JP2017089309A - Manhole and installation structure for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manhole capable of increasing a flotation prevention effect while keeping a cost low, and an installation structure for the same.SOLUTION: A manhole has a shape of an approximately cylindrical body with an opened upper end, and has a wall part of the cylindrical body provided with a drain hole 31 penetrating the wall part. The drain hole 31 is covered with a net-like covering material 15 from the outside. The wall part has an inclined wall part 24 with an outside diameter gradually enlarged downward from an upper end side, and the covering material 15 is arranged in at least an area of the inclined wall part 24.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a manhole buried in the ground at an intermediate position of a sewer pipe and an installation structure thereof.

  Conventionally, in the sewer main installation area, manholes are installed at predetermined intervals so as to connect the sewer mains. Manholes are installed in such a way that the whole is buried in the ground, the upper circular opening is exposed on the ground, and people can enter the manhole from the ground. That is, by installing a manhole, an inspector or an operator can get down to the position of the sewer pipe in order to maintain and manage various functions of the sewer pipe.

  Such manholes are lifted from the ground when the groundwater level of the surrounding ground rises due to rainwater, etc., or when a large earthquake occurs, especially when the ground liquefies due to an earthquake. It may protrude from the surface, obstruct traffic, and stop the function of the sewer pipe. In the liquefaction phenomenon, the ground pressure repeatedly receives shear forces due to earthquakes, and the water pressure between the pores increases between the soil particles (excess pore water pressure). Disappears and the bond structure of soil particles breaks down.

  In order to avoid such a situation, a manhole rising prevention structure for preventing the manhole from rising during an earthquake has been proposed.

  For example, in the manhole described in Patent Document 1, an overhanging body that protrudes radially outward from the wall of the manhole is provided on the upper portion of the manhole formed in the cylindrical body, and the upper portion of the overhanging body is covered in a contact state. In addition, a high weight levitator is provided. In this manhole, the lifting of the manhole can be prevented by increasing the weight of the levitating restraint and the frictional resistance due to the provision of the overhanging body and the levitating restraint.

  Further, in the manhole described in Patent Document 2, a drain hole penetrating the wall portion is formed in the wall portion of the manhole formed in a cylindrical shape, and the wall portion is covered with a covering material so as to cover the drain hole. being surrounded. In this manhole, when the excess pore water pressure rises due to an earthquake, groundwater can flow into the manhole from the drain hole to dissipate the excess pore water pressure, and as a result, the manhole can be prevented from rising. Further, the covering material can prevent earth and sand from entering the manhole from the drain hole.

JP 2010-121386 A JP 2007-39945 A

  In the manhole described in Patent Document 1, when the ground around the overhanging body and the floating suppression body is liquefied, the floating prevention effect due to the load and frictional resistance is reduced, and the buoyancy acting on the overhanging body and the floating suppression body is reduced. By increasing, the effect of preventing the entire manhole from rising is reduced.

  On the other hand, in the manhole described in Patent Document 2, groundwater can be allowed to flow into the manhole to dissipate excess pore water pressure, thereby preventing liquefaction of the surrounding ground. However, in order to further increase the floating prevention effect, if an overhanging body or a floating suppression body of Patent Document 1 that increases the frictional resistance is separately provided, the member cost increases, and further, the covering material that covers the wall portion is increased. Due to the presence, the installation work of the overhanging body and the floating suppression body becomes complicated, and the construction cost increases.

  This invention is made | formed in view of the said subject, The objective is to provide the manhole which can raise a floating prevention effect, suppressing the cost, and its installation structure.

In order to achieve the above object, the manhole according to claim 1,
In the manhole having the shape of a substantially cylindrical body having an upper end opened, and having a drainage hole penetrating the wall portion in the wall portion of the cylindrical body,
The drainage hole is covered with a net-like coating material from the outside,
The wall portion has an inclined wall portion whose outer diameter gradually increases downward from the upper end side,
The covering material is disposed at least in the region of the inclined wall portion.

  According to this configuration, groundwater can flow into the manhole from the drainage hole and the excess pore water pressure can be dissipated, and earth and sand mixed in the groundwater can flow into the manhole from the drainage hole by the covering material. Can be prevented. In addition, the inclined wall portion can increase the frictional resistance between the ground and the outer wall surface of the manhole to prevent the manhole from rising, and the covering material is disposed at least in the region of the inclined wall portion. The groundwater around the sloping wall can be collected by the covering material and allowed to flow into the drainage hole, and even if the excess pore water pressure rises, the excess gap in the ground around the sloping wall The water pressure can be dissipated and the frictional resistance acting on the inclined wall can be maintained.

  In addition, the inclined wall portion is a portion constituting the wall portion of the manhole, and it is not necessary to separately provide an overhanging body or a floating suppression body that protrudes from the wall portion. It is possible to suppress both the member cost and the construction cost.

The manhole according to claim 2 is:
2. The manhole according to claim 1, wherein the covering material is annular and covers the inclined wall portion in a contact state.

  According to this configuration, the groundwater around the inclined wall can be collected efficiently. Further, the frictional resistance of the inclined wall portion can be further increased to enhance the effect of preventing the manhole from rising.

The manhole according to claim 3 is:
3. The manhole according to claim 1, wherein the wall portion has a groove continuously extending downward from the drain hole on the outer wall surface,
A water permeable material is disposed in the groove.

  According to this configuration, the groundwater around the manhole can be guided to the drainage hole along the groove, the groundwater can be efficiently collected by the permeable material, and the effect of dissipating excess pore water pressure is enhanced. Can do.

The manhole according to claim 4 is:
4. The manhole according to claim 3, wherein the width of the groove becomes narrower from the outer wall surface side toward the inner wall surface side.

  According to this configuration, the water-permeable material can be brought into close contact with the inner surface of the groove by external pressure, and as a result, the groundwater can be efficiently guided along the inner surface of the groove to the drain hole.

The manhole according to claim 5 is:
The manhole according to claim 3 or 4, wherein the groove extends to a lower end of an outer wall surface, and the water-permeable material extends from an upper end to a lower end of the groove.

  According to this configuration, it is possible to suppress an increase in excess pore water pressure generated at the bottom of the manhole, and to reduce buoyancy acting on the bottom. Thereby, the floating prevention effect of a manhole can be improved more.

The manhole according to claim 6 is:
The manhole according to any one of claims 3 to 5, wherein the water-permeable material is a tubular body having a large number of holes formed on a peripheral surface thereof.

  According to this configuration, groundwater can be collected inside the water-permeable material made of a tubular body, and earth and sand mixed in the groundwater can be prevented from flowing into the tubular body. Thereby, it is possible to prevent the earth and sand from entering the manhole from the drainage hole through the groove while collecting groundwater efficiently.

The manhole according to claim 7 is:
The manhole according to any one of claims 1 to 6, wherein a filter member for filtering groundwater is disposed in the drain hole.

  According to this configuration, since the earth and sand mixed in the groundwater that passes through the covering material and enters the manhole from the drain hole is blocked by the filter member, the effect of preventing the intrusion of earth and sand into the manhole is achieved. high.

The manhole according to claim 8 is:
The manhole according to any one of claims 1 to 7, wherein in the covering material, the hole width of the mesh hole is increased from the outer surface side toward the inner surface side which is the wall portion side.

  According to this configuration, when fine earth and sand enter the mesh hole, the earth and sand moves to the inner side of the wide hole and flows into the manhole, thereby preventing clogging of the mesh hole due to earth and sand. be able to.

The manhole according to claim 9 is:
9. The manhole according to claim 1, wherein the inclined wall portion has a substantially truncated cone shape and occupies a range of at least a half of a total length in a vertical direction from an upper end of the manhole. It is characterized by that.

  According to this configuration, the frictional resistance between the ground and the outer wall surface of the manhole can be sufficiently increased to prevent the manhole from being lifted. Further, since the amount of backfilling soil placed on the inclined wall portion can be made relatively large, an effect of preventing lifting due to the load of the backfilling soil can be expected.

The manhole installation structure according to claim 10 is:
The manhole installation structure according to any one of claims 1 to 9, wherein a gravel material layer having a higher water permeability than that of a surrounding ground is provided around the drain hole.

  According to this configuration, when the excess pore water pressure rises, the pore water can be collected inside the gravel material layer to dissipate the excess pore water pressure. In other words, the pore water is discharged from the drainage hole to the inside of the manhole and also to the gravel material layer provided outside the drainage hole, so that the effect of preventing the liquefaction of the ground becomes higher.

  According to the present invention, the excess pore water pressure is dissipated by flowing groundwater from the drainage hole, and the slant wall part and the covering material disposed on the slant wall part are maintained by this dissipative effect. By ensuring the frictional resistance, the effect of preventing the manhole from rising can be enhanced. In addition, by forming a part of the wall portion of the manhole as a slant wall portion having a drain hole and covered with a covering material, the cost required for the anti-floating structure can be suppressed while enhancing the anti-floating effect.

The side view which shows the state which embed | buried the manhole which is embodiment of this invention in the ground. Sectional drawing which follows the II-II line | wire of FIG. FIG. 3 is a conceptual enlarged view of a portion surrounded by III in FIG. 2, and shows a flow of groundwater when excess pore water pressure increases. The side view which shows the state which embed | buried the manhole in other embodiment of this invention in the ground. FIG. 5 is a longitudinal sectional view of the manhole shown in FIG. 4. Sectional drawing which follows the VI-VI line of FIG. The cross-sectional view which follows the VII-VII line of FIG. The principal part enlarged view of FIG. The same side view of FIG. 4 which shows the other example of a coating | covering material. The figure explaining the construction process of a manhole. The figure similar to FIG. 4 which shows other embodiment of a manhole. The figure similar to FIG. 4 which shows other embodiment of a manhole. (A) is a longitudinal cross-sectional view of the manhole shown in FIG. (B) is a longitudinal cross-sectional view of the manhole shown in FIG.

  FIG. 1 is a longitudinal sectional view showing a state where a manhole 10 according to Embodiment 1 of the present invention is buried in the ground. 1 to 13 are schematic diagrams and do not strictly show the dimensions and the like of each component member.

  The manhole 10 includes a main body 12 made of a bottomed cylindrical body and a covering material 15.

  The main body 12 is made of concrete and has a circular opening serving as an entrance to the inside of the main body 12 at the upper end. The opening is closed by a lid 13 so as to be opened and closed. The main body 12 has a bottom portion 21 and a wall portion 22. The bottom portion 21 is a portion serving as a base of the manhole 10 and forms a bottom surface, and the wall portion 22 is formed in a cylindrical shape above the bottom portion 21. The wall portion 22 includes a straight wall portion 23 and an inclined wall portion 24.

  The straight wall portion 23 is a portion extending in a cylindrical shape upward from the bottom portion 21. The straight wall portion 23 is formed with a mounting hole 26 penetrating from the inner wall surface 22b to the outer wall surface 22a. The sewer main pipe 60 is mounted in the mounting hole 26 with its end portion inserted.

  The inclined wall portion 24 is located above the straight wall portion 23, and the outer wall surface 22a is inclined so that the outer diameter gradually increases from the upper end side of the manhole 10 downward. The slanted wall portion 24 has a substantially frustoconical shape, preferably a substantially right truncated cone shape.

  A lid installation portion 24A for installing the lid body 13 is formed at the upper end portion of the inclined wall portion 24 serving as an opening (entrance / exit portion) of the manhole 10. The ratio of the lid installation portion 24A to the total length L1 in the vertical direction of the manhole 10 is small. In the manhole 10 having a total length L1 of about 3 to 5 m, the height dimension (dimension in the vertical direction) of the lid installation portion 24A is About 2 to 20 cm. In the example shown in FIG. 1, the outer peripheral surface of the lid installation portion 24 </ b> A is formed in a substantially cylindrical shape, but may be formed in a substantially truncated cone shape so that the outer diameter gradually increases downward.

  A plurality of drain holes 31 are formed in the straight wall portion 23 and / or the inclined wall portion 24. The drain holes 31 are holes that penetrate from the inner wall surface 22 b to the outer wall surface 22 a, and a plurality of drain holes 31 are formed along the circumferential direction of the wall portion 22. In the embedded state of the manhole 10, the drain hole 31 is located above the groundwater level W at the normal time of the ground. In addition, the number, shape, and position of the drain holes 31 can be set as appropriate. Although not shown, the drain hole 31 may be formed in the inclined wall portion 24 and the straight wall portion 23.

  The covering material 15 is for preventing the inflow of earth and sand 71 and 72 (see FIG. 3) into the manhole 10, and at least the slant wall portion 24 of the slant wall portion 24 so as to cover at least the entire arrangement region of the drain holes 31. Provided in the region. In the example shown in FIG. 1, the drain hole 31 and the covering material 15 are located on the inclined wall portion 24, but the drain hole 31 is located on the straight wall portion 23, and the covering material 15 covers the entire drain hole 31. As described above, the straight wall portion 23 and the inclined wall portion 24 may be disposed. The covering material 15 is a net-like member, has an annular shape so as to surround the wall portion 22, and covers the outer wall surface 22 a of the wall portion 22 in a contact state. In the present embodiment, a wire mesh in which a metal wire is woven in a net shape is used as the covering material 15, but the material is not limited to this, and various materials formed in a net shape, such as a synthetic resin, can be used. .

  As shown in FIG. 3, the mesh hole of the covering material 15 has a hole width that increases from the outer surface 15a side to the inner surface 15b side. In this embodiment, the cross section of the covering material 15 has such a hole width. Is substantially V-shaped.

  In the manhole 10 described above, when the excess pore water pressure of the surrounding ground increases due to the earthquake, groundwater can be flowed into the manhole 10 from the drain hole 31, thereby dissipating the excess pore water pressure and The ground can be prevented from liquefying. As shown by the phantom line in FIG. 2, a removable cap 39 for closing the hole can be attached to the drain hole 31. In addition, the arrow in FIG. 2 has shown the flow of groundwater when the excess pore water pressure rises. The cap 39 is attached to the inner wall surface 22b side of the drain hole 31 so that the closed state is maintained when the groundwater is at a hydrostatic pressure, and the cap 39 is easily removed due to an increase in excess pore water pressure.

  Moreover, the covering material 15 can prevent the earth and sand 71 and 72 from flowing into the manhole 10 from the drain hole 31. Further, as shown in FIG. 3, since the hole width of the covering material 15 is wide on the inner surface 15 a side, when the fine earth and sand 72 enters the mesh hole while preventing the earth and sand 71 and 72 from entering. Can prevent clogging due to the earth and sand 72.

  Furthermore, in the manhole 10 of the present embodiment, the slant wall portion 24 can increase the frictional resistance between the ground and the outer wall surface of the manhole 10 to prevent the manhole 10 from being lifted. The inclined wall portion 24 is provided with the covering material 15, and the covering material 15 covers the drain hole 31, so even if the excess pore water pressure increases, The groundwater in the ground can be collected by the covering material 15 and can flow into the drain hole 31. As a result, the excess pore water pressure in the ground around the inclined wall portion 24 can be dissipated, and the frictional resistance acting on the inclined wall portion 24 can be maintained.

  Further, by covering the outer wall surface 22a of the inclined wall portion 24 with the annular covering material 15, the frictional resistance of the inclined wall portion 24 can be further increased, and the floating prevention effect of the manhole 10 can be enhanced. Further, when the drainage hole 31 is located in the inclined wall portion 24, the groundwater around the inclined wall portion 24 can be more efficiently flowed into the manhole 10. Furthermore, since the outer diameter of the inclined wall portion 24 gradually increases downward, the covering material 15 remains in close contact with the inclined wall portion 24 even when the main body 12 exhibits a floating behavior. Therefore, there is no possibility that the mounting position is shifted.

  In addition, the inclined wall portion 24 having the drainage hole 31 and having a high anti-floating effect is a portion constituting the wall portion 22 of the manhole 10 (that is, a part of the wall portion 22). In order to increase the resistance, there is no need to provide an overhanging body that protrudes rapidly from the wall portion 22. Therefore, it is possible to easily dispose the covering material, and it is possible to suppress the member cost and the construction cost while enhancing the floating prevention effect.

  Next, still another embodiment of the manhole 10 according to the present invention will be described. 4 to 8 show the manhole 10 according to the second embodiment. FIG. 4 is a side view showing a state where the manhole 10 is buried in the ground, and FIG. 5 shows the state shown in FIG. 1 is a longitudinal sectional view of a manhole 10. FIG. In FIG. 4, the description of the joining flange 14 shown in FIG. 5 is omitted. In the second embodiment, parts corresponding to those in the first embodiment are denoted by the same reference numerals, and the details of the same configuration are omitted here.

  In the present embodiment, the manhole 10 includes a main body 12, a lid body 13, a covering material 15, and a water permeable material 35.

  The main body 12 has a bottom portion 21 and a wall portion 22, and the wall portion 22 has a straight wall portion 23 positioned below and an inclined wall portion 24 positioned above.

  The inclined wall portion 24 has an outer wall surface 22a inclined so that the outer diameter gradually increases downward from the upper portion of the manhole 10, and a plurality of substantially truncated cone-shaped cylinders 25A, 25B, 25C having different outer diameters. It is formed by stacking. A joint flange 14 projecting radially outward is formed at a joint part between the cylinders 25A, 25B, 25C and the straight wall part 23 adjacent to each other in the vertical direction, and a sealing material or a necessary fixture (not shown) is formed. ) And are watertightly joined and fixed. A lid installation portion 24 </ b> A for installing the lid body 13 is formed at the upper end portion of the inclined wall portion 24.

  In the manhole 10 shown in FIG. 4, the outer wall surface 22 a of the inclined wall portion 24 has a curved surface shape that protrudes radially outward. Although the inner wall surface 22b of the inclined wall portion 24 may extend in the vertical direction, it is preferable that the inner wall surface 22b is inclined with respect to the vertical direction so that the inner diameter gradually increases downward as shown in FIG. In such a case, a wide internal space of the manhole 10 can be secured. The inner wall surface 22b is more preferably inclined along the outer wall surface 22a so that the wall thickness is substantially constant.

  The inclined wall portion 24 is located at the upper portion of the manhole 10 and occupies a range of at least one half of the total length L1 in the vertical direction of the manhole 10 from the upper end of the manhole 10. In other words, the length dimension (dimension in the vertical direction) L2 of the inclined wall portion 24 is equal to or more than half of the entire length L1 of the manhole 10, and the maximum outer diameter portion of the wall portion 22 (that is, the inclined wall portion 24). The lower end 24B) is located below the intermediate position C or the intermediate position C that bisects the entire length L1 of the manhole 10. Here, the inclined wall portion 24 refers to a portion including both the lid installation portion 24A and a portion where the outer wall surface 22a is inclined so that the outer diameter increases downward from the lower end of the lid installation portion 24A. .

  The wall portion 22 further includes a plurality of drain holes 31 and a groove 32 that continuously extends downward from the drain holes 31.

  As shown in FIGS. 4 and 6, the drain holes 31 are holes that penetrate from the inner wall surface 22 b to the outer wall surface 22 a, and a plurality of drain holes 31 are formed along the circumferential direction in the region of the inclined wall portion 24. A filter member 37 is disposed in the drain hole 31.

  The filter member 37 filters groundwater to separate earth and sand mixed in the groundwater, and prevents the earth and sand from entering the manhole 10. The filter member 37 includes a filter portion 37A that covers the drain hole 31, and a flange portion 37B that surrounds the filter portion 37A. The filter part 37 </ b> A is formed in a convex shape so as to protrude from the flange part 37 </ b> B, and has an outer diameter that is substantially equal to the inner diameter of the drain hole 31 and that can be fitted into the drain hole 31. ing. The filter member 37 is attached to the wall portion 22 by fitting the filter portion 37 </ b> A into the drain hole 31 and bringing the flange portion 35 </ b> B into contact with the outer wall surface 22 a of the inclined wall portion 24. In the present embodiment, a wire mesh is used as the filter member 37, but the material is not limited to this, and it is sufficient that at least the filter portion 35A has a filtering function.

  As shown in FIGS. 4 and 6 to 8, the groove 32 is formed in the outer wall surface 22 a of the wall portion 22, and continuously extends downward from each drain hole 31 along the vertical direction. The groove 32 preferably extends to the lower end of the outer wall surface 22 a of the wall portion 22, and more preferably extends to the bottom portion 21 that is the lower end of the manhole 10. The width of the groove 32 becomes narrower from the outer wall surface 22a side toward the inner wall surface 22b side. In this embodiment, the groove 32 has a substantially V-shaped cross section. In addition, the groove | channel 32 may be extended in the direction which inclines with respect to the up-down direction toward the downward direction from the drain hole 31, as shown by the virtual line in FIG.

  The covering material 15 is provided on the wall portion 22 so as to cover at least the entire arrangement region of the drain holes 31. In the present embodiment, the covering material 15 is provided only on the inclined wall portion 24 of the straight wall portion 23 and the inclined wall portion 24. The mesh hole of the covering material 15 has a hole width that increases from the outer surface 15a side toward the inner surface 15b side (see FIG. 3). In addition, it is preferable that the hole diameter of the filter part 37A mentioned above is smaller than the hole diameter of the mesh hole of the covering material 15 (hole diameter on the inner surface 15a side where the hole width is minimized).

  The water permeable material 35 is a member having a higher water permeability than the ground around the manhole 10 and having a groundwater collecting effect, and is disposed in the groove 32. As the water permeable material 35, for example, a gravel material or a tubular body having a large number of holes formed on the peripheral surface can be used. In the present embodiment, a drain pipe that is a porous tubular body is used as the water permeable material 35, and the drain pipe extends from the upper end to the lower end of the groove 32. When a gravel material is used as the water permeable material 35, it may be disposed inside and around the groove 32 so as to extend in the vertical direction along the groove 32.

  As shown in FIGS. 4 and 5, a gravel material layer 62 is provided around the drain hole 31 when the manhole 10 is buried. The gravel material layer 62 is a layer filled with gravel material so as to have higher water permeability than the lower layer region, and is located above the groundwater level W at the normal time.

  The manhole 10 of the present embodiment has the effects described in the first embodiment, has the grooves 32 and the water permeable material 35, and the inclined wall portion 24 occupies a relatively large proportion, so that the manhole 10 floats. The prevention effect can be further enhanced.

  Specifically, the proportion of the inclined wall portion 24 is more than half of the total length L1 of the manhole 10 and is larger than that of the conventional manhole. In the inclined wall portion 24, the frictional resistance between the ground and the outer wall surface 22 a becomes larger than that of the straight wall portion 23 due to the load of the backfill soil placed on the wall surface. Therefore, by increasing the ratio of the inclined wall portion 24, the frictional resistance between the ground and the outer wall surface 22a of the manhole 10 can be increased as compared with the conventional manhole, and the manhole 10 can be prevented from being lifted. Furthermore, since the amount of backfilling soil placed on the inclined wall portion 24 can be made relatively large, the effect of preventing lifting due to the load of the backfilling soil is enhanced.

  In order to enhance the floating prevention effect, it is preferable that the maximum outer diameter portion of the wall portion 22 (the lower end 24B of the inclined wall portion 24) is located below the intermediate position C. It is more preferable to occupy a range of two-thirds or more of the total length L1.

  Moreover, by making the inclined wall portion 24 into a substantially truncated cone-like cylinder, it is possible to increase the frictional resistance over the entire circumferential direction. Furthermore, by making the inclined wall portion 24 into a substantially right truncated cone shape, the frictional force between the ground and the outer wall surface 22a of the manhole 10 can be made to act substantially uniformly over the circumferential direction of the manhole 10, and the manhole Ten local lifts can be prevented.

  Further, by making the outer wall surface 22a of the inclined wall portion 24 curved so as to protrude radially outward, the outer wall surface 22a of the inclined wall portion 24 in a longitudinal section is straight toward the lower end 24B of the inclined wall portion 24. Compared with the one extending in a shape (the one with a substantially constant expansion rate of the outer diameter of the inclined wall portion 24), the area of the outer wall surface 22a can be increased to increase the frictional resistance with the ground. Furthermore, the durability against external pressure can be enhanced by using such a curved surface. Further, by bending the outer wall surface 22a radially outward, the inner wall surface 22b can be bent radially outward while ensuring the required wall thickness, and the internal space of the manhole 10 can be widened.

  Furthermore, in the manhole 10 of the present embodiment, by forming a groove 32 extending downward from the drain hole 31 in the outer wall surface 22a of the wall portion 22, groundwater can be guided to the drain hole 31 along the groove 32. Further, not only the ground around the drain hole 31 but also the ground around the inclined wall portion 24 positioned below the drain hole 31 can suppress an increase in excess pore water pressure and prevent liquefaction. Furthermore, by arranging the water permeable material 35 in the groove 32, the groundwater can be collected efficiently, and the groundwater can be guided to the drain hole 31 while preventing the intrusion of earth and sand into the groove 32. Further, by providing the groove 32 and the water permeable material 35 having such a water collecting effect on the outer wall surface 22a of the manhole 10, compared to the case where the water collecting pipe is disposed at a position away from the outer wall surface 22a, Excess pore water pressure acting on the outer wall surface 22a can be efficiently dissipated.

  As described above, a detachable cap 39 for closing the hole can be attached to the drain hole 31 (see FIG. 6).

  As shown in FIG. 4, when the groove 32 and the water permeable material 35 extend from the drain hole 31 to the lower end of the manhole 10, the pore water around the bottom 21 is collected and allowed to flow into the manhole 10. be able to. Thereby, it is possible to suppress the increase in the pore water pressure that occurs immediately below the manhole 10 and suppress the buoyancy acting on the bottom 21. In addition, as shown by phantom lines in FIG. 4, when the groove 32 and the water permeable material 35 extend while being inclined with respect to the vertical direction, the water collection effect is enhanced, the outer peripheral surface of the manhole 10 and the surrounding ground It is possible to increase the frictional resistance between the two and increase the anti-floating effect.

  Furthermore, in the manhole 10 of this embodiment, it is possible to prevent soil and sand from flowing into the manhole 10 from the drain hole 31 by both the covering material 15 and the filter member 37. As shown in FIG. 9, the covering material 15 may be disposed not only on the inclined wall portion 24 but also on the straight wall portion 23. Thus, by providing the covering material 15 in a wide range, it is possible to prevent earth and sand from entering the grooves 32 and the water permeable material 35. The earth and sand deposited on the inner surface of the drain hole 31 and the filter member 37 can be removed, for example, by jetting a high-pressure water flow from the inside of the drain hole 31 to the outside.

  Furthermore, by providing the gravel layer 62 around the drain hole 31, when the excess pore water pressure rises, the pore water can be discharged into the manhole 10 and to the surrounding gravel layer 62. it can. Thereby, while being able to increase the discharge | emission amount of pore water, an excess pore water pressure can be dissipated quickly and the effect which prevents the liquefaction of the ground becomes high.

  Next, a construction method of the manhole 10 shown in FIG. 4 will be described with reference to FIG.

  First, as shown in FIG. 10A, a shaft for burying the manhole 10 is dug and installed with the bottom portion 21 and the straight wall portion 23 of the manhole 10. The bottom portion 21 and the straight wall portion 22 may be separate or integrated. In the case of separate bodies, the bottom 21 and the straight wall 22 are joined so that the joint is watertight. Thereafter, the sewer main 60 is attached to the attachment hole 26 of the straight wall portion 23.

  Next, as shown in FIG. 10B, the cylindrical body 25A, which is a part of the inclined wall portion 24, is stacked on the straight wall portion 23, and the joining flange 14 of the straight wall portion 23 and the cylindrical body 25A (see FIG. 5). The straight wall portion 23 and the cylindrical body 25A are joined and fixed to each other using a necessary fixture or sealing material. Thereafter, the water permeable material 35 is disposed in the groove 32 formed in the straight wall portion 23 and the cylindrical body 25 </ b> A, and the periphery of the wall portion 22 is backfilled.

  As shown in FIG. 10 (c), a cylinder 25B having an outer diameter smaller than the cylinder 25A is stacked above the cylinder 25A, and the joining flanges 14 of the cylinders 25A and 25B are joined and fixed in a watertight manner. A water-permeable material 35 is disposed on the outer wall surface 22a of the cylinder 25B in which the drain holes 31 are formed, and then the covering material 15 is attached. Further, the surrounding area is filled with gravel as backfill soil.

  As shown in FIG. 10D, a cylindrical body 25C having a lid installation portion 24A is loaded on the uppermost portion of the manhole 10, and is joined and fixed to the lower cylindrical body 25B. Thereafter, the surroundings are backfilled, and the lid 13 is attached to the lid installation portion 24A.

  Thus, by forming the inclined wall portion 24 by stacking the plurality of divided cylinders 25A, 25B, and 25C, it is not necessary to perform the concrete placement at the installation site to form the inclined wall portion 24, which is a large-scale. The manhole 10 can be easily installed on site without using construction equipment. In addition, it is preferable that the backfilling soil mounted on the inclined wall portion 24 is an improved soil that forms a non-liquefied layer.

  11 and 12 are views similar to FIG. 4 showing another embodiment of the manhole 10 according to the present invention, respectively, and FIG. 13A is a longitudinal sectional view of the manhole shown in FIG. 13 (b) is a longitudinal sectional view of the manhole shown in FIG. 11 to 13, the same reference numerals are given to the portions corresponding to the installation structure of the manhole 10 shown in the second embodiment.

  In the manhole 10 according to the third embodiment shown in FIGS. 11 and 13A, the inclined wall portion 24 has a substantially right truncated cone shape, and the diameter expansion rate of the outer diameter of the inclined wall portion 24 is substantially constant. Further, the outer wall surface 22a of the inclined wall portion 24 extends linearly in the longitudinal section. The inclined wall portion 24 may have an eccentric truncated cone shape. By forming the inclined wall portion 24 in this manner, the load of the backfilling soil acting on the inclined wall portion 24 is increased as compared with the case where the inclined wall portion 24 has a curved surface that protrudes radially outward. Can be suppressed.

  In the manhole 10 according to the fourth embodiment shown in FIGS. 12 and 13B, the wall portion 22 is formed in a substantially oval shape. The wall portion 22 includes a straight wall portion 23, an inclined wall portion 24, and a reduced diameter inclined wall portion 27. In the reduced diameter inclined wall portion 27, the outer diameter gradually decreases from the upper side to the lower side. Thus, the outer wall surface 22a is inclined. The reduced diameter inclined wall portion 27 is located below the inclined wall portion 24 and above and / or below the straight wall portion 23 where the sewer main pipe 60 is disposed. In such a substantially egg-shaped manhole 10, the internal space above the manhole 10 can be widened and a sufficient working space can be secured as compared with the third embodiment. Furthermore, by providing the wall portion 22 with the diameter-reduced inclined wall portion 27, an increase in the volume of the main body 12 can be suppressed, and the buoyancy acting on the manhole 10 can be reduced, or the member cost can be reduced. As described above, the inclined wall portion 24 is formed by stacking a plurality of cylinders 25A, 25B, and 25C. In the present embodiment, the cylinders 25A, 25B, and 25C are formed in a substantially right cone shape, In addition, by changing the diameter expansion rate for each of the cylinders 25A, 25B, and 25C, the wall portion 22 has an outer shape close to a spherical shape such as an egg shape.

  In the embodiment shown in FIG. 11 and FIG. 12, the length dimension L2 of the inclined wall portion 24 is at least half of the entire length L1 of the manhole 10, and the maximum outer diameter portion of the wall portion 22 (an oblique angle). The lower end 24B) of the wall portion 24 is located below the intermediate position C or the intermediate position C that bisects the entire length L1 of the manhole 10, and the ratio of the inclined wall portion 24 is larger than that of the conventional manhole. It has become. By increasing the ratio of the inclined wall portion 24 in this way, it is possible to always suppress the manhole lifting behavior by the shape of the wall portion 22 without separately providing an overhanging body or the like that protrudes from the wall portion 22. It becomes possible. As shown in the second, third, and fourth embodiments, the shape of the wall portion 22, particularly the shape of the inclined wall portion 24, depends on the ground and the outer wall surface 22 a depending on the surrounding ground state, the type of backfill soil, and the like. The frictional resistance between them can be appropriately selected.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the invention. For example, in the manhole 10 shown in FIGS. 11 and 12, the covering material 15 may be disposed almost all over the inclined wall portion 24. In such a case, the frictional resistance between the manhole 10 and the ground may be further increased. it can.

DESCRIPTION OF SYMBOLS 10 Manhole 12 Main body 13 Cover body 15 Cover material 22 Wall part 22a Outer wall surface 22b Inner wall surface 23 Straight wall part 24 Slanted wall part 31 Drain hole 32 Groove 35 Water permeable material 37 Filter member 62 Gravel material layer

Claims (10)

In the manhole having the shape of a substantially cylindrical body having an upper end opened, and having a drainage hole penetrating the wall portion in the wall portion of the cylindrical body,
The drainage hole is covered with a net-like coating material from the outside,
The wall portion has an inclined wall portion whose outer diameter gradually increases downward from the upper end side,
The manhole, wherein the covering material is disposed at least in the region of the inclined wall portion.   The manhole according to claim 1, wherein the covering material is annular and covers the inclined wall portion in a contact state. The wall portion has a groove extending continuously downward from the drain hole on the outer wall surface,
The manhole according to claim 1, wherein a water-permeable material is disposed in the groove.   The manhole according to claim 3, wherein the width of the groove becomes narrower from the outer wall surface side toward the inner wall surface side.   5. The manhole floating prevention structure according to claim 3, wherein the groove extends to a lower end of an outer wall surface, and the water-permeable material extends from an upper end to a lower end of the groove.   The manhole according to any one of claims 3 to 5, wherein the water-permeable material is a tubular body having a large number of holes formed on a peripheral surface thereof.   The manhole according to claim 1, wherein a filter member that filters groundwater is disposed in the drain hole.   The manhole according to any one of claims 1 to 7, wherein in the covering material, a hole width of the mesh hole is increased from an outer surface side toward an inner surface side which is the wall portion side.   9. The oblique wall according to any one of claims 1 to 8, wherein the inclined wall portion has a substantially truncated cone shape and occupies a range of at least a half of a total length in a vertical direction from an upper end of the manhole. The listed manhole. The manhole installation structure according to any one of claims 1 to 9,
A manhole installation structure, wherein a gravel material layer having a higher water permeability than the surrounding ground is provided around the drain hole.

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