JP2008266981A - Steel slit dam - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively prevent debris flow and raft produced in a river from flowing to the downstream side of the river, while reducing the construction cost. <P>SOLUTION: This steel slit dam is disposed between concrete side parts 2 formed on both riverbanks of a river 10 in the river width direction. The steel slit dam comprises steel tube columns vertically installed at predetermined intervals in the river width direction; steel tube beams 13, 14 having both ends buried in the side parts formed on both riverbanks of the river in the river width direction and installed between the side parts 2, while crossing the steel tube columns; and branched steel tubes 32, 42 branched and extending from the steel tube columns in the river width direction, at intervals in the vertical direction and made with reduced diameter than those of the steel tube columns and the steel tube beams 13, 14. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a steel slit dam suitable for river debris flow countermeasures or driftwood countermeasures.

  Conventionally, a transmission-type sabo dam has been proposed that can capture boulders, driftwood, and a large amount of sediment when a debris flow occurs to prevent outflow to the downstream of the river (see, for example, Patent Document 1). The disclosed technique of Patent Document 1 has been devised from the viewpoint of preventing re-flow of gravel and sediment trapped when debris flow occurs while maintaining the sediment control function. The longitudinal direction of the river and the transverse direction of the river A frame constructed by laying rod-shaped members on the riverbed is installed on the river bed.

  However, according to the disclosed technique of Patent Document 1, a rod-shaped member must be installed in the longitudinal direction of the river. This increases the cost of the member and increases the work effort, resulting in a significant increase in the construction cost. In addition, in the disclosed technique of Patent Document 1, since a three-dimensional structure is provided by providing rod-shaped members in the longitudinal and transverse directions of the river, when earth and sand etc. enter and mix inside the three-dimensional solid surrounded by a grid, It is difficult to take this out of the solid and remove it.

  In addition, a steel slit dam is proposed in which a beam material is installed between concrete sleeve portions formed on both banks in the river width direction of the river (see, for example, Patent Document 2). In the disclosed technique of Patent Document 2, the levee body installed on both river banks, the girder connected to the levee body and passed between the two dam bodies in the river width direction, and the girder and the base of the river bottom position are connected. A columnar steel slit dam structure is configured by arranging vertical members in a columnar shape at a required interval in the river width direction. That is, with this slit dam structure, the structure can be simplified and strengthened as much as possible, and the manufacturing cost can be reduced.

  Conventionally, this columnar slit dam structure has the disadvantage that the length between the fulcrums of the vertical members is long and the impact force absorption performance of the debris flow is inferior. The structure which arrange | positions a horizontal girder member in the intermediate part of this is proposed. However, in such a configuration, in order to receive the impact, it is difficult to sufficiently receive the impact force because the lower base portion of the vertical member and the upper beam portion installed on the sleeve portion must be handled. Therefore, it is necessary to increase the diameter of the steel pipe member or to increase the thickness of the steel pipe member. In addition, in order to receive relatively small gravel other than boulders, it is necessary to reduce the distance between the vertical members, which necessitates an increase in the number of members, resulting in an increase in production and installation costs. There was a point.

  Furthermore, as an example of such a steel slit dam, an open-type steel sabo dam as shown in Patent Document 3, for example, has been proposed. In the technique disclosed in Patent Document 3, a protruding portion is formed at a portion where the steel sabo units are spaced apart from each other so as to block the spaced portion.

However, the overhanging portion is provided only to fill the gap between the steel sabo units, and a steel pipe having substantially the same diameter as that of the steel column or the like is used. Constructing this overhang with a steel strut or the like having the same diameter means that it has a large diameter, but the problem is that the construction cost increases accordingly. There was a point.
JP-A-7-82725 JP 2002-121728 A Japanese Patent Laid-Open No. 11-286922

  Accordingly, the present invention has been devised in view of the above-described problems, and the object of the present invention is to reduce the construction cost and to discharge the debris flow and driftwood generated in the river downstream of the river. It is in providing the steel slit dam which can prevent effectively.

  The invention according to claim 1 of the present invention is the steel slit dam disposed between the civil engineering structures formed in the river width direction of the river, the steel pipe struts erected in the river width direction, and both ends of the sleeve portion. Embedded in the steel pipe strut while crossing the steel pipe strut and extending between the sleeve portions, and branching and extending from the steel pipe strut in the river width direction, and having a diameter smaller than that of the steel pipe strut and the steel pipe beam. A branched steel pipe is provided.

  The invention according to claim 2 of the present application is characterized in that, in the invention according to claim 1, the branched steel pipe has a diameter of about 1/2 to 3/4 of the diameter of the steel pipe support column. And

  The invention according to claim 3 of the present invention is the invention according to claim 1 or 2, wherein a vertical steel pipe and a branched steel pipe having a small diameter branched on both sides from the vertical steel pipe toward the river width direction are provided. The branched steel pipes that are formed by connecting the steel pipe units in the vertical direction via the steel pipe beams and that are branched and extended from the steel pipe units adjacent to each other in the river width direction are separated from each other in the river width direction. It is characterized by becoming.

  Further, the invention according to claim 4 of the present application is the invention according to any one of claims 1 to 3, wherein the invention is connected to a joining steel pipe extended from the steel pipe beam toward the downstream side, and the joining material, It further comprises a reinforced steel pipe beam erected between the sleeve portions in the river width direction.

  When boulders and driftwood flow into the river 10, they can be received through the steel pipe columns 13, the steel pipe beams 14, and the vertical pipes 31 and 41.

  Both ends of the steel pipe beams 13 and 14 are connected to the first embedded steel pipe 11 and the second embedded steel pipe 12, and the first embedded steel pipe 11 and the second embedded steel pipe 12 are connected to the sleeve portion 2. It is buried in. For this reason, the impact force caused by the boulders applied to the steel pipe beams 13 and 14 can be handled by the concrete sleeve portion 2 via the first buried steel pipe 11 and the second buried steel pipe 12. As a result, the number of pillars can be reduced and the construction cost can be reduced.

  Moreover, since the steel pipe beam 13, the steel pipe beam 14, and the vertical steel pipes 31 and 41 have a diameter larger than that of the small-diameter branched steel pipes 32 and 42, the boulders flowing from the upstream direction are the first. The steel pipe beam 14 and the vertical steel pipes 31 and 41 collide with each other, and no impact resistance is applied to the branched steel pipes 32 and 42.

  Further, small gravel can be received by the branched steel pipes 32 and 42 in addition to the steel pipe beam 13, the steel pipe beam 14 and the vertical steel pipes 31 and 41. That is, by providing the branched steel pipes 32 and 42, the area of the grid formed by the steel pipes can be reduced, and small gravel can be caught through the small grid. In addition, since the small gravel does not receive a large impact compared to the big gravel and does not require a large strength for receiving this, it is particularly a problem even if the branched steel pipes 32 and 42 are configured with a small diameter. There is no. Further, by making the branched steel pipes 32 and 42 with a particularly small diameter, the manufacturing cost and the material cost can be reduced, and the branched steel pipes 32 extended from the steel pipe units 15 adjacent to each other in the river width direction. Since they are configured to be separated from each other, it is possible to omit the construction process associated with the joining, and it is possible to reduce the construction cost as a whole.

  Hereinafter, as a best mode for carrying out the present invention, a steel slit dam applied to a river or the like will be described in detail with reference to the drawings.

  The steel slit dam to which the present invention is applied is applied to a river 10 as shown in FIG. This river 10 has a concrete sleeve 2 formed on both banks, and a concrete foundation 3 formed on the river bottom. The river 10 is formed by being surrounded by the sleeve 2 and the concrete foundation 3. Water flows through the flow path from upstream to downstream.

  A steel slit dam 1 to which the present invention is applied is embedded in a concrete foundation 3 and a first embedded steel pipe 11 and a second embedded steel pipe 12 embedded in each sleeve 2 on both banks. A steel pipe beam 13 constructed between the third buried steel pipe 17 and the first buried steel pipe 11 buried in each sleeve 2 on both banks, and a second buried in each sleeve 2 on both banks. Provided between the steel pipe beam 14, the steel pipe beam 13 provided between the steel pipe beam 13 and the third buried steel pipe 17. The steel pipe unit 16 is provided.

  FIG. 2 shows a front view of the steel slit dam 1. The first buried steel pipe 11 has a flange attached to the tip thereof, and the second buried steel pipe 12 has a flange attached to the tip thereof. The flange may have any shape, but in the following description, a case where the flange is formed in a disk shape will be described as an example. Incidentally, this flange may be similarly formed at the end of the third buried steel pipe 17 other than the buried steel pipes 11, 12, the steel pipe beam 13, the steel pipe beam 14, the steel pipe unit 15, and the steel pipe unit 16. Further, any conventional method may be applied as a method for joining the flanges. Further, it is not essential that the flanges are formed at the tips of the buried steel pipes 11 and 12, and it is of course possible to join them by welding in addition to the flange connection.

  Further, the steel pipe beam 13 is provided with vertical steel pipes 25 branched toward the lower side at a predetermined interval. That is, the vertical beam 13 is provided with a vertical steel pipe 25 intersecting in a T shape.

  The steel pipe beam 14 is provided with a vertical steel pipe 35 branched toward the upper side at a predetermined interval. The steel pipe beam 14 is provided with a vertical steel pipe 37 branched downwardly at a predetermined interval. That is, the vertical beam 14 is provided with vertical steel pipes 35 and 37 so as to cross in a cross shape.

  The steel pipe unit 15 includes a vertical steel pipe 31 having a large diameter, and a branched steel pipe 32 having a small diameter branched from the vertical steel pipe 31 toward both sides in the river width direction. It consists of the shape.

  The steel pipe unit 16 includes a vertical steel pipe 41 having a large diameter, and a branched steel pipe 42 having a small diameter branched from both sides of the vertical steel pipe 41 in the river width direction. It consists of the shape.

  These steel pipe units 15 and 16 should just be formed over at least 1 row.

  Next, a construction method of the steel slit dam 1 having the above-described configuration will be described.

  First, the first buried steel pipe 11, the second buried steel pipe 12, the third buried steel pipe 17, the steel pipe beam 13, the steel pipe beam 14, the steel pipe unit 15, and the steel pipe unit 16 constituting the steel slit dam 1 are each factory. Etc. and transport it to the river that will be the construction site. In the present invention, since the respective components are finely divided in this way, it is possible to reduce the burden of labor when the components are manufactured at the factory and transported to the site.

  Next, the third embedded steel pipe 17 is embedded in the concrete foundation 3. Further, the first embedded steel pipe 11 and the second embedded steel pipe 12 are embedded in the sleeve portion 2.

  Next, the steel pipe beam 13 is arranged. Specifically, flanges formed at both ends in the river width direction of the steel pipe beam 13 are brought into contact with flanges provided at the tip of the first buried steel pipe 11, and these are joined with bolts or the like. . Similarly, in the steel pipe beam 14, flanges formed at both ends in the river width direction of the steel pipe beam 14 are brought into contact with flanges provided at the tip of the second embedded steel pipe 12, and these are joined by bolts or the like.

  Next, the steel pipe unit 15 is joined. In the steel pipe unit 15, the upper end of the vertical steel pipe 31 is joined to the vertical steel pipe 25 in the steel pipe beam 13 so as to contact each other. Further, the lower end of the vertical steel pipe 31 of the steel pipe unit 15 is joined with the vertical steel pipe 35 of the steel pipe beam 14 in contact with each other.

  Next, the steel pipe unit 16 is joined. The steel pipe unit 16 joins the upper end of the vertical steel pipe 41 to the vertical steel pipe 37 in the steel pipe beam 14. Further, the lower end of the vertical steel pipe 41 of the steel pipe unit 16 and the upper end of the third embedded steel pipe 17 are joined to each other. Thereby, the steel slit dam 1 which consists of the above structures is completed. At this time, the branched steel pipes 32 branched and extended from the steel pipe units 15 adjacent to each other in the river width direction are not joined to each other and are separated from each other in the river width direction, but these are joined to each other. Of course, it is also good. That is, when the assembly of each unit is completed, a so-called steel pipe column constituted by connecting the vertical steel pipes 31 and 41 in the vertical direction via the steel pipe beam 14 is formed.

  Next, the effect of the structure slit dam 1 which consists of the structure mentioned above is demonstrated. When boulders and driftwood flow into the river 10, they can be received mainly through the steel pipe beam 13, the steel pipe beam 14, and the vertical steel pipes 31 and 41. That is, the steel pipe beam 13, the steel pipe beam 14, and the vertical steel pipes 31 and 41 need to have strength sufficient to receive such boulders and the like. It is assumed that the steel pipe beam 13 and the steel pipe beam 14 have a diameter of 500 mm, and the vertical steel pipes 31 and 41 have a diameter of 400 mm. In particular, when receiving this boulder, a large impact force is applied. In order to counter this impact resistance, it is necessary to increase the diameter of the steel pipe beam 13 or the like. In addition, although the arrangement | positioning space | interval of this steel pipe beam 13, the steel pipe beam 14, and the vertical steel pipes 31 and 41 is set comparatively wide, it is not necessary to receive small gravel, and if it can focus on only a big boulder and can receive it to the last The desired effect of the present invention can be realized.

  Moreover, since the steel pipe beam 13, the steel pipe beam 14, and the vertical steel pipes 31 and 41 have a diameter larger than that of the small-diameter branched steel pipes 32 and 42, the boulders flowing from the upstream direction are the first. The steel pipe beam 14 and the vertical steel pipes 31 and 41 collide with each other, and no impact resistance is applied to the branched steel pipes 32 and 42.

  Further, both ends of the steel pipe beams 13 and 14 are connected to the first embedded steel pipe 11 and the second embedded steel pipe 12, and the first embedded steel pipe 11 and the second embedded steel pipe 12 have sleeves. Embedded in part 2. For this reason, the impact force caused by the boulders applied to the steel pipe beams 13 and 14 can be handled by the concrete sleeve portion 2 via the first buried steel pipe 11 and the second buried steel pipe 12. As a result, the number of pillars can be reduced and the construction cost can be reduced.

  Further, small gravel is received by the branched steel pipes 32 and 42 in addition to the steel pipe beam 13, the steel pipe beam 14 and the vertical steel pipes 31 and 41. That is, by providing the branched steel pipes 32 and 42, the area of the grid formed by the steel pipes can be reduced, and small gravel can be caught through the small grid. In addition, since the small gravel does not receive a large impact compared to the big gravel and does not require a large strength for receiving this, it is particularly a problem even if the branched steel pipes 32 and 42 are configured with a small diameter. There is no. Further, by making the branched steel pipes 32 and 42 with a particularly small diameter, the manufacturing cost and the material cost can be reduced, and the branched steel pipes 32 extended from the steel pipe units 15 adjacent to each other in the river width direction. Since they are configured to be separated from each other, it is possible to omit the construction process associated with the joining, and it is possible to reduce the construction cost as a whole. Further, by separating the branched steel pipes 32 from each other, the amount of work when the steel pipe unit 15 is replaced can be reduced. In particular, in the present invention, the diameter of the branched steel pipes 32 and 42 is 200 mm. However, the diameter is not limited to this, and the diameter of the vertical steel pipes 31 and 41 is about 1/2 to 3/4. It only has to be configured. If the branched steel pipes 32 and 42 are too thick, the weight becomes heavy and the construction and conveyance work may be hindered. Also, when manufacturing at the factory, the margin for welding to the vertical steel pipes 31 and 41 becomes large. This is because there is a drawback that it will end up.

  Furthermore, since this structure slit dam 1 is not a three-dimensional structure but a planar structure to the last, when the gravel and earth and sand received are collected, this can be removed easily. Furthermore, since the configuration slit dam 1 to which the present invention is applied can be configured by assembling the units, in some cases, it can be disassembled to remove earth and sand.

  The steel slit dam 1 to which the present invention is applied is not limited to the above-described embodiment, and can be applied to a form as shown in FIG. 3, for example.

  In the steel slit dam 1 shown in FIG. 3, the same components and members as those shown in FIG. 1 described above are denoted by the same reference numerals, and the following description is omitted.

  In the form shown in FIG. 3, steel pipe units 18 and 19 are applied as an alternative to the substantially cross-shaped steel pipe units 15 and 16. The steel pipe units 18 and 19 are arranged at a fine pitch toward the river width direction. The steel pipe units 18 and 19 are provided with branch steel pipes 32 and 42 in a plurality of stages, respectively. For this reason, in the form shown in FIG. 3, it is possible to further reduce the area of the grid formed by the steel pipes, and it is possible to catch particularly small gravel and driftwood without escaping downstream. As described above, the steel slit dam 1 to which the present invention is applied is constituted by a steel pipe by adjusting the arrangement interval in the river width direction in the steel pipe units 18 and 19 and the vertical interval between the molecular steel pipes 32 and 42. It is possible to freely adjust the area of the grid. For this reason, the size of gravel and driftwood flowing in the river 10 in which the steel slit dam 1 is arranged is investigated in advance, and based on this, the design of the grid area composed of steel pipes is optimized. Is also possible.

  Moreover, in the example mentioned above, although the case where one steel slit dam 1 was constructed by combining the units each manufactured in the factory to the last was demonstrated as an example, it is not limited to this. For example, the steel slit dam 1 may have a completely integrated configuration that cannot be assembled and disassembled. In such a case, a steel pipe strut mainly composed of vertical steel pipes 31 and 41 and a branch extending in the river width direction with a vertical interval from this steel pipe strut, and having a smaller diameter than the steel pipe strut and the steel pipe beams 13 and 14. The branched steel pipes 32 and 42 and the steel pipe beams 13 and 14 are configured as integrated struts that cannot be assembled and disassembled with each other. Of course, only some of them may be assembled and disassembled.

  In addition, the steel slit dam 1 to which the present invention is applied is not limited to the above-described embodiment. For example, when the intermediate structure 5 is formed between the sleeve portions 2 as shown in FIG. The steel slit dam 1 may be provided between the sleeve 2 and the intermediate structure 5. Moreover, when the intermediate part structure 5 is provided over several places, of course, the steel slit dam 1 may be provided between the intermediate part structures 5.

  The sleeve 2 is assumed to be made of concrete, but is not limited to this, and is embodied as a civil engineering structure in which earth and sand or soil cement is put in a steel frame. May be.

  5 (a) and 5 (b) show another embodiment of the steel slit dam 1 to which the present invention is applied. In this embodiment, the same components and members as those shown in FIG. 1 described above are denoted by the same reference numerals, and the following description is omitted.

  5 (a) and 5 (b), a connecting steel pipe 53 extending from the steel pipe beam 13 toward the downstream side is connected to the connecting material 53 and between the sleeve portions 2 toward the river width direction. Further, a reinforced steel pipe beam 52 is provided. The reinforcing steel pipe beam 52 is joined to an embedded steel pipe 51 embedded in the sleeve portion 2.

  By comprising in this way, especially when a boulder flows in in the river 10, when this collides with the steel pipe beam 13, a big impact force will be added. However, since the steel pipe beam 13 is connected to the reinforcing steel pipe beam 52 connected to the joining material 53 to reinforce it, even if a boulder having an unexpected size collides with this, The steel slit dam 1 including the steel pipe beam 13 can be prevented from being damaged. In addition, since such boulders flow near the water surface in the river 10, it is possible to catch boulders by forming the connecting steel pipe 53 and the reinforcing steel pipe beam 52 only in the upper stage. At the same time, it is possible to reduce the manufacturing cost by making it possible to configure with only the minimum required reinforcing steel pipe beam 52.

  6 (a) and 6 (b) show another embodiment of the steel slit dam 1 to which the present invention is applied. In this embodiment, the same components and members as those shown in FIG. 1 described above are denoted by the same reference numerals, and the following description is omitted.

  6 (a) and 6 (b), the connecting steel pipe 53 extending from the steel pipe beam 13 toward the downstream side is connected to the connecting material 53 and between the sleeve portions 2 toward the river width direction. Further, a reinforced steel pipe beam 52 is provided. The reinforcing steel pipe beam 52 is joined to an embedded steel pipe 51 embedded in the sleeve portion 2. Further, the welded steel pipe 53 and the reinforcing steel pipe beam 52 are also connected to the steel pipe beam 14 positioned at the lower stage of the steel pipe beam 13 in the same manner.

  By comprising in this way, even if a big boulder collides with any of the steel pipe beams 13 and 14, and a big impact force is added, it becomes possible to counter this and make it a stronger slit dam. Is possible.

  In the first and second embodiments described above, the distance between the steel pipe units 15 and the vertical distance between the branched steel pipes 32 and 42 may be of any length.

It is a perspective view of the steel slit dam to which the present invention is applied. It is a front view of the steel slit dam to which the present invention is applied. It is a figure which shows the example which made fine the grid | lattice comprised with a steel pipe in the steel slit dam to which this invention is applied. It is a figure which shows the structure which provided the steel slit dam 1 when the intermediate part structure is formed between the sleeve parts. It is a figure which shows the other Example of the steel slit dam to which this invention is applied. It is a figure which shows the further another Example of the steel slit dam to which this invention is applied.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Steel slit dam 2 Sleeve part 3 Concrete foundation 10 River 11 1st buried steel pipe 12 2nd buried steel pipe 13, 14 Steel pipe beam 15, 16 Steel pipe unit 25, 31, 35, 37, 41 Vertical steel pipe 32, 42 minutes Branch steel pipe

Claims (4)

In the steel slit dam arranged between civil engineering objects formed in the river width direction of the river,
Steel pipe struts erected in the river width direction,
Both ends are embedded in the sleeve part, and the steel pipe beam laid between the sleeve parts while intersecting the steel pipe column,
A steel slit dam comprising a branch pipe extending from the steel pipe strut in the river width direction and having a diameter smaller than that of the steel pipe strut and the steel pipe beam. 2. The steel slit dam according to claim 1, wherein the branched steel pipe has a diameter of about ½ to 3/4 of the diameter of the steel pipe support. A steel pipe unit having a vertical steel pipe and a branched steel pipe having a small diameter branched on both sides from the vertical steel pipe toward the river width direction is configured by connecting the steel pipe units in the vertical direction via the steel pipe beams. The steel slit dam according to claim 1 or 2, wherein the branched steel pipes that are branched and extended from the steel pipe units adjacent in the river width direction are spaced apart from each other in the river width direction. A joining steel pipe extended from the steel pipe beam toward the downstream side;
The steel slit dam according to any one of claims 1 to 3, further comprising a reinforced steel pipe connected to the joint material and laid in the river width direction between the sleeve portions. .

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