KR101399183B1 - Circulating water velocity regulation of a drainageway and arsenic acid prevention structure - Google Patents

Abstract

The present invention relates to a structure of a drainage passage installed on a roadside and a mountain slope, and more particularly, to a drainage passage provided with a constant inclined surface, in which a stepped hole having a predetermined size is provided so as to dampen the flow rate according to the amount of stormwater, By reducing the amount of water that flows over the drainage channel by suppressing the water that is scattered by bumping into the floor with the conventional drainage, it is possible to prevent the loss of the soil around the drainage line and to control the flow rate of the slope drainage line which can prevent natural disasters such as landslides Scattering prevention structure.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a flow velocity control and a scattering prevention structure for a slope drainage channel,

The present invention relates to a structure of a drainage passage installed on a roadside and a mountain slope, and more particularly, to a drainage passage provided with a constant inclined surface, in which a stepped hole having a predetermined size is provided so as to dampen the flow rate according to the amount of stormwater, By reducing the amount of water that flows over the drainage channel by suppressing the water that is scattered by bumping into the floor with the conventional drainage, it is possible to prevent the loss of the soil around the drainage line and to control the flow rate of the slope drainage line which can prevent natural disasters such as landslides Scattering prevention structure.

In general, drains are installed on slopes such as embankment, cut slope and mountain slope in order to prevent slope failure due to runoff and runoff and to prevent landslides due to loss of slope. However, in the case of rainy season or heavy rains, as the water is discharged from the drainage line in the drainage line (the ridge and ridge), the surrounding soil is often lost and causes a disaster such as a landslide.

The applicant of the present invention proposes an overflow prevention lid at the end of a drainage channel in order to prevent a disaster such as landslides and landslides when the water flows over the drainage passage when the rainfall due to the heavy rain is large as described above -0014864) There was a bar.

As shown in the accompanying drawing 1, a roadway is installed on a steep slope side such as a mountain slope, and the steep slope side of the slope face And the water is smoothly flowed through the drainage path in the middle part of the steeply sloped surface, and a ridge-like sidewall is formed on the steeply sloping surface,

The flow passage 56 is provided with a flow rate reduction facility 60 to reduce the speed of water flowing along the water discharge passage 56 while the flow rate sensing facility 60 is provided on both side wings of the bearing structure 62 64 are secured to the upper horizontal portion of the drainage duct by fastening bolts 66 and the anchor bolts 68 are coupled to the bearing structure 62 at the middle portion thereof, The plate 72 is coupled and the flow rate reduction plate 72 is operated naturally according to the flow of the water flowing through the water discharge channel 56. The water flow rate is reduced by the flow rate reduction plate 72, Wherein the water flow velocity in the section (C) is reduced and a problem of sinking of the drainage channel due to no occurrence of the overflowing of the drainage channel (56) is prevented. And the like,

As shown in FIG. 2, the drainage passage is integrally formed of a concrete material, and its cross section is formed in a concave shape. A plurality of drainage holes are formed in a drainage line located at the upper end of the intersection so that the drainage water is drained to the drainage line located at the lower end of the drainage line. At the upper and lower ends thereof, And two drainage passages are connected to the end of the drainage port, respectively, so as to reduce the dropping speed, and one drainage port and one drainage port are formed respectively so that two drainages are branched starting from the inlet. Drainage facilities. And the like,

In addition to the above, a method has been proposed in which the inner bottom surface of the drainage channel is formed stepwise to reduce the flow rate of the drainage channel, or a plurality of protruding jaws are formed on the side wall of the drainage channel so that the flowing water hits the protruding jaws to delay the flow of water.

However, even though the drainage facilities as described above are complicated in construction and have a large expenditure of expenditure, the drains can not be sufficiently drained due to the increase in the quality of the drainage, There were problems that could not be effectively prevented.

Accordingly, the present invention reduces the flow rate naturally due to the increase or decrease of water according to the amount of precipitation in the existing drainage path and the newly installed drainage path, and prevents the water from being scattered by the tension due to the specific gravity of the water, I would like to.

The present invention relates to a drainage channel provided on embankment surfaces, cut slopes and mountain slopes, and has a step formed by a predetermined hole at a predetermined position of a deceleration portion forming a plane with an end portion of a drainage which forms an inclined surface along a slope, As shown in Fig.

According to the present invention as described above, the flow of water can be flexibly decelerated according to the amount of storm. When the amount of water is small, the water is naturally drained through a hole in the step. When the amount of water is increased, As the water is fed by the steps, it primarily serves to reduce the flow of water. Secondly, when more water comes down depending on the amount of precipitation, the water level naturally increases and the water flows over the step and drains. .

In this way, the water contained in the step is generated by the specific gravity of the water, so that the water flowing down along the slope is slowed down by the water.

In addition, since it has the effect of preventing the water splashing on the bottom of the drainage channel due to the tension of the water, it is possible to prevent the drainage of the slope on the slope by suppressing the water flowing over the drainage channel.

In addition, it also prevents the floor from collapsing due to a rapid flow from the slope of the drainage channel to the flat bottom of the drainage channel, thereby reducing maintenance and repair costs.

In addition, the present invention as described above has a useful effect that installation is simple and easy and can be installed in an existing drainage channel.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a flow-rate reduction induction facility of a conventional drainage structure; FIG.
FIG. 2 is a view showing another drainage facility for reducing fall.
FIG. 3 is a cross-sectional view showing the overflow and scour of a conventional general drainage channel. FIG.
4 is a perspective view showing a drainage passage of the present invention.
5 is a cross-sectional view showing aspects of the present invention.
6 is a sectional view showing the flow of water when the precipitation amount of the present invention is small.
7 is a cross-sectional view showing the flow of water when the precipitation amount of the present invention is large;
8 is a sectional view showing another embodiment of the step of the present invention;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a cross-sectional view of a conventional drainage line. FIG. 3 is a cross-sectional view of a conventional drainage line, showing a phenomenon in which water flowing down a slope of a drainage passage is scattered by colliding with a floor surface, It is.

FIGS. 4 to 5 are a perspective view and a cross-sectional view showing a drainage passage of the present invention, FIGS. 6 to 7 are sectional views showing an operation state of water flow in a drainage passage of the present invention, Fig.

The present invention is characterized in that a step 4 in which a predetermined hole 5 is opened at a predetermined position of a deceleration portion constituting a plane 3 with an end portion of a drainage forming a slope 2 along a slope surface of a drainage passage 1, And is formed to have a predetermined height from the bottom surface.

As shown in Fig. 6, the drainage passage 1 of the present invention is formed in the step 4 when the amount of water is small and the amount of water is small. The drainage passage 1 is naturally drained through a plurality of openings 5, Water that can not escape through the large number of holes 5 is accumulated by the step 4 when the amount of water is large due to a large amount of precipitation as a result of which water falling down the slope 2 of the drainage path 1 strikes against the water The effect of suppressing the water scattered by the tensile force of the water and the force to shrink the bottom surface of the drain canal 1 are relatively weakened, so that the maintenance of the drain can be avoided.

Also, the water flowing over the step 4 of the drain canal 1 decelerates and flows down while the accelerated flow descending on the inclined surface 2 is stagnated.

Therefore, when a plurality of steps 4 are provided at a predetermined position of the plane 3 positioned at the end of the inclined plane 2 of the drainage channel 1, it is possible to more effectively control the flow velocity of the drainage channel will be.

The shape of the open step 4 of the hole 5 of the present invention may be formed in a trapezoidal shape as shown in FIG. 8 to effectively cope with the flow velocity of water flowing down. The shape may be modified to have the same effect by various shapes and various materials in addition to the structures exemplified above.

On the other hand, the present invention having the above-described structure can be installed from the beginning by being poured by a form at the time of the construction of the embankment surface and the drainage path 1 provided on the slope slope surface and the mountain slope surface. In the case of the existing drainage path (1) It is only necessary to provide an anchor bolt or other structure at a predetermined position forming the drainage path plane 3 and then to construct a step 4 in which a plurality of holes 5 are opened by pouring or installing concrete. Of course, it is very beneficial to make the installation cost cheaper and expect a useful effect.

1. Drain 2. Slope
3. Plane 4. Step
5. Hole

Claims (3)

In the drainage path provided on the embankment surface, cut slope surface and mountain slope surface,
Wherein a step of forming a plurality of holes at a predetermined position of a decelerating portion forming a plane with an end portion of the drainage channel forming an inclined surface of the drainage channel is formed to the inside of the drainage channel to a predetermined height from the bottom surface, Prevention structure.
The method according to claim 1,
Wherein a stepped hole formed in the inner side of the drainage channel is formed in a trapezoidal shape in a downwardly directed flow.
The method according to claim 1,
Characterized in that the stepped hole formed in the inner side of the drainage channel is formed of a cement structure or a structure of a synthetic resin material.

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