KR200167575Y1 - Corner overflow structure - Google Patents

Abstract

The present invention relates to a corner drainage structure to facilitate the angle control of the drainage when constructing the drainage.

Drainage paths are constructed by connecting each of the drainage paths of a certain length in succession. When constructing a drainage path, it is necessary to change the angle of the drainage path according to the terrain, and therefore, a drainage path having a separate angle control function is required.

Therefore, in the present invention, in the drainage structure, a portion of both side walls of the cylinders 12a and 12b having the upper portion is cut at regular intervals, and the square tube-shaped channel 16a having the upper portion is opened at the one incision portion ( A pair of inner and outer connecting cylinders 10a and 10b integrally connected to each other and forming the cylinder 12a of the inner connecting cylinder 10a so that each of the flow paths 16a and 16b is formed. The cylinder 12a of the inner connecting cylinder 10a was inserted into the cylinder 12b of the outer connecting cylinder 10b in a state in which the opposite direction was achieved, thereby enabling horizontal rotation within a predetermined angle to each other.

By the present invention of such a structure there is an effect that can be easily changed direction without leakage of sewage and rain water.

Description

Corner gutter structure

The present invention relates to a drainage channel, and more particularly, to a corner drainage structure installed at a portion where the direction of the drainage path is changed.

In general, the drainage is to allow the rainwater or sewage to flow smoothly into the river or river, such a drainage is installed in the same place as the edge of the road and mainly composed of concrete structures.

Nowadays, synthetic resins are injected to a certain length or steel plates are banded to produce drainage channels of a certain length, and they are used by assembling them together when constructing drainage channels.

However, the drainages made in this way are constructed by connecting each drainage of a certain length in succession when installing, and when the drainage is constructed, it is necessary to change the direction of the drainage depending on the terrain. It requires a corner drain that is easy to adjust.

The present invention is devised to facilitate the angle adjustment of the drainage channel, and an object of the present invention is to provide a corner drainage structure that facilitates the angle adjustment without leaking sewage and rainwater.

1 is a perspective view showing a corner drainage structure according to the present invention,

Figure 2 is an exploded perspective view showing a corner drainage structure according to the present invention,

3 is a cross-sectional perspective view of FIG.

Figure 4 is a bottom perspective view showing the structure of the coupling portion of the flow path according to the present invention,

Figure 5 is a longitudinal cross-sectional view of the connecting portion according to the present invention,

Figure 6 is a plan view showing the operating state of the connecting portion according to the present invention,

Figure 7 is a state in which the pin drained to the ground installed corner drainage of the present invention,

8 is a state diagram in which the corner drainage of the present invention is fixed to the ground by a synthetic resin plate.

*** Explanation of symbols for the main parts of the drawing ***

10a, 10b-Internal and External Connections 12a, 12b-Cylinders

14a, 14b-floor 15a, 15b-sidewalls

16a, 16b-Euro 18-Axis

19-step 20-extension

21-Coupling 23-Flange

24-Strength 25-Elastic Piece

26-coupling groove 28-insert

29-Horizontal ribs 30a, 30b-Straight drain

40-Pin 42-Jam Jaw

44- Synthetic resin board

The present invention for achieving the above object, in the connecting portion structure provided between the drainage and the drainage so as to easily change the direction of the drainage, the upper part of the opening of both sides of the wall section of the cylindrical section is cut at regular intervals, one side incision A pair of inner and outer connecting cylinders formed by integrally connecting a rectangular tubular channel having an upper portion opened therein, the inner connecting cylinder in a state in which each of the flow paths are formed in the opposite direction by forming a smaller cylinder of the inner connecting cylinder. It is achieved by inserting the cylinders inside the cylinder of the external connection cylinder to allow horizontal rotation within a certain angle to each other.

Hereinafter, described in detail with reference to the accompanying drawings the structure of the subject innovation.

1 is a perspective view showing a corner drainage structure according to the present invention, Figure 2 is an exploded perspective view showing a corner drainage structure according to the present invention.

As shown, the connection portion of the present invention is composed of an inner connecting tube (10a) and the outer connecting tube (10b).

The inner and outer connecting cylinders 10a and 10b cut both side walls of the cylinders 12a and 12b having the upper portion opened at regular intervals, and the square tube-shaped flow passages 16a and 16b having the upper portion opened to the one cut portion. ) Is integrally connected, the diameter of the cylinder (12a) of the inner connecting cylinder (10a) has a size of the inner diameter of the cylinder (12b) of the outer connecting cylinder (10b) of the cylinder of the inner connecting cylinder (10a) 12a) is inserted into the cylinder 12b of the outer connecting tube 10b. At this time, the flow paths 16a and 16b of the respective inner and outer connection cylinders 10a and 10b are coupled in a state in which the opposite directions are achieved.

When the inner connecting tube 10a is inserted into the outer connecting tube 10b, the cylindrical side wall 15b of the outer connecting tube 10b elastically supports the cylindrical side wall 12a of the inner connecting tube 10a to be in close contact. Thus rotation is possible while maintaining airtightness. The inner connection tube 10a coupled as described above is rotated within the clearance gap of the flow passage 16a inserted into the cutout portion of the outer connection cylinder 10b as shown in FIG. 6. It is preferable to divert at an angle of about 45 ° because there is a risk of damaging or flooding the drainage path under hydraulic pressure.

In addition, a plurality of horizontal ribs 29 are provided on the inner surface of the inner connecting cylinder 10a at regular intervals, and a plurality of horizontal ribs 29 are formed in the flow path 16b of the outer connecting cylinder 10b.

In addition, FIG. 3 is a step 19 having the thickness of the cylindrical bottom 14a of the inner connecting cylinder 10a on the cylindrical bottom 14b of the outer connecting cylinder 10b as shown in the cross-sectional perspective view of FIG. Therefore, when the inner connecting tube 10a is inserted, the bottom 14a of the inner connecting tube 10a is inserted into the step 19 of the bottom 14b of the outer connecting tube 10b. do. Thus, sewage and rainwater flowing through the connection flows smoothly.

In addition, as shown in Figs. 1 and 5, the flow paths of the inner and outer connecting cylinders 10a and 10b are connected to drainage paths through which wastewater and rainwater flow in and out. The ends of each of the flow paths 16a and 16b of the inner and outer connecting cylinders 10a and 10b are easily connected to the straight drain passages 30a and 30b. That is, flanges 23 are formed at both upper ends of the inner and outer connecting cylinders 10a and 10b. In particular, the bottom surface of the flange 23 formed on both sides of the flow path 16b is formed with a force 24 for reinforcing the flange 23, between the force 24 and the side wall of the flow path elastic piece inclined in the side wall direction Protruding from the 25 to form a coupling groove 26 between the side wall.

At this time, the end portion of the flow path 16a connected to the straight drain passage 30a into which rainwater or filthy water flows has a step of about 1/2 of the thickness of the drain passage so that the insertion portion 28 to be described later is inserted. Expanded portion 20 is formed to expand the width of the flow path, the flange 23 formed on both sides of the upper end of the expansion portion 20 is forcibly fitted to the coupling groove 26 of the linear drainage channel 30a Coupling portion 21 is formed.

At the end of the flow path 16b on the opposite side of the coupling portion 21, as shown in FIG. 4, an insertion portion 28 having a step is formed in a structure corresponding to the step of the expansion part 20. At this time, the elastic piece 25 and the force 24 are not formed in the site | part of the length of the step part of the expansion part 20 in the bottom end of the flange 23 which forms a step.

The structure of such a flow path has the same structure of the linear drainage paths 30a and 30b. Accordingly, when the corner drainage passage is connected to the straight drainage passages 30a and 30b, the upper end of both sides of the expansion portion 20 is inserted while inserting the insertion portion 28 of the straight drainage passage 30a connected to the inside of the extension portion 20. The coupling portion 21 formed in the coupling groove 26 of the drainage path to be connected by inserting the interference fit.

In addition, the flow path 16b through which the rainwater or filthy water is drained is formed with an insertion portion 28 having a stepped outer surface, and is inserted into the expansion portion 20 of the linear drainage channel 30b, and the coupling part of the linear drainage channel 30b. (21) is fitted into the coupling groove 26 of the flange 23 by fitting.

Due to this connection structure, no gap is generated between the flange 23, the flange 23, the flow paths 16a, 16b, and the drainage path, and within the connection portion of the flow paths 16a, 16b and the straight line drainage paths 30a, 30b, The outer side faces side by side to form a gas tight and rigid channel.

On the other hand, when the inner and outer connecting cylinders (10a, 10b) is installed on the ground in such a structure, as the season changes, the ground freezes and melts, causing the upset settlement. At this time, unless the inner and outer connecting cylinders 10a and 10b are fixed to the ground, the inner and outer connecting cylinders 10a and 10b are separated from the ground. For this reason, conventionally, a pin was put in the center of the bottom of the drainage passage and fixed to the ground. However, sewage leaks between the fins and the drainage channels, which eventually causes groundwater to be contaminated. Therefore, the present invention drives the pin 40 having the locking jaw 42 on the outer periphery in the diagonal direction from the bottom to both sides of each of the flow paths (16a, 16b) installed as shown in Figure 7, the outer connecting cylinder (10a) ( Fix 10b) to the ground. When it is fixed in this way, even if the pin 40 is located above the level of the sewage flowing through the flow path or is within the water level, the sewage does not occur because it receives less water pressure. The drainage channel is firmly installed because it does not fall off once it gets stuck in the ground by the locking jaw 42 formed in the pin 40. In particular, since the direction in which the drainage path is separated by earth pressure acts in the vertical direction from the ground, there is also an effect that is more firmly installed by the pins 40 installed diagonally on both sides.

In addition, as another structure for fixing the inner and outer connection cylinders (10a, 10b) to the ground as shown in Figure 8 coupling portion 21 is connected to the flow path (16a), 16b and the linear drainage channel (30a, 30b) And a flexible synthetic resin plate 44 which is not corroded between the coupling groove 26 and the expansion part 20 and the insertion part 28, and both ends thereof are elongated to be embedded in the ground. It is constructed firmly without any damage to (16b).

As discussed above, the drainage connection part of the present invention is inserted into the external connection tube so that the cylindrical side wall of the external connection cylinder is elastically supported while keeping the cylindrical side wall of the internal connection cylinder close and easy to change direction within a certain angle and airtightness. There is an advantage that can easily change the direction of the flow path without maintaining the leakage of sewage and rain water.

In addition, when the straight drainage channel and the flow path are connected, the layers are not layered with each other, and the insertion part and the expansion part are overlapped and inserted so that the coupling part is coupled to the coupling groove in a tight fit so that the rainwater and sewage flow can be smoothly connected. At the same time, the appearance is beautiful.

Claims (6)

In the structure of the connection portion provided between the drainage and the drainage so as to easily change the direction of the drainage, As long as some sections of both side walls of the cylinders 12a and 12b having the upper opening are cut at regular intervals, and the square tube-shaped flow paths 16a and 16b having the upper opening are integrally connected to one side cutout. Provided with a pair of inner and outer connecting cylinders (10a) (10b), The cylinder 12a of the inner connecting cylinder 10a is made small so that each of the flow paths 16a and 16b has the opposite direction, and the cylinder 12a of the inner connecting cylinder 10a is connected to the outer connecting cylinder 10b. Corner drainage structure, characterized in that inserted into the cylinder (12b) of the inside to enable horizontal rotation within a certain angle to each other. The corner drainage structure according to claim 1, wherein a central portion of the bottoms (14a) and (14b) of the nested inner and outer connecting cylinders (12a) (12b) is pivotally coupled (18). 3. The flange of claim 1 or 2, further comprising flanges 23 on both upper ends of the inner and outer connecting cylinders. Forces 24 are formed on both sides of the bottom surface of the flange 23 at the end of the flow path 16b through which rain water and sewage are discharged. Between the force ribs 24 and the side wall of the flow path 16b to form an engaging groove 26 between the side wall by protruding the elastic piece 25 inclined downward, An insertion portion 28 which forms a thin step around the end outer surface of the side flow path 16b through which the rainwater or filthy water is drained, and at the same time, a thin bottom end of the flange 23 at a predetermined length; An expansion part 20 having an inner side extended to have a step so as to correspond to the insertion part 28 on an inner side of an end of the other side flow path 16a connected to the drainage path 30a through which rainwater and sewage flow; Corner drainage structure, characterized in that the upper portion of the expansion portion (20) constitutes the engaging portion (21) for fitting the flange 23 into the coupling groove 26 of the flange of the other side of the drainage. The corner drainage structure according to claim 1, wherein a plurality of horizontal ribs (29) are formed at regular intervals on the inner wall surfaces of the inner connecting tube (10a) and the outer connecting tube (10b). The pins 40 having the locking jaws 42 on the outer periphery of the lower flow paths 16a and 16b are driven on both sides of each of the flow paths 16a and 16b. Corner drainage structure, characterized in that fixed to the ground. The method of claim 3, wherein the coupling portion 21, the coupling groove 26 and the expansion portion 20 and the insertion portion 28 of the passage 16a, 16b and the linear drainage path 30a, 30b are connected. A corner drainage structure comprising a flexible synthetic resin plate 44 that does not corrode in between, and its length is elongated to be embedded in the ground to fix the flow paths 16a and 16b to the ground.