KR101889839B1 - Water purification apparatus - Google Patents

Abstract

The present invention relates to a water purification apparatus for purifying source water coming from water sources such as rivers, reservoirs, and valleys. Disclosed are a technique to adjust the amount of source water being supplied to a filtration membrane module by sensing the turbidity of source water or the pressure of source water returning to a source water reservoir after having passed through the filtration membrane module from the source water reservoir; and a technique to facilitate the mixing of chemicals when backwashing. To this end, the water purification apparatus comprises: an inverter pump which can regulate the amount of source water being supplied to a filtration membrane module, and a flow rate proportional control valve which regulates the flow rate of source water returning to a source water reservoir through the filtration membrane module. The water purification apparatus further comprises a roll-shaped chemical mixer which thoroughly mixes chemicals to maximize washing effects. According to the present invention, the water purification apparatus can prevent an abrupt decrease in performance or damage of a filtration membrane, and can prevent a loss of chemicals and a decrease in treatment efficiency due to reduced backwashing process.

Description

[0001] WATER PURIFICATION APPARATUS [0002]

The present invention relates to a water treatment apparatus for purifying raw water of a river, a lake, a reservoir or a valley.

The water treatment apparatus is a device for purifying raw water containing particulate matter such as gravel or contaminants such as Escherichia coli and green algae (hereinafter referred to as "particulate nonconforming material").

Such a water treatment apparatus is provided with a filtration membrane module having a function of microfiltration to filter out particulate unsuitable substances and pathogenic coliform bacteria in use.

The filtration membrane transfers the treated water filtered by the pump from the raw water supplied from the raw water supply tank to the treated water tank side through the particulate inadequate material and the pathogenic coliform bacteria group and passes the filtration size of the filtration membrane so that some raw water which has not passed through the filtration membrane, As shown in FIG. At this time, some of the raw water that has not passed through the filtration membrane functions to maintain the function of the filtration membrane by washing the particulate nonconforming materials attached to the filtration membrane surface together. In addition, the raw water supply tank, in which the raw water (circulating water) containing a large amount of particulate nonconforming materials is introduced and the turbidity is increased, is automatically implemented by discharging the stored raw water periodically, thereby maintaining the quality of the raw water supply tank, .

On the other hand, the turbidity (inclusion of particulate nonconforming material) of the raw water may change instantaneously due to flooding of green algae or mass inflow of soil by climate or rainy weather. Thus, the raw water from the raw water source may be low turbidity below the reference or high turbidity above the reference.

Therefore, when raw water of high turbidity is supplied, the particulate nonconforming material is stuck to or strongly stuck to the filtration membrane, resulting in rapid performance deterioration or damage of the filtration membrane, and frequent backwashing process leads to waste of chemicals and deterioration of treatment efficiency.

Korean Patent Publication No. 10-2011-0004942 Korean Patent Publication No. 10-2018-0008175

Disclosure of Invention Technical Problem [8] The present invention provides a technique for automatically maintaining the function of the filtration membrane in the case where the raw water is maintained at a high turbidity and the degree of contamination of the filtration membrane.

A water treatment apparatus according to a first aspect of the present invention includes: a raw water supply tank for storing raw water coming from a raw water supply source and supplying the raw water to a downstream end; An automatic backwash screen filter for filtering a large amount of suspended particulate matter which may damage the surface of the filtration membrane from the raw water coming from the raw water supply tank; A filtration membrane module having a microfiltration function to filter out particulate nonconforming material from the raw water coming from the automatic backwash screen filter to return to the downstream and return some of the raw water to the raw water supply tank; An inverter pump for supplying raw water of the raw water supply tank to the filtration membrane module through the automatic backwash screen filter and adjusting the supply amount of raw water; A flow rate proportional control valve installed on the line returning from the filtration membrane module to the raw water supply tank to regulate the flow rate of the raw water; A turbidimeter for measuring the turbidity of raw water supplied by the inverter pump; A treatment water tank for storing treated water coming from the filtration membrane module; A backwash water tank for storing treated water coming from the filter unit and sending the treated water to the treated water tank for performing a backwash process; The raw water is supplied in the first mode when the raw water supplied to the filtration membrane module from the raw water supply tank is low turbidity lower than the reference value and the raw water is supplied in the second mode when high turbidity is higher than the reference value, A controller for controlling the flow proportional control valve; Wherein the controller is configured to increase the amount of raw water returning to the raw water supply tank through the filtration membrane module to increase the raw water supply amount and the return amount in the second mode so as to increase the amount of particulate non- And controls the inverter pump and the flow rate proportional control valve to be greater than the raw water supply amount in the first mode.

Further comprising: a pressure gauge for measuring the pressure of the raw water returning to the raw water supply tank from the filtration membrane module; and when the pressure of the raw water returning to the raw water supply tank is equal to or higher than a reference value, And controls the flow proportional control valve.

A water treatment apparatus according to a second aspect of the present invention comprises: a raw water supply tank for storing raw water coming from a raw water supply source and supplying the raw water to a downstream end; An automatic backwash screen filter for filtering a large amount of suspended particulate matter which may damage the surface of the filtration membrane from the raw water coming from the raw water supply tank; A filtration membrane module having a microfiltration function to filter out particulate nonconforming material from the raw water coming from the automatic backwash screen filter to return to the downstream and return some of the raw water to the raw water supply tank; An inverter pump for supplying raw water of the raw water supply tank to the filtration membrane module through the automatic backwash screen filter and adjusting the supply amount of raw water; A treatment water tank for storing treated water coming from the filtration membrane module; A pressure gauge for measuring the pressure of the raw water returning from the filtration membrane module to the raw water supply tank; A backwash water tank for storing treated water coming from the filtration membrane module and then sending the treated water to the treated water tank for performing a backwash process; A controller for controlling the inverter pump to supply raw water in a first mode when the pressure of the raw water returning to the raw water supply tank is equal to or lower than a reference value and to supply raw water in a second mode if the pressure is higher than a reference value; Wherein the controller controls the supply amount of the raw water in the second mode so as to increase the amount of the particulate nonconforming material returned to the raw water supply tank by increasing the amount of raw water returning to the raw water supply tank via the filtration membrane module, Mode, the inverter pump is controlled.

The water treatment apparatus according to the first or second aspect may further include an inverter backwash pump that supplies the treated water from the backwash water tank to the filtration membrane module and adjusts the amount of backwash water supplied; A chemical mixer for mixing the backwash water transferred from the inverter backwash pump and the chemicals for backwashing; A CIP tank provided for periodically cleaning contaminants of the filtration membrane module; A CIP pump for supplying the raw water of the CIP tank to the filtration membrane module; As shown in FIG.

The present invention has the following effects.

First, it prevents the damage and deterioration of the filtration membrane due to the sudden introduction of the high turbidity particulate nonconforming material.

Second, it reduces the number of suitable backwash processes to prevent the waste of used chemicals used in the backwash process and improves the treatment efficiency.

third. In the backwash process, by using a pulp mixer and a pulverizer, it is possible to reduce the amount of chemicals used by the minimum input of the chemicals.

1 is a schematic view of a water treatment apparatus according to an embodiment of the present invention.

Preferred embodiments according to the present invention will be described with reference to the accompanying drawings, but for the sake of brevity of description, descriptions of redundant or substantially identical configurations are omitted or compressed as much as possible.

1 is a schematic diagram of a water treatment apparatus 10 according to an embodiment of the present invention.

1, the water treatment apparatus 10 according to the present invention includes a raw water supply tank 11, an automatic backwash screen filter 12, an inverter pump 13, a turbidimeter 14, a filtration membrane module 15, The treatment water tank 17, the backwash water tank 18, the backwash pump 19, the chemical pump 20, the chemical mixer 21, the CIP tank 22, the CIP pump 23, A water tank 24, a first pressure gauge P1, a second pressure gauge P2, a third pressure gauge P3, and a controller CD.

The raw water supply tank 11 is provided for storing the raw water coming from the raw water supply source S and then sending it to the automatic backwash screen filter 12 side at the rear end. The raw water supply tank 11 is provided to automatically discharge raw water stored periodically in order to maintain the quality of raw water.

The automatic backwash screen filter 12 filters a large amount of suspended particulate matter large enough to damage the surface of the filtration membrane from the raw water coming from the raw water supply tank 11 and sends it to the downstream filtration membrane module 15 side.

The filtration membrane module 15 has a filtration membrane F for filtering out particulate matters from the raw water passing through the automatic backwash screen filter. This filtration membrane module 15 has a microfiltration function, and a part of the raw water is returned to the raw water supply tank 11. That is, the treated water that has passed through the filtration film F is sent to the treated water tank 17, and the raw water that has not passed through the raw filter membrane F sweeps the particulate nonconforming material on the surface of the filtration film F, 11).

The inverter pump 13 supplies the raw water of the raw water supply tank 11 to the filter module 15 through the automatic backwash screen filter 12 and controls the supply amount of the raw water under the control of the controller CD do.

The turbidimeter 14 measures the turbidity of the raw water supplied by the inverter pump 13 and sends the measured information to the controller (CD).

The flow proportional control valve 16 is provided on the line returning from the filtration membrane module 15 to the raw water supply tank 11 to regulate the flow rate of the raw water (circulating water).

The treatment water tank 17 is provided for storing the treatment water coming from the filtration membrane module 15 and supplying it to a necessary place.

The backwash water tank 18 stores the treated water coming from the filtration membrane module 15 and sends it to the treatment water tank 17. Further, the backwash water tank 18 is provided so as to clean the filtration membrane module 15 by flowing the treated water back to the filtration membrane module 15 through the backwash process. In this process, The supply of air can be achieved.

The backwash pump 19 mixes the treated water of the backwash water tank 18 and the chemicals of the medicine pump 20 in the mixer 21 and supplies them to the filtration membrane module 15. It is preferable that the backwash pump 19 is also provided with an inverter pump.

The chemical pump (20) supplies the medicine during the backwash process.

The medicine mixer 21 mixes the medicine from the medicine pump 20 into the treated water from the backwash pump 19. It is preferable that the drug mixer 21 is provided in a spiral shape so that the use of the medicines can be reduced by the minimum introduction of medicines.

The CIP tank 22 is provided to allow the organic and inorganic substances included in the incoming raw water to be repetitively cleaned using acid and alkali chemicals, the substances immersed in the filtration film F installed in the filtration membrane module 15, In this process, supply of the medicine by the drug supply device (DS) can be performed.

The CIP pump 23 supplies the dissolved medicines of the CIP tank 22 to the filtration membrane module 15.

The discharge water tank 24 stores waste water coming from the filtration membrane module 15 by the backwash process and the CIP process. Of course, the effluent water in the discharge water tank 20 is discharged to the rivers after being treated within the limits of the relevant discharge standards.

The first pressure gauge P1 measures the pressure of the raw water supplied to the filtration membrane module 15 by the inverter pump 13.

The second pressure gauge P2 measures the pressure of raw water (circulating water) returning from the filtration membrane module 15 to the raw water supply tank 11.

The third pressure gauge P3 measures the pressure of raw water (treated water) sent from the filtration membrane module 15 to the backwash water tank 18.

Of course, the pressure information measured by the first pressure gauge P1, the second pressure gauge P2 and the third pressure gauge P3 is sent to the controller CD.

The controller CD is controlled by the inverter pump 13 to operate in the first mode or the second mode based on information from the turbidimeter 14, the first pressure gauge P1, the second pressure gauge P2 and the third pressure gauge P3. The flow rate proportional control valve 16, and the medicine pump 20, respectively.

 For reference, the signs B are the valves used to perform the required process.

Next, the purification process according to the control of the inverter pump 13 and the flow proportional control valve 16 by the controller in the first mode and the second mode will be described. Here, the driving conditions of the first mode and the second mode are set at two criteria. One is the turbidity and the other is the pressure of the enemy.

≪ Description of first mode and second mode based on turbidity >

1. First mode

The first mode of operation is when the turbidity is below the reference value of 50 NTU, that is, when the turbidity of the raw water is lower than 50 NTU. Of course, the standard value of turbidity may vary depending on the water treatment area and water quality required for the treated water.

The amount of raw water supplied to the filtration membrane module 15 by the inverter pump 13 in the first mode is, for example, 412 m ³ / d.

Treated water filtered by the particulate nonconforming material through the filtration membrane module 15 is sent to the treatment water tank 16 via the backwash water tank 17 and part of the raw water does not pass through the filtration membrane F of the filtration membrane module 15 And returns to the raw water supply tank 11 while sweeping the particulate nonconforming material on the surface of the filtration film F. [

At this time, since the amount of the raw water returning to the raw water supply tank 11 is, for example, 38 m ³ / d, the flow rate proportional control valve 16 is adjusted so as to provide a passage corresponding thereto.

2. Second mode

The second mode of operation is performed when the turbidity is higher than the reference value of 50 NTU or higher.

The amount of the raw water supplied to the filtration membrane module 15 by the inverter pump 13 in the second mode is, for example, 493 m ³ / d. That is, the controller C increases the amount of raw water supplied to the filtration membrane module 15 when the turbidity is high.

Likewise, the treated water filtered by the particulate nonconforming material through the filtration membrane module 15 is sent to the treated water tank 16 via the backwash water tank 17, and some of the raw water does not pass through the filtration membrane F of the filtration membrane module 15 And returns to the raw water supply tank 11 while sweeping the particulate nonconforming material on the surface of the filter membrane F. [ The amount of raw water, where that is supplied to the filter (12) but larger than that when the first mode because it is limited to the filtration capacity of the membrane (F), the amount of the raw water which returns to the water supply tank 11, for example, 110m ³ / d. As the amount of raw water returning to the raw water supply tank 11 increases through the filter module 15, the amount of the particulate nonconforming material swirled by the raw water returning from the surface of the filtration film F is increased, ) Is prevented from being damaged or deteriorated by the particulate nonconforming material.

Of course, the amount of the raw water is adjusted to return to the water supply tank 11 to flow proportional control valve (16) due to 110m neuleonatgi ³ / d provides an extended pathway rather than when the first mode so as to be corresponding.

≪ Explanation of first mode and second mode based on pressure >

1. First mode

The operation of the first mode is maintained when the pressure sensed by the first pressure gauge P1 and the second pressure gauge P2 is equal to or lower than the reference value. At this time, the water treatment apparatus 10 is operated in the first mode based on the turbidity described above.

2. Second mode

The operation of the second mode is maintained when the pressure sensed by the first pressure gauge P1 and the second pressure gauge P2 is equal to or higher than the reference value.

The fact that the pressure of the raw water returning to the raw water supply tank 11 through the filtration membrane module 15 by the drive of the inverter pump 13 is high means that the amount of the treated water passing through the filtration membrane F to the treatment water tank 17 It means that it is small. This is because the filtration membrane F can not perform its function due to an increase in particulate nonconforming material, so that the amount of the raw water to be supplied is increased so that the particulate nonconforming material on the surface of the filtration membrane F can be washed away.

At this time, the water treatment apparatus 10 is operated in the second mode based on the turbidity described above.

3. Third Mode

The third mode is the cleaning mode. For example, when the pressure sensed by the first pressure gauge P1 and the second pressure gauge P2 shows a reference value higher than the reference value of the operating condition in the second mode, the filtration membrane module 15 and the raw water supply tank The valve B between the filtration membrane module 15 and the discharge water tank 24 is switched to the closed state and the backwash water supplied from the backwash water tank 18 passes through the filtration membrane module 15 All are discharged to the discharge water tank 24. At this time, the flow proportional control valve 16 is controlled to provide a wider maximum passage than in the second mode, and the chemical injection concentration injected into the chemical mixer 21 installed on the backwash pump line 19 is controlled to be higher than the first mode And is controlled to be input.

The operation of the water treatment apparatus 10 according to the present invention is controlled on the basis of the turbidity and the pressure of the raw water. The operation in the second mode is performed under the condition that the turbidity of the raw water is equal to or higher than the reference value, The pressure of the raw water returning to the pressure reducing valve 11 is equal to or higher than the reference value. That is, even if the turbidity of the raw water is lower than the reference value, if the pressure of raw water returning to the raw water supply tank 11 through the filtration membrane module 15 is equal to or higher than the reference value, the water treatment apparatus 10 must be operated in the second mode, It is preferable that the water treatment apparatus 10 is operated in the second mode if the turbidity of the raw water is equal to or lower than the reference value even if the pressure of the raw water returning to the raw water supply tank 11 through the water treatment tank 15 is equal to or lower than the reference value.

Of course, even if the turbidity of the raw water is lower than the reference value and the pressure of the raw water returning to the raw water supply tank 11 through the filter unit 12 is lower than the reference value even during the second mode operation, .

Although the present invention has been fully described by way of example only with reference to the accompanying drawings, it is to be understood that the present invention is not limited thereto. It is to be understood that the scope of the invention is to be construed as being limited only by the following claims and their equivalents.

10: Water treatment device
11: raw water supply tank 12: automatic backwash screen filter
13: Inverter pump 14: Turbidimeter
15: Filtration membrane module 16: Flow proportional control valve
17: Treatment tank 18: Backwash tank
19: Backwash pump 20: Reverse pump medicine pump
21: drug mixer 22; CIP group
23: CIP pump 24: Exhaust water tank
P1: first pressure gauge P2: second pressure gauge
CD: Controller

Claims (4)

A raw water supply tank for storing the raw water coming from the raw water supply source and supplying the raw water to the rear end;
An automatic backwash screen filter for filtering out suspended solids that can damage the surface of the filtration membrane from the raw water coming from the raw water supply tank;
A filtration membrane module having a microfiltration function to filter out particulate nonconforming material from the raw water coming from the automatic backwash screen filter to return to the downstream and return some of the raw water to the raw water supply tank;
An inverter pump for supplying raw water of the raw water supply tank to the filtration membrane module through the automatic backwash screen filter and adjusting the supply amount of raw water;
A flow rate proportional control valve installed on the line returning from the filtration membrane module to the raw water supply tank to regulate the flow rate of the raw water;
A turbidimeter for measuring the turbidity of raw water supplied by the inverter pump;
A treatment water tank for storing treated water coming from the filtration membrane module;
A backwash water tank for storing treated water coming from the filtration membrane module and then sending the treated water to the treated water tank for performing a backwash process;
A backwash pump provided to perform a backwash process by supplying treated water from the backwash water tank to the filtration membrane module; And
When the raw water supplied to the filtration membrane module in the raw water supply tank is low turbidity lower than the reference value, the raw water is supplied in the first mode so that the treated water filtered through the filtration membrane module is filtered through the backwash water tank, And some of the raw water is returned to the raw water supply tank while sweeping the particulate nonconforming material on the surface of the filtration membrane without passing through the filtration membrane of the filtration membrane module. When the turbidity is higher than the reference value, The treated water filtered by the particulate nonconforming material through the filtration membrane module is sent to the treated water tank through the backwash water tank and a part of the raw water passes through the filtration membrane of the filtration membrane module, So as to return to the raw water supply tank A controller for controlling the flow rate profile and the proportional control valve; Lt; / RTI >
Wherein the controller is configured to increase the amount of the particulate nonconforming material returned to the raw water supply tank by increasing the supply amount of the raw water returning to the raw water supply tank through the filtration membrane module in the second mode, 2 mode, the controller controls the inverter pump and the flow rate proportional control valve in such a manner that the raw water supply amount and the return amount are greater than the raw water supply amount and the return amount in the first mode
Water treatment device. The method according to claim 1,
Further comprising: a pressure gauge for measuring the pressure of the raw water returning from the filtration membrane module to the raw water supply tank,
The controller controls the inverter pump and the flow rate proportional control valve to operate in the second mode when the pressure of the raw water returning to the raw water supply tank is equal to or higher than a reference value
Water treatment device. A raw water supply tank for storing the raw water coming from the raw water supply source and supplying the raw water to the rear end;
An automatic backwash screen filter for filtering out suspended solids that can damage the surface of the filtration membrane from the raw water coming from the raw water supply tank;
A filtration membrane module having a microfiltration function to filter out particulate nonconforming material from the raw water coming from the automatic backwash screen filter to return to the downstream and return some of the raw water to the raw water supply tank;
An inverter pump for supplying raw water of the raw water supply tank to the filtration membrane module through the automatic backwash screen filter and adjusting the supply amount of raw water;
A treatment water tank for storing treated water coming from the filtration membrane module;
A pressure gauge for measuring the pressure of the raw water returning from the filtration membrane module to the raw water supply tank;
A backwash water tank for storing treated water coming from the filtration membrane module and then sending the treated water to the treated water tank for performing a backwash process;
A backwash pump provided to perform a backwash process by supplying treated water from the backwash water tank to the filtration membrane module; And
If the pressure of the raw water returning from the filtration membrane module to the raw water supply tank is lower than a reference value, raw water is supplied in the first mode so that the treated water filtered by the filtration membrane module is sent to the treated water tank through the backwash water tank, The raw water is returned to the raw water supply tank while sweeping the particulate nonconforming material on the surface of the filtration membrane without passing through the filtration membrane of the filtration membrane module. If the raw water is not less than the reference value, raw water is supplied in the second mode, The treated water filtered by the nonconforming material is sent to the treated water tank through the backwash water tank and some raw water is returned to the raw water supply tank while sweeping the particulate nonconforming material on the surface of the filtration membrane without passing through the filtration membrane of the filtration membrane module. A controller for controlling the inverter pump to control the inverter pump; Lt; / RTI >
Wherein the controller is configured to increase the amount of the particulate nonconforming material returned to the raw water supply tank by increasing the supply amount of the raw water returning to the raw water supply tank through the filtration membrane module in the second mode, 2 mode, the inverter pump is controlled to be larger than the raw water supply amount and the return amount in the first mode
Water treatment device. 3. The method according to claim 1 or 2,
A chemical mixer for mixing the backwash water transferred from the backwash pump and the chemicals for backwashing;
A CIP tank provided for periodically cleaning contaminants of the filtration membrane module; And
A CIP pump for supplying the raw water of the CIP tank to the filtration membrane module; Further comprising
Water treatment device.

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