KR102196538B1 - Earthquake-resistant valve room for prevention of water accumulation - Google Patents

Abstract

The present invention relates to a seismic valve chamber for preventing water accumulation, and for this purpose, a valve for controlling the flow rate of a pipe, and a chamber buried in the ground to protect a pressure or flow meter measuring instrument; And, in the pipe and underground in the chamber Seismic connection means coupled to both sides of the chamber to connect the buried pipe and canceling the displacement transmitted from external force or earthquake; And a trench coupled to the bottom of the bottom plate of the chamber to discharge condensation inside the chamber according to the temperature difference with the ground, but collecting condensation flowing along the wall plate into the trench at both edges of the bottom plate of the chamber. A cutout is formed for the cutout, and a perforated plate with a plurality of discharge holes is seated in the cutout, and the bottom plate of the chamber has a downward gradient from the center to both edges, so that condensation can be guided to the perforated plate without pooling water. It is characterized by being.

Description

Earthquake-resistant valve room for PREVENTION OF WATER ACCUMULATION

The present invention relates to a seismic valve chamber to prevent water accumulation, and more particularly, a valve that is buried in the ground to control the flow rate of a pipe, or a variety of measuring instruments that measure pressure or flow rate can be effectively protected from external forces or earthquakes. , It relates to a seismic valve chamber that prevents water accumulation, as long as it can minimize the occurrence of condensation in the chamber by embedding insulation in the wall plate of the chamber.

Since the 1970s, water supply in Korea has been buried in the underground due to the rapid supply of water supply. It is a necessary location to quickly respond to emergency situations such as urgent water quality accidents and pipe damage as well as stable supply of clean and clean water through the pipes. The valve chamber is installed in the.

In addition, the valve chamber may be equipped with expensive measuring devices such as a flow meter and a pressure gauge to measure the flow rate and pressure of the pipeline.

These valve chambers are mainly installed in the form of manholes in the ground below the road, and a manhole cover is installed on the road surface for workers to enter and exit.

As a conventional valve chamber, "a structure for connecting a manhole with a seismic structure and a sewage pipe (Korean Patent Registration No. 01077284)" has been proposed.

However, such prior literature is an invention in mind that the sewage pipe is destroyed due to earthquake resistance by installing a buffer in the water collection well, and there is a disadvantage that it is difficult to solve the problem caused by the damage of the water collection well.

In addition, in recent years, the valve chamber is made of synthetic resin or PRP for convenient construction and maintenance. To prevent water retention, a number of drainage holes are formed on the bottom of the valve chamber, and a trench is installed at the point where the drainage hole is formed. If the trench is damaged, it is difficult to repair the trench because the bottom surface must be cut.

In view of the above-described problems, when the trench recessed in the bottom surface of the valve chamber is integrally formed, another problem that makes it difficult for a worker to walk is caused.

Korean Patent Registration No.01077284

The present invention was conceived in consideration of the above problems, and the first object of the present invention is to effectively protect a valve buried in the ground to control the flow rate of a pipe, or various instruments that measure pressure or flow rate from external forces or earthquakes. In addition to being able to do, it eliminates interference in walking by workers in the chamber, and in addition, water pool that effectively collects condensation caused by water discharged from the pipe when replacing facilities and condensation caused by the temperature difference between the chamber and the ground. It is to provide an anti-seismic valve chamber.

A second object of the present invention is to provide a seismic valve chamber for preventing water accumulation, which can minimize the occurrence of condensation in the chamber by embedding an insulating material in the wall plate of the chamber.

According to the features for achieving the above object, the first invention relates to a seismic valve chamber for preventing water accumulation, and for this purpose, to protect a valve that regulates the flow rate of a pipe, and a meter that measures pressure or flow rate. A chamber buried in the ground; and seismic connection means coupled to both sides of the chamber to connect the piping in the chamber and the piping buried in the ground, and offsetting displacement transmitted from an external force or an earthquake; And a trench coupled to the bottom of the bottom plate of the chamber to discharge condensation inside the chamber according to the temperature difference with the ground, but collecting condensation flowing along the wall plate into the trench at both edges of the bottom plate of the chamber. A cutout is formed for the cutout, and a perforated plate with a plurality of discharge holes is seated in the cutout, and the bottom plate of the chamber has a downward gradient from the center to both edges, so that condensation can be guided to the perforated plate without pooling water. It is characterized by being.

In the second invention, in the first invention, the chamber is divided into two to facilitate movement and installation of valves or various measuring instruments, and a drain hole is further formed to discharge water accumulated in the trench.

In the third invention, in the first invention, the wall plate of the chamber is composed of an inner wall and an outer wall, an insulating material is embedded between the inner wall and the outer wall, the insulating material is configured to be separated into two, and between the insulating material and the insulating material It characterized in that the insulation board is interposed.

In the fourth invention, in the third invention, a plurality of spikes for temporary coupling with an insulation material are further coupled to the insulation board, and a plurality of hemispherical grooves and hemispherical projections are formed on one side and the other side so that an air layer with the insulation material can be formed It is characterized by being.

According to the seismic valve chamber to prevent water accumulation of the present invention, even if an external force (partial subsidence, subsidence, and uplift of the ground) or an earthquake occurs and a large displacement occurs in the chamber or the pipe buried in the ground, the seismic connection means cancels it or As it can be buffered, there is an effect of stably protecting a valve that controls the flow rate of the pipe as well as the pipe in the chamber, and an expensive measuring instrument that measures pressure or flow rate.

In addition, a perforated plate is installed close to the wall plate, and a trench is connected to the lower part of the perforated plate to effectively collect condensation caused by the temperature difference between the chamber and the ground, and water retention due to water fall in the pipe when replacing facilities. As there is no interference in walking by the worker, there is an effect that can prevent safety accidents.

In addition, there is an effect of minimizing the generation of condensation in the chamber by embedding an insulating material in the wall plate, but by forming an air layer on the insulating material to lower the heat transmission rate.

1 is a cross-sectional view of a seismic valve chamber for preventing water accumulation according to a first embodiment of the present invention,
2 is an enlarged configuration diagram of an enlarged main part of FIG. 1,
3 is a cross-sectional view of a seismic valve chamber for preventing water accumulation according to a second embodiment of the present invention.

The following objects, other objects, features, and advantages of the present invention will be easily understood through the following preferred embodiments related to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used in the specification, "comprise" and/or "comprising" does not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and to aid understanding. However, readers who have knowledge in this field enough to understand the present invention can recognize that it can be used without these various specific contents. In some instances, it should be noted in advance that parts that are commonly known in describing the invention and are not significantly related to the invention are not described in order to avoid confusion in describing the invention.

1 is a cross-sectional view of a seismic valve chamber for preventing water accumulation according to a first embodiment of the present invention, and FIG. 2 is an enlarged view of a main part of FIG. 1.

As shown in Figs. 1 and 2, the present invention effectively protects a valve that is buried in the ground and controls the flow rate of a pipe or a measuring instrument (not shown) that measures pressure or flow rate from external forces or earthquakes. It relates to a seismic valve chamber 100 for preventing water accumulation to collect condensation caused by a temperature difference between a chamber, a pipe, and the underground, and water storage due to water loss in a pipe when a facility is replaced. Here, the external force is a force generated from the outside of the chamber and collectively refers to vibrations, sinkholes, partial subsidence, subsidence, and elevation occurring in the ground and in the ground.

The anti-water seismic valve chamber 100 of the present invention is largely composed of three parts, which is composed of a chamber 10, a seismic connection means 20, and a trench 15.

The chamber 10 is buried in the ground to protect a valve that controls the flow rate of the pipe or a meter that measures pressure or flow rate.

The chamber 10 may be divided into two to facilitate installation and movement of various measuring instruments.

The seismic connection means 20 are coupled to both sides of the chamber 10 in order to connect the pipe buried in the ground and the pipe, and function to offset a displacement transmitted from an external force or an earthquake.

The seismic connection means 20 is specifically composed of a vibration-proof joint 21, an auxiliary chamber 22, and a vibration-proof pad 23.

The vibration-proof joint 21 is for connecting the pipe in the chamber 10 and the pipe buried in the ground, flanges F for connecting the pipe are formed on both sides, and a corrugated corrugated part 211 at the center portion Is a formed structure.

The corrugated part 211 can be easily changed in each axial direction as well as expansion and contraction, so that a large displacement transmitted from an earthquake or an external force can be offset.

The vibration-proof joint 21 is coupled to the corrugated part 211 to be exposed to the outside of the chamber 10, so that even if the pipe or the entire chamber 10 buried in the ground flows by external force or earthquake, it can buffer it. So that it functions.

In addition, the main function of the auxiliary chamber 22 serves to prevent soil from flowing into the corrugated part 211 exposed to the outside of the chamber 10 so that the function of the corrugated part 211 is maintained.

To this end, the auxiliary chamber 22 wraps the corrugated portion 211 and seals the corrugated portion 211 independently, and thus, an extended end integrally extended from the chamber 10 is trapezoidal around the vibration-proof joint 21. It is a configuration that is arranged in a form.

At this time, the auxiliary chamber 22 is sealed through an open extended end and a vibration-proof pad 23 coupled to the outer peripheral surface of the vibration-proof joint 21.

Here, the anti-vibration pad 23 closes the auxiliary chamber 22 and compensates for a relatively small displacement, and may be made of an elastic synthetic resin material.

In addition, a flange F for fixing the vibration-proof pad 23 is formed at the extended end of the auxiliary chamber 22, and a separate support flange 212 is formed on the outer circumferential surface of the vibration-proof joint 21. .

Accordingly, the edge of the anti-vibration pad 23 is fixed through the first connection flange 24 fastened to the flange F of the auxiliary chamber 22, and the inner part of the anti-vibration pad 23 is the vibration-proof joint It is fixed through the second connection flange 25 that is fastened with the support flange 212 of (21).

The anti-vibration pad 23 fixed in this way responds to a relatively small displacement, but when a displacement higher than the limit value occurs in case of emergency, it may be damaged, thereby finally protecting the vibration-proof joint 21.

Meanwhile, when the chamber 10 is buried in the ground, condensation is generated in the wall plate 12 due to a temperature difference between the pipe and the underground, and such condensation occurs along the wall plate 12 of the chamber 10 and the bottom plate 13 It becomes a factor of failure due to corrosion of various valves and measuring instruments.

In addition, when the facility inside the valve room is replaced, the water inside the pipe is discharged, and the discharged water accumulates on the bottom of the valve room, which also becomes a factor of failure due to corrosion of various valves and measuring instruments.

To this end, cutouts 131 for collecting condensation flowing through the wall plate 12 into the trench 15 are formed at both edges of the bottom plate 13 of the chamber 10, and each of the cutouts 131 A trench 15 for collecting condensation is coupled to the lower portion.

This configuration collects the condensation in the chamber 10 into the trench 15, but when the trench 15 is damaged, the perforated plate 14 is separated to prevent maintenance of the damaged trench 15 through the cutout 131. This is a configuration that can be easily done.

In addition, by placing the cutout 131 and the perforated plate 14 at the edge of the bottom plate 13 so that condensation flowing along the wall plate 12 does not accumulate on the bottom plate 13, the user can work inside the chamber 10 It is a configuration that does not interfere with walking when doing it.

In addition, it is preferable that the bottom plate 13 of the chamber 10 forms a downward gradient 13a from the center toward both edges in order to induce condensation.

Meanwhile, when the trenches 15 are connected through an interconnection pipe 151 to drain the water collected in any one trench 15, the water collected in the two trenches 15 can be drained collectively. So it is made.

At this time, the chamber 10 may be formed with a drain hole 11 for connecting a drain pipe to discharge water accumulated in the trench 15 in case of emergency.

3 is a cross-sectional view of a seismic valve chamber for preventing water accumulation according to a second embodiment of the present invention.

As shown in Fig. 3, the second embodiment includes the first embodiment, but the wall plate 12 of the chamber 10 further includes an insulating material 121 to prevent condensation from being generated. to be.

The wall plate 12 is composed of an inner wall 12a and an outer wall 12b, and an insulating material 121 is embedded between the inner wall 12a and the outer wall 12b. Here, the insulating material 121 may be any one selected from styrofoam, isopink, glass wool, cellulose, and urethane foam.

At this time, the insulating material 121 is configured to be separated into two to increase the heat insulation efficiency, and an insulating board 122 is interposed between the heat insulating material 121 and the heat insulating material 121.

Here, the two insulation materials 121 may be composed of different insulation materials, for example, a combination of Styrofoam and isopink. It can be composed of a combination of Styrofoam and cellulose.

The above-described heat insulating structure is a structure capable of improving the heat transmission rate (lowering the heat transmission rate to increase the heat insulation performance) by configuring the heat insulating material layer with two heat insulating materials 121 and heat insulating board 122.

Meanwhile, the insulating board 122 has two insulating materials 121 and a plurality of spikes 122c for temporary coupling through through coupling, and the spikes 122c have wedges formed on both sides of the insulating material 121 By facilitating temporary bonding, insulation construction can be conveniently performed.

In addition, a plurality of hemispherical grooves 122a and hemispherical protrusions 122b are formed on one surface and the other surface of the insulating board 122 so that an air layer with the insulating material 121 can be formed in order to improve thermal insulation performance.

In the above structure, when the insulation material 121 is closely coupled to both sides of the insulation board 122, an air layer is formed in the space of the groove portion 122a and the lifted portion of the protrusion portion 122b, thereby improving the insulation effect. to be.

In the seismic valve chamber 100 for preventing water accumulation of the present invention described above, even if a large displacement occurs in the chamber 10 or the pipe buried in the ground due to an external force or an earthquake, the seismic connection means 20 compensates or buffers it. In addition to the piping in the chamber 10, the valve that controls the flow rate of the piping and the expensive measuring instrument that measures pressure or flow can be reliably protected. In addition, condensation in the needle burr is generated by the insulator embedded in the wall plate of the chamber. Can be minimized.

Since the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, various equivalents that can replace them at the time of application And it should be understood that there may be variations.

10: chamber 11: drain hole 12: wall plate
12a: inner wall 12b: outer wall
121: insulation 122: insulation board
122a: groove 122b: protrusion
122c: spike 13: bottom plate
13a: downward gradient 131: incision
14: perforated plate 141: discharge hole
15: trench 151: connector
20: seismic connection means 21: vibration-proof joint 211: corrugated part
212: support flange 22: auxiliary chamber
23: anti-vibration pad 24: first connection flange
25: second connection flange
100: seismic valve chamber
F: flange

Claims (4)

A chamber 10 buried in the ground to protect a valve for controlling the flow rate of the pipe and a measuring instrument for measuring pressure or flow;
Seismic connection means (20) coupled to both sides of the chamber (10) to connect the pipes in the chamber (10) and the pipes buried in the ground and to offset displacements transmitted from external forces or earthquakes; And
Including a trench 15 coupled to the bottom surface of the bottom plate 13 of the chamber 10 in order to discharge condensation inside the chamber 10 according to the temperature difference with the ground,
Cutouts 131 for collecting condensation flowing through the wall plate 12 into the trench 15 are formed at both edges of the bottom plate 13 of the chamber 10,
A perforated plate 14 in which a plurality of discharge holes 141 is formed is seated in the cutout 131,
The bottom plate 13 of the chamber 10 is configured to have a downward gradient 13a from the center toward both edges so that condensation can be guided to the perforated plate 14 without pooling water,
The wall plate 12 of the chamber 10 is composed of an inner wall 12a and an outer wall 12b, and an insulating material 121 is embedded between the inner wall 12a and the outer wall 12b,
The insulating material 121 is configured to be separated into two, an insulating board 122 is interposed between the insulating material 121 and the insulating material 121,
The insulating board 122 is further coupled with a plurality of spikes 122c for temporary coupling with the insulating material 121, and a hemispherical groove 122a and a hemispherical shape so that an air layer with the insulating material 121 can be formed on one side and the other side. A number of protrusions 122b are formed,
Each of the trenches (15) is a seismic valve chamber to prevent water accumulation, characterized in that connected through a connection pipe (151).


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