KR101100749B1 - Buoyancy valve for regulated flow - Google Patents

Abstract

PURPOSE: A centering valve for controlling the flow of wastewater is provided to constantly maintain the flow of wastewater discharging into a chemical treating bath by adjusting the opening and closing amount of a waste water transferring pipe. CONSTITUTION: A centering valve for controlling the flow of wastewater includes a sealed tube(10), a fence(11), and an expanding unit(14). The sealed tube is hollow and floats on the surface of water based on buoyancy. The fence surrounds a transferring pipe and is opened for the introduction of the transferring pipe. The expanding unit is in connection with the tube using a supporting unit(13) and is combined with a cone-shaped cap(15). The con-shaped cap opens and closes the outlet of the transferring pipe. The length of the expanding unit is capable of being adjusted.

Description

Valve for regulating wastewater flow {BUOYANCY VALVE FOR REGULATED FLOW}

The present invention relates to a waste valve for regulating wastewater flow rate, which can maintain a constant flow rate of wastewater flowing into a chemical treatment tank in order to separate and coagulate sludge contained in the wastewater from wastewater. By controlling the opening and closing amount of the transfer pipe by the buoyancy of the inflow of the waste water conveyed by the transfer pump, the wastewater flow rate that can control the flow rate of the coagulant and the wastewater flowing into the chemical treatment tank It relates to an adjustment regulator valve.

In general, for the protection of water quality, wastewater, such as domestic sewage, industrial wastewater, or livestock manure, is sufficiently purified and discharged before discharge.

In purifying water quality, various purification methods are used depending on the condition of waste and wastewater, the type of pollution source, and the degree of pollution. For example, wastewater such as livestock manure has a serious pollution concentration of manure, so that excessive contaminants are physically or chemically removed first before the sewage treatment, and the water quality of the wastewater is purified.

The sludge removal method includes a physical removal method using various types of filters, a method of flocculating sludge contained in the wastewater by inputting a chemical such as a coagulant, and a method of dewatering the flocculated sludge and separating it from the wastewater.

Of course, if the sludge contained in the wastewater is sufficiently removed, the wastewater can not only increase the purification efficiency when purifying the wastewater, but also shorten the biological treatment process of removing contaminants such as nitrogen and phosphorus by microorganisms. It can reduce the efficiency of treatment tanks and treatment methods for wastewater and wastewater treatment, and reduce operating and management costs of wastewater and wastewater treatment facilities.

As described above, in order to remove the sludge contained in the wastewater, a flocculant is introduced into the treatment tank into which the wastewater flows in to coagulate the sludge, depending on the flow rate of the wastewater flowing into the chemical treatment tank or the wastewater. The sludge flocculation effect can be expected only when the input amount of flocculant is properly adjusted according to the pollutant source and pollution concentration.

When the amount of flocculant is excessively high, the operation load increases when the dehydrating device is operated. On the contrary, when the amount of the flocculant is too low, the flocculation effect of the sludge decreases. Therefore, the operation load increases when the wastewater is purified. Is generated.

As such, it is important to maintain the coagulation conditions optimized by the coagulant introduced into the chemical treatment tank, so that the wastewater flowing into the chemical treatment tank is preferably administered in proportion to the flow rate flowing into the chemical treatment tank.

However, the existing chemical treatment tank is discharged to the dewatering device (see Fig. 1) as the wastewater introduced into the overflow overflow by the triangular way, at this time, if the level of the chemical treatment tank falls below a certain level, the transfer pump (4) ), The waste water stored in the sedimentation tank (1) is transferred to the chemical treatment tank, while the transfer pump is introduced into the chemical treatment tank during the operating period (time of operation and rest of the transfer pump) There arises a problem that the flow rate of the waste water becomes irregular.

If the flow rate of the incoming wastewater becomes irregular, the amount of coagulant input must be adjusted accordingly. Therefore, separate management is required, and the continuous work process is delayed. The sludge present in the wastewater has caused a problem in that the operating load increases during the treatment of biological wastewater.

The present invention has been invented to solve the problems as described above, the object of the present invention is to treat the chemical treatment for the flocculation of sludge when transporting the waste water to the dewatering device to separate the waste water and sludge stored in the sedimentation tank By providing a constant flow rate of the wastewater introduced into the tank to provide a flow rate adjustment valve for automatically adjusting the flow rate to maintain a constant dose of the flocculant introduced into the chemical treatment tank.

An implementation means of the adjustment valve for flow rate adjustment according to the present invention,

A hollow, closed tube (10) to rise to the surface by buoyancy. The transfer pipe 4a is opened so that the transfer pipe 4a can enter and surrounds the circumference of the transfer pipe 4a while guiding in the longitudinal direction of the transfer pipe, and radially inwardly inside the tube 10. It can be implemented by the careful valve 100 including a conical stopper for opening and closing the outlet 4b of the transfer pipe toward the opening 12 of the fence to the support member 13 connected to each other.

According to the present invention, while opening and closing the outlet of the transfer pipe discharged by the transfer pump discharged by buoyancy, the opening and closing amount is controlled to maintain a constant flow rate discharged to the chemical treatment tank is injected into the chemical treatment tank Even if the dosage of the flocculant is not controlled separately, the flow rate discharged to the chemical treatment tank can be managed constantly.

1 is a configuration diagram illustrating a configuration of a conventional sludge flocculation treatment apparatus,
2 is a perspective view illustrating a part of the cutting valve according to the present invention;
3 is a cross-sectional view of the regulator valve shown in FIG.
4 is a cross-sectional view illustrating a state in which the outlet of the transfer pipe is blocked by the careful valve according to the present invention;
5 is a cross-sectional view illustrating a state in which the outlet of the transfer pipe is blocked by the careful valve according to the present invention;
Figure 6 is a block diagram of a sludge flocculation treatment apparatus employing a flow rate adjusting valve according to the present invention.

Hereinafter will be described in detail with reference to the accompanying drawings for the control valve for the flow rate adjustment according to the present invention.

2 to 6, Figure 2 is a perspective view illustrating a part of the cutout valve according to the present invention, Figure 3 is a cross-sectional view of the control valve shown in Figure 2, Figure 4 is a watch valve according to the present invention Is a cross-sectional view illustrating a state in which the outlet of the transfer pipe is blocked by, Figure 5 is a cross-sectional view illustrating a state in which the outlet of the transfer pipe is blocked by the careful valve according to the present invention, Figure 6 is adopted by the careful valve according to the present invention It is a block diagram which illustrated one sludge flocculation apparatus.

In FIG. 6, reference numeral 1 is a sedimentation tank storing waste water, 2 is a flow rate adjusting tank, 3 is a chemical treatment tank, 5 is a transfer pump employed in the present invention, and 6 is a dewatering device.

The sedimentation tank 1 is a wastewater storage container having the same structure and function as described above, and is a container for accommodating wastewater during the first inflow of wastewater from a wastewater purification facility or a wastewater during a purification process. As a treatment tank is introduced, a large amount of sludge is included in the sewage and wastewater introduced into the sedimentation tank.

The sludge is to remove the sludge from the waste water in order to improve the treatment efficiency of the waste water, there is provided a transfer pump (5) for transferring the sludge to the dewatering device to separate the sludge.

The wastewater transported by the transfer pump 5 is mixed with the flocculant introduced into the chemical treatment tank and introduced into the dehydration apparatus via the chemical treatment tank before entering the dehydration apparatus in order to aggregate the sludge contained in the wastewater.

The dewatering device 6 is not shown in detail in the drawing, but the sludge contained in the waste water by centrifugation is dewatered, and the dewatered sludge is discharged along the conveyor belt in the form of a piece having a constant width and thickness in the process of being discharged.

The present invention is to put a flocculant so that the sludge contained in the waste water in the chemical treatment tank (3) is agglomerated in the process of transferring the waste water and sludge from the sedimentation tank (1) to the dehydration device (6) as described above. At this time, a flow rate adjusting tank 2 for adjusting the flow rate of the waste water flowing into the chemical treatment tank 3 is further provided.

The flow rate adjusting tank 2 is connected with a conveying pipe 4a through which the waste water conveyed by the conveying pump 5 is discharged, and a control valve 100 for adjusting the flow rate is connected to the conveying pipe 4a.

As shown in FIG. 2, the flow rate adjusting valve 100 is attached to an upper portion of the hollow cylindrical tube 10 and the cylindrical tube 10, and the waste water discharged from the discharge port of the transfer pipe 4a is externally provided. It includes a conical fence 11 to block the splashing.

The upper end of the fence 11 is provided with an open portion 12 so that the feed pipe (4a) can enter, the lower end is coupled to the tube (10).

The cylindrical tube 10 has a plurality of support members 13 attached to the inside thereof in the axial direction, and an extension member 14 capable of length adjustment in the vertical direction of the support member 13 is attached.

Since the extension member 14 is accommodated in a slide manner into the pipe 14b having a small diameter so that the pipe 14a having a small diameter is folded like a telescope, the length of the extension member 14 can be adjusted. A tightening screw 14c is attached to the connection portion of the multistage pipe to fix the height. The tightening screw 14c can fix and disassemble the multistage pipe by screwing.

In addition, a conical stopper 15 for opening and closing the outlet 4b of the transfer pipe 4a is attached to the upper portion of the extension member 14. It is preferable that the conical stopper 15 has a diameter whose outer diameter is larger than the outer diameter of the outlet 4b of the feed pipe 4a.

The tube 10 is maintained in the longitudinal direction of the feed pipe 4a in accordance with the change in the water level of the flow adjusting tank 2 while maintaining the watch valve 100 always floated on the water surface by buoyancy on the surface of the flow adjusting tank 2. Ascend and descend.

At this time, the opening 12 of the fence 11 is in contact with the outer wall of the feed pipe (4a) serves to guide the careful valve 100.

Therefore, as shown in FIG. 5, when the water level of the flow adjusting tank 2 is lowered, the conical stopper 15 is connected to the outlet 4b of the feed pipe 4a. The amount of waste water discharged from the outlet 4b is increased while moving away from it. On the contrary, when the water level of the flow regulating tank 2 rises as shown in FIG. 4, the tube 10 rises by buoyancy and has a conical plug. Since 15 gradually closes the outlet 4b of the transfer pipe 4a, the flow rate of the wastewater flowing into the flow regulating tank 2 is reduced.

The transfer pump 4 shown in FIG. 1 is a pump that is operated and stopped by power supply. However, the transfer pump 5 employed in the present invention is controlled by the pressure in the transfer pipe 4a connected to the flow adjusting tank 2. By employing a pump with a variable rotation speed, the rotational speed of the transfer pump 5 is adjusted according to the opening and closing degree of the transfer pipe by the careful valve 100 so that the transfer pump 5 is not overloaded.

In FIG. 1 and FIG. 6, reference numeral 3a denotes a flocculant input device.

As shown in FIG. 6, the flow rate adjusting valve 100 according to the present invention has a constant flow rate introduced into the flow rate adjusting tank 2, and thus is discharged from the flow rate adjusting tank 2 to the chemical treatment tank 3. · The amount of waste water can be kept constant at all times.

As described above, the operator can continuously administer the amount of flocculant to the chemical treatment tank 3 even if the operator does not manage it separately. Therefore, a background is provided to automate the installation and operation. Since the flocculation effect of the sludge can be optimized, there is an effect that can reduce the operating cost or operating load when purifying the water quality of the waste water.

1: settling tank 2: flow adjusting tank
3: chemical treatment 4a: transfer pipe
4b: transfer pipe outlet 5: transfer pump
6: dehydrator 10: cylindrical tube
11: Higgs 12: Higgs opening
13: support member 14: extension member
14a, 14b: Pipe 14c: Tightening Screw
15: Conical stopper 100: Flow adjustment regulator

Claims (2)

A hollow, closed tube (10) to rise to the surface by buoyancy. A fence 11 which is open so that the transfer pipe 4a can enter and surrounds the circumference of the transfer pipe 4a while guiding in the longitudinal direction of the transfer pipe,
Is connected to the tube 10 by a support member 13, the conical stopper 15 is coupled to open and close the outlet of the transfer pipe 4a toward the opening 12 of the fence 11 A watch valve for adjusting the flow rate of waste water, characterized by a watch valve (100) composed of an extension member (14). The control valve of claim 1, wherein the extension member (14) is connected so that the multi-stage pipe is folded so as to adjust its length.

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