KR100786776B1 - Membrane filtration water treatment equipment - Google Patents

Abstract

The present invention relates to a membrane filtration purified water treatment device capable of maximizing raw water recovery rate and automatically adjusting flocculant input and discharge flow rates to prevent membrane contamination and improve filtration performance. A raw water storage tank for storing, a coagulant injection pump for supplying a flocculant, a mixing tank for temporarily storing raw water supplied from the raw water storage tank, and providing a space in which the flocculant introduced from the flocculant injection pump is mixed with the raw water; A coagulation tank which receives raw water mixed with a coagulant from the tank and stirs the raw water to completely mix the coagulant and the raw water; and a first water in which the raw water is introduced from the coagulation tank and performs primary water purification treatment of the raw water. Membrane filtration device and the first membrane filtration device to receive untreated wastewater A second membrane filtration device which performs a secondary water purification treatment on the discharge water, and a flow current value of raw water flowing into the first membrane filtration device provided at a rear end of the agglomeration tank or in front of the first membrane filtration device ( SCV) and SCV, which are used to measure SCV, are compared with the set current value measured by the flow current value SCV measured by the flow current meter SCD. , Controlling means for controlling the coagulant injection pump to control the amount of coagulant introduced into the mixing tank.

Description

Apparatus for water treatment using membrane filtration}

1 is a block diagram of a membrane filtration water treatment apparatus according to an embodiment of the present invention.

2 is a block diagram of a second membrane filtration device according to an embodiment of the present invention.

Flow chart for explaining the operation of the membrane filtration water treatment apparatus according to an embodiment of the present invention.

The present invention relates to a membrane filtration water treatment device, and more particularly, to a membrane filtration water purification device that can maximize the raw water recovery rate and automatically adjust the flocculant input and discharge flow rate to prevent membrane contamination and improve the filtration performance. .

In recent years, as the pollution of water sources has increased, interest in purified water quality has increased, and the demand for advanced water treatment has increased. Therefore, supplementation of existing water treatment facilities or introduction of new processes have been attempted. However, in order to supplement existing water purification facilities or to introduce new advanced water treatment facilities, there are many difficulties, including securing the site. Accordingly, a high water purification process using membrane filtration that is easy to operate and maintain as well as stable water quality has been proposed.

Membrane filtration is a method of separating contaminants in raw water using a membrane having a selective permeation function, which has the advantage of reliably removing suspended substances of a predetermined size or more contained in raw water.

On the other hand, membrane filtration processes generally treat raw water at a recovery rate of 90 to 95% and treat and discharge the remaining 5 to 10% of the effluent using gravity settling, chemical injection sedimentation or other effluent treatment facilities.

In the treatment method of the discharged water, the gravity sedimentation concentration treatment method or the chemical input precipitation method has a problem that the facility area is large and the treatment water quality is not good, and the amount of chemicals is used, and the economic efficiency is low. In addition, the method using the other wastewater treatment equipment is usually treated with effluent through a fibrous filtration method to remove turbidity, but the treated water quality is less than the water purification level has a disadvantage in that it is not economical in terms of raw water recovery.

In addition, in the conventional membrane filtration apparatus, the discharge flow rate of the discharge water is continuously discharged at a constant flow rate to adjust the concentration rate, or to measure the turbidity of the incoming raw water to increase the discharge flow rate at high turbidity to adjust the concentration rate. In the former method, the discharge water may be excessively discharged at a constant flow rate regardless of raw water quality, and turbidity may be concentrated at high turbidity. In addition, the latter method is difficult to grasp the correlation between the raw water turbidity measurement value and the discharge flow rate adjustment, and difficult to control due to the precision problem of the raw water turbidimeter at high turbidity.

On the other hand, in the membrane filtration process, it is possible to improve the filtration flow rate by removing organic substances, which are membrane contaminants, through the flocculation pretreatment process. Falls and the unreacted aluminum material is adsorbed on the filtration membrane to increase the membrane differential pressure.

The present invention has been made to solve the above problems, to provide a membrane filtration purified water treatment apparatus that can maximize the raw water recovery rate and automatically adjust the flocculant input and discharge flow rate to prevent membrane contamination and improve the filtration performance. There is a purpose.

Membrane filtration water treatment apparatus according to the present invention for achieving the above object is a raw water storage tank for storing the raw water, a coagulant injection pump for supplying the flocculant, and receiving the raw water from the raw water storage tank for temporary storage, the flocculant injection pump A mixing tank providing a space where the coagulant introduced from the raw water is mixed with the coagulant, a coagulation tank serving to completely mix the coagulant and the raw water by receiving raw water from which the coagulant is mixed, and stirring the raw water; A first membrane filtration device that receives raw water from the primary water and performs a primary water treatment process, and receives a second water purification treatment for the untreated water from the first membrane filtration device. A second membrane filtration device to be performed and a rear end of the flocculation tank or a front end of the first membrane filtration device It is set in advance with the flow current meter (SCD) and the flow current value (SCV) measured by the flow current meter (SCD) which serves to measure the flow current value (SCV) of the raw water flowing into the first membrane filtration device And a control means for controlling the amount of coagulant introduced into the mixing tank by controlling the coagulant injection pump according to the comparison result.

The first membrane filter device may be a pressurized hollow fiber membrane, the second membrane filter device may be an immersion hollow fiber membrane, and the immersion hollow fiber membrane may be discharged water not treated by the first membrane filter device. An immersion tank providing a space for storing the membrane module, which is provided in the immersion tank and serves to purify the discharged water in the immersion tank, and is provided at one side of the immersion tank to detect the height of the sludge in the immersion tank to detect the corresponding. It may include a sludge detection sensor for transmitting a signal to the control means, and a sludge discharge valve for discharging the sludge in the immersion tank to the outside under the control of the control means.

According to a feature of the present invention, by applying a two-stage membrane filtration process through the first and second membrane filtration devices, it is possible to improve the water treatment ratio, and a flow current meter is provided at the front of the first membrane filtration device. By measuring the flow current value of the raw water flowing into the first membrane filtration device through the flow meter, the coagulant dose can be effectively controlled by administering the coagulant accordingly.

Hereinafter, a membrane filtration water purification apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram of a membrane filtration water treatment apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the membrane filtration water purification apparatus according to an embodiment of the present invention includes a raw water storage tank 101, a mixing tank 102, a flocculation tank 104, a first membrane filtration device 105, and a second membrane filter. Membrane filtration device 106 and treatment bath 109.

The raw water storage tank 101 is a space for storing raw water taken from a river or a lake, and the mixing tank 102 receives the raw water from the raw water storage tank 101 and temporarily stores the raw water, and is supplied from the coagulant injection pump 103. It provides a space in which coagulant and the raw water are mixed. Here, the flocculant injection pump 103 may be provided on one side of the mixing tank 102. The coagulation tank 104 receives raw water mixed with the coagulant from the mixing tank 102 to agitate the drainage to completely mix the raw water and the coagulant.

On the other hand, the present invention applies a two-step membrane filtration process to improve the raw water recovery. The first and second membrane filter devices 105 and 106 are configured to improve the raw water recovery rate, and the first membrane filter device 105 uses a pressurized hollow fiber membrane and the second membrane filter device 106 is used. It is preferable to use an immersion hollow fiber membrane.

The first membrane filtration device 105 using the pressurized hollow fiber membrane receives the mixed-aggregated raw water from the coagulation tank 104 to produce purified water at a recovery rate of 90 to 95%, and the remaining untreated water 5 to 10 % Is supplied to the second membrane filtration device 106 as effluent (first concentrated sludge). Here, the purified water is supplied to the treatment tank 109.

On the other hand, the second membrane filtration device 106 using the submerged hollow fiber membrane, as shown in detail in Figure 2, the immersion tank 201, filtration suction pump (not shown), membrane module 202, sludge It comprises a detection sensor 203, the sludge discharge valve 205. The immersion tank 201 is a space in which the discharge water discharged from the first membrane filtration device 105 is stored, and the discharge water stored in the immersion tank 201 is transferred to the membrane module 202 through the filtration suction pump. Supplied. The membrane module 202 serves to filter the discharge water of the immersion tank 201 to purify water, and the sludge detection sensor 203 is provided at one side of the second membrane filtration device 106. It serves to measure the height of the sludge in the immersion tank 201. When the sludge (second concentrated sludge) 204 in the immersion tank 201 is a predetermined height or more is discharged to the outside through the sludge discharge valve 205, the treated water passing through the membrane module 202 is It is supplied to the processing tank 109. For reference, the process of the second membrane filtration device 106 may be performed in the order of filtration-physical cleaning (backwashing, air cleaning, etc.)-(Politics) -emission or in the order of filtration- (politics) -exhaust-physical cleaning. May proceed to.

90 to 95% of the raw water (5 to 10% of the original raw water) introduced from the first membrane filtration device 105 by the second membrane filtration device 106 is purified and finally, the first and the second The ratio of water purification treatment by the two membrane filtration devices 105 and 106 is 99 to 99.8%.

On the other hand, as described in the object of the present invention, the present invention aims to improve the raw water recovery rate and automatically adjust the flocculant input amount. In order to improve the raw water recovery rate, as described above, a two-stage membrane filtration device, that is, the first and second membrane filtration devices 105 and 106, is provided, which is another object of the present invention. For regulation, the following configuration is suggested.

The present invention is provided with a flow current detector (SCD: Stream Current Detector) and control means 108 for the automatic adjustment of the flocculant input amount.

The flow current meter 107 is provided at the rear end of the flocculation tank 104 and the surface charges of all ions and colloids included in the raw water flowing into the first membrane filtration device 105, that is, the flow current value (SCV). : Measures Stream Current Value). The control means 108 receives the flow current value (SCV) from the flow current meter 107 (SCD) and compares the flow current value with a set-point and, according to the comparison result, a coagulant injection pump ( The amount of flocculant introduced into the mixing tank 102 is adjusted by controlling the rotation speed or the stroke of the 103.

Looking at the linkage process between the flow current value measurement and the operation of the coagulant injection pump 103 in detail as follows.

First, a set-point of the floating current value (SCV) is set. Here, the reference value serves as a reference for determining whether the flocculant is added. In setting the reference value, the membrane differential pressure is considered. The membrane differential pressure refers to a pressure difference between the input stage P1 and the discharge stage P2 of the first membrane filtration apparatus 105, and the membrane differential pressure increase rate per unit time ( kgf / cm ² · hr) is calculated to set the portion having the lowest rise rate as a reference value. For reference, the membrane differential pressure is continuously checked during the operation period.

In this state in which the reference value is set, the flow current value of the raw water discharged from the flocculation tank 104 is measured through the flow current meter 107. Next, the measured flow current value is compared with the reference value to determine whether the measured flow current value exceeds the reference value.

As a result of the comparison between the flow current value and the reference value, if the flow current value exceeds the reference value, the control means 108 controls the coagulant injection pump 103 to inject coagulant into the mixing tank 102. . At this time, the rotation speed or the stroke of the coagulant injection pump 103 is selectively controlled according to the flow current value exceeded the reference value. For example, if the reference value is -50 and the measured flow current value (SCV) is -1000, the flocculant injection pump 103 causes the flocculant to be introduced into the mixing tank 102 until the flow current value is -50. Put it in.

On the other hand, the calculation from the setting of the reference value to the rotational speed control (or stroke control) of the coagulant injection pump 103 may use a PID (Proportional Integral Derivative) control method.

In the above, the configuration of the membrane filtration water treatment apparatus according to an embodiment of the present invention has been described. Hereinafter, the operation of the membrane filtration water purification apparatus according to an embodiment of the present invention will be described.

First, as shown in FIG. 3, raw water is supplied from the raw water storage tank 101 to the mixing tank 102 (S301). Raw water stored in the raw water storage tank 101 may be withdrawn from a river or a lake. In the state in which the raw water is supplied to the mixing tank 102, the flocculant is introduced into the mixing tank 102 through the flocculant injection pump 103 (S303). The amount of flocculant introduced through the flocculant injection pump 103 is determined by the control means 108 (S302), which will be described later.

The raw water mixed with the flocculant is supplied to the flocculation tank 104 and the flocculant and the raw water are completely mixed through the agitation in the flocculation tank 104 (S304) (S305). The fully mixed raw water is then supplied to the first membrane filtration device 105. As described above, the first membrane filtration device 105 may use a pressurized hollow fiber membrane, and the first membrane filtration device 105 may purify 90 to 95% of the raw water supplied from the coagulation tank 104. (First water purification treatment) and the remaining 5 to 10% is supplied to the second membrane filtration device 106 as discharged water (first concentrated sludge) (S306).

On the other hand, the rear end of the coagulation tank 104 is provided with a flow current meter 107 (SCD) flow current value of the raw water flowing into the first membrane filtration device 105 through the flow current meter (107) ( SCV) can be measured. Here, the flow current value means a surface charge value of all ions and colloids contained in the raw water.

The flow current value (SCV) measured through the flow current meter 107 (SCD) is transmitted to the control means 108, and the control means 108 is set in advance with the measured flow current value (SCV). The set-point is compared and the rotation speed (or stroke) of the coagulant injection pump 103 is controlled to adjust the amount of coagulant introduced into the mixing tank 102 according to the comparison result. At this time, the reference value is set in consideration of the membrane differential pressure, and the membrane differential pressure refers to the pressure difference between the input end and the discharge end of the first membrane filtration device 105.

Meanwhile, the discharged water discharged through the first membrane filtration device 105 flows into the second membrane filtration device 106, and the second membrane filtration device 106 may use an immersion hollow fiber membrane. 90 to 95% of the raw water introduced into the second membrane filtration device 106 through the second membrane filtration device 106 is purified (secondary purification) and finally, the first and second membrane filtration. The ratio of water treatment by the devices 105 and 106 is 99 to 99.8% (S307). At this time, the sludge (second concentrated sludge) not purified through the second membrane filtration device 106 is discharged through the sludge discharge valve 205 provided on one side of the second membrane filtration device 106. . For reference, the sludge concentrated in the immersion tank 201 of the second membrane filtration device 106 is detected by the sludge detection sensor 203, the height thereof is transmitted to the control means 108, the control means ( 108 controls the sludge discharge valve 205 to discharge the sludge (second concentrated sludge).

The membrane filtration water treatment device according to the present invention has the following effects.

The first and second membrane filtration devices can be used to improve the water purification rate by applying a two-stage membrane filtration process. A flow current meter is provided at the front of the first membrane filtration device to provide a flow current measuring device. Coagulant dosage can be effectively controlled by measuring the flow current value of the raw water flowing into the first membrane filtration apparatus and administering the coagulant accordingly.

Claims (4)

A raw water storage tank for storing raw water; A coagulant injection pump for supplying a coagulant; A mixing tank configured to temporarily receive raw water from the raw water storage tank and to provide a space in which the raw water is mixed with the coagulant introduced from the coagulant injection pump; An agglomeration tank that receives raw water from which the coagulant is mixed and agitates the raw water to completely mix the coagulant and the raw water; A first membrane filtration device which receives raw water from the coagulation tank and performs a primary water purification treatment of the raw water; A second membrane filtration device receiving the untreated water from the first membrane filtration device and performing a second water purification treatment on the discharge water; A flow current meter (SCD) provided at a rear end of the coagulation tank or at a front end of the first membrane filtration device to measure a flow current value (SCV) of raw water flowing into the first membrane filtration device; And The flow current value (SCV) measured by the flow current measuring device (SCD) is compared with a preset set point (point-point), and according to the comparison result, controlling the flocculant injection pump to control the flocculant introduced into the mixing tank It comprises a control means that serves to adjust the amount, The second membrane filtration device is a membrane filtration water treatment apparatus, characterized in that using the immersion hollow fiber membrane. The membrane filtration water treatment device according to claim 1, wherein the first membrane filtration device uses a pressurized hollow fiber membrane. delete The method of claim 1, wherein the immersion hollow fiber membrane, An immersion tank for providing a space for storing the effluent not purified by the first membrane filtration device, A membrane module provided in the immersion tank and serving to purify the discharged water in the immersion tank; A sludge detection sensor provided at one side of the immersion tank and detecting a height of sludge in the immersion tank and transmitting a corresponding detection signal to the control means; And a sludge discharge valve for discharging the sludge in the immersion tank to the outside under the control of the control means.

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