WO2020059966A1 - Inclined multi-stage spiral underground inlet - Google Patents

Abstract

An inclined multi-stage spiral underground inlet according to one aspect of the present invention may comprise: a flow unit through which water flows; a shaft for conveying the water to an underground inflow facility through the flow unit; a vortex unit which is provided on one side of the flow unit and connected to the shaft to form a vortex of the water conveyed to the shaft; and an inclined inflow part which is provided between the vortex unit and the shaft, and accelerates the flow of the water.

Description

Inclined multi-stage spiral underground entrance

The present invention relates to an inclined multi-stage spiral underground inlet, and more particularly, to an inclined multi-stage spiral spiral underground inlet capable of increasing inflow efficiency and inflowable flow rate.

Generally, an inlet through which rain may flow into an underground inflow facility after rain may be formed in a side drain of an existing drainage channel or road.

These, the inlet is a type that is mainly used there are tangential and spiral. The tangential inlet does not take up much installation space during construction, and construction is simple. In addition, the spiral inlet has a spiral structure from the shaft to the inlet to form a vortex inside the inlet, thereby enabling natural vortex flow formation.

However, vortex flow is formed inside the inlet that flows water such as rain into the existing underground inflow facility, and flow is excluded. The bottom surface of the existing inlet has a flat shape and applies a floor slope or approaches a vertical tunnel. By changing the width of the vortex flow is induced. In this process, the efficiency of the flow rate exclusion is highest along the streamline where the flow rate is formed most rapidly. Due to the flat bottom surface, there is a limit to increase the flow rate exclusion efficiency by utilizing these advantages.

In addition, there is a problem that the flow rate may be lowered because the friction surface between the flat bottom surface and the running water is widened.

The present invention was devised to solve the above problems, and an object of the present invention is to provide an inclined multi-stage spiral spiral underground inlet capable of forming a vortex and stably maintaining the efficiency of flow exclusion even at low flow rates.

An inclined multi-stage spiral underground inlet according to an embodiment of the present invention for achieving the above object is a flow portion through which water flows, a shaft for transferring water to the underground inflow facility by the flow portion, and one side of the flow portion It may be provided with a vortex portion which is provided in and connected to the shaft to form a vortex of water delivered to the shaft, and is provided between the vortex portion and the shaft to provide an inclined inlet to accelerate the flow of water.

The flow portion may include a pair of multi-stage plates facing each other, and a connection plate provided between the pair of multi-stage plates to connect the pair of multi-stage plates.

The multi-stage plate may include a horizontal surface formed by protruding horizontally from the side surface of the flow portion to the other side, and a vertical surface formed by descending vertically from the horizontal surface.

The inclined inlet portion is provided in a form facing each other, but is provided between a pair of multi-stage inclined plates and a pair of multi-stage inclined plates in which a downhill is formed in the direction of the vortex in the flow portion to connect the pair of multi-stage inclined plates It can be provided with a connecting inclined plate.

The multi-stage inclined plate has a horizontal inclined surface on which one side extends from the horizontal surface and the other side is connected to the vortex part, and a vertical inclined surface on which one side extends vertically from the horizontal inclined surface and one side extends from the vertical surface and the other side is connected to the vortex part. can do.

The vortex portion may be provided in a shape in which the width narrows toward the shaft to increase the flow rate of water.

The shaft may be provided with a spiral spiral on the inner surface so that water can maintain a vortex when water enters the underground inflow facility.

According to the inclined multi-stage spiral inlet according to the present invention, it is possible to stably maintain the flow rate exclusion efficiency even at low flow rates by the flow portion, the inclined portion, and the vortex portion.

1 is a perspective view of an inclined multi-stage spiral underground inlet according to an embodiment of the present invention.

Figure 2 is a plan view of the inclined multi-stage spiral underground inlet shown in Figure 1;

Figure 3 is a perspective view showing the flow portion of the inclined multi-stage spiral underground inlet shown in Figure 1;

Figure 4 is a perspective view showing the inclined inlet of the inclined multi-stage spiral inlet shown in Figure 1;

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the inclined multi-stage spiral underground inlet according to an embodiment of the present invention.

1 is a perspective view of an inclined multi-stage spiral underground inlet according to an embodiment of the present invention, and FIG. 2 is a plan view of an inclined multi-stage spiral underground inlet shown in FIG. 1.

1 and 2, the inclined multi-stage spiral underground inlet 10 according to an embodiment of the present invention includes a flow part 100 through which water flows and an underground inflow facility 20 by the flow part 100 The water shaft 200 for transferring water to the vortex unit 300 and the vortex unit 300 provided on one side of the flow unit 100 and connected to the water shaft 200 to form a vortex of water delivered to the water shaft 200 It is provided between and the shaft 200 may be provided with an inclined type inlet 400 to accelerate the flow of water.

The sloped multi-stage spiral underground inlet 10 forms a vortex when rainwater flows into an underground passage formed at a lower altitude than the surroundings, such as a tunnel or underpass, when it flows to a reservoir or underground inflow facility 20 installed in the basement. It can be a passage to the underground inlet, and when water flows into the underground inlet, such as a farm waterway, it can form a vortex and the water can be delivered to the bottom.

On the other hand, the flow portion 100 of the inclined multi-stage spiral underground inlet (10) may be formed in connection with the underpass so that water such as rainfall in rainy weather flows into the underground inflow facility (20). The flow part 100 may be formed with side walls 30 that induce water to flow into the underground inflow facility 20 through the flow part 100. The side wall 30 is formed to a predetermined height and may be prevented from overflowing in the rain. In addition, the flow unit 100 is formed at a higher position than the water shaft 200 so that water flows into the water shaft 200, and water flowing from the flow unit 100 may flow into the water shaft 200. In addition, the flow unit 100 may be formed in a multi-stage so that even a small amount of water in the rain can flow into the shaft 200. The flow portion 100 will be described in detail later.

On the other hand, the shaft 200 may be formed vertically so that water flowing through the flow portion 100 and the inclined inlet portion 400 can pass through the vortex portion 300 and flow into the underground inflow facility 20. . Here, the water shaft 200 is formed in a cylindrical shape, and water flowing through the flow part 100 may form a vortex by the vortex part 300 and may fall downward. Water flowing into the underground inflow facility 20 through the shaft 200 forms a vortex and falls to the bottom, so that even if a small flow rate is introduced, energy of the flow may be dissipated.

On the other hand, the vortex section 300, the water delivered to the shaft 200 through the flow portion 100 and the inclined inlet portion 400 forms a vortex in the shaft 200 and the underground inflow facility 20 formed at the bottom. The width becomes narrower as it moves toward the shaft 200 to form a vortex when it is transferred to and may be formed in a spiral shape.

In general, when water flows into the vortex portion 300 through the flow portion 100 and the inclined inflow portion 400, the maximum flow velocity may be generated when water passes through the vortex portion 300. At this time, as shown in the drawing, when the outermost line is formed in a V-shape and a U-shape along the streamline where the maximum flow rate occurs, the maximum flow rate can be induced from the spiral to the vortex part 300.

In addition, the shape of the vortex part 300 may be changed in size, shape, and material according to characteristics of the area to be constructed.

Next will be described in detail with respect to the flow portion 100 of the inclined multi-stage spiral underground inlet (10). In the following description, only different parts from the above-described embodiment are described in detail, and detailed descriptions of the same or extremely similar parts are omitted.

3 is a perspective view showing a flow portion of the inclined multi-stage spiral underground inlet shown in FIG.

1 to 3, the inclined multi-stage spiral underground inlet 10 according to an embodiment of the present invention flows through the water flowing part 100 and the flow part 100 to the underground inflow facility 20 Water shaft 200, which is provided on one side of the flow unit 100 and connected to the water shaft 200 to form a vortex of water delivered to the water shaft 200 and the vortex unit 300 and the vortex unit 300 and It is provided between the shaft 200 may be provided with an inclined inlet 400 to accelerate the flow of water.

Here, the flow unit 100 may include a pair of multi-stage plates 110 and a connecting plate 120 facing each other.

The multi-stage plate 110 may include a horizontal surface 111 formed by protruding horizontally from the side of the flow portion 100 to the other side, and a vertical surface 112 formed by descending vertically from the horizontal surface 111. A plurality of horizontal surfaces 111 and vertical surfaces 112 are continuously provided toward the longitudinal center of the flow part 100, and the deeper the flow part 100 is, the deeper the depth of the flow part 100 is toward the longitudinal center of the flow part 100. You can.

In addition, the connecting plate 120 is provided between the pair of multi-stage plates 110 in the longitudinal center of the flow portion 100, that is, facing each other, to serve to connect the pair of multi-stage plates 110. have. Here, the connecting plate 120 is formed at the deepest position where water can flow through the flow portion 100 so that the water flowing through the horizontal surface 111 collects into the connecting plate 120, and the connecting plate 120 and both sides Water may move to the vortex part 300 along the flow path formed in the vertical surface 112. Therefore, even a small flow rate can be easily moved to the underground inlet 10.

Next will be described with respect to the inclined inlet portion 400 of the inclined multi-stage spiral inlet (10). In the following description, only different parts from the above-described embodiment are described in detail, and detailed descriptions of the same or extremely similar parts are omitted.

4 is a perspective view showing an inclined inlet of the inclined multi-stage spiral inlet shown in FIG.

1 to 4, the inclined multi-stage spiral underground inlet 10 according to an embodiment of the present invention flows through the water flowing part 100 and the flow part 100 to the underground inflow facility 20 Water shaft 200, which is provided on one side of the flow unit 100 and connected to the water shaft 200 to form a vortex of water delivered to the water shaft 200 and the vortex unit 300 and the vortex unit 300 and It is provided between the shaft 200 may be provided with an inclined inlet 400 to accelerate the flow of water.

Here, the inclined inlet part 400 may include a pair of multi-stage inclined plates 410 and a connecting inclined plate 420 provided in a form facing each other.

The multi-stage inclined plate 410 is provided to form a downhill direction from the flow portion 100 to the vortex portion 300, one side extending from the horizontal surface 111 of the multi-stage plate 110 and the other side connected to the vortex portion 300 The vertically inclined surface 411 and the horizontally inclined surface 411 descend vertically, and one side extends from the vertical surface 112 of the multi-stage plate 110 and the other side is provided with a vertical inclined surface 412 connected to the vortex part 300 You can. The horizontal inclined surface 411 and the vertical inclined surface 412 are continuously provided toward the center of the inclined type inlet 400 in the longitudinal direction, so that the inclined inlet part 400 toward the longitudinal center of the inclined inlet 400 is provided. The depth of 400) can be deeper.

In addition, the connecting inclined plate 420 is provided between a pair of multi-stage inclined plates 410 in the longitudinal center of the inclined type inlet 400, that is, facing each other, to serve to connect a pair of multi-stage inclined plates 410. can do. Here, the connecting inclined plate 420 is formed at the deepest position where water can flow through the inclined inlet 400 so that the water flowing through the horizontal inclined surface 411 collects in the connected inclined plate 420, and the connected inclined plate 420 ) And water flows along the flow paths formed on both sides of the vertical inclined surfaces 412 to the vortex part 300. Accordingly, even at a small flow rate, the flow of water can be accelerated at the same time as it is easily moved to the underground inlet 10, thereby increasing the inflow efficiency and the inflowable flow rate.

In the above, the inclined multi-stage spiral underground inlet according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. And those skilled in the art to understand the spirit of the present invention can easily propose other embodiments by adding, changing, deleting, adding, or the like components within the scope of the same spirit, but it is also within the scope of the invention. will be.

Claims (7)

1. The flow part where water flows,

   A shaft that delivers water to the underground inflow facility by the flow part,

   A vortex portion provided on one side of the flow portion and connected to the shaft to form a vortex of water delivered to the shaft,

   An inclined multi-stage spiral underground inlet including an inclined inlet provided between the vortex and the shaft to accelerate the flow of water.
2. According to claim 1,

   The flow portion and a pair of multi-stage plates facing each other,

   It is provided between the pair of multi-stage plate, characterized in that it comprises a connecting plate for connecting the pair of multi-stage plate inclined multi-stage spiral underground inlet.
3. According to claim 2,

   The multi-stage plate is a horizontal surface formed by protruding horizontally from the side surface of the flow portion to the other side,

   Inclined multi-stage spiral underground inlet, characterized by having a vertical surface formed by descending vertically from the horizontal surface.
4. According to claim 3,

   The inclined inlet portion is provided in a form facing each other, a pair of multi-stage inclined plate is formed in the direction of the vortex portion in the flow portion,

   It is provided between the pair of multi-stage inclined plate, the inclined multi-stage spiral underground inlet, characterized in that it comprises a connecting inclined plate for connecting the pair of multi-stage inclined plate.
5. The method of claim 4,

   The multi-stage inclined plate has a horizontal inclined surface with one side extending from the horizontal surface and the other side connected to the vortex portion,

   An inclined multi-stage spiral underground inlet, characterized in that vertically descending from the horizontal inclined surface, one side extends from the vertical surface and the other side has a vertical inclined surface connected to the vortex.
6. The method of claim 5,

   The vortex portion inclined multi-stage spiral underground inlet, characterized in that provided with a shape that narrows the width toward the water shaft to increase the flow rate of the water.
7. The method of claim 6,

   The shaft is an inclined multi-stage spiral spiral inlet, characterized in that it has a spiral helical projection on the inner surface so that water can maintain a vortex when water enters the underground inflow facility.

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