JP5612186B1 - Buried structure - Google Patents

Abstract

An object of the present invention is to provide an embedded structure capable of changing a gradient angle. An embedded structure (side groove) 100 that is embedded in a road surface R and forms a drainage channel for draining rainwater and the like from the road surface R, and a main body portion 120 having a water collection space 110 therein, and a main body portion And a base portion 130 provided with an installation surface 131 for installing 120, the bottom wall 121 of the main body 120 has an arc shape, and the installation surface 131 has a shape corresponding to the bottom wall 121. It is characterized by. [Selection] Figure 4

Description

  The present invention relates to a buried road structure such as a road having a slope, a side ditch buried so as to cross a road surface such as a forest road, and a catchment.

  On sloped roads and forest roads, buried structures such as gutters and catchment basins are buried so as to cross the road surface. This gutter collects rainwater and the like from the road surface and drains it to a catchment connected to the gutter. However, there are many cases where the gutters and catchment basins are installed horizontally, and the change in gradient is discontinuous between the gutters and catchment basin and the road surface having a gradient around it. Therefore, when a vehicle or the like traveling on the road crosses a side ditch or a catchment, there is a problem that a discontinuous gradient change is picked up and an impact is transmitted to passengers and cargo. Moreover, the buried structure was also damaged by the impact.

  In order to solve this problem, an embedded structure that can be installed at an inclination at an installation site so as to coincide with the gradient of the road surface to be embedded is known. As such an embedded structure, for example, a gutter in Patent Document 1 is known. This side groove is composed of a side groove body and a foundation block.The side groove body is a general U-shaped side groove with a flat bottom wall, and the foundation block has an installation surface for installing the bottom wall of the side groove body. I have. And since this installation surface inclines according to a road surface gradient, if a side groove main body is installed in this installation surface, the upper end surface of a side groove main body will be located on the same plane as a road surface. In addition, by adopting a structure similar to the above-mentioned side groove in the catchment basin, even if the road surface has a slope, the upper end surface of the catchment basin and the road surface are located on the same plane.

  However, the foundation block of the side groove is formed by casting concrete or the like into a mold designed so that its installation surface is inclined. Therefore, when the slope of the installation surface is different from the actual road surface slope of the installation site, the upper end surface of the installed gutter and the road surface are not located on the same plane, and there is a step between the road surface. End up. Further, when it is desired to manufacture a basic block having a different gradient, a mold having a modified design of the gradient must be prepared separately, which increases the manufacturing cost.

Japanese Patent Application No. 2004-272574

  Therefore, an object of the present invention is to provide an embedded structure in which the gradient angle can be freely changed.

  In order to solve the above problems, an embedded structure of the present invention is an embedded structure that is embedded in a road surface and forms a drainage channel that drains rainwater and the like from the road surface, and has a water collecting space inside. And a base portion provided with an installation surface for installing the main body, the bottom wall of the main body has an arc shape, and the installation surface has a shape corresponding to the bottom wall. It is characterized by that.

  According to the above feature, the bottom wall of the main body portion has an arc shape, and the installation surface of the base portion has a shape corresponding to the bottom wall, so if the main body portion is installed on the base portion, the main body portion is It can be tilted freely on the mounting surface of the foundation. That is, the inclination angle of the main body can be freely changed in accordance with the slope of the road surface at the installation site, and no step is produced between the road surface. Further, unlike the conventional case, the design change of the base portion is not forced according to the gradient.

  The “arc-shaped” bottom wall is not only a circular arc-shaped bottom wall having a smooth surface as shown in FIG. 1, but also a substantially arc-shaped surface having a plurality of flat surfaces as shown in FIG. Including the bottom wall.

  Next, in the buried structure of the present invention, a through hole through which the fixing member can penetrate is provided in the bottom wall of the main body, and a fixing hole through which the tip of the fixing member can be fixed is provided in the installation surface. It is characterized by that.

  According to the above feature, since the main body portion and the base portion are fixed to each other by the fixing member, it is easy to maintain the position and orientation of the inclined main body portion.

  Next, in the embedded structure of the present invention, a body part side recess is provided on the bottom wall surface of the body part, and the mounting surface of the base part is at a position facing the body part side recess. The base portion side recess is provided.

  According to the above feature, when the main body portion is installed on the base portion, a space is formed between the main body portion-side indented portion and the base portion-side indented portion at the opposite position due to the mutual indentations. . And if concrete etc. are poured into the space, each hollow part will be filled with the solid concrete. After that, the solidified concrete becomes a fixing member that prevents the relative positions of the indented portions from shifting, and the main body portion is prevented from tilting (turning) on the installation surface. The position and orientation are fixed.

Next, the embedded structure according to the present invention is characterized in that irregularities are provided on the bottom surface of the main body portion side recess portion and the base portion side recess portion.

  According to the above feature, since the unevenness is provided on the bottom surface of the main body side recess and the base side recess, if concrete or the like is poured into the space formed by both recesses, the concrete enters the unevenness and hardens. As a result, the position and orientation of the main body is more firmly fixed.

  As described above, according to the buried structure of the present invention, the gradient angle can be freely changed.

It is the perspective view which showed the state which embed | buried the side groove which is an embedment structure of this invention, and a water catchment in the road surface. The main-body part of the side groove | channel which is an embedded structure of this invention is shown, (a) is a perspective view of a main-body part, (b) is a top view, (c) is a side view, (d) is a bottom view. . The base part of the gutter which is an embedded structure of this invention is shown, (a) is a perspective view of a base part, (b) is a top view, (c) is a side view. (A) And (b) is the side view which showed the state which embed | buried the side groove which is an embedment structure of this invention in the road surface. The modification (1) of the side groove | channel of this invention is shown, (a) is a perspective view of the main-body part of a side groove, (b) is AA sectional drawing. The modification (1) of the side groove | channel of this invention is shown, (a) is a perspective view of the base part of a side groove, (b) is BB sectional drawing. The modification (1) of the side groove | channel of this invention is shown, (a) And (b) is the perspective view which combined the base part and main-body part of the side groove | channel. (A) is CC sectional drawing in FIG.7 (b), (b) is sectional drawing which inclined the base part. The modification (2) of the side groove | channel of this invention is shown, (a) And (b) is the figure which combined the base part and main-body part of the side groove | channel. (A) is a side view showing a modification (3) of the side groove of the present invention, (b) is a plan view thereof, and (c) is a side view showing a modification (4) of the side groove of the present invention. It is. (A) And (b) is the side view which showed the modification (5) of the side groove | channel of this invention. The modification (6) of the side groove | channel of this invention is shown, (a) is a side view of a main-body part, (b) is a top view, (c) is FF sectional drawing in FIG.12 (b). . FIG. 12 shows a side groove in which the main body part according to the modification (6) shown in FIG. 12 is installed on the base part, (a) is a side view of the side groove, (b) is a plan view, and (c) is It is GG sectional drawing in FIG.13 (b), Comprising: It is an enlarged view of a through-hole vicinity. (A) is a figure which shows the state which inclined the main-body part in GG sectional drawing in FIG.13 (b). (B) is a state in which the main body is rotated 180 degrees in the horizontal direction and installed on the base portion, and is a longitudinal sectional view at the center of the through hole, and (c) is the main body from the state of FIG. It is a longitudinal cross-sectional view which shows the state which inclined the part. The main part of the catchment basin which is an embedded structure of the present invention is shown, (a) is a perspective view of the main part, (b) is a plan view, (c) is a side view, and (d) is a bottom view. It is. (A) And (b) shows the base part of the catchment basin which is an embedded structure of this invention, (a) is a top view, (b) is a side view. (C) And (d) is the side view which showed the state which embed | buried the water catchment which is an embedment structure of this invention in the road surface. The modification (1) of the catchment of this invention is shown, (a) is a perspective view of the main-body part of a catchment, and (b) is DD sectional drawing. The modification (1) of the catchment of this invention is shown, (a) is the perspective view which combined the base part and main-body part of the catchment, and (b) is EE sectional drawing. (A) is a side view showing a modification (2) of the catchment basin of the present invention, (b) is a side view showing a modification (3) of the catchment basin of the present invention, and (c) is the invention of the present application. The side view which showed the modification (4) of this water catchment, (d) is the side view which showed the modification (5) of the catchment of this invention. The modification (6) of the catchment basin of this invention is shown, (a) is a side view, (b) is a top view.

100 Side groove 110 Catchment space 120 Body part 121 Bottom wall 130 Base part 131 Installation surface
R road surface

Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 shows a state in which a gutter 100 and a drainage basin 200 that are buried structures are buried in the road surface R. In the drawings, a part of the road surface R (the front side in the drawing) is removed in order to make it easy to understand the installation state of the gutter 100 and the catchment basin 200.

  The upper end of the side groove 100 is located on the same plane as the road surface R, and rainwater from the road surface R can be collected into the internal water collection space 110 via a grating fitted into the upper end. The catchment basin 200 is disposed adjacent to the side groove 100, and rainwater collected in the catchment space 110 of the side groove 100 is transferred to the catchment space (空間) inside the main body 220. Collecting. Then, the rainwater collected in the water collection space inside the water collecting basin 200 is drained to a river or the like via, for example, another gutter 100 connected to the water collecting basin 200 or a drain pipe (not shown). . In this manner, the side groove 100 and the water collecting basin 200 are embedded in the road surface to form a drainage channel that drains rainwater and the like from the road surface.

  The side groove 100 is roughly composed of a main body portion 120 and a base portion 130. The base portion 130 is installed substantially horizontally in a hole formed by digging down the road surface R, and the main body portion 120 is installed inclined on the installation surface 131. This inclination is appropriately adjusted at the installation site so as to coincide with the gradient of the road surface R. Therefore, no matter what gradient the road surface R has, if the inclination of the main body 120 is changed, the upper end of the main body 120 and the road surface R become the same plane, and no step is generated.

  On the other hand, the catchment basin 200 has basically the same configuration as the side groove 100 and includes a main body 220 and a base 230. The base part 230 is embedded substantially horizontally, and the main body part 220 is inclined and installed thereon. This inclination can be appropriately adjusted at the installation site in accordance with the gradient of the road surface R, and the upper end of the main body 220 and the road surface R are in the same plane, so that no step is generated between the road surface R and the road surface R. Further, no step is generated on the upper end surface of the adjacent side groove 100. Therefore, since the buried structure composed of the gutter 100 and the water collecting basin 200 can be installed so as to correspond to the gradient of the road surface R, there is no step between the road surface R and rainwater from the road surface R. Etc. can also be collected efficiently.

In addition, the main-body part 120 and the base part 130 of the gutter 100, and the main-body part 220 and the base part 230 of the catchment 200 are formed by pouring concrete into a formwork corresponding to each shape.

<About gutter>
Hereinafter, the structure of the side groove 100 will be described in more detail.

  First, the structure of the main body 120 of the side groove 100 will be described. As shown in FIG. 2, the main body 120 of the side groove 100 includes an arc-shaped bottom wall 121 and flat side walls 122 connected to both ends thereof in the vertical direction. And the main-body part 120 becomes the substantially U shape extended in the longitudinal direction by these three wall parts, and forms the water collection space 110 which can flow rainwater etc. in the U shape inside. The outer surface of the bottom wall 121 has an arc shape with a radius R1. A step portion is formed inside the upper end 123, and a grating or the like can be placed thereon.

Next, the structure of the base part 130 of the gutter 100 will be described. As shown in FIG. 3, the base portion 130 of the lateral groove 100 has a substantially rectangular parallelepiped shape with the center cut into an arc shape. The length of the base portion 130 in the vertical direction (longitudinal direction) matches the length of the main body portion 120 in the vertical direction (longitudinal direction). Further, the lateral width of the base portion 130 is wider than the lateral width of the main body portion 120.

A step portion 134 is formed at the upper end 133 of the side wall 132 at both ends of the base portion 130, and an installation surface 131 is formed at the center of the base portion 130. The installation surface 131 is continuous with the inner end portion 135 of the step portion 134 and is provided at a position lower than the step portion 134.

Further, the installation surface 131 has an arc shape with a radius R 2 equal to the radius R 1 of the bottom wall 121, and has a shape corresponding to the bottom wall 121. Therefore, if the bottom wall 121 of the main body 120 is placed on the installation surface 131, the main body 120 can be tilted (rotated) left and right on the surface of the installation surface 131.

The radius R2 is preferably equal to the radius R1, but the radius R2 may be set to be equal to or greater than the radius R1. That is, the “shape corresponding to the bottom wall” of the installation surface 131 means a shape that is substantially similar to the shape of the bottom wall 121 and that allows the main body 120 to be tilted left and right.

  Next, referring to FIG. 4, a mode in which the side groove 100 is embedded and installed in the road surface when the road surface R does not have a slope and when the road surface R has a slope will be described.

  First, FIG. 4A shows a case where the road surface R has no gradient (the road surface R is substantially horizontal). As a procedure for installing the gutter 100, first, a hole is dug in the road surface R, and the base portion 130 is installed substantially horizontally there. And the main-body part 120 is installed on the installation surface 131 so that the upper end surface of the main-body part 120 may become substantially horizontal.

  In this installed state, the step portion 134 forms a frame with the upper ends 133 and the side walls 122 on both sides thereof. And if concrete F is poured into this step part 134 as a fixing material, the concrete F will accumulate in a frame, and will harden soon. Then, the main body 120 is fixed to the outside of the both side walls 122 by the concrete F, and cannot be inclined from that state. As a result, the posture of the main body 120 is fixed.

Thereafter, the soil dug up around the main body 120 and the base 130 is backfilled until the upper end surface on which the grating G of the main body 120 is placed and the road surface R are flush with each other.

  The fixing material is not limited to concrete F, and may be any material that becomes liquid during construction and solidifies after construction, such as asphalt.

  Next, FIG. 4B illustrates a case where the road surface R has a gradient. The installation procedure is basically the same as that shown in FIG. 4A, but differs in that the main body 120 is tilted in accordance with the gradient of the road surface R after the main body 120 is installed on the installation surface 131. Then, the concrete F is poured into the stepped portion 134 in a state where the main body portion 120 is inclined as shown in FIG. Thereafter, the concrete F is solidified, so that the posture of the inclined main body 120 is also fixed.

  Here, since the main body portion 120 is inclined toward the right side in the drawing, the weight of the main body portion 120 is set on the right side wall 122 of the main body portion 120 and the contact surface P at the upper right end of the base portion 130. It becomes easier to apply a larger load. However, the concrete F is damaged by the force received from the contact surface P and does not reach the foundation portion 130 itself. Therefore, even if it is damaged by the force received from the contact surface P, it is only necessary to pour new concrete F into the stepped portion 134 and repair it, so that it is not necessary to replace the entire base portion 130, and maintenance costs can be reduced. it can.

  Further, if the upper end 133 of the base portion 130 is extended upward to deepen the step portion 134, the concrete F poured into the step portion 134 can be fixed up to the upper side of the side wall 122, so that the posture of the main body portion 120 is further fixed. It becomes easy.

In addition, since the posture of the tilted main body 120 can be maintained and fixed by the friction between the surface of the bottom wall 121 and the surface of the installation surface 131, the step 134 is used to fix the posture of the main body 120. Not required. However, when the auxiliary body is used to fix the posture of the main body 120 or when the base portion 130 is prevented from being damaged, the step portion 134 is arbitrarily provided and the concrete F is poured. Good.

(Modification 1)
Below, the side groove | channel 300 which is a modification of the side groove | channel 100 of this invention is demonstrated. The side groove 300 includes a main body portion 320 and a base portion 330. FIG. 5 illustrates the configuration of the main body portion 320, and FIG. 6 illustrates the configuration of the base portion 330. In addition, description is abbreviate | omitted about the structure which is common with the side groove | channel 100. FIG.

  As shown in FIG. 5, the main body 320 is provided with a total of four indentations (main body indentations) 324 on the surface of the bottom wall 321. The indented portion 324 is provided on the side of the bottom wall 321, and the end of the indented portion 324 is continuous with the side wall 322. Furthermore, unevenness is provided on the bottom surface 325 of the recessed portion 324. Note that the position, size, and number of the recessed portions 324 may be arbitrarily changed as long as the surface of the bottom wall 321.

  Next, in the base portion 330 shown in FIG. 6, a total of four recess portions (base portion side recess portions) 335 are provided on the installation surface 331. Each indentation 335 is provided at each end of the installation surface 331 at a position opposite to each indentation 324 shown in FIG. The upper end of the recessed portion 335 is continuous with the inner end portion 337 of the step portion 334, and the bottom surface 336 is provided with irregularities. Note that the position, size, and number of the recessed portions 335 may be changed according to the recessed portions 324 of the main body 320 shown in FIG.

  Next, in FIG. 7, a side groove 300 in which the main body portion 320 shown in FIG. 5 and the base portion 330 shown in FIG. 6 are combined will be described.

  In FIG. 7A, the main body 320 is installed on the installation surface 331 of the base unit 330. Since the installation surface 331 has a shape corresponding to the arcuate bottom wall 321, the main body 320 can be inclined on the installation surface 331.

Next, as shown in FIG. 7B, concrete F is poured into the step portion 334. Then, the concrete F flows downward between the indented portion 324 and the indented portion 335 at a position facing the indented portion 324. FIG. 8 is a cross-sectional view taken along the line C-C in order to make it easy to understand how the concrete F flows between the recessed portion 324 and the recessed portion 335.

  As shown in FIG. 8A, since the indented portion 324 and the indented portion 335 are in a positional relationship facing each other, a space S is formed between them. And since the upper end of the hollow part 335 is continuing with the edge part 337 of the step part 334, the concrete F poured into the step part 334 flows into the whole space S via the upper end of the hollow part 335. Become.

In this way, by providing a recessed portion on each of the bottom wall 321 and the installation surface 331 that are the contact surfaces of the main body portion 320 and the base portion 330, the concrete F enters the recessed portion and is solidified. Fix the posture. That is, the solidified concrete F is inserted so as to straddle both indentations, and functions as a fixing member that fixes the relative position of each indentation. The fixing member in the indented portion prevents the main body 320 from tilting (turning) on the installation surface 331, and as a result, the posture of the main body 320 is fixed.

  Further, by providing irregularities on the bottom surface 325 of the indented portion 324 and irregularities on the bottom surface 336 of the indented portion 335, the concrete F that has flowed into the unevenness and solidified, and the position and orientation of the main body 320 are more firmly fixed. Is done.

  Next, FIG. 8B shows a state in which the main body 320 is installed inclined. Even if the main body 320 is inclined on the installation surface 331, the space S between the recess 324 and the recess 335 is secured, and the upper end of the recess 335 is continuous with the end 337 of the step 334. Yes. Therefore, the concrete F poured into the stepped portion 334 flows into the space S via the upper end of the recessed portion 335. And the state in which the main-body part 320 was inclined is fixed because the concrete F hardens | cures.

  In the present modification, the upper end of the indented portion 335 is continuous with the stepped portion 334, so that the concrete F poured into the stepped portion 334 flows into the space S through the upper end of the indented portion 335. However, when the stepped portion 334 is not provided, the concrete F can be poured into the space S from the upper end of at least one of the recessed portion 324 and the recessed portion 335 as long as the upper end communicates with the outside.

  In addition, the recessed portion 335 is provided at both ends of the installation surface 331, and the upper end of the recessed portion 335 communicates with the step portion 324 or the outside. Therefore, even if the main body 320 is inclined at any angle, the concrete F can be poured into the space S from the upper end of the recess 335.

(Modification 2)
Next, in FIG. 9A, a modified example in which the position of the indented portion is changed will be described. In addition, description is abbreviate | omitted about the structure which is common with the side groove | channel 100. FIG. The body portion 420 of the side groove 400 is provided with a recessed portion 424 near the center of the bottom wall 421. On the other hand, the base portion 430 is provided at a position facing the indented portion 424 and in the vicinity of the center of the installation surface 431.

  Actually, when the main body 420 is installed on the base 430, the concave portion 435 of the base 430 is filled with a large amount of concrete F (for example, overflowing from the concave portion 435), and from above The bottom wall 421 of the main body 420 is placed. Then, the space S formed between the indented part 424 and the indented part 435 is filled with the concrete F, and the posture of the main body 420 is fixed by the concrete F solidifying.

  Moreover, in FIG.9 (b), the main-body part 420 is made to incline before the concrete F hardens | cures from the state of Fig.9 (a). Even if the main body 420 is inclined as shown in FIG. 9B, the space S is secured between the recessed portion 424 and the recessed portion 435, so that the concrete F filled in the space S is solidified. The posture of the inclined main body 420 is fixed.

(Modification 3)
Next, in FIGS. 10 (a) and 10 (b), a modified example using means for fixing the main body part by means other than the recessed part will be described. In addition, in FIG. 10, you may use a hollow part together. The description of the configuration common to the side groove 100 is omitted.

  As shown in FIGS. 10A and 10B, the main body 520A is provided with a through hole 524A near the center of the bottom wall 521A. On the other hand, in the base portion 530A, a protrusion 535A is formed to protrude in the vicinity of the center of the installation surface 531A. When the main body portion 520A is placed on the installation surface 531A of the base portion 530A, the protrusion 535A is inserted into the through hole 524A. Since the through hole 524A is wider than the protrusion 535A, spaces S are secured on both sides of the protrusion 535A.

Therefore, even when the protrusion 535A is inserted into the through hole 524A, the main body 520A can be tilted left and right within the space S, that is, until the protrusion 535A contacts the end of the through hole 524A. And after inclining the main-body part 520A to arbitrary angles, the concrete F is poured into the space S inside the through-hole 524A from the water collection space 510A side, and the posture of the main-body part 520A is fixed by the concrete F solidifying. The

(Modification 4)
Next, in FIG. 10C, a modified example in which a groove 535B is provided instead of the protrusion 535A shown in FIGS. 10A and 10B will be described. In addition, description is abbreviate | omitted about the structure which is common with the side groove | channel 100. FIG.

The groove 535B is provided near the center of the installation surface 531B, and is located at a position facing the through hole 524B. And after mounting the main-body part 520B on the installation surface 531B and inclining the main-body part 520B to arbitrary angles, the concrete F is poured into the through-hole 524B from the water collection space 510B. Then, the concrete F is filled in the groove 535B and the through hole 524B, and the concrete F is solidified, so that the posture of the main body 520B is fixed.

(Modification 5)
Next, in FIG. 11, a modified example in which the shape of the surface of the bottom wall of the main body part and the surface of the installation surface of the base part is changed will be described. In addition, description is abbreviate | omitted about the structure which is common with the side groove | channel 100. FIG.

As shown in FIG. 11A, a plurality of flat surfaces 624A are continuously provided on the surface of the bottom wall 621A of the main body 620A. On the other hand, a plurality of flat surfaces 635A are continuously provided on the surface of the installation surface 631A of the base portion 630A. The width L1 of the plane 624A is equal to the width L1 of the plane 635A, and when the bottom wall 621A is placed on the installation surface 631A, the surfaces of the planes 624A and 635A coincide.

Therefore, even if the main body 620A is inclined at an arbitrary angle, the inclined posture of the main body 620A is maintained by matching the flat surfaces 624A and the flat surfaces 635A. Further, the range of the plane 635A can be changed as appropriate within the range in which the main body 620A is inclined according to the gradient of the road surface R.

  Next, in FIG. 11B, the width L2 of the plane 624B and the plane 635B is made wider than the width L1 of the plane 624A. Thus, the widths of the plane 624B and the plane 635B can be arbitrarily changed. Note that indentations shown in FIG. 8 or FIG. 9 may be formed in the plane 624B and the plane 635B.

(Modification 6)
Below, the side groove | channel 1000 which is a modification of the side groove | channel 100 of this invention is demonstrated. The side groove 1000 includes a main body portion 1200 and a base portion 1300. FIG. 12 illustrates the configuration of the main body portion 1200, and FIG. 13 illustrates the configuration of the side groove 1000 in which the main body portion 1200 and the base portion 1300 are combined. In addition, description is abbreviate | omitted about the structure which is common with the side groove | channel 100. FIG.

  As shown in FIGS. 12 (a) to 12 (c), the main body portion 1200 of the side groove 1000 includes an arc-shaped bottom wall 1210 and flat side walls 1220 connected to both ends thereof in the vertical direction. And the main-body part 1200 becomes the substantially U shape extended as a whole in the longitudinal direction by these three wall parts, and forms the water collection space 1100 which can flow rain water etc. in the U-shape.

  The bottom wall 1210 is provided with two parallel through holes 1240 that are long in the short direction. The through hole 1240 is provided from the side wall 1221 side (left side in the drawing) from the center line mm of the bottom wall 1210. In other words, the through hole 1240 extends longer from the center of the bottom wall 1210 to one side.

  Further, on both inner walls of the through hole 1240, a step portion 1241 is provided that is lowered by one step from the upper end surface of the through hole 1240. Then, a bolt as a fixing member, which will be described later, passes through the through hole 1240. Preferably, the head of the bolt is locked to a stepped portion 1241 that is a part of the through hole 1240. The shaft portion of the bolt may penetrate between the step portions 1241.

  That is, the opening width L4 of the through-hole 1240 is set to be wider than the head of the bolt, and the width L3 between the stepped portions 1241 is set to be narrower than the head of the bolt while being wider than the shaft portion of the bolt. The longitudinal width L5 of the through hole 1240 may be set to an arbitrary length according to the angle at which the main body 1200 is desired to be inclined.

  Next, the side groove 1000 in which the main body 1200 shown in FIG. 12 is installed on the base 1300 will be described in detail with reference to FIG.

First, although it is the base part 1300, it has the substantially rectangular parallelepiped shape by which the center was shaved in circular arc shape. The length of the base portion 1300 in the vertical direction (longitudinal direction) matches the length of the main body portion 1200 in the vertical direction (longitudinal direction), and the width of the base portion 1300 in the horizontal direction (short direction) is the main body portion 1200. It is wider than the width in the horizontal direction. Further, both ends of the base portion 1300 are flat upper ends 1330, and an arcuate installation surface 1310 is formed at the center of the base portion 1300. Further, a fixing hole H provided with a groove for screwing a bolt is formed at the center of the installation surface 1310 (corresponding to the center mm line of the bottom wall 1210).

Further, a gradient adjusting groove 1340 is provided at the center of the base portion 1300 in the longitudinal direction (see FIG. 13B). The gradient adjusting groove 1340 is formed such that the inner end portion of the flat upper end 1330 is obliquely cut out, and a gap X is formed between the inclined surface 1341 of the gradient adjusting groove 1340 and the outer surface of the bottom wall 1210. it can. Further, the inclined surface 1341 of the gradient adjusting groove 1340 is continuous with the installation surface 1310 and the upper end 1330. The width of the gradient adjusting groove 1340 in the longitudinal direction is wider than the tip width of the gradient adjusting auxiliary member so that the tip side of a gradient adjusting auxiliary member such as a bar described later can be easily inserted. The gradient adjusting groove 1340 is provided at the center in the longitudinal direction of the base portion 1300 and is provided at each of the upper ends 1330 on both sides. However, the present invention is not limited to this, and a plurality of gradient adjusting grooves 1340 may be provided.

  And if the bottom wall 1210 of the main-body part 1200 is installed in the installation surface 1310 of this base part 1300, it will be in the state of the side groove 1000 shown to Fig.13 (a).

  Further, in this state, the bolt P is passed through the through hole 1240 from the inside of the bottom wall 1210. Specifically, the shaft portion P1 of the bolt P is passed through the step portion 1241 to the fixing hole H of the installation surface 1310, and the distal end side of the shaft portion P1 is screwed into the fixing hole H. Then, it will be in the state shown to FIG.13 (b) and (c). In this state, the bolt P is screwed into the fixing hole H so that the lower end of the head portion P2 of the bolt P is lightly contacted with the stepped portion 1241 or is not in contact with the stepped portion 1241. This is called temporary fixing.)

  Since the bottom wall 1210 of the main body part 1200 and the installation surface 1310 of the base part 1300 have a corresponding arc shape, the main body part 1200 is inclined at an arbitrary angle as shown in FIG. Can be made. Specifically, the main body 1200 can be tilted within a range where the bolts P in the through hole 1240 are in contact with both ends of the through hole 1240 in the longitudinal direction. In particular, the through-hole 1240 extends longer from the center of the bottom wall 1210 to one side (left side in the drawing). Therefore, the main body 1200 can be inclined in the extending direction (left side in the drawing).

  Note that when the main body 1200 is tilted, the gradient adjusting groove 1340 provided in the base portion 1300 may be used. Specifically, the tip of a gradient adjustment auxiliary member (not shown) is inserted into the gap X between the inclined surface 1341 of the gradient adjustment groove 1340 and the outer surface of the bottom wall 1210. This gradient adjustment auxiliary member is, for example, a rod-shaped member formed of a sturdy metal such as a bar, and has a thin flat end. Then, with the tip of the gradient adjustment assisting member inserted into the gap X, the back surface of the gradient adjustment assisting member is pressed against the surface of the inclined surface 1341, and a downward force is applied to the rear end of the gradient adjustment assisting member. Then, using the principle of scissors, a large upward force is applied to the tip of the gradient adjustment assisting member, and the bottom wall 1210 of the main body 1200 can be pushed up and tilted.

  Then, after inclining at an arbitrary angle, the bolt P is screwed into the fixing hole H strongly. Then, the lower end of the head P2 is strongly locked to the stepped portion 1241, and the main body portion 1200 is strongly fixed to the base portion 1300 in an inclined state. Further, after that, a fast-drying adhesive material (for example, a high-strength repair material / mortar that develops strength in a short time, a high-strength non-shrink repair material, or the like) is used in the through hole 1240 from the inside of the bottom wall 1210. .)), The main body portion 1200 is more firmly fixed to the base portion 1300.

  Incidentally, in FIG. 14A described above, the case where the main body 1200 is desired to be inclined to the left in the drawing has been described. In the following FIGS. 14B and 14C, a case where the main body 1200 is desired to be inclined to the right in the drawing will be described.

  As shown in FIG. 14B, the main body 1200 is installed on the base 1300 so as to be opposite to the installation direction of the main body 1200 shown in FIG. That is, the main body 1200 is rotated 180 degrees in the horizontal direction and installed on the base 1300 so that the front end 1250 and the rear end 1260 are reversed as shown in FIG. For this reason, in FIG. 14B, the rear end 1260 is positioned in front of the drawing.

  Thus, when the main body 1200 is rotated 180 degrees in the horizontal direction and installed, the through-hole 1240 extends longer from the center line mm of the bottom wall 1210 to the side wall 1221 side (right side in the drawing). Will be established.

  Therefore, as shown in FIG. 14C, the extending direction of the through hole 1240 (on the right side in the drawing) is within the range where the bolt P in the through hole 1240 contacts both ends of the through hole 1240 in the longitudinal direction. The main body 1200 can be inclined.

  In this way, by extending the through hole 1240 from the center of the bottom wall 1210 to the one side longer, if the installation direction of the main body 1200 is changed by 180 degrees, the main body 1200 is turned rightward or rightward, Can be selectively tilted.

  In the sixth modification, the bolt P is used as a fixing member for fixing the main body portion 1200. However, a simple bar-shaped member may be used in addition to the bolt. In that case, the rod-shaped member is passed through the through hole, and the tip thereof is inserted into the fixing hole H. In this state, when a fast-drying adhesive material is poured into the through-hole, the rod-shaped member serves as a connecting member, and the main body 1200 and the base 1300 are firmly fixed.

  In addition, the main body part 1200 and the base part 1300 shown in the sixth modification can be provided with the main body part side indentation part and the base part side indentation part shown in the first modification example, respectively.

<About the water catch>
Hereinafter, the structure of the catchment basin 200 will be described in detail.

As shown in FIG. 15, the main body 220 of the catchment basin 200 has a hollow, substantially cubic shape with a bottom wall 221 including four side walls 222 surrounding the four sides. Therefore, a water collection space (basket) 210 in which rainwater and the like can be collected and stored is formed inside the water collection basin 200. Further, the outer surface of the bottom wall 221 has an arc shape with a radius R3.

In addition, a step portion on which a grating or the like can be placed is provided at the upper end 223 of the main body 220. Further, the front and rear side walls 222 are provided with water outlets 224, and the water outlets 224 are connected to the water collecting space 110 of the side groove 100 (see FIG. 1), so that the water collecting space 110 and the main body of the side groove 100 are connected. The water collection space 210 of the part 220 is communicated. Accordingly, it is possible for rainwater and the like to come and go inside the gutter 100 and the water collecting basin 200.

Next, the base part 230 of the catchment basin 200 is shown to Fig.16 (a) and (b). The base portion 230 has basically the same configuration as the base portion 130 of the gutter 100, but the size of each portion is different. Specifically, the base 230 is formed to have a substantially square shape in plan view in consideration of placing the main body 220 having a substantially cubic shape instead of a long shape like the base portion 130 of the lateral groove 100. Has been. Further, the installation surface 231 has an arc shape with a radius R4 equal to the radius R3 of the bottom wall 221, and has a shape corresponding to the bottom wall 221.

Next, referring to FIGS. 16C and 16D, when the road surface R does not have a gradient and when the road surface R has a gradient, the catchment basin 200 is embedded in the road surface and installed. A mode to be described will be described.

  FIG. 16C shows a case where the road surface R has no gradient (the road surface R is substantially horizontal). As a procedure for installing the catchment basin 200, first, a hole is dug in the road surface R, and the base portion 230 is installed almost horizontally there. And the main-body part 220 is installed on the installation surface 231 so that the upper end surface of the main-body part 220 may become substantially horizontal.

  On the other hand, as shown in FIG. 16D, when the road surface R has a gradient, the main body 220 installed on the installation surface 231 is inclined according to the gradient of the road surface R.

  When the concrete F is poured into the step portion 234, the concrete F accumulates in the frame formed by the step portion 234, the upper ends 233 and the side walls 222 on both sides thereof, and eventually hardens. Then, since the side walls 222 on both sides of the main body 220 are fixed by the concrete F, the posture of the main body 220 is fixed. Then, the soil dug up around the main body 220 and the base 230 is backfilled until the upper end surface of the main body 220 and the road surface R are flush with each other.

Then, although the modified example of the catchment basin 200 of this invention is demonstrated next, description is abbreviate | omitted about the structure which is common in the catchment basin 200. FIG. Note that the features of FIGS. 5 to 14 that represent modified examples of the side groove 100 can also be applied to the catchment 200, and FIGS. 17 to 20 below show the modified examples. Therefore, the effect produced from the modified example (FIGS. 5 to 14) of the side groove 100 is also maintained as it is in the modified example (FIGS. 17 to 20) of the water collecting bowl 200 described below.

(Modification 1)
First, a water collecting basin 700 according to Modification 1 includes a main body portion 720 and a base portion 730, and the main body portion 720 shown in FIG. 17 is the surface of the bottom wall 721 and is measured on the left and right sides. Two indentations 724 are provided. The end of the indented portion 724 is continuous with the side wall 722, and the bottom surface 725 is provided with irregularities. Note that the position, size, and number of the recessed portions 724 may be arbitrarily changed as long as the surface is the bottom wall 721.

  In addition, water outlets 726 are provided on the left and right side walls 722. This water flow port 726 allows rainwater or the like to flow between the drain pipe connected to the main body 720, the gutter 100, or the like, and can be arbitrarily provided at the installation site.

  Next, FIGS. 18A and 18B show a state where the main body 720 of the catchment basin 700 is installed on the installation surface 731 of the base 730. FIG. The base portion 730 has the same configuration as the base portion 230 shown in FIG. 16, but is different in that a recess portion 735 is provided at both ends of the installation surface 731 and at a position facing the recess portion 724 of the main body portion 720.

Then, as shown in FIG. 18B, after installing the main body 720 on the installation surface 731, the concrete F is poured into the stepped portion 734. Then, the concrete F flows downward between the recessed portion 724 and the recessed portion 735, and the space F is filled with the concrete F. And if the concrete F hardens, the attitude | position of the main-body part 720 will be fixed. The bottom surface 725 of the indented portion 724 and the bottom surface 736 of the indented portion 735 are provided with irregularities so that the main body 720 is more firmly fixed.

(Modification 2)
Next, in FIG. 19A, a modified example in which the position of the indented portion is changed will be described. The main body 820A of the catchment basin 800A is provided with a recess 824A near the center of the bottom wall 821A. On the other hand, the base portion 830A is a position opposite to the indentation portion 824A, and the indentation portion 835A is provided near the center of the installation surface 831A. When the filled concrete F is solidified in the space S formed between the recessed portion 824A and the recessed portion 835A, the posture of the main body portion 820A is fixed.

(Modification 3)
Next, in FIG. 19B, a modified example using means for fixing the main body part by means other than the recessed part will be described. In addition, in FIG.19 (b), you may use a hollow part together.

  As shown in FIG. 19B, the main body 820B is provided with a through hole 824B in the vicinity of the center of the bottom wall 821B, while a protrusion 835B is formed in the vicinity of the center of the installation surface 831B of the base 830B. Has been. Since the through hole 824B is wider than the protrusion 835B, a space S is secured on both sides of the protrusion 835B. Therefore, even when the protrusion 835B is inserted into the through hole 824B, the main body 820B can be tilted left and right until the protrusion 835B contacts the end of the through hole 824B. And after inclining the main-body part 820B to arbitrary angles, the concrete F is poured into the space S in the through-hole 824B, and the concrete F hardens | solidifies, and the attitude | position of the main-body part 820B is fixed.

(Modification 4)
Next, in FIG. 19C, a groove 835C is provided instead of the protrusion 835B shown in FIG. 19B. The groove 835C is provided near the center of the installation surface 831C, and is located at a position facing the through hole 824C. Then, after placing the bottom wall 821C on the installation surface 831C and inclining the main body 820C at an arbitrary angle, the concrete F is poured into the through hole 824C. Then, the concrete F is filled in the groove 835C and the through hole 824C, and the concrete F is solidified, so that the posture of the main body 820C is fixed.

(Modification 5)
Next, in FIG. 19D, a plurality of planes 824D are continuously provided on the surface of the bottom wall 821D of the main body 820D. On the other hand, a plurality of planes 835D are continuously provided on the surface of the installation surface 831D of the base portion 830D. The planes 824D and 835D have the same width, and when the bottom wall 821D is placed on the installation surface 831D, the surfaces of the planes 824D and 835D coincide. Therefore, even if the main body 820D is inclined at an arbitrary angle, the inclined posture of the main body 820D is maintained by matching the planes 824D and 835D.

(Modification 6)
Hereinafter, a water collecting tank 2000 in which a main body portion 2200, which is a modification of the main body portion 220 of the present invention, is installed on a base portion 2300 will be described with reference to FIG. Note that a description of the configuration common to the main body 220 is omitted.

As shown in FIGS. 20 (a) and 20 (b), the main body 2200 of the drainage basin 2000 is composed of four side walls 2220 that surround the four sides and a bottom wall 2210 having an arcuate outer surface. It has a cubic shape. On the other hand, the base portion 2300 of the catchment basin 2000 is formed so as to have a substantially square shape in plan view in consideration of mounting the substantially cubic body portion 2200. Further, the installation surface 2310 has an arc shape whose surface corresponds to the bottom wall 2210.

  The bottom wall 2210 of the main body 2200 is provided with two through holes 2240 having the same structure as the through hole 1240 shown in FIG. The through-hole 2240 is elongated and extends longer from the center line nn of the bottom wall 2210 toward one side wall 2221 (left side in the drawing). Furthermore, a step portion 2241 that is lowered by one step from the upper end surface of the through hole 2240 is provided on both inner walls of the through hole 2240.

  A bolt P passes through the through hole 2240. Specifically, the lower end of the head P2 of the bolt P is in light contact with or not in contact with the stepped portion 2241, and the tip P1 is screwed into a fixing hole H provided at the center of the installation surface 2310. (This is called temporary fixing of the main body 2200).

  From this state, the main body 2200 is inclined at an arbitrary angle in the extending direction of the through-hole 2240 (left side in the drawing). After that, the bolt P is firmly screwed into the fixing hole H, whereby the lower end of the head P2 is strongly locked to the step portion 2241, and the main body portion 2200 is strongly fixed to the base portion 2300 in an inclined state. The Furthermore, if a quick-drying adhesive material is poured into the through hole 2240 and filled, the main body 2200 is more firmly fixed to the base 2300.

  In addition, when it is desired to incline the main body 2200 to the right side in the drawing, the main body 2200 may be installed on the base 2300 by rotating 180 degrees in the horizontal direction. Then, since the through-hole 2240 extends longer to the right side than the center line nn of the bottom wall 2210, the main body 2200 can be inclined to the right side. Further, the base 2300 may be provided with a slope adjusting groove having the same structure as the slope adjusting groove 1340 shown in FIGS. 13 and 14, and the slope adjusting groove may be used when the main body 2200 is inclined.

  The embedded structure of the present invention is not limited to the above-described examples, and various modifications and combinations are possible within the scope of the claims and the scope of the embodiments. Combinations are also included in the scope of rights.

Claims (3)

An embedded structure that is buried in a road surface and forms a drainage channel for draining rainwater from the road surface,
A main body portion provided with a water collection space inside, and a base portion provided with an installation surface for installing the main body portion,
Since the bottom wall of the main body has an arc shape and the installation surface has a shape corresponding to the bottom wall , the main body can be inclined on the installation surface,
The bottom wall of the main body is provided with a long through hole through which the fixing member can pass,
The embedded structure according to claim 1, wherein a fixing hole capable of fixing the tip of the fixing member is provided on the installation surface . On the surface of the bottom wall of the main body, a main body side recess is provided,
The embedded structure according to claim 1 , wherein a base-side recess is provided on the installation surface of the base at a position facing the main-body-side recess. The embedded structure according to claim 2 , wherein unevenness is provided on a bottom surface of the main body portion side recess portion and the base portion side recess portion.

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