KR20210013907A - Structure of Waterway - Google Patents

Abstract

The present invention relates to a waterway structure comprising: a pair of support rails installed to maintain the same separation distance along a water guide path; a socket block formed to allow both longitudinal ends and the upper surface thereof to be opened and have a socket bottom surface unit having a pair of socket block rail grooves formed on the lower surface thereof to maintain the same separation distance and a pair of socket sidewall units bent from both edges in the width direction of the socket bottom surface unit in the same direction, and installed on the support rails to insert the support rails into the socket block rail grooves; and a plurality of waterway pipes formed to allow both longitudinal ends and the upper surface thereof to be opened and have a pipe bottom surface unit and a pair of pipe sidewall units bent from both edges in the width direction of the pipe bottom surface unit, and installed on the socket block to connect both longitudinal opening areas thereof to longitudinal opening areas of the socket block. Accordingly, the initial shape condition of a waterway can be stably maintained. A horizontal direction change and a vertical direction change of the waterway are facilitated. Connection work of waterway pipes is facilitated.

Description

Structure of Waterway

The present invention relates to a channel structure, and more particularly, to a structure for forming a channel by a method of continuously installing a plurality of channel pipes having a predetermined length section, such as a flume tube (Flume Tube).

It is necessary to form a waterway on the surface of the waterway area in order to guide a large amount of water such as rainwater from roadsides, agricultural waterways, and large residential areas to rivers, reservoirs, or agricultural land.

In order to form a water channel, a method of continuously installing a plurality of water pipes having a predetermined length section, such as a flume tube, on the ground surface has been devised and used.

13 is a view showing a water pipe according to a conventional water passage structure.

The conventional water channel structure has a plurality of water pipes 150 installed along a predetermined water guide path, and a wire rope 161 installed in the water pipe 150, as shown in FIG. 13.

Each waterway pipe 150 includes a pipe bottom portion 151, a pair of observation wall portions 152 bent in the same direction from both edges in the width direction of the pipe bottom portion 151, and an outer surface of each observation wall portion 152 It has a horizontal rib 153 and a vertical rib 154 formed in.

Each water pipe 150 is formed so that both ends and upper surfaces are open.

The tube bottom portion 151 has a tube bottom seating step 151b formed at one end of the bottom, and a tube bottom seating groove 151c formed at the top of the other end.

Each observation wall portion 152 is formed on an outer surface of one end so that an observation wall seating stair portion 152a is connected to the pipe floor seating stair portion 151b, and an observation wall seating groove 152b is formed on the inner surface of the remaining one end. It is formed to be connected to the pipe bottom seating groove (151c).

The horizontal rib 153 has a rope insertion hole 153a formed in the central region.

In addition, the horizontal rib 153 has a rope laying hole 153b connected to the rope insertion hole 153a and formed to be disposed along the longitudinal direction of the tube bottom portion 151.

The vertical rib 154 is formed to intersect with the horizontal rib 153.

The wire rope 161 is installed to pass through the rope laying hole 153b.

A method of forming a waterway using a conventional waterway structure having the above-described configuration will be described with reference to FIG. 14 as follows. For convenience of explanation, a method of forming a partial section of a waterway will be described.

First, a water channel 150 is installed so that the bottom of the bottom surface 151 contacts the ground.

Install another waterway pipe so that the pipe floor seating stair part 151b and the observation wall seating stair part 152a are respectively seated in the pipe bottom seating groove 151c and the observation wall seating groove 152b belonging to the next installed waterway pipe 150 do.

Next, after laying the wire rope 161 to pass through the rope laying hole (153b) belonging to a pair of adjacent waterway pipes through the rope insertion hole (153a), the waterway pipe by clamping both ends of the wire rope 161 (150) Constrain each other.

Next, a leak prevention work is performed on the connection area between the water pipes 150 by applying mortar to the pipe bottom mounting groove 151c and the observation wall mounting groove 152b.

However, according to the conventional water channel structure, there is a problem in that it is difficult to stably maintain the initial formation state of the water channel because there is no means for maintaining the initial installation state of the water channel 150.

And since the water pipes 150 are directly connected to each other, there is a problem in that it is difficult to change the horizontal direction or the vertical direction of the water channel.

In addition, since the wire rope 161 is installed in the rope laying hole 153b and then clamped, and the shape of both ends of the waterway pipe 150 is different, there is a problem that it is difficult to connect the waterway pipe 150.

As a related prior document, there is Korean Utility Model Registration Publication No. 20-0381471 (Registration date: April 04, 2005, title of invention: water pipe unit), and the prior document contains the technology related to the conventional water channel structure described above. It is disclosed.

Accordingly, an object of the present invention is to provide a waterway structure that can stably maintain the initial formation state of a waterway, facilitates horizontal or vertical changeover of a waterway, and facilitates connection work of waterway pipes.

The above object is, according to the present invention, a pair of support rails installed so as to maintain the same separation distance along the water guide path; Both ends and upper surfaces have a socket bottom surface on the bottom surface in which a pair of socket block rail grooves are formed to maintain the same separation distance, and a pair of socket side wall portions bent in the same direction from both edges in the width direction of the socket bottom surface. A socket block formed to be opened and installed on the support rail so that the support rail is inserted into the socket block rail groove; With a pair of observation wall portions bent in the same direction from both edges in the width direction of the tube bottom surface and the tube bottom surface, both ends and top surfaces are open, and the end open area is connected to the terminal open area of the socket block. It is achieved by a channel structure, characterized in that it includes a plurality of channel pipes installed in the socket block.

Here, in order to stably maintain the initial installation state of the water pipe, the pipe bottom portion is formed such that a pair of water pipe rail grooves on the bottom surface maintain the same separation distance; The water channel pipe is preferably installed in the socket block so that the support rail is inserted into the water channel pipe rail groove.

In addition, it is preferable to further include a rail restraint bracket installed on the support rails to stably maintain the initial installation state of the support rails so as to maintain a separation distance between the support rails.

In addition, in order to more stably maintain the initial installation state of the support rail, the rail restraint bracket is formed in a concave cross-section with both ends and upper surfaces open, respectively, and a pair of rail restraint pockets arranged parallel to each other and the above It is preferable that it has a connecting plate portion connecting the inner lower end of the rail constraining pocket, the upper surface open area of the rail constraining pocket faces upward, and the support rail is inserted into the rail constraining pocket.

In addition, in order to maintain the initial installation state of the support rail more stably and to facilitate the installation work of the rail restraint bracket, the rail restraint brackets are formed in concave cross-sections with open ends and bottoms, respectively, and parallel to each other. It has a connecting plate part connecting the arranged pair of rail constraining pockets and the inner lower end of the rail constraining pocket, and is installed so that the bottom open area of the rail constraining pocket faces downward and the support rail is inserted into the rail constraining pocket. It is desirable.

In addition, in order to more stably maintain the initial installation state of the support rail, the support rail includes a long rectangular support plate portion, and a groove insertion portion formed on an upper surface of the support plate to have a narrower width than the support plate portion; The socket block is preferably installed on the support rail so that the groove insertion part is inserted into the socket block rail groove.

In addition, to facilitate the installation work of the support rail, the support rail is divided into a plurality, and when the divided portion of the support rail is referred to as a split rail, the split rail is formed in a tubular shape; It has a fitting plate formed to have the same appearance as the split rail and a pair of force fitting protrusions extending in a direction away from both sides of the fitting plate, and the force fitting protrusion is forcibly fitted into an adjacent end of an adjacent segment rail. It is preferable to further include a rail connector installed so that the fitting plate is fitted between adjacent ends of the adjacent split rails.

Therefore, according to the present invention, a pair of support rails installed to maintain the same separation distance along the water guide path, a socket block installed on the support rail so that the support rail is inserted into the socket block rail groove formed on the bottom surface, and both ends By including a plurality of channel pipes installed on the support rail so that the open area is connected to the terminal open area of the socket block, the initial formation state of the channel can be stably maintained (the initial installation state of the channel pipe can be stably maintained by the socket block. Yes), it is easy to change the horizontal direction or vertical direction of the waterway by changing the shape of the socket block, and the connection work of the waterway pipe becomes easy (no wire rope is required, and the shape of both ends of the waterway pipe can be the same).

1 is a view showing a socket block according to an embodiment of the present invention;
Figure 2 is a view showing a water pipe according to an embodiment of the present invention,
3 is a view showing a rail restriction bracket according to an embodiment of the present invention,
4, 5, and 6 are views each showing a method of forming a waterway using a waterway structure according to an embodiment of the present invention;
7 is a view showing a rail restraint bracket according to another embodiment of the present invention;
8 is a view showing a support rail according to another embodiment of the present invention,
9, 10 and 11 are views each showing a socket block according to another embodiment of the present invention;
12 is a view showing a water pipe according to another embodiment of the present invention;
13 is a view showing a water pipe according to a conventional water passage structure;
14 is a diagram showing a method of forming a water channel using a conventional water channel structure.

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

1 is a view showing a socket block according to an embodiment of the present invention, Figure 2 is a view showing a water channel according to an embodiment of the present invention, Figure 3 is a rail restraint according to an embodiment of the present invention It is a diagram showing the bracket.

A waterway structure according to an embodiment of the present invention, as shown in these drawings, a pair of support rails 10 installed to maintain the same separation distance along the water guide path, and installed on the support rail 10 It has a rail connector 20, a rail restraint bracket 30 and a socket block 40, and a plurality of water channel pipes 50 installed in the socket block 40.

The support rail 10 is divided into a plurality, and the split rail 10a is formed in a tubular shape. Here, the split rail 10a means each divided portion of the support rail 10.

The rail connector 20 has a fitting plate 21 formed to have the same appearance as the split rail 10a, and a pair of force fitting protrusions 22 extending in a direction away from both sides of the fitting plate 21.

The rail connector 20 having such a configuration is forcibly fitted inside the adjacent end of the split rail 10a adjacent to the forcing fitting protrusion 22, and between the adjacent ends of the split rail 10a adjacent to the fitting plate 21 It is installed to fit in.

The rail restraint bracket 30 has a pair of rail restraint pockets 31 formed in concave cross-sections with both ends and the upper surface open, and a connection plate part 32 connecting the inner lower end of the rail restraint pocket 31 Has.

A pair of rail restriction pockets 31 are arranged to be parallel to each other.

The rail confinement bracket 30 having such a configuration is installed so that the upper surface open area of the rail confinement pocket 31 faces upward, and the support rail 10 is inserted into the rail confinement pocket 31.

The rail restraint bracket 30 restrains the support rails 10 so that the separation distance between the support rails 10 is maintained in a state installed on the support rails 10.

The socket block 40 has a socket bottom surface portion 41 and a pair of socket side wall portions 42 bent in the same direction from both edges in the width direction of the socket bottom surface portion 41.

The socket block 40 is formed so that both ends and upper surfaces are open.

The socket bottom portion 41 is formed so that a pair of socket block rail grooves 41a are kept at the same distance on the bottom surface.

The socket block rail groove 41a is formed to have a width through which the upper end of the rail constraining pocket 31 can enter.

In addition, the socket bottom portion 41 has socket bottom seating grooves 41b formed at both ends of the upper surface.

Each socket side wall portion 42 has one socket side wall seating groove 42a formed at both ends thereof.

The socket block 40 having this configuration is installed on the support rail 10 so that the support rail 10 is inserted into the socket block rail groove 41a.

Each waterway pipe 50 has a pipe bottom surface portion 51 and a pair of observation wall portions 52 bent in the same direction from both edges in the width direction of the pipe bottom surface portion 51.

Each water channel 50 is formed so that both ends and upper surfaces are open.

The pipe bottom portion 51 is formed such that a pair of water channel pipe rail grooves 51a on the bottom surface maintain the same separation distance.

The waterway pipe rail groove 51a is formed to have a width through which the upper end of the rail restriction pocket 31 can enter.

In addition, the tube bottom portion 51 has one tube bottom seating step portion 51b formed at both ends of the bottom surface.

Each observation wall portion 52 has an observation wall seating step portion 52a formed at both ends thereof.

The waterway pipe 50 having this configuration is installed so that the support rail 10 is inserted into the waterway pipe rail groove 51a.

In addition, the waterway pipe 50 is attached to the socket block 40 so that the pipe bottom seating step (51b) is seated in the socket floor seating groove (41b) and the observation wall seating step portion (52a) is seated in the socket side wall seating groove (42a). It is installed, and accordingly, both end open areas of the water pipe 50 are connected to the end open areas of the socket block 40.

A method of forming a waterway using a waterway structure according to an embodiment of the present invention having the above-described configuration will be described with reference to FIGS. 4 to 6 as follows. For convenience of explanation, a method of forming a partial section of a waterway will be described.

First, the split rails 10a are coupled to each other (see Fig. 4).

Next, install the rail restraint bracket (30) to the support rail (10) apart (see Fig. 5).

Next, the support rail 10 is installed on the ground (see Fig. 5).

Next, the socket block 40 is installed on the support rail 10 (see Fig. 6). The socket block 40 is installed so that the upper end of the rail constraining pocket 31 enters the socket block rail groove 41a.

Next, the water pipe 50 is installed in the socket block 40 (see Fig. 6). Installation of the waterway pipe 50 is made so that the upper end of the support rail 10 and the rail restriction pocket 31 enter the waterway pipe rail groove 51a.

Next, a leak prevention work is performed on the connection area between the water pipe 50 and the socket block 40 by applying mortar to the socket bottom mounting groove 41b and the socket side wall mounting groove 42a.

Meanwhile, in the above-described embodiment, the present invention is implemented by dividing the support rail 10, but when the formation section of the water channel structure is short, the support rail 10 may be integrally formed to implement the present invention.

In addition, in the above-described embodiment, the rail confinement bracket 30 is formed so as to have the rail confinement pocket 31 with an open top surface, but as shown in FIG. 7, the rail confinement bracket has a rail confinement pocket with an open bottom surface. 30') can be formed to practice the present invention.

7 is a view showing a rail restriction bracket according to another embodiment of the present invention.

The rail restriction bracket 30 ′ according to another embodiment of the present invention includes a pair of rail restriction pockets 31 ′ and rail restriction pockets 31 ′ formed in concave cross-sections with open ends and bottom surfaces. It has a connecting plate part 32' that connects the inner lower end of the.

A pair of rail constraining pockets 31' are arranged to be parallel to each other.

The rail confinement bracket 30' having such a configuration is installed such that the bottom open area of the rail confinement pocket 31' faces downward, and the support rail 10 is inserted into the rail confinement pocket 31'.

The rail restraint brackets 30 ′ constrain the support rails 10 so that the separation distance is maintained while being installed on the support rails 10.

The socket block rail groove 41a is formed to have a width through which the upper end of the rail restriction pocket 31 ′ can enter.

The waterway pipe rail groove 51a is formed to have a width through which the upper end of the rail restriction pocket 31 ′ can enter.

In addition, in the above-described embodiment, the support rail 10 is formed to have the same width over the entire height section, but the present invention can be carried out by forming the support rail with a relatively wide lower width as shown in FIG. have.

8 is a view showing a support rail according to another embodiment of the present invention.

The support rail 10 ′ according to another embodiment of the present invention includes a long rectangular support plate 11 ′, and a groove formed to have a narrower width than the support plate 11 ′ on the upper surface of the support plate 11 ′. It has an insertion part 12'.

The socket block 40 is installed on the support rail 10 so that the groove insertion portion 12' is inserted into the socket block rail groove 41a.

The waterway pipe 50 is installed on the support rail 10 so that the groove insertion part 12' is inserted into the waterway pipe rail groove 51a.

In addition, in the above-described embodiment, the socket block 40 and the socket block rail groove 41'a are formed in a form without bending, but as shown in Figs. 9, 10 and 11, in a form having a bending. The present invention can be practiced by forming a socket block and a socket block rail groove.

The socket block 40' and the socket block rail groove 41'a shown in FIG. 9 are formed in a form bent once in the horizontal direction in the middle.

If the socket block shown in Fig. 9 is used, the water channel can be switched in the horizontal direction.

The bending angle of the socket block 40' and the socket block rail groove 41'a shown in Fig. 9 is up to 90 degrees left and right (Fig. 1 shows that the bending angle of the socket block according to an embodiment of the present invention is zero. Case) possible. It is possible to bend up to 90 degrees in the opposite direction to the socket block 40' and the socket block rail groove 41'a shown in FIG.

The socket blocks 41" and 41"-1 and the socket block rail grooves 41"a and 41"-1a shown in FIGS. 10 and 11 are formed to be bent in a vertical direction in the middle.

If the socket block shown in Figs. 10 and 11 is used, the water channel can be changed in the vertical direction.

The bending of the socket blocks 41", 41"-1 and the socket block rail grooves 41"a, 41"-1a can be formed in a bent form (Figs. 9 and 10) or a curved shape (Fig. 11). .

In addition, in the above-described embodiment, the water pipe 50 is installed in the socket block 40 so that the support rail 10 is inserted into the water pipe rail groove 51a by forming a water pipe rail groove 51a on the pipe bottom surface 51 However, as shown in Fig. 12, the present invention can be practiced without forming a channel pipe rail groove. In the case of the water pipe shown in Fig. 12, since it is formed in the same shape over the entire length section, it can be cut and used as many times as necessary at the site.

As described above, according to the embodiment of the present invention, a pair of support rails 10 installed to maintain the same separation distance along the water guide path, and the support rail 10 in the socket block rail groove 41a formed on the bottom surface. ) By including a socket block 40 installed on the support rail 10 to be inserted, and a plurality of water channel pipes 50 installed so that both end open areas are connected to the end open areas of the socket block 40, The initial formation state can be stably maintained (the initial installation state of the waterway pipe can be stably maintained by the socket block), and the horizontal or vertical change of the waterway is easy by changing the shape of the socket block 40, It is easy to connect water pipes (no wire rope is required, and both ends of water pipes can be the same).

And while forming a water channel pipe rail groove on the bottom of the pipe bottom surface 51, by installing the water pipe 50 in the socket block 40 so that the support rail 10 is inserted into the water pipe rail groove 51a, the water pipe 50 ), the initial installation state can be stably maintained.

In addition, by adding rail restraint brackets 30 that are installed on the support rails 10 to constrain the support rails 10 so that the separation distance between the support rails 10 is maintained, the initial installation state of the support rails 10 It will be able to keep it stable.

In addition, a rail restraint bracket 30 is formed to have a pair of rail restraint pockets 31 formed in a concave cross-section with an open upper surface and a connection plate 32 connecting the inner lower end of the rail restraint pockets 31. Thus, by installing so that the upper surface open area of the rail constraining pocket 31 faces upward, it is possible to more stably maintain the initial installation state of the support rail 10.

In addition, the rail restraint bracket 30 has a pair of rail restraint pockets 31' formed in a concave cross-section with an open bottom and a connection plate part 32' connecting the inner lower end of the rail restraint pockets 31'. By forming') and installing it so that the bottom open area of the rail restriction pocket 31' faces downward, it is possible to more stably maintain the initial installation state of the support rail 10 and install the rail restriction bracket 30' The work becomes easy.

In addition, a support rail 10' is formed to have a long rectangular support plate 11' and a groove insert 12' formed to have a narrower width than the support plate 11' on the upper surface of the support plate 11'. By doing so, it is possible to more stably maintain the initial installation state of the support rail 10'.

In addition, by dividing the support rails 10 into a plurality and connecting the split rails 10a to each other through the rail connector 20 frame, the installation work of the support rails 10 is facilitated.

10: support rail 20: rail connector
30, 30': Rail restriction bracket 31, 31': Rail restriction pocket
32, 32': connection plate 40, 40', 40", 40"-1: socket block
41, 41': socket bottom portion 42, 42': socket side wall portion
50, 150: water pipe 51, 151: pipe bottom
52, 152: observation wall 161: wire rope

Claims (7)

A pair of support rails installed to maintain the same separation distance along the water guide path;
Both ends and upper surfaces have a socket bottom surface on the bottom surface in which a pair of socket block rail grooves are formed to maintain the same separation distance, and a pair of socket side wall portions bent in the same direction from both edges in the width direction of the socket bottom surface. A socket block formed to be opened and installed on the support rail so that the support rail is inserted into the socket block rail groove;
With a pair of observation wall portions bent in the same direction from both edges in the width direction of the tube bottom surface and the tube bottom surface, both ends and top surfaces are open, and both ends are connected to the terminal open area of the socket block. A water passage structure comprising a plurality of water passages installed on the socket block as possible. The method of claim 1,
The pipe bottom portion is formed such that a pair of water pipe rail grooves are kept at the same separation distance on the bottom surface;
The water channel structure, characterized in that installed in the socket block so that the support rail is inserted into the channel pipe rail groove. The method according to claim 1 or 2,
And a rail restraint bracket installed on the support rails to constrain the support rails to maintain a separation distance between the support rails. The method of claim 3,
The rail restraint bracket has a connecting plate connecting a pair of rail restraint pockets each formed in a concave cross-section with both ends and an upper surface open and arranged parallel to each other, and an inner lower end of the rail restraint pocket, the A waterway structure, characterized in that the upper surface open area of the rail confinement pocket faces upward and the support rail is inserted into the rail confinement pocket. The method of claim 3,
The rail restraint bracket has a connecting plate connecting a pair of rail restraint pockets each formed in a concave cross-section with both ends and bottom surfaces open and arranged parallel to each other, and an inner lower end of the rail restraint pocket, the A waterway structure, characterized in that the bottom open area of the rail confinement pocket faces downward and the support rail is inserted into the rail confinement pocket. The method according to claim 1 or 2,
The support rail includes a long rectangular support plate portion, and a groove insertion portion formed on an upper surface of the support plate portion to have a narrower width than the support plate portion;
The socket block is a water channel structure, characterized in that installed on the support rail so that the groove insertion portion is inserted into the socket block rail groove. The method according to claim 1 or 2,
The support rails are divided into a plurality, and when the divided portion of the support rail is referred to as a split rail, the split rail is formed in a tubular shape;
It has a fitting plate formed to have the same appearance as the split rail and a pair of force fitting protrusions extending in a direction away from both sides of the fitting plate, and the force fitting protrusion is forcibly fitted into an adjacent end of an adjacent segment rail. A waterway structure, characterized in that it further comprises a rail connector installed so that the fitting plate is fitted between adjacent ends of the adjacent split rails.

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