KR200421727Y1 - Underground structure with buoyancy control apparatus - Google Patents

Abstract

The present invention is an underground water inlet pipe including a steel pipe installed to penetrate the ground and inside the underground structure, the drainage system; And buoyancy caps attached to the upper portion of the groundwater inflow pipe, the buoyancy cap including a weight to be lifted by the incoming groundwater pressure so that the groundwater flows into the underground water tank structure. It is about.

Buoyancy prevention, underground, water tank structure

Description

Underground structure with buoyancy control device {UNDERGROUND STRUCTURE WITH BUOYANCY CONTROL APPARATUS}

Figure 1a shows a state of a conventional buoyancy underground tank structure,

Figures 1b and 1c together shows a means for resisting buoyancy in a conventional buoyant underground structure,

Figure 2 illustrates an underground structure installed buoyancy control device of the present invention,

Figures 3a, 3b, 3c and 3d is a view showing the operating state of the underground structure is installed buoyancy control device of the present invention.

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

100: underground water tank structure 200: groundwater inlet pipe

300: buoyancy cap 310: annular fixed end

320: check valve 330: round weight

400: blind tiger

The present invention relates to an underground structure equipped with a buoyancy control device. More specifically, when the underground structure installed on the ground receives the buoyancy according to the groundwater level, it relates to a buoyancy control device for underground structures that can prevent damage and leakage of the structure by buoyancy.

As shown in FIG. 1A, an underground tank structure (water treatment plant, a drainage pool, a swimming pool, etc.) 10 filled with water usually needs to be emptied of water in a structure for cleaning or performing a function of each tank.

At this time, when the groundwater level of the underground water tank external ground 20 becomes much higher (such as rainfall or emptying water in the tank), the empty box-shaped underground water tank structure 10 receives buoyancy (B) by the groundwater level. If the buoyancy is greater than the weight (W) of the underground tank structure (10), etc., the underground tank structure floats up or the floor slab constituting the structure is broken, and water leaks to the damaged part. do.

In order to prevent the damage of the underground tank structure caused by the buoyancy, conventionally, the size of the underground tank structure (method of increasing the thickness d, etc.) is increased to increase the self-weight (W) than the buoyancy (B). Or, as shown in Figure 1c by installing the anchor 30 to the bottom plate 11 of the underground tank structure firmly fixed to the underground rock, there was a problem that increases the construction and construction cost of the underground tank structure, Above all, it is very uneconomical and inefficient because the size (thickness) of the underground water tank structure and the anchor should be manufactured or installed in case of the maximum buoyancy, which is not acting as an effective buoyancy prevention means at that time. There was a problem.

The present invention is to solve the problems of the prior art,

The object of the present invention is to provide a buoyancy control device for the structure that is easy to maintain the underground structure by freely adjusting the buoyancy acting on the underground structure in which the drainage facility is constructed in a low cost and simple way.

The present invention to achieve the above technical problem

For example, in the case where the water level of the groundwater tank structure and the groundwater level of the outer ground are different than the level of buoyancy that the groundwater tank structure can withstand, the groundwater structure inside the underground water tank structure is provided through the buoyancy control device installed on the groundwater slab floor slab. Inflow to the basement, by controlling the difference in the water level in the underground tank structure to below a certain level, it was possible to control the lifting of the underground tank structure by buoyancy, or the damage of the bottom slab of the underground tank structure.

The buoyancy control device is

In the buoyancy control device installed below the groundwater level of the underground structure where the drainage facility is constructed,

An underground water inflow pipe 200 including a steel pipe installed to penetrate the inside and the ground of the underground structure 100; And a cap having a stopper shape on the groundwater inflow pipe 200, the buoyancy cap 300 including a weight that is elevated by groundwater pressure to allow groundwater to flow into the underground structure.

Hereinafter, with reference to the embodiment shown in the drawings the underground structure installed buoyancy control device according to the present invention will be described in detail.

Figure 2 shows the underground water tank structure is installed buoyancy prevention device of the present invention, Figure 3a to 3d shows a state diagram of the buoyancy prevention device of the present invention.

First, by digging the ground 20 in which the underground water tank structure 100 is installed, the underground water tank structure can be buried and installed.

At this time, by installing the blind gambu 400 first on the lower ground of the underground water tank structure 100, the groundwater can be collected.

The blind chamfer 400 is formed by excavating the lower ground in a predetermined form to form a trench 410, and then formed by laying a permeable layer material 420 such as gravel in the trench, but is not limited thereto. After arranging the perforated pipes, it is also possible to form gravel around them.

The reason for installing such blind culvert 400 is to allow the groundwater to be collected to the position where the buoyancy control device of the present invention is installed, the buoyancy control device of the present invention is easily exposed to the influence of buoyancy change the groundwater level The function according to the can be quickly exhibited.

Next, as shown in FIG. 2, first, the groundwater inflow pipe 200 is installed so that the lower portion extends to the blind lumber 400.

After the groundwater inlet pipe 200 is installed in this way, the base concrete layer 500 is formed at the place where the underground water tank structure 100 is to be placed on the top of the blind lumber 400, which is the bottom plate of the underground water tank structure 100. In order to be in uniform contact with the scavenger to contact, and to transfer the weight of the underground tank structure 100 to the ground effectively, it can be omitted in the case of a small underground tank structure.

The underground concrete structure 100 is installed on the base concrete layer 500, which may be manufactured in the form of a rectangular box having an open top surface according to the purpose, and the underground water tank structure is made of cast-in-place concrete. After installing the formwork, etc. not shown in the figure, concrete is poured into the formwork and cured, and then the final disassembly of the formwork can produce a completed underground tank structure. At this time, the bottom of the underground water tank structure to form a form so that the opening for the ground water inlet pipe 200 can be formed, and finally the upper portion of the ground water inlet pipe 200 protrudes into the ground water tank structure (100) Install it if possible.

If the underground water tank structure is installed as a precast product, the ground water inflow pipe 200 may be formed in the bottom plate so that an opening in which the ground water inflow pipe 200 may be installed in the bottom plate 110 of the underground water tank structure is formed in advance. Allow it to be fitted and installed.

In the case of using a circular steel pipe as the groundwater inflow pipe 200, there is an advantage that the manufacturing and processing is easy, but is not necessarily limited thereto, and may use concrete products.

In the lower inner side of the groundwater inlet pipe 200, for example, the annular fixed end 210 may be formed, and the annular fixed end may be installed by welding the steel plate.

The annular fixed end 210 allows one side of the backflow control valve 220 to be fixed by bolts and nuts. The lower surface of the back flow control valve 220 is formed to be flat so that the hydraulic pressure is evenly transmitted so that the back flow control valve 220 is lifted, the upper surface is concentrated to the outer portion while the lower surface to minimize the space occupied It can be manufactured in an annular shape of rubber material made in the form of a convex shape of rubber material, but other materials are also possible, and when groundwater flows from the lower surface, one side is lifted up to the shaft and the groundwater flows into the gap spaced apart from the annular fixed end. To be possible.

The buoyancy cap 300 is installed above the counter flow control valve 220.

The buoyancy cap 300 is an annular head 310 that covers the upper surface of the groundwater inflow pipe 200 as shown in Figure 2; And the lower portion of the annular head 310 is formed with a body portion 320 that can be inserted into the groundwater inlet pipe 200, the body portion formed inside the core around the core 321 to accommodate the weight Out part S; And an annular weight mounted to the inner block-out portion.

The buoyancy cap 300 is the overall shape is produced in the form of a bottle cap, the annular head 310 according to the shape of the steel pipe is formed to be caught in close contact with the upper surface of the groundwater inlet pipe 200.

The lower part of the annular head 310 is formed with a body portion 320 that can be inserted into the groundwater inlet pipe 200, the body portion of the inner block-out around the core 321 to accommodate the annular weight The portion S is formed.

The buoyancy cap 300 is to use a cast-type product considering the shape of the first manufacturing, the handle portion 322 is on the top surface of the core 321 so that the buoyancy cap 300 can be easily transported, installed To be installed.

The annular weight 330 is shown in a semi-circular shape because it is shown in a cross-sectional view in Figure 2, but the overall shape is preferably produced in an annular shape, but may be manufactured in a semi-circular shape for weight control, such as the inner block out It is installed in such a way as to be inserted into the core 321, so as to be able to adjust the weight of the total buoyancy cap 300 by the sum of the weight per piece with a plurality of individual annular weights.

Since the magnitude of buoyancy due to the change of groundwater level can be predicted within a predetermined range, the buoyancy larger than the weight of the underground tank structure is generated or when the member force of the structure generated by buoyancy is greater than the cross-sectional force of the member. To adjust the size of the number of installation and the buoyancy cap of the annular weight 330 that can not lift the ground water tank structure.

Figure 3a to 3d is a view showing the operating state of the buoyancy control device of the present invention.

Referring to FIG. 3A, it can be seen that the lower portion extends to the blind lumber 400 and the groundwater inflow pipe 200 protrudes upward into the groundwater tank structure through the support concrete layer 500 is installed. . In addition, the bottom of the ground water inlet pipe 200 is provided with a permeable material 230 that can filter the foreign matter of the ground water flowing in. Such a permeable material uses a material having a high permeability such as sand.

The counter flow prevention valve 220 is installed above the water permeable material, and the buoyancy cap 300 having an annular weight 330 is installed on the counter flow prevention valve 220.

Accordingly, groundwater can be introduced into the groundwater tank structure 100 from the surrounding ground of the underground water tank structure through the blind pit 400, the permeable material 230, the non-return valve 220, and the buoyancy cap 300. For example, when the water level inside the underground tank structure is emptied and the inner water level is lowered, the groundwater gradually flows into the underground tank structure.

As shown in FIG. 3B, the buoyancy prevention valve 220 is lifted by the water pressure according to the groundwater inflow as shown in FIG. 3B, and the groundwater inflow is gradually increased to slightly lift up to the buoyancy cap 300. It can be seen that the water level inside the underground water tank structure 100 is somewhat higher.

As more ground water is introduced as shown in FIG. 3c, the buoyancy prevention valve 320 is lifted up a lot, and the buoyancy cap 300 is also protruded considerably upward to show a state in which groundwater inflow is greatly increased. At this time, there is a possibility that the groundwater flows back to the ground and flows back to the ground, so that the non-return valve 220 is blocking the groundwater outflow path to minimize the flow of groundwater backflow.

When groundwater is introduced into the underground water tank structure 100 as shown in FIG. 3d, the weight of the ground water is added to the underground water tank structure so that the buoyancy does not proceed anymore. The buoyancy cap 300 is lowered by the weight, so that the non-return valve 220 is also in close contact with the annular fixed end 210 so that the groundwater is no longer introduced.

As a result, when the weight of the buoyancy cap is adjusted by the annular weight, it can be seen that the weight of the underground tank structure that resists buoyancy can be adjusted.

Underground water tank structure equipped with buoyancy control device of the present invention is simple, easy to install by the buoyancy cap and ground water inlet pipe can prevent the phenomenon of the underground water tank structure due to the change of buoyancy, the underground water tank structure Not only is maintenance economical,

The buoyancy cap has various applicability as it can adjust the weight according to the size of the groundwater tank structure (size or cross-sectional force) and the buoyancy, so it is very versatile and can be used to standardize the buoyancy prevention device. Device provision becomes possible.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. Those skilled in the art of the present invention can modify and change the technical idea of the present invention in various forms. Therefore, such improvements and modifications fall within the protection scope of the present invention as long as it is obvious to those skilled in the art.

Claims (5)

In the buoyancy control device installed below the groundwater level of the underground structure in which the drainage system is constructed, the buoyancy control device is An underground water inflow pipe including a steel pipe installed to penetrate the ground and the ground under the underground structure; And a buoyant cap having a stopper shape on the upper portion of the groundwater inflow pipe, the buoyancy cap including a weight which is lifted by the groundwater pressure to allow the groundwater to flow into the underground structure. structure. The method of claim 1, wherein the buoyancy cap An annular head covering the upper surface of the groundwater inlet pipe; And the lower part of the annular head is formed in the body portion that can be inserted into the groundwater inlet pipe, the body portion formed inside the block around the core to accommodate the weight; And a weight mounted to the inner block-out part. 3. The underground structure according to claim 2, wherein the weight is made in an annular shape and the weight can be adjusted by a plurality of stacked individual weights. The underground structure according to any one of claims 1 to 3, further comprising a reverse flow control valve having one side fixed to a fixed end formed inside the steel pipe under the buoyancy cap. 5. The underground structure according to claim 4, wherein a water permeation material is further formed in the steel pipe under the backflow regulating valve, and the water permeation material is installed to be in contact with a blind pit installed in the lower ground of the structure.

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