KR101087062B1 - Filtration system using backwash-pressure fluctuations - Google Patents

Abstract

The present invention relates to a system that can easily remove contaminants trapped on the screen filter by forming a vacuum in the drain path, and more particularly, an inflow path through which contaminated water is supplied and contaminated water introduced into the inflow path to the screen filter. A strainer having a discharge path for filtering and discharging the filtered water, a drain path for discharging backwash water containing contaminants generated when the contaminated water is filtered, a drain valve for opening and closing the drain path, and a switch for controlling opening and closing of the drain valve; And a filtration pump disposed in the discharge path for discharging the filtered water; and a drain pump disposed in the drain path for discharging contaminants through the drain path when the drain valve is opened; And a switch disposed between the drain valve and the drain pump to close the drain path after opening the drain valve to form a vacuum in the drain path, in order to increase the suction power of the drain path to remove contaminants trapped in the screen filter. It is achieved by a back pressure fluctuating filtration system comprising a; Accordingly, by installing a reverse flow path opening and closing valve between the drain valve and the drain pump to control the vacuum pressure and the pressure cycle formed in the drain path, the suction power of the drain path is increased to effectively remove the contaminants that are strongly stuck in the screen filter. Can be.

Description

Filtration system using backwash-pressure fluctuations

The present invention relates to a backwashing variable filtration system, and more particularly, to a backwashing variable filtration system capable of easily removing contaminants caught on a screen filter by forming a vacuum in a drain path.

In general, a water filter (STRAINER, strainer) is a device for filtering organic suspended matter, which may be introduced or generated in various equipment systems using a mesh or screen filter, and is widely used for filtering agricultural water, industrial water, and the like. In general, factories are mainly equipped with a water filter for filtering contaminated cooling water and the like to filter a large amount of contaminated water.

In particular, as shown in FIG. 1, the automatic backwash type automatic strainer 100 of the water filter is referred to as a `` strainer '' 100 through a filtration process and a drain valve 110 for filtering contaminated water. It is widely used because the backwashing process, which discharges backwashing water containing contaminants generated when filtering contaminated water, can be simultaneously performed to the outside of the strainer.

Here, when the pressure difference measured by the pressure gauge 120a located in the path through which the contaminated water is introduced and the pressure gauge 120b located in the path through which the filtered water is discharged increases by more than a certain level, it is determined that the pollutant is full in the strainer 100. Thus, the switch 130 opens the drain valve 110. Thus, the backwash water mixed with a part of the contaminated water is discharged to the outside of the strainer 100.

Referring to FIG. 1, as a device for introducing contaminated water into the strainer 100 and discharging the filtered water filtered by the strainer 100, the pump 150 is generally installed together with the strainer 100. However, the pump 150 had to be installed in a path through which the contaminated water flows into the strainer 100 (hereinafter referred to as 'inflow path A').

The reason for this is that when the pump 150 is located in a path through which the filtered water filtered by the strainer 100 is discharged (hereinafter, referred to as 'discharge path B'), suction force of the pump 150 is generated during the backwashing process. . This is because outside air may be introduced into the strainer 100 through a path through which backwash water containing contaminants is discharged (hereinafter, referred to as a 'drain path C'). This is because the suction force of the pump 150 acts in a direction opposite to the direction of reverse wash flow discharged through the drain path C. Accordingly, when outside air flowed into the strainer 100 during the filtration process, the filtration process had to be stopped. Therefore, when performing the backwashing step of the filtration process by placing the pump 150 in the inflow path (A), it was common to prevent the outside air flows into the strainer 100 by the pump 150.

Therefore, when the pump 150 is located in the inflow path A, since the contaminated water is supplied to the strainer 150 via the pump 150, the impeller of the pump 150 is caused by the contaminants contained in the contaminated water. Problems such as damage occurred.

In order to solve this problem, as shown in FIG. 2, the pump 150 is disposed in the discharge path B, and the drain pump 300 is disposed in the drain path C, thereby preventing the impeller of the pump 150. Air was prevented from entering 100a. However, since the backwashing process is performed by opening the drain valve 300 during the operation of the pump 150, the pressure drawn from the drain pump 300 must be higher than the pressure drawn into the pump 150. That is, even if the pressure suctioned from the drain pump 300 is higher than the pressure suctioned from the pump 150, if the difference is insignificant, only the contaminants that are weakly trapped among the contaminants stuck to the screen filter SF are dropped. To be discharged. Therefore, a drain pump 300 having a capacity significantly higher than that of the pump 150 should be installed. That is, since an expensive drain pump or a large drain pump must be installed, a problem that requires a large cost and a large installation space occurs.

The present invention has been made to solve the above problems, by increasing the suction force of the drain path to effectively remove the contaminants stuck in the screen filter, the reverse flow path opening and closing valve between the drain valve and the drain pump by installing the drain path It is an object of the present invention to provide a backwashing variable filtration system that can control the vacuum pressure and the pressure cycle formed in the.

According to the present invention, an inlet path through which contaminated water is supplied, a discharge path through which contaminated water introduced into the inlet path is filtered through a screen filter, and discharge filtered water, and a drain path through which backwash water including contaminants generated when the contaminated water is filtered are discharged. A strainer having a drain valve for opening and closing the drain path and a switch for controlling opening and closing of the drain valve; and a filtration pump disposed at the discharge path for discharging the filtered water; and a contaminant disposed at the drain path when the drain valve is opened. Drain pump for discharging through the drain path; And the drain pump is disposed in front of the drain pump to increase the suction power of the drain path to remove contaminants trapped in the screen filter, while the drain pump is operated after the drain valve is opened. And a backwash flow channel opening and closing valve actuated by a switch to repeatedly perform opening and reopening the drain path.

The apparatus may further include a chamber disposed between the backflow channel opening and closing valve and the drain pump to expand the vacuum space in order to further increase the suction force of the drain path.

In addition, the back-flow path opening and closing valve can open and close the drain path so as to form a vacuum state in a continuous cycle in the drain path so that contaminants trapped in the screen filter can be easily removed.

In addition, the reverse flow path opening and closing valve can open and close the drain path in order to make the vacuum in the drain path non-continuous so that contaminants trapped in the screen filter can be easily removed.

By the above configuration, the backwash pressure fluctuation type filtration system according to the present invention has an effect of easily removing contaminants trapped in the screen filter by controlling the suction pressure and the pressure cycle of the drain path to pulsate the inside of the strainer. . In particular, by installing a chamber that expands the space in which the vacuum is formed, there is an effect of easily removing contaminants strongly stuck in the screen filter.

1 and 2 schematically show a conventional filtration system.
3 is a view schematically showing a backwash pressure filtration system according to an embodiment of the present invention.
4 is a view schematically showing a backwash pressure filtration system according to another embodiment of the present invention.
5 is a partial cross-sectional view schematically showing the interior of the strainer in the present invention.

The present invention, when the contaminated water is supplied to the inlet path (A), the contaminated water introduced into the inlet path (A) is filtered through the screen filter (SF) discharge path (B) to discharge the filtered water, Strainer 10 having a drain path (C) for discharging backwash water containing contaminants, a drain valve (11) for opening and closing the drain path (C), and a switch (12) for controlling the opening and closing of the drain valve (11). And, disposed in the discharge path (B) and the filtration pump 20 for discharging the filtered water; And, disposed in the drain path (C) when the drain valve 11 is open, contaminants through the drain path (C); A drain pump 30 for discharging; And the drain pump 30 is disposed in front of the drain pump 30 to increase the suction power of the drain path C to remove contaminants trapped in the screen filter SF. In the operating state, the backwash flow path actuated by the switch 12 cuts the drain path C to form a vacuum in the drain path C, and then repeatedly opens the drain path C again. On-off valve 70; is achieved by the backwash pressure variable filtration system (1, 1a) comprising a.

In addition, in order to further increase the suction force of the drain path (C), the chamber 71 is disposed between the reverse flow path opening and closing valve 70 and the drain pump 30 to further expand the vacuum space.

In addition, the reverse flow path opening and closing valve 70 may open and close the drain path C so as to form a vacuum state in a continuous cycle in the drain path C so that contaminants trapped in the screen filter SF are easily released. .

In addition, the reverse flow path opening and closing valve 70 may open and close the drain path C so as to discontinuously vacuum the drain path C so that the contaminants trapped in the screen filter SF are easily removed.

Hereinafter, with reference to the accompanying drawings an embodiment of the backwash pressure fluctuation filtration system 1 according to the present invention will be described in detail.

As shown in FIG. 3 and FIG. 5, the strainer 10, the filtration pump 20, the drain pump 30, and the backwash channel open / close valve 70 are illustrated in FIG. 3 and FIG. 5. ), And may further include a chamber 71.

The strainer 10 includes an inflow path A through which contaminated water is introduced, a screen filter SF for filtering the introduced contaminated water, and a suction pipe 10a for removing the contaminant contained in the contaminated water when it is caught by the screen filter SF. ), A discharge path (B) for discharging the filtered water filtered by the screen filter (SF), and a drain path (C) for discharging contaminants generated when the contaminated water is filtered through the suction pipe (10a). That is, as shown in Figure 5, the suction hole (10b) of the suction pipe (10a) connected to the drain path (C) is almost in close contact with the inside of the screen filter (SF) is sandwiched inside the screen filter (SF) Inhale contaminants to drain backwash. This is because the negative pressure of the drain path C generates a suction force in the suction hole 10b of the suction pipe 10a, so that the suction pipe 10a sucks the contaminants. Here, the inside of the strainer 10 includes a configuration for filtering the contaminated water, such as a screen filter (SF), a motor (not shown) for rotating the suction pipe (10a), which will be understood by those skilled in the art Is omitted.

The strainer includes a drain valve 11 positioned in the drain path C to open and close the drain path C, and a switch 12 to control the opening and closing of the drain valve 11. Here, as shown in FIG. 3, the switch 12 places the pressure gauge 13 in the inflow path A and the discharge path B so that the difference in pressure measured by the pressure gauge 13 may be increased by a predetermined pressure or more. In this case, it is assumed that the switch 12 opens the drain valve 11. In addition, the switch 12 may open and close the drain valve 11 when a flowmeter (not shown) is disposed in the discharge path B so that the flow rate decreases below a predetermined flow rate. This is for the case where the backwash pressure fluctuating filtration system 1 according to the present invention is used in a situation where a constant flow rate of filtered water must be discharged. In addition, the switch 12 may be set to open and close the drain valve 11 at regular time intervals. This is to periodically remove the contaminants accumulated in the strainer 10 to maintain a constant discharge of the filtered water.

Here, the process of filtering the contaminated water introduced through the inflow path (A) in the strainer 10 and discharging the filtered filtrate through the discharge path (B) will be referred to as a filtration process. In addition, the process of discharging contaminants generated while the contaminated water is filtered through the strainer 10 and the backwash water including the same to the drain path C will be referred to as a backwash process.

The filtration pump 20 is located in the discharge path B to discharge the filtered water filtered by the strainer 10. Here, the filtration pump 20 operates during the filtration process.

The drain pump 30 is located in the drain path C and discharges backwash water containing contaminants generated in the strainer 10 in which the drain valve 11 is opened to the drain path C.

Here, since the drain pump 30 does not need to operate when the drain valve 11 is closed, it can be controlled to operate only during the backwashing process by the switch 12. Accordingly, even when the backwashing process is performed while the suction force is applied to the inside of the strainer 10 in the direction of the discharge path B by the filtration pump 20 during the filtration process, the external air is drained by the drain pump 30. It is prevented to flow into the strainer 10 through (C). That is, the drain pump 30 generates a suction force for discharging the backwash water to the drain path C during the backwashing process, thereby preventing external air from flowing into the strainer 10 through the drain path C. In addition, the suction power of the drain pump 30 during the backwashing process also serves to increase the discharge efficiency of the backwashing water.

The back-flow path open / close valve 70 is disposed between the drain valve 11 and the drain pump 30 to be installed in the drain path C and operated by the switch 12 to form a vacuum in the drain path C. The drain path C is opened and closed so as to be closed. That is, in order to form a vacuum in the drain path C, after the drain valve 11 is opened and the drain pump 30 is operated in the backwashing process, the backwash passage opening / closing valve 70 is drained for a predetermined time. ). Accordingly, a vacuum is formed in the drain path C between the back flow channel open / close valve 70 and the drain pump 30. At this time, after a predetermined time, the back flow channel open / close valve 70 is operated to open the drain path C. Open and repeat this. Accordingly, the suction force increases in the drain path C instantaneously due to the vacuum formed in the drain path C, and contaminants trapped in the screen filter S.F are more easily dropped by the increased suction force.

Here, the reverse back channel open / close valve 70 may be a stop valve, a gate valve, a ball valve, or the like operated by an electric motor (not shown) to continuously form or release a vacuum in the drain path C. Here, the stop valve, the gate valve, the ball valve will be apparent to those skilled in the art, and a detailed description thereof will be omitted, and an electric motor or a driving device for operating the valve is also already known and widely known and will not be described in detail. Accordingly, when the reverse flow path open / close valve 70 is operated, a pulsation may be formed in the strainer 10 by forming or releasing a vacuum state in a continuous and constant cycle in the drain path C. Therefore, a pulsation may be formed inside the strainer 10 to easily drop and remove contaminants stuck to the screen filter S.F. In addition, the reverse flow path open / close valve 70 may include a stop valve, a gate valve, a solenoid valve, and the like operated by hydraulic pressure, pneumatic pressure, and electromagnetic force so as to continuously form or release a vacuum in the drain path C. FIG. That is, the pulsation time of the drain path C can be increased, and the drain path C can be quickly opened and the backwash water is sucked instantaneously, whereby a larger pulsation can be formed in the strainer 10. Therefore, contaminants stuck to the screen filter S.F can be easily dropped and removed. Here, the stop valve, the gate valve and the solenoid valve are already known and widely used, and thus detailed description thereof will be omitted.

The above-described backwash channel open / close valve 70 may adjust a vacuum pressure formed in the drain path C by adjusting an operation time. That is, the degree of contaminants trapped in the screen filter SF is inversely proportional to the pressure value measured by the pressure gauge 13. Based on this, the backflow channel opening / closing valve 70 is operated regularly or irregularly so that the drain path C By adjusting the vacuum pressure formed in the), the contaminants stuck to the screen filter SF are removed.

The chamber 71 has a substantially constant space in order to expand the space in which the vacuum is generated, and is disposed between the backflow channel opening and closing valve 70 and the drain pump 30 to be connected to the drain path C. Accordingly, the space in which the vacuum is generated can be expanded to further increase the suction force of the drain path C. Therefore, contaminants more tightly stuck to the screen filter SF can be dropped more easily.

On the other hand, with reference to Figure 4 will be described in detail backwash pressure fluctuation type filtration system (1a) according to another embodiment of the present invention.

Prior to the description, the description of the same configuration in the backwash pressure variable filtration system 1 according to the embodiment of the present invention will be omitted, and the same reference numerals will be used.

As shown in FIG. 4, the backwash pressure fluctuating filtration system 1a according to another embodiment of the present invention discharges backwash water discharged to the drain path C in the amount of contaminated water flowing into the inflow path A. Contaminated water (hereinafter referred to as 'extended contaminated water'), with the addition of the amount of filtrate corresponding to the amount of, may be introduced into the inflow path (A).

That is, assuming that the amount of contaminated water flowing into the inflow path (A) is (P) and the amount of backwashed water discharged into the drain path (C) (Q), the amount of increased contaminated water is (P + Q). do.

In this configuration, the backwash pressure variable filtration system 1a according to another embodiment of the present invention may further include an expansion unit 40, a feedback path D, and a feedback valve 50.

The expansion unit 40 is installed in the inflow path (A) to expand the portion adjacent to the strainer 10 of the pipe forming the inflow path (A).

The feedback path (D) communicates between the discharge path (B) and the inflow path, the inflow path (A) corresponding to the amount of backwash water discharged by the drain valve 11 of the filtered water discharged to the filtration pump 20 It is provided for reflowing into the portion expanded by the heavy expansion unit (40).

The feedback valve 50 is located in the feedback path D to open and close the feedback path D. Here, the feedback valve 50 is controlled by the switch 12, and opens the feedback path (D) during the backwashing process. Here, the feedback valve 50 may be provided to supply an amount corresponding to the amount of backwash water in the filtered water to the feedback path (D), but the inner diameter of the pipe forming the feedback path (D) is equal to the amount of backwashed water in the filtered water. Of course, it can be configured to supply a corresponding amount.

Therefore, in the backwashing process, the feedback valve 50 is opened and the amount corresponding to the amount of backwash water discharged by the drain valve 11 from the filtered water discharged to the discharge path B is the inflow path A through the feedback path D. ) Is introduced into the portion expanded by the expansion unit (40). Therefore, when the pipe forming the inflow path A is exposed to the suction power of the filtration pump 20 and the drain pump 30 for a long time, and the drain path C is blocked by the backwash channel opening / closing valve 70, the inflow It is provided to prevent the group from going to the pipe forming the path (A) and to extend the service life of the pipe forming the inflow path (A).

That is, it is assumed that the amount of contaminated water flowing into the inflow path A is Q and the amount of backwash water discharged through the drain path C is P. Here, when the backwashing step of the filtration process, the amount of filtered water discharged from the strainer 10 to the discharge path (B) is (Q-P).

Here, the backwashing process is a process in which both the filtration pump 20 and the drain pump 30 operate. Therefore, if the backwashing process is performed while the filtration pump 20 generates the suction force for sucking the amount of contaminated water by (Q) and performs the filtration process, the drain pump 30 sucks the backwashing water of the amount of (P). Generate suction power. Thus, the inflow path (A) receives a suction force for suctioning the increased amount of (Q + P) contaminated water by the filtration pump 20 and the drain pump (30).

Here, in the state where the strainer 10 is previously installed to filter the water, the pipe forming the inflow path A according to the present invention is provided as a pipe having a supply capacity of Q, which is the amount of contaminated water. Accordingly, while the suction force for suctioning positive water by (Q + P) by the filtration pump 20 and the drain pump 30 acts for a long time, the drain path C may be blocked by the backwash channel opening / closing valve 70. When the inlet path (A) to form a bunch can come. Therefore, as shown in FIG. 4, in the backwash pressure fluctuating filtration system 1a according to another embodiment of the present invention, an inflow path A is installed by installing an expansion unit 40 capable of supplying increased contaminated water to the inflow path A. ) And further install a feedback path (D) provided with a feedback valve 50 for introducing the same amount of backwash water into the inflow path (A) of the filtered water discharged into the discharge path (B).

Therefore, the feedback valve 50 is opened during the backwashing process, and when the filtered water corresponding to the amount (P) of the filtered water discharged into the discharge path B is re-introduced into the inflow path A, the filtered water supplied to the strainer 10 is supplied. Becomes the (Q + P) positive filter. Thus, the increased filtered water satisfies the required amount of suction by the filtration pump 20 and the drain pump 30, so that the pipe forming the inflow path A is a suction force of the filtration pump 20 and the drain pump 30 for a long time. Even if exposed to the crowd will not come.

Meanwhile, reference numeral 60 shown in FIGS. 3 and 4 is a check valve 60 to prevent backflow of contaminated water, filtered water, and backwash water.

Therefore, in the backwash pressure fluctuation type filtration system of the present invention, by providing the drain valve and the chamber 71, the drain pump 30 having a smaller capacity than the conventional drain pump can be used to prevent the entire system from becoming excessive. In addition, manufacturing costs can be reduced.

In describing the present invention described above, even if the embodiment is different, the same reference numerals are used for the same configuration, and the description may be omitted as necessary.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Shall not be construed as being understood. Therefore, a person having ordinary knowledge in the technical field to which the present invention pertains may easily implement other forms of the present invention within the same scope as the above-described embodiments, or the present invention only by the description of the embodiments of the present invention. It will be possible to practice the invention in the same and equal range.

1, 1a; Backwash pressure filtration system 10; Strainer
10a; Suction tube 10b; Suction hole
11; Drain valve 12; switch
13; Manometer 20; Filtration Pump
30; Drain pump 40; Expansion unit
50; Feedback valve 70; Back-flow channel open / close valve
71; Chamber SF; Screen filter

Claims (4)

An inflow path through which contaminated water is supplied, a discharge path through which the contaminated water introduced into the inflow path is filtered through a screen filter to discharge filtered water, and a drain path to discharge backwash water including contaminants generated when the contaminated water is filtered; A strainer having a drain valve for opening and closing the drain path and a switch for controlling opening and closing of the drain valve;
A filtration pump disposed in the discharge path to discharge the filtered water;
A drain pump disposed in the drain path and configured to discharge the pollutants through the drain path when the drain valve is opened; And
It is disposed in front of the drain pump, in order to increase the suction force of the drain path to remove the contaminants stuck in the screen filter, the drain path is blocked in the state that the drain pump is operated after the drain valve is opened And a backwash channel opening and closing valve actuated by the switch to form a vacuum in the drain path and to repeatedly open the drain path again.
The method of claim 1,
And a chamber disposed between the backflow channel opening / closing valve and the drain pump to expand a space in which the vacuum is generated to further increase the suction force of the drain path.
The method of claim 1,
The reverse flow path opening and closing valve is,
And opening and closing the drain path to form a vacuum state in a continuous cycle in the drain path so that contaminants trapped in the screen filter are easily removed.
The method of claim 1,
The reverse flow path opening and closing valve is,
And opening and closing the drain path so as to vacuum the drain path in a non-continuous manner so that contaminants trapped in the screen filter are easily removed.

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