KR102380257B1 - The water treatment system for fish breeding by applying membrane filtration process - Google Patents

Abstract

The present invention treats aquaculture water using a pressurized hollow fiber membrane module having a central baffle, but the contamination of the hollow fiber membrane is reduced so that the transmembrane pressure difference (TMP) increase rate (Δp) is low and stable even when used for a long time It is about a system that can process raw water and supply breeding water to aquaculture farms. In addition, the present invention applies RCC (Reuse Circulated CIP), which applies a method of recovering after circulating a high-concentration cleaning chemical solution, to chemically clean the separation membrane module and then replenish the stock solution by the reduced concentration without discharging the waste solution. It relates to a farm breeding water treatment system to which a separation membrane technology that can stably supply farm breeding water is applied using a separation membrane cleaning method that maintains a high cleaning concentration without generating waste liquid.

Description

Farm breeding water treatment system to which separation membrane technology is applied {The water treatment system for fish breeding by applying membrane filtration process}

The present invention relates to a fish farm breeding water treatment system to which a separation membrane technology is applied.

More specifically, the transmembrane pressure (transmembrane It is about a system that can supply breeding water to aquaculture farms by stably treating raw water because of a low pressure difference (TMP) increase rate.

In addition, the present invention applies RCC (Reuse Circulated CIP), which applies a method of recovering after circulating a high-concentration cleaning chemical solution, to chemically clean the membrane module and then replenish the stock solution by the reduced concentration without discharging the waste solution. It relates to a farm breeding water treatment system to which a separation membrane technology that can stably supply farm breeding water is applied using a separation membrane cleaning method that maintains a high cleaning concentration without generating waste liquid.

The biggest problem in the domestic aquaculture industry is the increase in mortality, which has been rapidly increasing every year since 2007. Among them, the mortality rate of fry is 50-60% of the total, and among the various causes of mortality, disease-related mortality is the most. The causes of the disease include parasitic scotchka disease, bacterial Edward's disease, streptococci, white point infection, etc. Most of them are caused by contamination of the breeding water in the farm. Existing aquaculture farms use a disinfectant to prevent this, but due to the difficulty in controlling the concentration, the disinfectant remains in the body of the fish, resulting in death of the fry or the remaining disinfectant being delivered to consumers. Therefore, the importance of supplying stable breeding water without additives such as disinfectants is increasing.

In addition, in most of the existing purification devices that do not use chemicals such as disinfectants, a filtration process using sand and a filtration network is applied, but the removal rate of actual pollutants is low and insufficient.

Biological and chemical treatment methods are mainly used as technologies for purifying the feedwater inflows from existing aquaculture farms. In the case of sand filtration or filter media filtration, which are physical treatment methods, the system is simple, so maintenance is easy and it is easy to apply to large-capacity treatment. can't

First, the biological treatment method has the advantage of being able to remove not only suspended matter but also organic contaminants dissolved in water, and is a method capable of removing nitrogen compounds that are biotoxic, such as ammonia. However, in the case of the activated sludge process, a large site is required for large-capacity treatment, and it is difficult to obtain high treatment efficiency due to the low C/N ratio. To improve this, a biofiltration process has recently been introduced, but it is not easily applied due to the low activity of microorganisms in seawater and difficult operating conditions, and has limitations in treatment and application. Ozone oxidation or electrolysis methods are being introduced.

Next, the ozone oxidation method uses the strong oxidizing power of OH radicals generated when ozone self-decomposes to remove organic matter and pathogens in the influent. Ozone is lethal to fish, and bromine oxide produced during oxidation is applied as a toxic substance to fish. In addition, the remaining ozone needs a residence time of 20 to 30 minutes to decompose into oxygen, and an additional ozone exhaust facility is needed to quickly remove it, but the ozone concentration decreases as time goes by because the catalyst is clogged by seawater scale, etc. There is a problem that does not happen.

Therefore, the electrolysis method is a method of sterilizing using low-concentration effective chlorine generated by flowing an electric current to the electrode plate in seawater. The amount of sterilizing and disinfecting agent generated is different and therefore the treatment efficiency is not constant. In addition, disinfection by-products are generated according to the concentration of natural organic matter (NOM) substances in seawater.

As a method using microorganisms to remove organic matter for water purification of such existing aquaculture farms, there is Korean Patent Registration No. 10-0769040, and as a method for removing substances causing fish diseases, patents related to ozone and electrolysis are registered in Korea. There are No. 10-0718234 and Korean Patent No. 10-1547566. However, the treatment method using these microorganisms has disadvantages in that the removal rate of pollutants is variable depending on the growth conditions of the microorganisms and the treatment efficiency is not constant. Accordingly, there is a disadvantage of having a limitation in its performance.

Korean Patent Registration No. 10-0769040. Korean Patent Registration No. 10-0718234. Korean Patent Registration No. 10-1547566.

The present invention was developed to solve the above problems, and it improves the disadvantages that the removal rate of contaminants is variable and the treatment efficiency is not constant depending on the microbial growth conditions related to the water purification of the existing aquaculture farm, and the pollution compared to the conventional method An object of the present invention is to provide a filtration system for breeding water for aquaculture using a separation membrane that is effective in removing organic matter and pathogens, but has improved the disadvantages of ozonation and electrolysis methods, which have limitations in their performance depending on the water quality conditions of the influent.

In addition, the present invention is to provide a method for generating clean and stable water quality treated water using a high contaminant removal rate by a separation membrane, and a method including a maintenance cleaning process for stably operating the present process.

In the present invention, in order to solve the above problems, the farm breeding water is treated using a pressurized hollow fiber separation membrane module having a central baffle, but the contamination of the hollow fiber membrane is reduced, so even when used for a long time, repeated filtration/backwashing or reused circulation method cleaning A system capable of supplying breeding water to aquaculture farms by stably treating raw water due to a low increase in transmembrane pressure difference (TMP) is provided.

In addition, in the present invention, unlike the existing CIP (Cleaning in Place) method, which neutralizes and discharges the cleaning waste liquid after chemically cleaning the existing separation membrane module, RCC applies a method of circulating a high-concentration cleaning chemical solution and then recovering it. (Reuse Circulated CIP) is applied to chemically clean the separation membrane module and then, without discharging the waste solution, only replenish the stock solution by the reduced concentration. Provided is a water treatment system for aquaculture farms to which a separation membrane technology capable of supplying aquaculture water is applied.

The present invention is an eco-friendly purification method for aquaculture water, a process for removing contaminants and pathogens contained in breeding water by applying a separation membrane filtration technology, and unlike other existing purification methods, it does not use a disinfectant, so it has high stability.

In addition, the purification method using microorganisms whose removal rate of pollutants is variable depending on the growth conditions of microorganisms and the treatment efficiency is not constant, and ozonation, which is effective in removing polluting organic matter and pathogens, but has limitations in its performance depending on the water quality conditions of the influent; It is a technology that has the advantage of improving the disadvantages of the electrolysis method.

In addition, unlike the existing CIP (Cleaning in Place) method, which chemically cleans the separation membrane module and then neutralizes and discharges the cleaning waste, the reuse circulated method is a method of circulating and recovering a high-concentration cleaning chemical solution. CIP: RCC) is applied to chemically clean the membrane module and then the waste solution is not discharged and the stock solution is only replenished as much as the reduced concentration. This has the advantage of being able to supply aquaculture breeding water.

1 schematically shows a process diagram of a farm breeding water treatment system to which a separation membrane technology is applied according to an embodiment of the present invention.
Figure 2 shows a water treatment system for aquaculture farms to which a separation membrane technology according to an embodiment of the present invention is applied.
3 shows a cross-section and a central baffle of a pressurized separator module having a central baffle therein according to an embodiment of the present invention.
Figure 4 shows the filtration flow rate according to the optimal operating conditions of the microfiltration membrane (MF) and the ultrafiltration membrane (UF) according to an embodiment of the present invention.
5 schematically shows the difference in pressure distribution according to the length of the separator of the pressurized hollow fiber module according to an embodiment of the present invention.
6 is a view showing the membrane contamination behavior according to the length of the separation membrane and the central baffle of the pressurized hollow fiber module according to an embodiment of the present invention.
7 shows the backwash discharge characteristics of the pressurized hollow fiber module according to an embodiment of the present invention.
8 is a comparison of the residual oxidizing agent (chlorine) concentration according to the electrolysis / ozone treatment method according to the prior art and the residual oxidizing agent (chlorine) concentration in the separation membrane filtration method according to an embodiment of the present invention according to the breeding water inflow time is indicated by
9 shows a result of maintaining an increase rate of a transmembrane pressure difference (TMP) according to a reuse circulated CIP (RCC) cleaning according to an embodiment of the present invention.
10 shows a comparison of drug consumption according to a cleaning in place (CIP) method according to the prior art and a reuse circulated CIP (RCC) method according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail. The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

The recently applied ozone oxidation and electrolysis methods are more effective in removing polluting organic matter and pathogens than the existing methods, but have limitations in their performance depending on the water quality conditions of the influent. Table 1 below shows a comparison of the performance of the present invention and the conventional water treatment method.

separator UV ozone electrolysis removal efficiency Turbidity, SS very high
(SS 1ppm or less) No removal function No removal function No removal function COD Particulate COD can be removed No removal function No removal function No removal function helminth
(including Cysticercus) very high lowness lowness lowness Germ very high height height height persistence does not exist does not exist has exist has exist Disinfection by-products does not exist does not exist has exist has exist electricity fee lowness middle lowness height

In the case of the conventional ozonation method, residual ozone is lethal to fish, and bromine oxide generated in the oxidation process is applied as a toxic substance to fish. Residual ozone requires a residence time of 20 to 30 minutes to decompose into oxygen, and an additional ozone exhaust facility is needed to quickly remove it, but there is a problem that the ozone concentration is not reduced because the catalyst is clogged by seawater scale, etc. In the case of electrolysis, the amount of sterilizing agent generated varies according to the temperature of the seawater, and the efficiency decreases. In addition, disinfection by-products are generated according to the concentration of natural organic matter (NOM) substances in seawater. On the other hand, the water treatment method using a separation membrane has very low turbidity in the removal efficiency, and the performance of removing particulate COD and bacteria including parasites is very superior compared to other methods, and has less residual and disinfection by-products, and operating costs including electricity. It is known as a very economical method.

Accordingly, an object of the present invention is to provide breeding water suitable for aquaculture that has an absolute removal efficiency for particulate matter and cells by applying a separation membrane process without risk due to disinfection by-products as described above.

In the present invention, in order to achieve the above object, a screen device equipped with a screen and a filtration pump for supplying raw water to the raw water inlet pipe by removing foreign substances remaining in the raw water supplied from the intake pipe and the intake pipe into which the raw water is introduced; a separation membrane module skid connected to the raw water inlet pipe to supply raw water to the separation membrane module; a pressurized hollow fiber membrane module comprising a raw water inlet for removing contaminants and pathogens present in the raw water, a plurality of which are connected in parallel to the separator module skid, a treated water concentrator, and a filtration part; a backwash pump for backwashing the membrane module and a blower for generating cleaning air for desorption of contaminants from the membrane surface; and a maintenance cleaning unit including a chemical stock solution tank, a chemical mixing tank, a chemical stock solution transfer pump, and a chemical circulation pump for chemically cleaning the separation membrane module, wherein the pressurized hollow fiber membrane module has a hollow inside A cylindrical body, comprising an air zone in which at least one back-pore is formed regularly or irregularly through its outer peripheral surface and a water zone in which one or more back-pores are regularly or irregularly penetrated, and is penetrated at the outer periphery of the air zone The back pore to be formed is larger than the size of the back pore formed through the water zone, and a central baffle having a larger area of the water zone compared to the area of the air zone is provided, and the filtration unit of the separation membrane module supplies filtered water to the aquaculture farm. The filter water supply pipe is connected, and the treated water concentrator of the membrane module is connected to the concentrated water outlet pipe.

In the fish farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the central baffle is located inside the module housing on the same axis as the thickener configured at one end of the pressurized hollow fiber membrane module, and the module The raw water inlet is provided at the other end of the housing, the filtering unit is provided on the side of the concentrating unit, the central baffle serving as the outlet for condensed water and air and the concentrating unit are located in the center of the housing. It is characterized in that the movement of concentrated water and air is uniform because the distance to the central baffle is constant.

In the farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the separation membrane length of the pressurized hollow fiber separation membrane module is preferably 250 to 1,500 mm, and the separation membrane length and baffle of the pressurized hollow fiber separation membrane module The ratio of the lengths is more preferably 1:0.5 to 0.7.

In the farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the separation membrane module is a microfiltration standard separation membrane. It is more preferable to include a hollow fiber type separation membrane having a pore size of 0.05 to 0.4 μm.

In the farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the maintenance and cleaning unit recovers the used cleaning agent in a state in which contaminants are removed through the filter, and supplements only the insufficient chemical stock solution to continuously It is characterized in that it is a reuse circulated CIP (RCC) that can be reused, and it is preferable that the maintenance and cleaning unit automatically replenishes the concentration of the consumed chemical to a concentration set through a meter.

In the farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the discharge water containing contaminants discharged to the concentrated water outlet pipe may be connected to a concentration treatment facility including a sedimentation tank or a pressurized flotation tank. .

In the farm breeding water treatment system to which the separation membrane technology is applied according to an embodiment of the present invention, the farm breeding water treatment system has a stabilizing device that blocks the supply of treated water when a toxic substance is generated by interlocking a residual chlorine meter and a pH meter It is preferable to be further provided.

Hereinafter, embodiments and examples of the present invention will be described in detail so that a person with general knowledge in the technical field to which the present application pertains can easily carry out preferred embodiments of the present invention as shown in the accompanying drawings. In particular, the technical spirit of the present invention and its core configuration and operation are not limited by this. In addition, the content of the present invention may be implemented in various other types of equipment, and is not limited to the implementation examples and embodiments described herein.

1 schematically shows a process diagram of a farm breeding water treatment system to which a separation membrane technology is applied according to an embodiment of the present invention.

It is supplied to the separation membrane module through a screen device equipped with a screen and a filtration pump for supplying raw water to the raw water inlet pipe by removing foreign substances remaining in the raw water supplied from the water intake pipe and the water intake pipe, and is supplied to the separation membrane module. The part is connected to a filtrate supply pipe that supplies filtrate water to the farm, and the treated water concentration part of the membrane module is connected to the concentrated water outlet pipe. In addition, the separation membrane module may be additionally connected to a backwash pump for backwashing the separation membrane module and a blower for generating cleaning air for desorption of contaminants from the surface of the separation membrane, and a chemical stock solution tank for chemically cleaning the separation membrane module, a chemical A mixing tank, a chemical stock solution transfer pump, and a maintenance cleaning unit including a chemical circulation pump may be connected and configured.

In the present invention, in order to solve the above problems, a screen device provided with a screen and a filtration pump for supplying raw water to the supply pipe by removing foreign substances remaining in the intake pipe and the raw water supplied from the intake pipe in order to solve the above problems; a transfer pump for transferring the raw water supplied from the supply pipe to the separation membrane module; and a separation membrane module for removing contaminants and pathogens present in the raw water transferred by the transfer pump.

2 is a view showing a farm breeding water treatment system to which a separation membrane technology is applied according to an embodiment of the present invention, and a more specific configuration of the system is as follows.

Large contaminants such as seaweed are removed from the extracted raw water through the raw water inlet pipe 14 equipped with a screen facility, and the raw water is transferred to the separation membrane module skid 1 through the raw water pump 3 . The transferred raw water is removed from fine particulate matter and pathogens while passing through the separation membrane module, and the removed treated water is transferred to the breeding tank through the filtered water supply pipe 16 . Contaminants removed by the separation membrane are desorbed from the separation membrane through a backwashing process, and backwashing water and discharged water containing contaminants are transferred to a wastewater treatment facility through the concentrated water outlet pipe 15 . If there is no separate wastewater treatment facility, it is possible to link the high-concentration-concentrated effluent generating process in conjunction with a dehydrator such as a pressurized flotation tank, settling, or centrifugal concentrator.

In order to chemically clean the contaminated membrane module, chemicals are generally used in two types, and the appropriate concentration of chemicals is transferred to the chemical A mixing tank ( 9), the chemical B mixing tank 11 and the membrane module skid 1 are circulated. Particulate matter contained in this process is removed by the chemical strainer 13, and after cleaning, the cleaning liquid is stored in the chemical A mixing tank 9 and the chemical B mixing tank 11 and reused again.

3 shows a cross-section and a central baffle of a pressurized separator module having a central baffle therein according to an embodiment of the present invention.

The pressurized hollow fiber membrane module of the present invention is provided with an inlet/air injection unit 30 for raw water at one end of a housing, and a cap including a filtration unit 10 and a concentration unit 20 at the other end. and has a structure in which an O-ring fixing groove (not shown) is installed to prevent mixing of concentrated water and outflow water. In addition, since the concentrator, which is the outlet of the concentrated water and the cleaning air, is located in the center of the housing, the distance from the edge of the housing to the baffle is constant, so that the concentrated water and the cleaning air move uniformly.

The pressurized hollow fiber separation membrane module of the present invention includes a plurality of hollow fiber separation membranes in an outer housing, and the hollow fiber is opened in the bonding portion of the potting material fixing the hollow fiber separation membrane and at least one potting material. It has a port that can be used and includes a central baffle for smooth flow of raw water and air inside the thickener. The potting material used to fix the hollow fiber membrane to the housing has a hardness of 40 to 70 (Shore D) after curing, and the potting material used has a thickness of 10 mm or more and 120 mm or less. The length of the baffle is 10 mm or more and 1,000 mm or less, the slope from the upper end to the lower end of the baffle has an angle of O° or more and 10° or less, and the baffle is in the form of a grid that can smoothly inflow air and raw water. In addition, a wave pattern embossing is provided on the outer surface of the baffle to prevent the separation membrane from adhering to the baffle and blocking the flow by the flow or pressure of water. The baffle is disposed in the center of the thickening part of the hollow fiber module in a form that can be fixed or detached.

Therefore, according to the present invention, as the thickener is installed in the center of the pressurized module, concentrated water and cleaning air can flow uniformly in all directions of the housing, which increases the pressure and linear velocity or stagnation that may occur in the existing module. There is an advantage that the contamination of the separation membrane can be reduced by effectively performing physical cleaning by improving the Because the copper wire is short and the density gradient is constant everywhere, because the copper wire is the same based on the cross-sectional area of the module, the difference in the concentration gradient and the physical stress of the membrane to the concentration part are resolved for each hollow fiber membrane. Although the movement of air and backwashing water may be restricted due to shaking or movement of the separation membrane due to high pressure and air injection, in the present invention, by installing a central baffle as shown in FIG. Since there is an advantage to be able to effectively discharge air during backwashing, there is an effective advantage when increasing the amount of injected air.

The upper part of the central baffle according to an embodiment of the present invention is an air zone for implementing an easy flow of air, and the lower part is water for implementing an easy flow of treated water, concentrated water or backwashing water. It is characterized in that the porosity of the air zone is higher than that of the water zone for the rapid movement of air that floats when backwashing water and air injection are made simultaneously to the water zone.

In the conventional pressurized hollow fiber membrane module, the hollow fiber is vertically disposed across the upper end and the lower end of the module, and the hollow fiber collecting speed or arrangement of the upper end and the lower end is the same. Because the collecting speed and arrangement of the lower part are different, the same number of hollow fibers are widely distributed in the lower part, that is, the dispersibility of the hollow fiber membrane is increased or the degree of integration is lowered, so that the resistance of the inflow of air or water from the inlet of the same cross-sectional area is small. It is effective, and as the separation membrane is arranged obliquely from the bottom to the top, it has an advantageous structure against shaking due to air injection, and has the advantage of being able to clean more effectively than when a high-turbidity material is introduced.

4 is a view showing a comparison of the filtration flow rates of a microfiltration membrane and an ultrafiltration membrane according to general optimal operating conditions. (Evaluation the Efficiency of Different Microfiltration and Ultrafiltration Membranes Used as Pre-treatment for Reverse Osmosis Desalination of Red Sea Water, Samer Khamees AlMashharawi , 2011)

The separation membrane used in one embodiment of the present invention is a hollow fiber membrane type microfiltration membrane and has a pore size of 0.05 to 0.4 um. In addition, it was manufactured with a separator using PE and PVDF, which are proven materials for stable durability in operation. In the case of the hollow fiber membrane, the removal rate for pathogens is 99.99%, which can completely prevent the inflow of seawater into the breeding tank for scutica and Edward streptococci, which generally cause fish death. In the case of using a disinfectant, in order to remove more than 99.9% of pathogens, a contact time of about 5 minutes with the breeding water at a concentration of 0.5 ppm of the disinfectant is required, and in the process, it may affect the farmed fish. When a microfiltration membrane is used according to an embodiment of the present invention, breeding water that does not contain a sterilizing agent can be continuously supplied to the breeding tank.

On the other hand, in the case of an ultrafiltration membrane, it has finer pores compared to a microfiltration membrane, so it can have a higher removal rate for contaminants, but some nutrients can be removed, which can be disadvantageous for the cultivation of farmed fish. In addition, the ultrafiltration membrane has a very high pollution load on seawater, making it difficult to operate a normal filtration process compared to the microfiltration membrane.

In general, land farms use large-capacity breeding water due to their characteristics. In the case of a farm with a size of 1,500 pyeong, an average of 3,000 m3/hr of breeding water is used, which is similar to the capacity of a large-scale sewage treatment plant. Therefore, the membrane filtration system applied to aquaculture is different from the existing membrane filtration method, and it is necessary to minimize the facility scale while allowing large-capacity treatment. In the case of the separation membrane module applied to the present invention, compared to the existing separation membrane module for general water treatment, it can handle a large flow rate and has excellent contamination resistance, and thus has characteristics applicable to land aquaculture.

The separation membrane module applied to the present invention has different structural characteristics to produce large-capacity treated water, unlike the existing separation membrane module for water treatment. The effective membrane length in the membrane module was adjusted to the point where the pressure gradient was minimized, and the ratio of the size of the inlet and outlet pipes to the membrane area was increased to make the use of the membrane uniform and to reduce the pressure loss to maximize the water treatment capacity per unit area. In the case of the existing module, only 70% of the separation membrane can be used, but in the developed module, more than 95% of the separation membrane is used uniformly.

5 schematically shows the difference in pressure distribution according to the length of the separator of the pressurized hollow fiber module according to an embodiment of the present invention. By installing a baffle in the center of the discharge pipe of the separation membrane module, it helps the discharge of backwash water smoothly during the backwashing process, thereby enhancing the contamination reduction capability of the separation membrane. By distributing it in such a way that no dead area occurs and the discharge area is increased several times, the flow of polluted discharge water and cleaning air during backwashing can be facilitated without stagnant phenomenon, so that efficient physical cleaning can be achieved.

<Example 1> Membrane contamination behavior according to the length of the separation membrane and the length of the central baffle

According to an embodiment of the present invention, a membrane module to which a module length change and a baffle is applied was used to change the membrane structure suitable for large-capacity treatment. In this case, it was tested for the behavior of membrane contamination, and the results are shown in Table 2 and FIG. 6 .

Experiment module Membrane Length (mm) Center baffle length (mm) length ratio
(α) TMP increase rate a 1,500 960 0.64 0.171 b 1,500 630 0.42 0.201 c 1,000 640 0.64 0.140 d 1,000 420 0.42 0.162 e 500 320 0.64 0.067 f 500 210 0.42 0.132 g 250 160 0.64 0.068 h 250 105 0.42 0.131

Length ratio = central baffle length/separator length

6 is a view showing the membrane contamination behavior according to the length of the separation membrane and the central baffle of the pressurized hollow fiber module according to an embodiment of the present invention.

First, as a result of the experiment on the membrane length and the length of the central baffle, as the membrane length was shorter, the width of the increase rate of the transmembrane pressure difference (TMP) increased due to repeated filtration/backwashing within the filtration time. During the process, the effect of reducing TMP was increased.

The shorter the membrane length, the more the TMP increase during the filtration process was reduced by up to 50% or more, but the TMP increase was the same below a certain length. This is caused by the difference in the usage rate according to the length of the separator, and as a result of the experiment, it was found that all separators were used evenly in the length of 500 mm or less. In addition, considering the installation area of the separation membrane facility, the larger the area (length) of the separation membrane per unit module, the more the facility site can be reduced.

7 is a view showing the discharge characteristics of backwash discharge water of the pressurized hollow fiber module according to an embodiment of the present invention, and the central baffle serves to facilitate discharge of air and backwash water during backwashing. In the case of a structure without a central baffle, the pore or backwashing water is discharged through the thickening pipe, but due to the module structure, the tube diameter of the thickening pipe has a limit, so the discharge does not occur smoothly, and the pollutants are not discharged well, which causes accumulation. When the central baffle is applied, the discharge area compared to the cross-section of the enrichment pipe increases by 5 to 10 times, making it possible to make a smooth flow of backwashing water and to reduce the contamination of the separation membrane. However, when a baffle of a certain length or longer is applied to the separation membrane module, the density of the separation membrane in the module increases, which can cause filtration resistance. Therefore, a baffle of an appropriate length must be applied.

Table 3 compares and summarizes membrane filtration performance according to the ratio of the central baffle according to an embodiment of the present invention.

Experiment module Membrane Length (mm) Center baffle length (mm) length ratio
(α) TMP increase rate a 500 420 0.84 0.145 b 500 350 0.70 0.101 c 500 320 0.64 0.067 d 500 250 0.50 0.099 e 500 210 0.42 0.132 f 500 105 0.21 0.165

Length ratio = central baffle length/separator length

Experiments were conducted by varying the length of the central baffle in the same membrane length. In the case of the central baffle, it can be judged that the longer the baffle is, the better because it plays a role of facilitating the discharge. Looking at the results of Table 3, which is the above example, it can be confirmed that the baffle length is preferably designed in a ratio of 0.5 to 0.7 in length in proportion to the length of the separator, and the most effective performance is achieved by designing in a ratio of 0.64. In addition, it was found that the efficiency of the central baffle decreased because the cleaning air and backwash water generated from the separation membrane module were not smoothly discharged when the design was made below a certain ratio.

Another advantage from the existing water purification method of a farm breeding water treatment system to which the separation membrane technology according to the present invention is applied is the stability of breeding water. Ozone or electrolysis, which is the existing advanced treatment method, has the advantage of being applicable to high capacity, but since it is a process of continuously injecting an oxidizing agent into the breeding water supplied to the tank, there may be residual oxidizing agents that do not react according to the change in the concentration of pollutants in the raw water. there is. This residual oxidizing agent causes death of fish, and especially in the case of fry, it is sensitive to a low concentration of oxidizing agent, and it acts fatally on fostering. For example, in the case of electrolysis, sterilization/sterilization is carried out by supplying and maintaining 0.06 ppm of residual oxidizing agent in the aquaculture water. Conversely, when the concentration of organic matter and pathogens in the raw water is low, the concentration of the oxidizing agent made by electrolysis remains, which has a fatal effect on fish.

8 is a comparison of the residual oxidizing agent (chlorine) concentration according to the electrolysis / ozone treatment method according to the prior art and the residual oxidizing agent (chlorine) concentration in the separation membrane filtration method according to an embodiment of the present invention according to the breeding water inflow time is indicated by

The separation membrane filtration system according to an embodiment of the present invention has the advantage that stable supply of breeding water is possible because an oxidizing agent is not used in the breeding water supply process except for the washing step. In the cleaning step, chlorine is used to clean the contaminated membrane, and after the cleaning process is completed, the production water is discharged to reduce residual chlorine. In general, the chlorine concentration is reduced to 0.01 ppm or less within 5 minutes, and when the production water is stabilized (discharged) for about 10 minutes, the chlorine supplied to the breeding water is measured to be 0.00 ppm. To manage this, it has a stabilization device that supplies breeding water only when stable water quality is guaranteed by linking an online residual chlorine measuring device and a pH meter to the treated water.

9 shows a result of maintaining an increase rate of a transmembrane pressure difference (TMP) according to a reuse circulated CIP (RCC) cleaning according to an embodiment of the present invention.

Aquaculture breeding water treatment system according to an embodiment of the present invention is operated with a higher flux (permeate flow per unit area of the separator) compared to a general water purification/sewage treatment process, and thus membrane contamination occurs rapidly. Therefore, for long-term and stable operation, a maintenance cleaning method different from the existing separation membrane system is required. Therefore, the maintenance cleaning method applied to the aquaculture breeding water treatment system according to an embodiment of the present invention is different from the cleaning of the conventional CIP method (Cleaning In Place), which neutralizes and discharges the cleaning waste solution after cleaning. We developed a reuse circulated CIP (RCC) that can be reused continuously by replenishing only the insufficient drug stock solution by recovering it in a state in which contaminants have been removed through the filter. This RCC method is an eco-friendly cleaning method because it does not discharge the waste liquid and only replenishes the undiluted solution as much as the reduced concentration. As can be seen from FIG. 9 , even in the case of this RCC method, when the membrane differential pressure increase rate reaches a certain level, a long-term and stable operation of the separation membrane is possible through periodic cleaning in addition to the backwashing process described above.

10 shows a comparison of drug consumption according to the Normal-CIP (NC) method according to the prior art and the reuse circulated CIP (RCC) method according to an embodiment of the present invention. As shown in FIG. 10, the conventional cleaning method (Normal-CIP, NC) is a method in which a new cleaning agent is mixed and applied every cleaning cycle, and the used cleaning liquid is neutralized and discarded, and the RCC cleaning method is used only when the cleaning target concentration is insufficient It is a method of replenishing the drug stock solution and reusing the mixed drug as it is in the next cleaning step. However, in the case of reuse, the cleaning mixture is applied to the separation membrane after removing particulate contaminants through a cartridge filter.

<Example 2> Membrane maintenance cost according to RCC cleaning method

At the same filtration flow rate (filtration flux), 1,000 mg/L of NaOCl was applied as a cleaning concentration for maintenance of a farm breeding water treatment system according to an embodiment of the present invention. In one embodiment of the present invention, in order to obtain a stable cleaning effect, a NaOCl concentration of at least 500 mg/L is required, and at a concentration of 1,000 mg/L or more, a constant cleaning efficiency was shown regardless of the increase in the concentration. In the conventional NC (Normal CIP) method, since the cleaning solution was discharged, NaOCL of 1,000 mg/L had to be injected into the chemical tank each time. On the other hand, in the RCC washing method according to an embodiment of the present invention, the concentration was reduced to 850 mg/L after washing, and NaOCl of 150 mg/L was charged after each washing. As a result of operating with the same cleaning cycle, the RCC cleaning method was effective in terms of maintenance of the increase rate of the transmembrane pressure difference (TMP) and was able to maintain the TMP stably.

Table 4 compares and summarizes the maintenance cost of the aquaculture water treatment system according to the RCC cleaning method and the NC cleaning method according to an embodiment of the present invention.

method Normal-CIP RC-CIP note cleaning agent concentration 1,000 ppm NaOCl 1,000 ppm NaOCl * NaOCl 143 won/kg
* RC-CIP: Once a month
cleaning solution exchange number of washes 4 times/day 4 times/day Filling Chemical Concentration 1,000 ppm/time 150 ppm/time
1,000 ppm/month NaOCl consumption per year 12,166.6 kg 1,925 kg drug consumption cost 174 million won 27.5 million won

As can be seen from Table 4, the RCC cleaning method was able to significantly reduce the amount of chemicals consumed compared to the conventional NC method, and thus the maintenance cost could be significantly reduced, and only the annual chemical usage cost could be reduced by 85%.

<Example 3> Effect of removing bacteria from influent water from aquaculture farms through membrane filtration process

Tables 5 and 6 show the removal rates of general bacteria and Vibrio bacteria, respectively, as a result of treatment by actually applying the farm breeding water treatment system according to an embodiment of the present invention to the farm.

analysis date enemy
(CFU/ml) membrane filtration
(CFU/ml) note 08/03 3,400 0 Swelling waves (typhoons) 08/31 1,200 0 09/14 200 0 09/28 120 0 10/13 630 0 Raw water E. coli detection
Non-detection of E. coli in membrane filtrate

analysis date enemy
(CFU/ml) membrane filtration
(CFU/ml) note 08/03 348 0 Swelling waves (typhoons) 09/14 62 0 10/13 140 0

The bacterial content in the influent raw water varied according to the conditions of storms and waves, but bacteria were not always detected in the membrane-filtered water. In the case of treatment systems such as sand filtration and fiber filtration, the treatment rate is good when the concentration of contaminants in the raw water is low, but when the concentration of contaminants in the raw water increases, the number of bacteria in the treated water also increases. It can be said to be a system that can supply stable breeding water.

The US Environmental Protection Agency's LT2ESWTR (Long Term 2 Enhanced Surface Water Treatment Rule) certification is a system that is certified for a treatment process suitable for the US water purification system. Whether this treatment criterion is met is included. Cryptosporidium is a type of sporidium and it is a substance that must be removed in the water treatment process because it has a great effect on the human body and animals.

As a result of testing the separation membrane according to an embodiment of the present invention at a membrane filtration facility in a water purification plant in California, USA, for 3 months, the removal performance of Cystic worms (parasites) by this separation membrane process was confirmed to be at least 5.23 LRV, thus obtaining LT2ESWTR certification did. LRV is an abbreviation of log removal value, and LRV3 represents a removal rate of 99.9%, and LRV4 represents a removal rate of 99.99%. Therefore, this membrane was evaluated to have a removal rate of 99.999% or more for sporangia, which can be evaluated as having a safe removal rate for fish disease-causing substances caused by scutica worms or sporangia in the aquaculture water.

1: Separator module skid
2: control panel
3: Raw water pump
4: backwash pump
5: Blower
6: Chemical A circulation pump
7: Chemical B circulation pump
8: water backwash tank
9: Chemical A mixing tank
10: Chemical A stock solution tank
11: Chemical B mixing tank
12: Chemical B stock solution tank
13: strainer for pharmaceuticals
14: Raw water inlet pipe with screen facility attached
15: concentrated water outlet pipe
16: filtered water supply pipe

Claims (10)

a screen device having a water intake pipe into which raw water is introduced, a screen for supplying raw water to the raw water inlet pipe by removing foreign substances remaining in the raw water supplied from the intake pipe, and a filtration pump;
a separation membrane module skid connected to the raw water inlet pipe to supply raw water to the separation membrane module;
a pressurized hollow fiber membrane module comprising a raw water inlet for removing contaminants and pathogens present in the raw water, a plurality of which are connected in parallel to the separator module skid, a treated water concentrator, and a filtration part;
a backwash pump for backwashing the membrane module and a blower for generating cleaning air for desorption of contaminants from the membrane surface; and
Doedoe comprising a chemical stock solution tank for chemically cleaning the separation membrane module, a chemical mixing tank, a chemical stock solution transfer pump, and a maintenance cleaning unit including a chemical circulation pump,
The pressurized hollow fiber membrane module is a cylindrical body having a hollow inside, and an air zone in which at least one back-pore is formed regularly or irregularly through its outer peripheral surface and a water zone in which one or more back-pores are regularly or irregularly penetrated. and a central baffle in which the size of the reverse pore penetrating through the outer periphery of the air zone is larger than the size of the reverse pore penetrating through the water zone, and the area of the water zone is larger than that of the air zone,
In the farm breeding water treatment system, the filtration unit of the separation membrane module is connected to a filtrate supply pipe for supplying filtrated water to the farm, and the treated water concentrator of the separation membrane module is connected to the concentrated water outlet pipe,
The farm breeding water treatment system to which a separation membrane technology is applied further comprises a stabilizing device that blocks the supply of filtered water when a toxic substance is generated by interlocking a residual chlorine meter and a pH meter. The method according to claim 1,
The central baffle is located inside the module housing on the same axis as the concentrating unit configured at one end of the pressurized hollow fiber membrane module, the raw water inlet is provided at the other end of the module housing, and the filtering unit is provided on the side of the concentrating unit, The central baffle and the concentrator, which are the outlets for the concentrated water and air, are located in the center of the housing, so the distance from the edge of the housing to the central baffle along the axial direction of the housing is constant, so that the movement of concentrated water and air is uniform. Aquaculture water treatment system to which separation membrane technology is applied. The method according to claim 1,
The separation membrane length of the pressurized hollow fiber separation membrane module is 250 to 1,500 mm. The method according to claim 1,
The ratio of the length of the separation membrane of the pressurized hollow fiber membrane module to the length of the baffle is 1: 0.5 to 0.7. delete The method according to claim 1,
The separation membrane module is a separation membrane of a microfiltration standard, and a farm breeding water treatment system to which a separation membrane technology is applied, characterized in that it includes a hollow fiber type separation membrane having a pore size of 0.05 to 0.4 μm. The method according to claim 1,
Separation membrane technology, characterized in that the maintenance and cleaning unit is a reuse circulated CIP (RCC) that can be continuously reused by recovering the used cleaning agent in a state in which contaminants have been removed through a filter and replenishing only the insufficient chemical stock solution Aquaculture water treatment system applied. 8. The method of claim 7,
The maintenance and cleaning unit is a farm breeding water treatment system to which the separation membrane technology is applied, characterized in that the concentration of the consumed drug is automatically replenished to the concentration set through the meter. The method according to claim 1,
The wastewater containing contaminants discharged to the concentrated water outlet pipe is connected to a concentration treatment facility including a sedimentation tank or a pressurized flotation tank. delete

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