethane layer 12 that covers the surface of the vertical wall waterproof unit 11.

Periphery waterproof unit 43 includes a first unit 431 for covering a portion of the inner peripheral surface of the groove portion 41a of the side surface of the outer peripheral side of the basic retaining wall 41, the cover region from basic retaining wall 41 to the drain groove 42 2 The unit 432, a flat bar 433 for fixing the first unit 431, and a urethane layer 434 covering the first unit 431 and the flat bar 433 are formed.

Thus, in the peripheral portion the waterproof structure 40, part of the inner circumferential surface of the groove portion 41a of the side surface of the outer peripheral side of the basic retaining wall 41, a region from the basic retaining wall 41 to the drain groove 42, and drainage groove 42 The outer peripheral surface is covered with the peripheral waterproof unit 43. Further, the region from the foundation retaining wall 41 to the drainage groove 42 is inclined from the foundation retaining wall 41 toward the drainage groove 42. Further, the permeation portion 421a of the side groove 421 of the drainage groove 42 is formed of porous concrete that allows water to pass therethrough, and the upper end portion of the permeation portion 421a is located above the lower surface of the peripheral crushed stone layer 44. Yes.

10 ... vertical wall, 11 ... vertical wall waterproof unit, 11a ... protective mat, 11b ... water shield sheet, 12 ... urethane layer, 12a ... urethane, 12b ... Coatings, 20 ... bottom plate structure, 21 ... first Crushed Layer, 21a ... convex portion, 22 ... first waterproof unit, 22a ... protective mat, 22b ... water shielding sheet, 23 ... second crushed stone layer, 23a ... first layer, 23b ... partition waterproof unit (third Waterproof unit), 23c ... second layer, 24 ... second waterproof unit, 25 ... protective sand layer, 26 ... drainage collecting pipe, 26a ... drainage tank, 27 ... inspection collecting pipe, 27a ... testing pipe, 28a , 28b, 28c ... connection part, 30 ... vertical wall support, 31 ... tapered surface, 32 ... horizontal surface, 40 ... peripheral waterproof structure, 41 ... foundation retaining wall, 41a ... groove part, 42 ... drainage groove, 421 ... side groove , 421a ... permeation section, 422 ... cradle , 423 ... basic crushed stone layer, 43 ... peripheral portion waterproof unit, 431 ... first unit, 4 31a ... protective mat, 431b ... water shield sheet, 432 ... second unit, 432a ... protective mat, 432b ... water shield sheet, 433 ... Flat bar, 434 ... Urethane layer, 434a ... Urethane, 434b ... Blowing material, 44 ... Peripheral crushed stone layer, 50 ... Roof, 51 ... Support pillar, 52 ... Roof, 60 ... Access path, 70 ... Soil, GL ... Ground surface, GR ... Ground.

Claims (5)

It is a bottom slab structure of the final disposal site that fills the embankment material containing inorganic waste as a compacted body,
A vertical wall erected on the outer periphery of the final disposal site;
A bottom plate structure that closes the bottom of the final disposal site surrounded by the vertical wall,
The bottom slab structure includes, in order from the ground side, a first crushed stone layer, a first waterproof unit, a second crushed stone layer, a second waterproof unit, and a protective sand layer provided on the ground. And
The first waterproof unit and the second waterproof unit are formed by laminating a water shielding sheet and a protective mat that covers and protects the surface of the water shielding sheet,
The first crushed stone layer is provided with a perforated drainage water collecting pipe for collecting and discharging groundwater,
A bottom plate structure of a final disposal site, wherein the second crushed stone layer is provided with a perforated water collecting pipe for collecting water inside the final disposal site. The bottom slab structure of the final disposal site according to claim 1,
The first crushed stone layer has a convex portion protruding to the ground side,
The drainage water collecting pipe is provided on the convex portion, and is a bottom slab structure of a final disposal site. The bottom slab structure of the final disposal site according to claim 1 or claim 2,
The second crushed stone layer is formed of a plurality of layers and a third waterproof unit disposed between the plurality of layers,
The bottom slab structure of a final disposal site, wherein the third waterproof unit is formed by laminating a water shielding sheet and a protective mat that covers and protects the surface of the water shielding sheet. The bottom plate structure of the final disposal site according to any one of claims 1 to 3,
The vertical wall has a fourth waterproof unit that covers the inner surface of the vertical wall and a urethane layer that covers the surface of the fourth waterproof unit;
The fourth waterproof unit is formed by laminating a water shielding sheet and a protective mat that covers and protects the surface of the water shielding sheet,
The urethane layer is formed of urethane covering the surface of the fourth waterproof unit and a nonflammable spray body sprayed on the surface of the urethane,
The bottom plate structure of a final disposal site, wherein the first waterproof unit and the second waterproof unit are connected to the fourth waterproof unit. The bottom plate structure of the final disposal site according to any one of claims 1 to 4,
A foundation retaining wall disposed on the vertical wall support;
A bottom slab structure of a final disposal site, comprising a roof portion supported by an upper end portion of the foundation retaining wall and covering the entire upper portion of the final disposal site.