JP2018188882A - Control type revetment and installation method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control type revetment capable of shortening a construction period and easily maintaining quality.SOLUTION: A control type revetment comprises: a water impermeable trench 7 provided in a hard ground 17; a leveling material 9 covering a bottom surface of the trench 7 and having a plane-shaped upper face; a structure 11 installed on the leveling material 9; and a water shielding material 13 provided in the trench 7 and in at least one side of the structure 11.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a management-type revetment and a method for installing a management-type revetment, and in particular, relates to one formed without using rubble.

  DESCRIPTION OF RELATED ART Conventionally, the revetment which arrange | positioned rubble on the ground and arrange | positioned gravity type structures, such as a caisson, on this rubble is known (for example, refer patent document 1).

JP 2005-207132 A

  By the way, in the conventional revetment, as a pre-stage process, rubble is spread on the ground with a thickness of 1m to 1.5m, and a rubble mound is built to support the gravity structure. Longer pre-construction period is required. Moreover, since the quality in stable performance, such as stably supporting the gravitational structure, depends on the rubble mound, there is a problem that it may be difficult to ensure a certain quality.

  Moreover, since the above-mentioned rubble mound has a gap of about 40% to 50% inside and outside, there is a problem that becomes fatal for the management-type waste landfill revetment that the rubble mound ground becomes a permeable layer.

  The present invention has been made in view of the above-mentioned problems, can shorten the construction period, can easily maintain the quality in the above-mentioned stable performance, and can eliminate a rubble mound that becomes a water-permeable layer. The purpose is to provide a management-type revetment that can measure water permeability and a method of installing a management-type revetment.

  The invention according to claim 1 covers a trench provided in a water-impermeable and hard conventional ground or an artificially-impermeable impermeable improvement base, and a bottom surface of the trench, and an upper surface is A management-type revetment having a leveling material in a planar shape, a structure installed on the leveling material, and a water shielding material provided in the trench on at least one side of the structure It is.

  According to a second aspect of the present invention, there is provided a trench forming step of forming a trench in a water-impermeable and hard conventional ground or an artificially impermeable improvement base, and a trench formed in the trench forming step. A leveling material installation step of installing a leveling material so as to cover the surface of the bottom and having a flat top surface, and after the leveling material installed in the leveling material installation step is cured, the leveling material A structure installation step of installing a structure on the surface, and a water shielding material installation step of installing a water shielding material in the trench on at least one side of the structure after the structure is installed in the structure installation step This is a management type revetment installation method.

  The invention described in claim 3 covers a predetermined area of the surface of the impervious and hard conventional ground or the artificially impermeable improved base, and the upper surface is flat. A block installed on the leveling material, a structure installed on the leveling material, a structure installed on the leveling material, a predetermined distance away from the structure on at least one side of the structure, It is a management-type revetment having a water shielding material provided in a groove-like part formed between the structure and the block.

  The invention according to claim 4 is a leveling material that covers a predetermined region of the surface of a water-impermeable and hard conventional ground or an artificially formed water-impermeable improvement base and has a flat upper surface. Leveling material installation step, and after the leveling material installed in the leveling material installation step is cured, a structure installation step for installing a structure on the leveling material, and A block installation step of installing a block on the leveling material at a predetermined distance away from the structure on at least one side, and a structure is installed in the structure installation step, and the block is installed in the block installation step Is installed in the grooved part formed between the structure and the block, and a water shielding material installing step of providing a water shielding material in the groove-shaped portion.

According to a fifth aspect of the present invention, in the managed revetment according to the first or third aspect, the leveling material is between the rubble with the underwater concrete, the soil-based water shielding material, and the leveled rubble. Underwater concrete filled in the gap, the asphalt mixture filled in the gap between the rubble with the leveled rubble, and the soil-based water shielding filled in the gap between the rubble with the leveled rubble It is a managed revetment that is made of wood or a material that has the required strength and has a lugion value of “1” or less and a hydraulic conductivity of “1 × 10 ⁻⁵ cm / s” or less.

  According to a sixth aspect of the present invention, in the managed revetment according to the first, third, or fifth aspect, the water shielding material is an asphalt material, a concrete material, a chemical material, or It is a management-type revetment made of soil-based materials.

  The invention according to claim 7 is a management-type revetment having a protective material provided on the water-blocking material in the management-type revetment according to claim 1 or claim 3 or claim 5 or claim 6. is there.

Invention of Claim 8 is the installation method of the management type revetment of Claim 2 or Claim 4, The said leveling material installation process installs underwater concrete as a leveling material, or uses as a leveling material Install a soil-based water-impervious material, spread rubble as a leveling material, and fill the gap between the leveled rubble with underwater concrete, or level the rubble as leveling material Fill the gap between the rubble with asphalt mixture, level the rubble as a leveling material, and fill the gap between the leveled rubble with the soil-based water barrier, or develop the required strength This is a management type revetment installation method, which is a process of installing a material having a Lujion value of “1” or less and a water permeability coefficient of “1 × 10 ⁻⁵ cm / s” or less.

  The invention according to claim 9 is the management type revetment installation method according to claim 2, claim 4 or claim 8, wherein the water shielding material installation step provides asphalt material as the water shielding material. This is a management type revetment installation method in which a concrete material is provided as a water shielding material, a chemical material is provided as a water shielding material, or a soil material is provided as a water shielding material.

  The invention according to claim 10 is the management type revetment installation method according to claim 2 or claim 4 or claim 8 or claim 9, after installing the water shielding material in the water shielding material installation step, It is the installation method of the management type revetment which has the protective material installation process which provides a protective material on the said water-impervious material.

  Advantageous Effects of Invention According to the present invention, it is possible to shorten the construction period, and to provide a management-type revetment and a management-type revetment installation method that are easy and inexpensive to maintain the above-described quality.

It is sectional drawing which shows schematic structure of the management type revetment which concerns on the 1st Embodiment of this invention. It is sectional drawing which shows schematic structure of the management type revetment which concerns on the modification of the 1st Embodiment of this invention. It is sectional drawing which shows schematic structure of the management type revetment which concerns on the 2nd Embodiment of this invention.

[First Embodiment]
In the management-type revetment 1 according to the first embodiment of the present invention, as shown in FIG. 1, for example, a sea area in which waste is landfilled and dumped is partitioned by shielding water so as to partition from the open sea 3. The section 5 is used as a waste landfill.

  The managed revetment 1 includes a trench 7, a leveling material (for example, underwater concrete) 9, a structure (for example, a gravitational structure; for example, caisson or cell) 11, and a water shielding material (for example, an asphalt mixture). More specifically, an asphalt mastic) 13 and a protective material (for example, asphalt mat) 15 are provided.

The trench 7 is provided in an impermeable and hard ground (for example, a conventional ground) 17. As the impermeable and hard ground 17, the rock (the ground composed of rock), C.I. D. M.M. An improved ground (artificially impermeable improvement base) having the necessary hardness and imperviousness can be raised by improving the ground by a construction method such as a construction method. More specifically, as the ground 17, the impervious rock mass having a lugeon value of “1” or less, C.I. D. M.M. An improved ground having a hydraulic conductivity of “1 × 10 ⁻⁵ cm / s” or less can be listed using a construction method or the like.

  Here, with reference to FIG. 1, the case where the ground 17 is composed of rock will be described in more detail as an example.

  For example, the trench 7 extends long with a predetermined depth and a predetermined width. That is, the cross section of the trench 7 (a cross section by a plane orthogonal to the longitudinal direction) is rectangular. However, the bottom surface (upper surface) of the trench 7 is uneven (surface that is not flat and has unevenness).

  Further, when the trench 7 is viewed in a plan view, the trench 7 extends long in a band shape with a predetermined width. The belt-like trench 7 is straight or bent as appropriate, or a part of the trench 7 is straight and the other part is curved. Along the coastline and extend to other predetermined locations on the coastline.

  The underwater concrete 9 covers the surface of the bottom of the trench 7 in order to level the unevenness of the surface of the bottom of the trench 7 and is hardened to have a flat upper surface. The caisson 11 is installed on the leveling material 9. The asphalt mastic 13 is provided in the trench 7 on one side of the caisson 11 or on both sides (at least one side).

  Here, although the caisson 11 is taken as an example and described in more detail, cells other than the caisson are formed in substantially the same manner as the caisson. The outer shape of the caisson 11 is, for example, an elongated rectangular parallelepiped. The width of the caisson 11 is narrower than the width of the trench 7.

  Then, the width direction of the caisson 11 and the width direction of the trench 7 coincide with each other, the longitudinal direction of the caisson 11 and the longitudinal direction of the trench 7 coincide with each other, the depth direction of the trench 7 and the height of the caisson 11 The caisson 11 is installed on the underwater concrete 9 so that the directions coincide with each other.

  Next, the aspect in which the asphalt mastic 13 is provided in the trench 7 on both sides in the width direction of the caisson 11 will be described in detail. The caisson 11 is installed at the center (for example, the middle) of the trench 7 in the width direction. The height dimension value of the caisson 11 is larger than the depth dimension value of the trench 7, and the caisson 11 is larger than the surface 17 </ b> A of the ground (part where the trench 7 is not provided) 17 in this height direction. Projects upward.

  The caisson 11 is placed on the underwater concrete 9 in direct contact with the underwater concrete 9 without using a mound of rubble or the like. Also, a plurality of caissons 11 are provided, and these are connected in the longitudinal direction and are aligned along the trench 7.

  Further, when the caisson 11 is installed on the underwater concrete 9 but the asphalt mastic 13 is not provided, grooves 7A and 7B formed by a part of the trench 7 are formed on both sides of the caisson 11 in the width direction. Has been. The cross section of the grooves 7A and 7B (cross section by a plane orthogonal to the longitudinal direction) is rectangular, and the width of each of the left and right grooves 7A and 7B in FIG. 1 (lateral dimension in FIG. 1). Are matching each other.

  The asphalt mastic 13 is provided in the grooves 7A and 7B so as to fill each of the grooves 7A and 7B. The height position of the planar upper surface 13A of the asphalt mastic 13 is, for example, coincident with the height position of the surface 17A of the ground (part where no trench is provided) 17, but may be slightly lower. , It may be slightly higher.

  The asphalt mat 15 is provided on the asphalt mastic 13. The asphalt mat 15 is formed in an elongated plate shape having a predetermined thickness and a predetermined width, the thickness direction is the height direction, and the width direction coincides with the width direction of the trench 7, In order to protect the asphalt mastic 13 from external force or the like, the asphalt mastic 13 is covered.

  The lower surface of the asphalt mat 15 is in contact with the upper surface 13A of the asphalt mastic 13. One end portion in the width direction of the asphalt mat 15 is bent and fixed to the caisson 11 in contact with the side wall of the caisson 11, for example, and the other end portion in the width direction of the asphalt mat 15 is over the asphalt mastic 13. It hangs and covers the upper surface 17A of the ground 17 and is fixed to the ground 17. Note that the bent portion of the asphalt mat 15 may be deleted.

  Structures such as the caisson 11, leveling materials such as the underwater concrete 9, and protective materials such as the asphalt mat 15 are also impermeable.

Note that the leveling material 9 is not underwater concrete, but a hardened soil-based water shielding material, underwater concrete filled in the space between the rubble and the rubble, and this rubble with the rubble rubble Asphalt mastic or other asphalt mixture filled in the gap between the soil, soil-based water shielding material filled in the gap between the rubble with the leveled rubble, or required strength (required as a leveling material (Strength) is expressed, and the lugion value may be “1” or less and the water permeability coefficient may be “1 × 10 ⁻⁵ cm / s” or less.

  Further, the water shielding material 13 may be made of an asphalt material (for example, asphalt mastic), a concrete material (for example, concrete), a chemical material, or a soil material.

  As leveling material 9, underwater concrete filled in the space between the rubble with the leveled rubble, asphalt mastic filled in the gap between the rubble with the leveled rubble, By using a soil-based water barrier filled in the gap between the rubble and the rubble, the amount of underwater concrete, asphalt mastic, and soil-based water barrier can be reduced. Becomes cheaper.

  Next, the installation method of the management type revetment 1 is demonstrated.

  First, the trench 7 is formed in the rock mass 17 (trench formation process).

  Subsequently, in order to level the surface unevenness of the bottom of the trench 7, the underwater concrete 9 is installed so as to cover the bottom surface of the trench 7 formed in the trench formation step and to have a flat top surface (leveling). Sushi installation process).

In this leveling material installation process, instead of installing underwater concrete as leveling material, install a soil-based impermeable material as leveling material, or leveling rubble as leveling material, Fill the gap with underwater concrete, level the rubble as a leveling material, and fill the gap between the leveled rubble with asphalt mastic, or level the rubble as leveling material. The gap between the rubble stones is filled with a soil-based water-impervious material, or the required strength (strength required as a leveling material) is expressed, the Luzione value is “1” or less, and the hydraulic conductivity is “ You may install the material which is 1 * 10 < ^-5 > cm / s "or less.

  Subsequently, after the underwater concrete 9 installed in the leveling material installation process is hardened, the caisson 11 is installed on the underwater concrete 9 (structure installation process).

  Subsequently, after the caisson 11 is installed in the structure installation process, the asphalt mastic 13 is provided in the trench 7 on both sides of the caisson 11 (water shielding material installation process).

  In this water shielding material installation process, instead of providing an asphalt material as a water shielding material, a concrete material as a water shielding material, a chemical material as a water shielding material, or a water shielding material A soil-based material may be provided.

  Subsequently, after installing the asphalt mastic 13 in the water shielding material installation step, the asphalt mat 15 is provided on the asphalt mastic 13 (protective material installation step).

  When the managed revetment 1 is installed, as shown in FIG. W. L. And L. W. L. The tide level fluctuates with time. However, the management water level is set on the land side, and the water level is fixed and managed.

  According to the management-type revetment 1, since the caisson 11 is placed on the underwater concrete 9 in direct contact with the underwater concrete 9 without using a member such as rubble, the installation period of the management-type revetment 1 is shortened. In addition, it is easy to maintain good quality such as eliminating dependence on rubble and stably supporting the gravitational structure of the management-type revetment 1.

  Moreover, according to the management-type revetment 1, there is no rubble, and asphaltmatic 13 and underwater concrete 9 (water-impermeable material) are used. Permeation of seawater between the side compartments 5 can be more easily and reliably prevented.

  Moreover, according to the management type revetment 1, since the trench 7 having a rectangular cross section is provided instead of the rubble whose skirt is widened by providing a slope, the dimension in the width direction can be reduced.

  More specifically, the following can be listed as the main purpose of providing a rubble mound when the management-type revetment 1 is installed.

  Objective A: To correct the unevenness of the foundation ground and aim for stable installation of the structure. Objective B: Distribute the load of the structure evenly to the ground. Objective C: Absorb the wave force acting on the structure with the frictional force between the mound interior and the foundation ground. Objective D: Prevent scouring of the ground at the bottom of the structure due to waves and tidal currents.

  The purpose A can be achieved more than when the management type revetment 1 in which the bottom surface of the trench 7 is leveled by the underwater concrete 9 is provided sufficiently or a rubble mound is provided.

  The purpose B is that the bottom surface of the trench 7 is leveled by the underwater concrete 9, and the lower surface of the caisson 11 is formed in a flat shape, and the upper surface of the underwater concrete 9 and the lower surface of the caisson 11 are in surface contact with each other. This can be achieved with the managed revetment 1 that is more than with a rubble mound.

  The purpose C is that the upper surface of the underwater concrete 9 and the lower surface of the caisson 11 are in surface contact with each other, so that the friction coefficient is increased and the grooves 7A and 7B on both sides of the caisson 11 in the width direction are asphalt. This can be achieved by the management-type revetment 1 filled with the mastic 13 more than when a rubble mound is provided.

  The purpose D can be sufficiently achieved by the management-type revetment 1 provided with the asphalt mat 15.

  In the above description, the case where the caisson 11 is installed in the middle of the trench 7 in this width direction is taken as an example. However, the caisson 11 is provided so as to be biased to either side in this width direction. Alternatively, the caisson 11 may be further provided in the width direction so that the asphalt mastic 13 and the asphalt mat 15 may be provided only on one side of the caisson 11 in the width direction. .

  More specifically, the caisson 11 is moved from the embodiment shown in FIG. 1 to the land side (right side) until the lower part of the land side surface of the caisson 11 contacts the land side surface of the trench 7, and the asphalt mastic 13 and the asphalt mat are moved. The aspect which provided 15 only in the sea side may be sufficient.

  Conversely, the caisson 11 is moved from the embodiment shown in FIG. 1 to the sea side (left side) until the lower part of the sea side surface of the caisson 11 abuts the sea side surface of the trench 7, and the asphalt mastic 13 and the asphalt mat 15 are moved. May be provided only on the land side.

  Further, as indicated by a broken line L1 in FIG. 1, the side surfaces (side surfaces opposite to the caisson 11) of the grooves 7A and 7B of the trench 7 may be inclined to be a slope. Thereby, it becomes easy to install the asphalt mastic 13 in the grooves 7A and 7B, and the surface pressure that the side surfaces of the grooves 7A and 7B receive from the asphalt mastic 13 and the like can be reduced. Further, the lower part of the caisson 11 (the part in contact with the asphalt mastic 13) may be sloped similarly.

  In addition, when the ground 17 is water-permeable and soft, it is necessary to improve the ground over a predetermined area in the ground improvement process prior to the trench formation process to ensure the strength and imperviousness of the ground. .

  With reference to FIG. 2, the case where the management-type revetment 1 is provided in the place where the ground improvement (for example, the ground improvement by a CDM method) is provided is demonstrated in detail.

  Before the start of the installation work of the management-type revetment 1, the upper side of the curves L2, L3, L4 is the soft ground 17B with the curves L2, L3, L4 as the boundaries, and the lower sides of the curves L2, L3, L4 are It is bedrock 17C.

  In this state, the predetermined area 19 necessary for the installation of the management-type revetment 1 is improved. The predetermined area 19 is an area within the lines L5, L3, and L7.

  In the embodiment shown in FIG. 2, after improving the ground in the area 19, the management-type revetment 1 is installed in the same manner as shown in FIG. 1.

[Second Embodiment]
The management type revetment 1a according to the second embodiment of the present invention is provided with a block (for example, an embedded formwork block) 21 instead of providing the trench 7, and the management according to the first embodiment of the present invention is provided. Unlike the type revetment 1, the other points are configured in substantially the same manner as the management type revetment 1, and have almost the same effects and can be deformed in substantially the same manner.

  That is, the management-type revetment 1a according to the second embodiment of the present invention includes an underwater concrete 9, a caisson 11, an embedded formwork block 21, an asphalt mastic 13 and an asphalt mat 15 as shown in FIG. Has been.

  The underwater concrete 9 is the bedrock 17 or C.I. D. M.M. In order to level the uneven surface of the improved ground, the bedrock 17 or C.I. D. M.M. It covers a predetermined area on the surface 17A of the improved ground and is hardened so that the upper surface is flat.

  When the area in which the underwater concrete 9 is provided is viewed in plan, it is in the form of an elongated strip having a predetermined width, as in the case of the trench 7. The caisson 11 is installed on the underwater concrete 9.

  The embedded form block 21 is placed on the underwater concrete 9 at a predetermined distance from the caisson 11 on one side or both sides of the caisson 11.

  The asphalt mastic 13 is provided in a groove-like portion 23 formed between the caisson 11 and the embedded form block 21. The asphalt mat 15 is provided on the asphalt mastic 13.

  Here, as in the case of the first embodiment, the caisson 11 will be described as an example. As described above, the outer shape of the caisson 11 has, for example, an elongated rectangular parallelepiped shape. The width of the caisson 11 is narrower than the width of the region where the underwater concrete 9 is provided.

  And the width direction of the caisson 11 and the width direction of the area | region in which the underwater concrete 9 is provided mutually correspond, and the longitudinal direction of the caisson 11 and the longitudinal direction of the area | region in which the underwater concrete 9 is provided mutually correspond. Thus, the caisson 11 is installed on the area where the underwater concrete 9 is provided.

  Moreover, the external shape of the embedded form block 21 is, for example, an elongated rectangular parallelepiped shape. The width of the embedded form block 21 is narrower than the width of the caisson 11, and the height of the embedded form block 21 is also lower than the height of the caisson 11.

  Then, the width direction of the embedded form block 21 and the width direction of the region where the underwater concrete 9 is provided coincide with each other, and the longitudinal direction of the embedded form block 21 and the length of the region where the underwater concrete 9 is provided. The embedded form block 21 is installed on the area where the underwater concrete 9 is provided so that the directions coincide with each other.

  Next, the aspect in which the embedded form block 21 and the asphalt mastic 13 are provided on both sides of the caisson 11 in the width direction will be described in detail. The caisson 11 is installed in the center (for example, the middle) of the region where the underwater concrete 9 is provided in the width direction.

  The embedded form block 21 on one side (for example, the land side) of the caisson 11 in the width direction is provided on the one side in the width direction of the caisson 11 by a predetermined distance from the caisson 11. Thus, a groove-like portion 23 (23A) is formed on one side of the caisson 11 in the width direction. The width of the groove-like portion 23A is equal to the distance between the caisson 11 and the embedded mold block 21, and the depth value of the groove-like portion 23A is equal to the height dimension value of the embedded mold block 21. Are equal.

  The embedded form block 21 on one side in the width direction of the caisson 11 is installed at one end of the area where the underwater concrete 9 is provided in the width direction of the area where the underwater concrete 9 is provided. ing.

  More specifically, one end of the embedded form block 21 on one side (the end opposite to the caisson; the right end of the right embedded form block 21 in FIG. 3) is one of the areas where the underwater concrete 9 is provided. It is located on the caisson 11 side (left side in FIG. 3) from the end (right end in FIG. 3). That is, the entire embedded form block 21 on one side is within the region where the underwater concrete 9 is provided in this width direction.

  A part of the embedded form block 21 on one side may protrude from the region where the underwater concrete 9 is provided in this width direction, or the end of the embedded form block 21 on one side ( The position of the end opposite to the caisson 11 may coincide with the position of the end on one side of the region where the underwater concrete 9 is provided.

  The caisson 11 and the embedded form block 21 are placed on the underwater concrete 9 in direct contact with the underwater concrete 9 without using a member such as rubble. The caisson 11 and the embedded form block 21 are provided in a plurality, and these are connected in the longitudinal direction along the region where the underwater concrete 9 is provided.

  Moreover, the asphalt mastic 13 is provided in the groove-shaped part 23A so as to fill the groove-shaped part 23 (23A). The height position of the planar upper surface 13A of the asphalt mastic 13 is lower than, for example, the height position of the upper surface of the embedded form block 21, but coincides with the height position of the upper surface of the embedded form block 21. It may be slightly higher.

  The asphalt mat 15 is formed in an elongated plate shape having a predetermined thickness and a predetermined width, the thickness direction is the height direction, and the width direction is the width direction of the region where the underwater concrete 9 is provided. In order to protect the asphalt mastic 13 from external force and the like, the asphalt mastic 13 is covered.

  The lower surface of the asphalt mat 15 is in contact with the upper surface 13A of the asphalt mastic 13. One end of the asphalt mastic 13 in the width direction is bent and fixed to the caisson 11 in contact with the side wall of the caisson 11, for example, and the other end in the width direction of the asphalt mastic 13 is also bent and embedded, for example. It is in contact with the side wall of the frame block 21 and is fixed to the embedded form block 21. Note that the bent portion of the asphalt mat 15 may be deleted.

  Similarly to the one side of the caisson 11 in the width direction, the buried form block 21 and the asphalt mastic (asphalt mastic in the grooved portion 23B) 13 are also formed on the other side (the sea side) of the caisson 11 in the width direction. An asphalt mat 15 is provided.

  In the above description, the case where the caisson 11 is installed in the middle of the area where the underwater concrete 9 is provided in the width direction is taken as an example, but as in the case of the first embodiment, The caisson 11 may be provided so as to be biased to either side in the width direction.

  Furthermore, the embedded form block 21, the asphalt mastic 13, and the asphalt mat 15 on either side in the width direction of the caisson 11 (the embedded form block 21 and the asphalt mastic 13 on the side where the caisson 11 is biased) The asphalt mat 15) may be deleted.

  Moreover, when the ground 17 is water-permeable and weak, it is assumed that the ground improvement is performed over a predetermined region in the ground improvement step, similarly to the case shown in the first embodiment.

  Next, the installation method of the management type revetment 1a is demonstrated.

  First, in order to level the unevenness of the surface of the rock mass 17, a predetermined area of the surface of the impermeable and hard rock mass 17 is covered with the underwater concrete 9 so that the upper surface is flat (equalizing material installation step). .

  Subsequently, after the underwater concrete 9 installed in the leveling material installation process is hardened, the caisson 11 is installed on the underwater concrete 9 (structure installation process).

  Subsequently, the embedded form block 21 is set on the underwater concrete 9 at a predetermined distance from at least one side of the caisson 11 (block setting step).

  Note that either the structure installation step or the block installation step may be performed first or at the same time.

  Subsequently, after the caisson 11 is installed in the structure installation process and the embedded form block 21 is installed in the block installation process, the inside of the groove-like portion 23 formed between the caisson 11 and the embedded form block 21 Asphalt mastic 13 is provided in (water shielding material installation step).

  Subsequently, after installing the asphalt mastic 13 in the water shielding material installation step, the asphalt mat 15 is provided on the asphalt mastic 13 (protective material installation step).

  According to the management type revetment 1a, since it is not necessary to provide a trench, the construction period can be further shortened.

1, 1a Management type revetment 7 Trench 9 Leveling material (underwater concrete)
11 Structure (caisson or cell)
13 Water shielding material (asphalt mastic)
15 Protective material (asphalt mat)
17 Ground (bedrock)
21 blocks (embedded formwork block)
23 Groove-shaped part

Claims (10)

A trench (7) provided in an impervious and hard conventional ground (17) or an artificially constructed impermeable improvement base,
Leveling material (9) covering the bottom surface of the trench and having a flat upper surface;
A structure (11) installed on the leveling material;
A water shielding material (13) provided in the trench on at least one side of the structure;
Management type revetment (1) characterized by having A trench forming step of forming a trench in a water-impermeable and hard conventional ground or an artificially-made impermeable improvement base;
A leveling material installation step of installing a leveling material so as to cover the bottom surface of the trench formed in the trench formation step and to have a flat upper surface.
After the leveling material installed in the leveling material installation step is cured, a structure installation step of installing a structure on the leveling material,
After installing the structure in the structure installation step, a water shielding material installation step of providing a water shielding material in the trench on at least one side of the structure;
A method of installing a managed revetment characterized by having A leveling material that covers a predetermined area of the surface of the impermeable and hard conventional ground or the artificially impermeable improved base, and the upper surface is flat,
A structure installed on the leveling material;
A block (21) placed on the leveling material at a predetermined distance from at least one side of the structure,
A water shielding material provided in a groove-like portion (23) formed between the structure and the block;
Management-type revetment (1a) characterized by having A leveling material installation step of covering a predetermined area of the surface of the impermeable and hard conventional ground or the artificially impermeable improvement base and installing the leveling material so that the upper surface is flat; ,
After the leveling material installed in the leveling material installation step is cured, a structure installation step of installing a structure on the leveling material,
A block installation step of installing a block on the leveling material at a predetermined distance away from the structure on at least one side of the structure;
Water shielding that provides a water shielding material in a groove-shaped part formed between the structure and the block after the structure is installed in the structure installation step and the block is installed in the block installation step. Material installation process;
A method of installing a managed revetment characterized by having In the management-type revetment according to claim 1 or claim 3,
The leveling material is submerged concrete, soil-based impermeable material, underwater concrete filled in the space between the rubble with the leveled rubble, and filled in the gap between the rubble with the leveled rubble Asphalt mixture, soil-based water shielding material filled in the gap between the rubble stones, or the required strength, the Luzion value is "1" or less, and the hydraulic conductivity is " A management-type revetment characterized in that it is made of a material that is 1 × 10 ⁻⁵ cm / s or less. In the management type revetment according to claim 1 or claim 3 or claim 5,
The management type revetment characterized in that the water shielding material is made of asphalt material, concrete material, chemical material, or soil material. In the management type revetment according to claim 1 or claim 3 or claim 5 or claim 6,
A management type revetment comprising a protective material (15) provided on the water shielding material. In the installation method of the management type revetment of Claim 2 or Claim 4,
In the leveling material installation step, underwater concrete is installed as a leveling material, a soil-based impermeable material is installed as a leveling material, or a rubble stone is leveled as a leveling material. Fill the air gap with underwater concrete, level the rubble as a leveling material, and fill the gap between the leveled rubble with the asphalt mixture, or level the rubble as the leveling material. The space between the rubble stones is filled with a soil-based water-impervious material, or the required strength is expressed, the Luzione value is “1” or less, and the hydraulic conductivity is “1 × 10 ⁻⁵ cm / s” or less. A management-type revetment installation method characterized by being a process of installing a certain material. In the installation method of the management type revetment of Claim 2 or Claim 4 or Claim 8,
In the water shielding material installation step, an asphalt material is provided as the water shielding material, a concrete material is provided as the water shielding material, a chemical material is provided as the water shielding material, or a water shielding material is provided. A management type revetment installation method characterized in that it is a step of providing a soil-based material. In the management type revetment installation method according to claim 2 or claim 4 or claim 8 or claim 9,
A management type revetment installation method, comprising: a protective material installation step of providing a protective material on the water shielding material after the water shielding material is installed in the water shielding material installation step.

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