KR101056450B1 - Filter system for water in the valle - Google Patents

Abstract

PURPOSE: An apparatus for purifying valley water is provided to stably obtain purified water without the damage of a membrane filter by separating sand from valley water using a varying filter and transferring the filtered valley water to the membrane filter. CONSTITUTION: A pump(11) transfers valley water in order to implement a water purifying process. A varying filter pre-filters the valley water. A flow controlling valve(12) selectively controls the path of the flow by being installed between the pump and the varying filter. A processed water storing bath(16) stores filtered valley water which is filtered in ultrafiltration membrane(14) or microfiltration membrane(15). The ultrafiltration membrane secondarily filters floats from the pre-filtered valley water. The microfiltration membrane filters floats from the valley water transferred by the pump.

Description

[0001] The present invention relates to an apparatus for treating water in a valley,

The present invention relates to a water treatment apparatus using valley counts, and more particularly, to a water treatment apparatus using valley counts, and more particularly, To a water treatment apparatus capable of preventing the movement of the pipeline or the breakage of the apparatus due to freezing of the water.

Generally, the water treatment device removes the suspended substances contained in the raw water through processes such as precipitation and filtration. In the case of the double filtration method, the foreign water is filtered while the raw water passes through the filter.

Especially, the number of valleys in the mountainous area contains a large amount of foreign matter such as sand, and a large amount of foreign matters accumulate in the filter at the time of the water purification, resulting in frequent filter clogging. These problems cause frequent replacement of the filter.

In order to solve such a problem, the filter is regenerated by backwashing without replacing the filter in the general water and wastewater treatment apparatus. Backwashing is caused by reversing the flow of the raw water in the water supply and drainage and discharging the accumulated foreign substances to the outside of the filter.

However, in the case of the valley number in the mountainous area, since there is a large amount of foreign matter such as sand in the valley number, if the valley number is used for backwashing, there is a high possibility that the filter is damaged, There is a problem that it needs to be replaced again.

In order to purify the number of valleys containing such a large amount of foreign matter, UF membrane or MF membrane can be used to precisely filter the raw water. However, when the number of the valleys is directly used, the fine pores of the filter Which is damaged and needs to be replaced.

In the mountainous area, the temperature outside the winter is very low compared to the urban area. Therefore, the number of valleys in the water treatment process is frozen and the water treatment is not smooth. Especially, when the water treatment device is stopped, the number of valleys remaining in the pipe is frozen, Serious problems arise.

Accordingly, there is an increasing demand for a water treatment apparatus for a valley water which overcomes the unreasonable points of such a conventional water treatment apparatus and smoothes the number of valleys containing a large amount of foreign substances such as sand, It is true.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a filter device capable of stably filtering without damaging the filter or damaging the filter when the number of valleys containing a large amount of foreign matter is kept constant. And to provide a water treatment apparatus.

Another object of the present invention is to prevent freezing of the number of valleys in the purification process due to the outside temperature in winter or freezing of the number of valleys remaining in the channel to prevent the pipe from being frozen.

It is still another object of the present invention to provide an apparatus and a method for controlling the number of valleys when the water treatment apparatus can not be used due to clogging of the filter for ordinary water treatment or backwashing of the filter, And supplies treated water.

In accordance with an aspect of the present invention, there is provided a method of controlling a water pump, including: a pump for feeding water to be introduced for an integer; a variable filter for pretreating and filtering the water of the water pressure fed through the pump; A flow path control valve provided between the pump and the variable filter for selectively controlling the path of the flow path; and a flow control valve for selectively controlling the path of the flow path when the variable filter or the UF membrane is in an abnormal state, An MF membrane for filtering the floating water of the valley number transferred from the pump by changing the flow path of the UF membrane or the MF membrane; and a process water reservoir for storing the filtered valley water in the UF membrane or the MF membrane, The backwashing of the filter is changed to change the path of the flow path to supply the valleys to the rear end of the variable filter, The flow path control valve changes the path of the flow path when the UF membrane is backwashed, so that the valleys are supplied to the MF membrane to primarily filter the suspended matters And the valley water is supplied to the downstream end of the UF membrane, and the valley water is discharged through the drain pipe installed at the front of the UF membrane or the UF membrane after backwashing.

And a temperature sensor for measuring the temperature of the water of the valley or the temperature of the outside of the water stored in the water storage tank, An air compressor for supplying compressed air to the water level sensor and a temperature sensor; and an air compressor for driving the air compressor when the water temperature of the water falls below a predetermined reference temperature based on the sensed values of the water level sensor and the temperature sensor, And a controller for controlling the forced drainage of the number of the valleys remaining in the pipeline at the rear end of the pump to the outside.

And a chemical supply unit installed between the MF membrane and the UF membrane to supply the chemical to decompose the suspended matter contained in the primary filtered water in the MF membrane during backwashing of the UF membrane .

A housing accommodating therein the pump, the variable filter, the UF membrane, the MF membrane, and the process water reservoir and embedded in the ground; and a heat insulating layer installed on the inner wall of the housing to protect heat from the outside air.

The solar heat exchanger may further include a solar heat exchanger that heats the number of the valleys beforehand by the solar heat before the pump is driven by the pump, and a reservoir that is buried in the ground and stores the valleys heated by the solar heat exchanger, / RTI >

According to the present invention as described above, the number of the valleys including a large amount of sand is transferred to the membrane filter in a state where the sand is separated from the variable filter, thereby obtaining the treated water stably filtrated without damaging the membrane filter.

In addition, the backwashing time is shortened by increasing the restoring force of the variable filter by the air compressor during the backwashing of the variable filter, in which foreign matter such as sand is accumulated at all times by pre-filtering the water in the valley, have.

In addition, the number of the valleys is primarily filtered through the MF membrane, the UF membrane is subjected to chemical treatment through the chemical feeder, and the UF membrane is backwashed to prevent damage to the UF membrane, thereby improving the regeneration efficiency of the UF membrane.

In addition, the present invention has the effect of forcibly discharging the number of the valleys remaining in the water line of the water treatment apparatus, thereby preventing the duct from being broken by the external temperature in winter or damaging the apparatus.

1 is a block diagram of an apparatus for processing water in a valley according to an embodiment of the present invention.
2 is a block diagram of an apparatus for processing water in a valley according to a second embodiment of the present invention.
3 is a block diagram of an apparatus for processing water in a valley according to a third embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an apparatus for processing water in a valley according to an embodiment of the present invention.

The apparatus for treating water in the valley according to the present invention includes a pump 11, a variable filter 13, a UF membrane 14, an MF membrane 15, a flow control valve 12, a process water reservoir 16 And a housing 24. As shown in Fig.

The pump 11 presses the number of valleys introduced for the constant to the variable filter 13 side.

The variable filter 13 filters the number of valleys fed from the pump 11 by pretreatment. The variable filter 13 pre-filters foreign substances such as sand contained in the valley count. Here, the filter of the variable filter 13 is preferably made of a foamed resin made of a material such as urethane which has an elastic force and a restoring force. When the raw water is filtered, the variable filter 13 compresses the filter to reduce the size of the filter cavity. When the filter is regenerated through backwashing, the filter is decompressed to increase the size of the filter cavity. At this time, a compression plate is formed on the lower side of the variable filter 13, and the compression plate is raised to compress the variable filter 13. Then, compressed air is supplied into the variable filter (13) to enhance the restoring force of the filter. The structure of such a variable filter is described in detail in Patent No. 875389 filed by the present applicant.

The UF membrane 14 (Ultrafiltration Membrane) secondly filters the number of valleys pretreated in the variable filter 13. Here, the UF membrane 14 is also referred to as ultrafiltration. It mainly separates biomaterials and is composed of micropores having a pore size in the range of 0.05 to 0.001 μm.

The flow control valve 12 is provided between the pump 11 and the variable filter 13 to selectively control the number of valleys so that the number of valleys can be transferred to the variable filter 13 side or to the MF membrane 15 side have.

The MF membrane 15 filters the number of valleys fed from the pump 11. Here, the MF membrane 15 is also referred to as microfiltration and is mainly used for selectively separating and removing by the molecular size, and the permeated water quality is good and the operation condition is easy compared with the conventional processes such as sedimentation, multi-layer filtration, centrifugation and filtration flotation. The pore size of the MF membrane 15 filter is in the range of 0.05-10 μm larger than the UF membrane 14 filter and removes suspended solids.

The process water reservoir 16 stores the number of valleys filtered in the MF membrane 15 or the UF membrane 14.

The housing 24 is embedded in the ground and accommodates the pump 11, the variable filter 13, the UF membrane 14, the MF membrane 15 and the treated water storage tank 16, A heat insulating layer 25 is provided to protect heat from outside air. The housing 24 is made of concrete or stainless steel to prevent the valley count from being frozen during the purification process due to the low outside temperature in winter.

Hereinafter, the operation and the operation of backwashing operation of the apparatus for treating water in the valley according to the embodiment of the present invention will be described in more detail.

In the apparatus for treating water in the valley water according to the present invention, the number of the valleys corresponding to the raw water is first passed through the variable filter (13) to separate the sand contained in the valley number, and then filtered through the UF membrane (15) filter. This is to prevent the filter from being clogged or damaged by floating matters when filtering the water of the valleys in the subsequent membrane filter by pretreating the sand contained in the valley number or the suspension having a size equal to or more than a predetermined size.

In the pretreatment filtration, a number of valleys including foreign matters such as sand are filtered, and a large amount of foreign matter accumulates in the filter at all times. The variable filter 13 is used as a pretreatment filter to facilitate backwashing when foreign substances are accumulated.

The variable filter 13 has a pore size of about 10 to 20 탆 which is larger than the UF membrane 14 filter, and pre-filters the foreign substances contained in the valley water. This is because a large amount of foreign matter is contained in the valley number and the foreign substance is pretreated in the variable filter 13 and then filtered in the UF membrane 14 to protect the UF membrane 14 filter having fine pores than the variable filter 13, To obtain permeated water with good water quality.

The number of valleys filtered in the UF membrane 14 is stored in the treated water reservoir 16 to use the valley number.

At this time, when the variable filter 13 or the UF membrane 14 is abnormal, the flow control valve 12 changes the path of the valley number so that the number of valleys conveyed from the pump 11 is transferred to the MF membrane 15. [ This is because the number of valleys is normally filtered while passing through the variable filter 13 and the UF membrane 14, and in the event of an emergency such as a filter failure, the MF membrane 15 changes the valley water flow path and performs filtration.

When the floating filter is accumulated in the variable filter 13 or the UF membrane 14 due to continuous filtration and the filter needs to be backwashed, the flow path control valve 12 changes the path of the valleys to perform backwashing.

The backwashing of the variable filter 13 is performed by supplying the number of valleys fed from the pump 11 to the variable filter 13 at the rear end of the variable filter 13 to backwash the variable filter 13. The backwashed valley number is discharged to the outside through a drain pipe (13a) provided at the front end of the variable filter (13).

The backwashing of the UF membrane 14 is carried out by transferring the valley water pressure-fed from the pump 11 to the MF membrane 15 side through the flow control valve 12 to remove the suspended matters from the downstream side of the UF membrane 14 And the UF membrane 14 is backwashed. The backwashed valley number is discharged to the outside through a drain pipe (14a) provided at the front end of the UF membrane (14). When the UF membrane 14 has fine voids in the filter and is washed with water containing a large amount of foreign matter, there is a high possibility that the membrane is damaged. First, the MF membrane 15 is backwashed with some foreign matter removed do.

A drug supply unit 17 is provided between the MF membrane 15 and the UF membrane 14 to primarily filter the valleys from the MF membrane 15 and then supply the medicine from the drug supply unit 17, Such as microorganisms remaining in the UF membrane 14 can be removed and the UF membrane 14 can be backwashed. It is preferable that the medicine of the medicine supply part 17 is made of sodium hydroxide (NaOH), sodium hypochlorite (NaOCL), or the like.

2 is a block diagram of an apparatus for processing water in a valley according to a second embodiment of the present invention.

Referring to the drawings, an apparatus for processing water in a valley according to a second embodiment of the present invention includes an air compressor 18 for providing compressed air, a temperature sensor 19 for determining the temperature and the water level of the water storage tank 16, And a control unit 21 for controlling the pump 11 and the air compressor 18 based on the sensed value of the water level sensor 20 and its sensed value.

The air compressor 18 supplies compressed air to the inside of the variable filter 13 or the front end pipe of the pump 11.

The water level measuring sensor 20 judges the water level of the valley water stored in the water storage tank 16.

The temperature sensor 19 measures the temperature of the valley water stored in the process water reservoir 16 or an external temperature.

The control unit 21 stops the operation of the pump 11 when the water level is full based on the sensed values of the water level measurement sensor 20 and the temperature sensor 19, And drives the air compressor 18 when the temperature is lower than the predetermined temperature.

Hereinafter, the operational relationship of the water droplet water purification apparatus according to the second embodiment of the present invention will be described in more detail.

The number of valleys filtered through the UF membrane 14 or the MF membrane 15 is stored in the process water reservoir 16. At this time, when the water level measuring sensor 20 measures the water level in the process water storage tank 16 and stops the operation of the pump 11 through the control unit 21 when the water level is higher than the reference water level of the preset number of troughs, So that the water does not flow into the reservoir 16.

When the temperature of the water in the water storage tank 16 or the external temperature is lower than a preset reference temperature in a state where the number of the valleys in the water storage tank 16 is full and the operation of the pump 11 is stopped, The compressed air is supplied from the front end of the pump 11 to the pump 11 side by driving the air compressor 18 so that the number of the valleys remaining in the pipeline at the rear end of the pump 11 is discharged to the outside through the drain pipes 14a and 15a Forced drainage. This is to prevent the number of the valleys remaining in the conduit from falling below the outside temperature when the operation of the pump 11 is stopped to freeze the number of valleys to prevent the conduit from being frozen.

In addition, the air compressor 18 supplies compressed air to the inside of the filter during backwashing of the variable filter 13 to improve the restoring force of the filter, thereby reducing the time taken for the filter to be restored, and shortening the backwashing time. In the variable filter 13 used as the pre-processing filter in the present invention, it is necessary to frequently clean the filter by accumulating a large amount of foreign matter in the filter at all times due to the number of valleys. Therefore, the backwashing time of the variable filter 13 is shortened by the air compressor 18, and the operation efficiency of the water treatment apparatus can be increased.

3 is a block diagram of an apparatus for processing water in a valley according to a third embodiment of the present invention.

Referring to the drawings, the apparatus for treating water in the valley according to the third embodiment of the present invention further includes a solar heat exchanger 22 for warming the valley count and a water tank 23 for storing the valleys heated by the solar heat exchanger 22 .

The solar heat exchanger 22 is installed at the front end of the pump 11 and heats the number of valleys introduced into the pump 11 by solar heat.

The water storage tank 23 is buried in the ground, stores the valleys heated by the solar heat exchanger 22, and supplies water to the valleys by the pump 11. Here, the water storage tank 23 may have a heat insulating layer formed therein.

The apparatus for processing water in the valley according to the third embodiment heats the number of valleys for the integer to a predetermined temperature through the solar heat exchanger 22 and stores the water in the water tank 23 and supplies it to the pump 11. This is to prevent the phenomenon that the valley number in the mountainous region is frozen while being transferred to the strong river, and to remove the impurities contained in the valley number stored in the water tank 23 to some extent by sedimentation.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims should include all such modifications and changes as fall within the scope of the present invention.

11: Pump 12: Flow control valve
13: Variable filter 14: UF membrane
15: MF membrane 16: treated water storage tank
17: drug supply part 18: air compressor
19: Temperature sensor 20: Water level measuring sensor
21: control unit 22: solar heat exchanger
23: water tank 24: housing
25: Insulating layer

Claims (5)

A pump for feeding the number of valleys introduced for an integer;
A variable filter for pretreating and filtering the number of valleys fed through the pump;
A UF membrane for secondarily filtering the floating water of the valley number pretreated in the variable filter;
A flow control valve provided between the pump and the variable filter for selectively controlling the path of the flow path;
An MF membrane which changes the path of the flow path in the flow control valve when the variable filter or the UF membrane is in an abnormal state, thereby filtering the suspended matter of the valleys conveyed from the pump;
A process water reservoir for storing the filtered valley number in the UF membrane or the MF membrane; Including,
The flow control valve
Wherein the control unit changes the path of the flow path during backwashing of the variable filter so that the valleys are supplied to the downstream end of the variable filter and the valley water is discharged through the drain pipe provided at the front end of the variable filter or the variable filter after backwashing,
During backwashing of the UF membrane, the flow path of the flow path control valve is changed so that the valleys are supplied to the MF membrane, the floats are primarily filtered, and the valley water is supplied to the rear end of the UF membrane, And the drain water is discharged through the drain pipe provided at the front end.
The method according to claim 1,
A water level measuring sensor for determining a water level of the water flowing into the treated water storage tank,
A temperature sensor for measuring a temperature of the valley water or an external temperature stored in the process water reservoir;
An air compressor for supplying compressed air to the front end of the variable filter or the pump,
When the water storage tank is full and the temperature of the water falls below a preset reference temperature based on the sensing values of the water level measuring sensor and the temperature sensor, the air compressor is driven so that the number of the valleys remaining in the channel at the rear end of the pump is A controller for controlling the forced drainage to the outside; Further comprising: a water level sensor for detecting the water level of the water level.
The method according to claim 1,
And a medicine supply unit installed between the MF membrane and the UF membrane for supplying the medicine to decompose the suspended matters contained in the primary filtered water from the MF membrane upon backwashing the UF membrane. Water treatment device.
The method according to claim 1,
A housing accommodating therein the pump, the variable filter, the UF membrane, the MF membrane, and the process water storage tank,
And a heat insulating layer provided on the inner wall of the housing to protect heat from the outside air.
The method according to claim 1,
A solar heat exchanger for previously heating the number of the valleys by the solar heat before the number of the valleys is drawn by the pump,
Further comprising: a reservoir for storing the number of valleys buried in the ground and heated by the solar heat exchanger, and supplying the water to the valleys by the pump.

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