KR20100010009U - Constructing device for hume pipe underground - Google Patents

Abstract

The present invention can minimize the generation of sediment by modifying the cross-sectional structure of the fume pipes buried in the ground for smooth drainage of general sewage, sewage, and wastewater, and at the same time ensure the airtightness of the connection parts of these fume pipes. In addition, the present invention relates to a construction structure of a landfilled fume pipe having a flow rate converting structure that can reliably prevent uneven settlement between the fume pipes as well as ease of construction.

The present invention is a construction structure of a landfilled fume pipe for draining wastewater by binding cylindrical fume pipes buried at regular intervals along the underground pipeline, and has an extended socket part connected to one edge by an inclined surface and at the bottom of the inner surface. It comprises a fume pipe formed on both sides facing each other and the support block is held between the bottom of the pipe and the bottom of the socket portion formed in the fume pipe, the cross section between the raised portion of the inner surface of the fume pipe for the flow rate conversion A reduced shaft diameter portion is provided, and on the surface of the support block, an enlarged diameter groove is formed in which the fume pipe can be seated by an arc groove formed continuously in the longitudinal direction, and at the same time, the diameter groove is expanded from the arc groove through an inclined surface.

Hume pipe, socket part, support block, ridge part, shaft part

Description

Construction of landfilled fume pipe with flow rate conversion structure {CONSTRUCTING DEVICE FOR HUME PIPE UNDERGROUND}

The present invention can minimize the generation of sediments by modifying the cross-sectional structure of the hume pipes buried in the ground for the smooth drainage of general sewage, sewage, and waste water. It relates to a construction structure of a landfilled fume pipe having a flow rate conversion structure that can ensure the airtightness, and easy construction, as well as to prevent uneven settlement between the fume pipes.

Hume pipes buried in the ground, such as sewage pipes and wastewater pipes, including general sewer pipes, can be made into a cylindrical cylinder of a predetermined standard and connected to each other to form a pipeline and drain them to a separate sewage treatment facility installed separately. Will be.

In the case of sewage, sewage, and wastewater flowing along the pipeline, a large amount of sediment is contained, so when these sediments accumulate on the inner surface of the sewage pipe, the effective pipe diameter of the fume pipe gradually decreases, and the drainage of the fume pipe is not achieved smoothly, and the odor is caused by its decay. It may be a cause of occurrence, and if there is a large amount of rainfall during the rainy season, there may be a problem that the sewage backflow due to lack of water supply capacity.

Therefore, in order to prevent such a phenomenon, in the case of installing a fume pipe, most of them have a certain inclination so that the flow rate of sewage flowing through the inside of the fume pipe maintains a minimum flow rate or more.

As a method for constructing a general fume pipe, as shown in FIG. 1, another fume pipe 1 in a state in which a watertight belt 3 is inserted into and connected to an inner surface of a socket part 2 formed on one side of the fume pipe 1. ) Is seated on the earth's surface as it is tied in the horizontal direction.

However, in this manner, as shown in FIGS. 2A and 2B, the lower sag of the socket part 2 may cause the flow of wastewater and wastewater to be stagnant, as well as the socket part 2 of the fume pipe when left for a long time. Is corroded or cracks (A) to leak the waste water, it will lead to the sinking of the road due to mutual inequality occurring in the socket portion (2).

In addition, when the fume pipe 1 is to be installed, the center of the fume pipe needs to be finely adjusted by using a mechanism such as a chain block, and thus requires the skill of the operator. In order to reinforce a soft ground or a high external pressure conduit, In order to lay the pipes, it requires complicated work such as input of many working people and concrete curing due to formwork installation and site casting.

As a technique disclosed in consideration of such a conventional problem, Korean Patent No. 0864768 discloses a "fume pipe embedding construction method" for quickly and accurately installing a fume pipe buried in the ground.

In this technique, the struts are erected at the start and end points of the excavation section where the fume pipe is installed, and the threads are connected to both struts according to the inclination value, and the tops of the supporting blocks are arranged in line with the thread heights. Fix the supporting block with the fixing pins and put the fume pipes in the settled part in line with the partition plate installed respectively, then line them up. It was to be buried.

In addition, `` Registered Utility Model No. 0274837 '' discloses a `` fume pipe installation structure '' that enables the construction of fume pipes by simply using ready-made supporting concrete to shorten the construction period, and simplify the installation of fume pipes. A technique is disclosed.

However, in the prior art as described above, since the wastewater is likely to leak due to poor surface flatness, sag caused by the weight of the fume pipe and poor construction of the fume pipe connection portion, high technical skill of the field personnel is required, Due to the sedimentation, the sedimentation, decay, and odor of sewage can occur, as well as groundwater or surrounding soil inflow, causing the road to sink.

Moreover, since various subsidiary materials have to be installed in the pipeline, the workability is greatly reduced and the cost is increased, and there is a problem that the maintenance work must be frequently performed due to leakage occurring at the joint of the fume pipe.

The present invention has been made in view of the problems of the prior art as described above, and an object of the present invention is to create a settlement by forming a ridge and a shaft diameter portion that can induce a flow rate conversion on the inner surface of a fume pipe buried in the ground. It is possible to minimize, and to provide a construction structure of the landfill fume pipe having a flow rate conversion structure excellent in workability while being able to reliably prevent the differential settlement between them by the support block holding the fume pipe.

The present invention for achieving the above object, as a construction structure of a buried fume pipe for draining the wastewater by binding the cylindrical fume pipe buried at regular intervals along the underground pipeline, connected to the slope at one edge to expand At the same time, it has a socket part with a sealing ring, and has a shaft diameter portion having a reduced cross section at the lower end of the inner surface, and is bound and maintained between the bottom of the pipe and the bottom of the fume pipe formed on the both sides thereof with the ridge facing each other. Comprising a support block, the surface of the support block is formed with a diameter-expanded groove extending from the circular arc groove formed in the longitudinal direction through the inclined surface, the lattice-shaped groove on the back of the support block It is formed to be symmetrical with respect to the center and is connected to the through hole of the support block. A reinforcement plate is provided between the enlarged diameter groove formed on the surface of the support block and the lattice-shaped groove formed on the rear surface thereof to cope with the vertical load acting on the connection portion of each fume pipe.

According to the construction structure of the landfill fume pipe having a flow rate conversion structure according to the present invention having the characteristics as described above, the bulge and shaft portion on the inner surface of the fume pipe buried in the ground for smooth drainage of general sewage, sewage, wastewater, etc. Forming a cross-sectional structure to form a can be minimized the generation of sediment due to the change in flow rate.

In addition, the airtightness can be secured through the contact ring of the fume pipes, and as a support block is installed between the socket part constituting the fume pipe and the ground surface of the bottom of the pipe, the unequal settlement of the fume pipes is prevented reliably. You can do it.

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

First, Figures 3 to 6a, Figure 6b is a view for explaining the construction structure of the buried fume pipe having a flow rate conversion structure according to the present invention, as shown in these drawings, such as a general sewage pipe, waste water pipes, etc. As described above, the conventional fume pipe 10 embedded in the ground is formed in a cylindrical shape having a predetermined size, thereby forming a pipeline by binding one socket portion 11 in series with each other.

The fume pipe 10 is connected to the inclined surface 11a at one edge thereof to form an extended socket portion 11, and at the same time, the ridges 12a and 12b are formed on both sides of the lower end of the inner surface to face each other. Between the base parts 12a and 12b, the shaft diameter part 13 whose cross section was reduced for the flow rate conversion is provided.

In addition, as the fitting groove 14 is formed in the socket portion 11 of the fume pipe 10 so as to mount the sealing ring 15, the airtightness and watertightness of the fume pipe 10 which are mutually bound together are adjacent to each other. It is sustainable.

A support block 20 is provided between the lower end of the socket portion 11 constituting the fume pipe 10 and the bottom surface of the conduit.

The support block 20 may be manufactured in a suitable thickness and length enough to sufficiently support the fume pipe 10 by molding a hard synthetic resin, and may also be molded in a conventional foamed polystyrene material.

In addition, the semi-spherical arc groove 21 is formed continuously on the surface of the support block 20 so that the body of the fume pipe 10 can be stably seated, and the support block 20 is provided. The enlarged diameter groove | channel 22 extended in diameter from the circular-arc groove 21 through the inclined surface 22a is formed in the substantially center part of ().

A plurality of lattice-shaped grooves 23a are formed on the back surface of the support block 20 so as to be symmetrical with each other except for the center portion, so that the through holes 23b may be formed at regular intervals at the same time. As it is prepared to accommodate the negative pressure generated by the sewage or waste water in the process of installing the support block on the bottom of the pipeline.

In addition, a reinforcing plate 24 is integrally embedded between the enlarged groove 22 formed on the surface of the support block 20 and the lattice-shaped groove 23a formed on the rear surface thereof.

The reinforcing plate 24 is formed by weaving a thick wire in the horizontal and vertical directions, but it is also possible to use a general mailing plate, and has sufficient coping force with respect to the vertical load acting on the connection part of each adjacent fume pipe 10. You can have

According to the present invention configured as described above, the ground block 20 is first dug up and aligned continuously after digging the ground to a certain depth for sewer or drainage work, and a plurality of grids are provided on the back of the support block 20. Since the mold groove 23a is provided, the binding force with the bottom surface of the pipe can be further increased, as well as the material consumption and weight can be reduced.

In addition, when there is water such as sewage or sewage on the bottom surface of the pipeline in the process of constructing the support block 20, the through-hole 23b formed in the support block 20 will escape to the surface to seat the support block It will accept the negative pressure that may occur in the process.

Subsequently, after the alignment of the support block 20 is completed, the fume pipe 10 is mounted to bind to each other. In this case, the arc groove 21 and the enlarged groove 22 formed on the surface of the support block 20 are used. Thus, the body of the fume pipe 10 can be stably mounted.

That is, since the support block 20 is formed on the surface of the circular groove 21 and the inclined surface 22a having the same shape as the outer circumferential surface of the fume pipe 10 made of a cylindrical shape, the usual work equipment By using the body and the socket portion 11 formed on one side of the fume pipe 10 is to be seated in the arc groove 21 and the enlarged groove 22 of the support block 20 as it is.

Thereafter, the other fume pipe 10 to be bound can be easily fixed by being inserted into the socket part 11 while moving horizontally, so that it does not require much skill, and at this time on the inner surface of the socket part 11 of the fume pipe 10. Since the sealing groove 15 is attached to the formed fitting groove 14, it is possible to maintain the airtightness and watertightness of the fume pipe 10 which are bound adjacent to each other.

On the other hand, since the reinforcing plate 24 is integrally embedded in the support block 20 of the portion where the fume pipe 10 is bound, a sufficient response force is applied to the vertical load acting on the connection portions of the adjacent fume pipes 10. You can have

The construction of a general fume pipe (10) is to install a plurality of support blocks 20 on the bottom surface of the ground and then install a fume pipe (10) on the upper surface of each support block 20 or each support block 20 and the fume pipe ( 10) can be installed alternately, which can be appropriately selected according to the convenience of work in the construction of the fume pipe (10) and the surrounding working conditions.

In this way, after the binding of the fume pipe 10 is made, the construction of the sewer or drainage is completed by covering the soil on the pipeline and laying it in the ground.

The technical problem of the present invention is achieved by the technical configuration as described above, although the present invention has been described by a limited embodiment and drawings, but the present invention is not limited thereto and is intended by one of ordinary skill in the art. Of course, various modifications and variations are possible within the scope of the technical spirit and equivalents of the utility model registration claims to be described below.

1 is a cross-sectional view showing a state in which a conventional fume pipe is connected,

Figure 2a, Figure 2b is a view showing the deflection and cracking occurring in the socket portion of the fume pipe,

Figure 3 is a side cross-sectional view showing an installation state of the fume pipe according to the present invention,

Figure 4 is a front cross-sectional view showing the installation state of the fume pipe shown in FIG.

5 is a front view showing an internal configuration example of a fume pipe;

6A and 6B are side cross-sectional and front cross-sectional views of the support block.

<Description of the symbols for the main parts of the drawings>

10: fume pipe 11: socket part

12a, 12b: ridge 13: shaft portion

14: fitting groove 15: sealing ring

20: support block 21: arc groove

22: Expansion groove 22a: slope

23a: lattice groove 23b: through hole

24: gusset

Claims (1)

As a construction structure of a landfill fume pipe for draining wastewater by binding cylindrical fume pipes buried at regular intervals along the underground pipeline, Connected to the inclined surface (11a) on one side of the expansion and at the same time having a socket portion 11 is equipped with a sealing ring (15) is formed in the lower end of the shaft diameter portion 13 is reduced in cross section is formed on both sides of the ridge (12a) (12b) comprises a fume pipe (10) formed to face each other and a support block (20) that is held between the bottom of the conduit and the bottom of the socket portion 11 formed in the fume pipe (10), On the surface of the support block 20 is formed a diameter-expanded groove 22 which extends in diameter from the circular arc groove 21 continuously formed in the longitudinal direction through the inclined surface 22a, and is formed on the rear surface of the support block 20. The lattice groove 23a is formed to be symmetrical with respect to the center portion thereof, and is connected to the through hole 23b of the support block 20. The reinforcing plate 24 corresponding to the vertical load acting on the connection portion of each fume pipe 10 between the enlarged diameter groove 22 formed on the surface of the support block 20 and the lattice groove 23a formed on the rear surface thereof. Construction structure of a buried fume pipe having a flow rate conversion structure, characterized in that the built-in).

Images