KR200225139Y1 - flow controller for reservoir of sewage treatments - Google Patents

Abstract

PURPOSE: The present invention aims to provide a flow control valve of rainwater tosoil that prevents the amount of more than the designed sewage from entering the sewage treatment plant during rainfall in response to changes in the water level in the collecting pipe passage in real time.

Composition: In the rainwater chamber system that collects and induces only a certain amount of sewage through the conduit on the combined conduit line where rainwater and sewage flow down the same pipeline, and discharges the excess flow, and the upper and lower sides of the neck It comprises a housing (20) of symmetrical symmetry, which is divided into a float seat 16 and a valve seat (18) and combined with each other, and between the two housings 20, the upper float 21 and the lower side The flow rate control valve 12, in which the valve body 26 of the valve 22 is coaxially connected via the middle rod 24, can be lifted and received inside the manhole cylinder 2. The float 21 rises due to the rise of the water level introduced through the rainwater inlet pipe 4 to shield the passage between the neck portion 14 by the valve 22 so that the rainwater is discharged to the river. will be .

EFFECT: The present invention has the effect of stably discharging excess sewage above a predetermined design sewage by automatically controlling the opening of the flow control valve located at the inlet of the collecting pipe line according to the vertical displacement of the float.

Description

Flow controller for reservoir of sewage treatments

The present invention relates to a sewage treatment pipe line, and the rainwater mixing is excessively increased due to seasonal factors, so that the inflow of rainwater is automatically controlled so that the sewage treatment efficiency does not decrease. It is related with the flow control valve of a toe chamber.

The sewer system as a sewer system is a pipeline facility for collecting sewage from the distal end of the sewage pipeline established in the basement of the city and transporting it to the sewage treatment plant. In the case of the whole sewage mixed with rainwater, only a certain amount of sewage is separated and sent to the sewage treatment plant. Here, the classification formula refers to the sewage system that separates and discharges sewage and rainwater, and the consolidation type refers to the sewage system that discharges them through the same pipeline. Most of the existing cities, which are not newly constructed, adopt a combined type of exclusion method.

The sewage treatment plant in the region that adopts such a combined exclusion method is designed to collect and process up to three times the pure sewage generation in rainy weather, so when the mixed sewage of rainwater and sewage exceeds the planned sewage, Lack of treatment can lead to unfavorable situations, such as a significant drop in treatment efficiency or failure in treatment.In addition, the annual rainfall patterns in Korea are not uniform, and there is a seasonal characteristic that rainfall is concentrated during the rainy season. As a result of the failure of stable collection, the treatment efficiency of sewage treatment plants is deteriorated.

In order to solve this problem, a system is applied to allow the discharge of rainwater into a river when the inflow of rainwater increases, and a known example of the facility is disclosed in Korean Utility Model No. 166989 registered on October 29, 1999. As the upper side has a hinged door, the rainwater flows into the bypass passage by the door being pushed open by the action of increased water pressure due to the inflow of rainwater.

Since the automatic opening and closing device having such a structure is operated when the amount of rainwater flowing in exerts a pressure greater than the weight of the door, only the simple opening and closing is possible depending on the difference between the weight of the door and the water pressure inside the door. Because it is impossible to quantitatively control the quantity of water, it is difficult to make only the planned sewage water, and it is difficult to apply in small rainwater silos.

The present invention reacts to the change of water level due to the increase and decrease of the amount of sewage in order to fundamentally solve the problems seen in the above-mentioned conventional storm soil. The purpose is to provide a flow control valve of rainwater tosoil that transfers and discharges excess water stably.

The present invention for realizing the above object in the manhole of the collecting pipe passage is provided with an automatic opening and closing facility between the sewage inlet pipe and sewage outflow pipe so that excessive amount of rainwater flowing through the rainwater inlet pipe is discharged through the bypass pipe, The upper and lower sides of the inner circumferential surface are each formed of a float seat and a valve seat, each of which is divided into a float seat and a valve seat, and includes a symmetrical housing which is combined with each other. A flow control valve having an integrally coaxially connected valve body capable of lifting up and down is accommodated inside the manhole cylinder, and the float rises due to a rise in the level of the rainwater introduced through the upper rainwater inlet pipe. By blocking the passage or adjusting the opening, only a certain flow rate (planned sewage) The remaining water is to be discharged to the stream.

In the above configuration, the float may include a plurality of spillways in the form of grooves on the outer circumferential surface of the float so that the rainwater smoothly flows out to the sewage treatment plant together with the sewage when the inflow of the rainwater is small.

In addition, the float may have a plurality of protrusions below the outer circumferential surface so that a predetermined interval for filthy water can flow down when the float is placed in the float.

1 is a schematic configuration diagram related to the manhole of the present invention.

Figure 2 is an exploded perspective view showing a main part flow control valve of the present invention.

3A is a side cross-sectional view showing the operation of the flow regulating valve.

<Explanation of symbols for main parts of the drawings>

2: manhole cylinder 4: rainwater inlet pipe

6: bypass pipe 8: sewage inflow pipe

10: sewage outflow pipe 12: flow control valve

14: neck portion 16: float sheet

18: valve seat 20: housing

21: float 22: valve

24: rod 26: valve body

28: turning 30: spillway

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

1 is a view showing a schematic configuration related to the manhole of the present invention, in which a plurality of rainwater inlet pipes 4 communicate with the uppermost part of the manhole cylinder 2, and a bypass pipe 6 is connected to a lower position thereof. have. The sewage inflow pipe 8 communicates to a position substantially lower than the bypass pipe 6, while the sewage outflow pipe 10 connected to one side of the manhole cylinder 2 communicates to the lowest position. And the inside of the manhole cylinder 2 is accommodated in the flow rate control valve 12 to adjust the amount of water flowing into the sewage inlet pipe 10 as the amount of rainwater increases.

That is, the flow rate control valve 12 has a housing formed so that the inside is divided into a float seat 16 and a valve seat 18 which are widened up and down, respectively, with the middle neck portion 14 as a boundary as shown in FIG. 20 is formed in a symmetrical form in which a pair is matched, and an upper float 21 and a lower valve 22 are integrally formed between both housings 20 via an intermediate rod 24. The valve body 26 which is coaxially connected with the furnace is arrange | positioned so that lifting is possible.

The float 21 is made of a hollow space structure by the extrusion of the synthetic resin can cause a significant buoyancy, the bottom of the outer periphery of the plurality of projections 28 are formed integrally protruding the float sheet 16 It is possible to form a gap at a predetermined interval between the gaps), and at the same time, a spillway 30 is formed in a groove shape at a predetermined position on the outer circumferential surface of the float sheet 16. The valve 22 is shown in this embodiment as a spherical body, but is not limited thereto, but may be of any form as long as it can fit with the valve seat 18 to block the passage defined by the neck portion 14.

The rod 24 is accommodated in the space defined by the neck 14 so that the float 21 is positioned about the center of the float seat 16 and also about the valve seat 18 by the valve 22. Allows to be located.

Referring to FIG. 3A, the valve 22 can see a state in which the float 21 is seated on the float seat 16 by its own weight. In this state, the float 21 forms a predetermined gap between the float sheet 16 by the protrusions 28 around the lower side, so that only the sewage flows through the upper portion of the housing 20 through the gap. It flows down the valve 22 and flows out through the sewage treatment pipe 10.

However, when rainwater begins to be mixed into the manhole cylinder 2 in an excessive amount in a short time, the amount of rain water that has not flowed through the interval set by the protrusion 16 is increased, and the inside of the manhole cylinder 2 is filled with rain water. To start. Since water pressure is generated inside the manhole cylinder 2 due to the accumulation of rainwater, the float 21 floats as shown in FIG. 3B in proportion to the increase in water pressure.

As the float 21 rises, the valve 22 connected to the lower side of the float 21 blocks the neck 14 and prevents water from flowing down, thereby further increasing the water pressure. As a result, when the float 21 floats completely, the passageway through which the sewage flows out becomes the interval between the valve 22 and the valve seat 18, and if this interval is set in advance with the designed sewage, the flow of the sewage is limited to the design sewage. On the other hand, further rainwater is discharged to the river through the bypass pipe (6).

Next, when the rainfall decreases and the internal water level of the manhole cylinder 2 is lowered, the position of the float 21 is also lowered, so that the valve 22 opens the neck portion 14 and is discharged through the bypass pipe 6. The rainwater is discharged through the sewage inlet pipe 10 again.

In this way, the present invention serves to properly adjust the amount of water that can flow down into the sewage inlet pipe 10 while the position of the float 21 is automatically displaced according to the internal water level of the manhole cylinder 2.

As described above, the present invention is to allow the float floated by the hydraulic pressure to move the valve together to reduce the cross-section of the sewage outflow passage, so that the planned sewage can be collected at the corresponding water level according to the changing water level regardless of rainfall. The amount of sewage flowing into the sewage treatment plant can be constantly adjusted according to the rainfall because the opening degree is automatically adjusted so that the surplus flow rate does not flow into the sewage treatment plant. Has the effect of being easier.

Claims (3)

Excessive amount of rainwater flowing through the sewage pipe is discharged to the river and partly drained to the teahouse pipe where the tea house is partially. The upper and lower inner circumferential surfaces include a housing 20 which is formed in a float seat 16 and a valve seat 18 on the border of the neck portion 14 and is formed in a symmetrical manner and combined with each other. The flow rate control valve 12 in which the upper float 21 and the lower valve 22 are elevated so that the valve body 26 which is coaxially connected integrally via the middle rod 24 is provided in the manhole. A flow control device configured to be housed inside the cylinder (2). The apparatus of claim 1, wherein the float (21) has a plurality of spillways (30) in a groove shape on an outer circumferential surface thereof. The flow control apparatus for rainwater soil according to claim 1 or 2, wherein a plurality of protrusions (28) are integrally formed equally under the outer circumferential surface of the float (21).