KR102328973B1 - A water treatment system capable of backwashing membrane - Google Patents

Abstract

In a water treatment system capable of backwashing a separation membrane according to an embodiment of the present invention, a separation membrane, a first inlet and a second inlet are provided, brine flows into the first inlet, and the influent flows into the second inlet, and forward osmosis a forward osmosis process unit for water-treating the brine as the first treated water through the process; a first reverse osmosis process unit which receives the first treated water and produces second treated water through a reverse osmosis process; a second reverse osmosis process unit for producing third treated water through a reverse osmosis process in which the second treated water is introduced; and a concentrated water supply unit for supplying concentrated water discharged from the second reverse osmosis unit to the forward osmosis unit; When washing the separation membrane, it is preferable that concentrated water flows into the forward osmosis process unit through the first inlet and brine flows through the second inlet to wash the separation membrane.

Description

A water treatment system capable of backwashing membrane

The present invention relates to a water treatment system capable of membrane backwashing, and more specifically, to a water treatment system capable of membrane backwashing in which the separation membrane of the forward osmosis process part is washed by using the concentrated water concentrated in the process of desalination of brine as washing water. it's about

The forward osmosis-reverse osmosis hybrid process is a process suggested for future low-energy seawater desalination.

Referring to FIG. 1, the desalination treatment of seawater by the forward osmosis-reverse osmosis hybrid process will be described as follows.

1, in the forward osmosis-reverse osmosis hybrid process, seawater is diluted through a forward osmosis process, and the diluted seawater is treated with a reverse osmosis process. The produced water is seawater of high salinity in the forward osmosis process unit 10, the first pressurization pump 20, the first reverse osmosis process unit 30, the second pressurization pump 40, and the second reverse osmosis process unit 50 ) was sequentially treated.

The forward osmosis process unit 10 is provided with a separation membrane 11 having selective permeability, and the osmotic pressure gradient, which is a physical phenomenon in which water on the low salinity side moves through the separation membrane 11 to the high salinity side in order to maintain the equilibrium of the concentration. (osmotic pressure gradient) is applied.

Seawater of high salinity and wastewater of low salinity are respectively introduced into the forward osmosis process unit 10 . In the forward osmosis process unit 10, wastewater flows from the second space 13 to the first space 12 through the separation membrane 11 due to a concentration difference with seawater, and foreign substances mixed in the wastewater are mixed with the separation membrane ( 11), so that only the water of the wastewater flows from the second space 13 to the first space 12 . Through the forward osmosis process, the seawater is mixed with the water flowing in the second space 13 and the concentration is diluted to become the first treated water. The first treated water has a lower salinity than that of seawater through the forward osmosis process.

The first treated water discharged from the first space 12 of the forward osmosis process unit 10 passes through the first reverse osmosis process unit 30 and the second reverse osmosis process unit 50 , the salt is removed and desalinated. . Unlike the conventional reverse osmosis process, the forward osmosis-reverse osmosis hybrid process has an advantage in that it consumes relatively little energy because it treats diluted seawater.

However, in the forward osmosis process unit 10, membrane contamination inevitably occurs during the filtration process. Here, the membrane contamination is a phenomenon in which various foreign substances present in the seawater flowing into the separation membrane 11 are deposited or adsorbed on the surface of the filtration membrane, thereby reducing the amount of permeated water of the separation membrane 11 .

Based on the causative material, particulate matter film contamination by colloids or suspended solids, organic film contamination by adsorption of organic matter such as natural organic matter, biological film contamination by the adhesion or growth of microorganisms, sedimentation or scale of metal salts, etc. It can be classified as inorganic material membrane contamination.

In addition, since the forward osmosis-reverse osmosis hybrid process uses wastewater when diluting seawater in the forward osmosis process, the separation membrane 11 of the forward osmosis process unit 10 is easily contaminated with organic matter contained in the wastewater. . Therefore, periodic membrane cleaning of the separation membrane 11 of the forward osmosis process unit 10 must be performed.

2 shows a process of washing the deposits 14 accumulated on the separation membrane 11 of the forward osmosis process unit 10 in the prior art. In the conventional forward osmosis-reverse osmosis hybrid process, the separation membrane 11 of the forward osmosis process unit 10 is washed with production water. The washing process of the separation membrane 11 is to wash the separation membrane 11 by flowing the fluid in the opposite direction to the flow direction of the fluid in the forward osmosis process during the water treatment process.

Referring to FIG. 2 , when the separation membrane 11 is washed, the produced water is supplied from the second reverse osmosis process unit 50 to the forward osmosis process unit 10 through a line 61 . The produced water flows into the first space 12 , and the seawater of high salinity flows into the second space 13 .

Conventionally, in order to use the produced water as washing water, the produced water is pressurized in the range of 0 to 2 bar through the pressure pump 62 for washing, and then the produced water is provided to the first space 12 . The produced water having a lower salinity than seawater flows from the first space 12 to the second space 13 to wash the deposits 14 accumulated on the separation membrane 11 . After the washing process, the washing treated water discharged from the forward osmosis process unit is discharged to the first reverse osmosis process unit 30 , and the washing wastewater is discharged to the outside.

In the conventional forward osmosis-reverse osmosis hybrid process, the washing process of the separation membrane 11 is eco-friendly compared to washing the separation membrane 11 using chemicals, but the final product water using water-treated production water as washing water There is a problem of reducing production.

In the conventional washing process of the separation membrane 11, in order to pressurize the production water, which is washing water, the washing pressure pump 62 is an essential component, and the installation cost of the washing pressure pump 62, the washing pressure pump 62 It is not economical in terms of cost, such as the amount of power consumed to operate the machine, the maintenance cost required to maintain the pressure pump 62 for washing, and the like.

US Patent No. 9,687,787 discloses a Reciprocal enhancement of reverse osmosis and forward osmosis.

An object of the present invention is to provide a water treatment system capable of backwashing a membrane capable of washing the membrane of a forward osmosis process by using the concentrated water concentrated in the course of desalination of brine as washing water.

In a water treatment system capable of backwashing a separation membrane according to an embodiment of the present invention, a separation membrane, a first inlet and a second inlet are provided, brine flows into the first inlet, and the influent flows into the second inlet, and forward osmosis a forward osmosis process unit for water-treating the brine as the first treated water through the process; a first reverse osmosis process unit which receives the first treated water and produces second treated water through a reverse osmosis process; a second reverse osmosis process unit for producing third treated water through a reverse osmosis process in which the second treated water is introduced; and a concentrated water supply unit for supplying concentrated water discharged from the second reverse osmosis unit to the forward osmosis unit; When washing the separation membrane, it is preferable that concentrated water flows into the forward osmosis process unit through the first inlet and brine flows through the second inlet to wash the separation membrane.

In an embodiment of the present invention, the second reverse osmosis process unit discharges concentrated water having a pressure higher than that of the brine to the concentrated water supply unit while undergoing the reverse osmosis process, and when the separation membrane is washed, the forward osmosis process unit is concentrated It is preferable to receive water from the concentrated water supply unit and wash the separation membrane using the concentrated water as washing water in a pressurized forward osmosis method using the pressure of the concentrated water.

In one embodiment of the present invention, the concentrated water supply unit, the concentrated water line connected to the second reverse osmosis process unit; a first branch line branched from the concentrated water line and connected to the first outlet of the forward osmosis process unit; a second branch line branched from the concentrated water line and connected to the first inlet of the forward osmosis process unit; The concentrated water line is installed at a branch point where the first branch line and the second branch line are branched, and includes a concentrated water valve selectively connecting any one of the first branch line or the second branch line to the concentrated water line, It is preferable that the water valve connects the concentrated water line and the second branch line when the separation membrane is washed.

In one embodiment of the present invention, the concentrated water valve connects the concentrated water line and the first branch line during brine water treatment so that the concentrated water is provided to the first outlet via the concentrated water line and the first branch line, It is preferable to be mixed with the first treated water discharged from the first outlet and provided to the first reverse osmosis process unit.

In one embodiment of the present invention, but the brine flows, the brine line connected in parallel to the first inlet and the second inlet; The influent flows, but an influent line connected to the second inlet; a first switching valve selectively connecting any one of the brine line or the concentrated water line to the first inlet; and a second selector valve selectively connecting either one of the brine line or the influent line to the second inlet, wherein the first selector valve connects the brine line and the first inlet during brine water treatment, and concentrates when the separation membrane is washed It is preferable that the water line and the first inlet are operated to connect, and the second switching valve is operated to connect the influent line and the second inlet during brine water treatment, and to connect the brine line and the second inlet when the separation membrane is washed.

In an embodiment of the present invention, the first outlets of the plurality of forward osmosis process units are connected in parallel to the first reverse osmosis process unit, and each forward osmosis process unit operates by opening and closing the first selector valve and the second selector valve. , it is preferable that the forward osmosis process is operated separately by receiving brine and influent water during water treatment of brine, or receiving concentrated water and brine when washing the separation membrane.

The present invention washes the separation membrane of the forward osmosis process part through a pressurized forward osmosis process using concentrated water concentrated in the process of water treatment of brine as washing water, and uses the produced water as washing water in the conventional forward osmosis-reverse osmosis hybrid process Compared to that, it is possible to increase the final production amount of produced water.

In addition, as compared to using a pressure pump for washing to pressurize the produced water in the conventional forward osmosis-reverse osmosis hybrid process, the present invention provides a method for brine while passing through the first reverse osmosis process part and the second reverse osmosis process part. By using the third concentrated water with high pressure as the washing water of the separation membrane, there is no need for a pressurized pump for washing, so it is economical by reducing the installation cost, maintenance cost, and operating cost of the washing pressurized pump.

In addition, according to the present invention, as the high-pressure third concentrated water is used as washing water, the pressure of the washing treated water discharged from the forward osmosis process unit after washing of the separation membrane is increased after using the previously produced water as washing water. It is higher than the pressure of the washing treatment water discharged by the government. Accordingly, the present invention reduces the pressure required to drive the first reverse osmosis process unit in order to water treatment the washing treated water, reduces the energy consumption used to operate the reverse osmosis process unit, and reduces the operating cost of a water treatment system capable of backwashing the separation membrane. can be reduced

In addition, according to the present invention, a plurality of forward osmosis process units perform a water treatment process or a washing process individually, and even if the washing process of any one forward osmosis process unit proceeds, the other forward osmosis process units perform the water treatment process, thereby continuously producing water. can produce

In addition, the present invention mixes the concentrated water having a pressure higher than the pressure of the first treated water through the reverse osmosis process with the first treated water discharged from the forward osmosis process unit with the first treated water during water treatment of brine, By increasing the pressure of the first treated water, the pressure required to drive the first reverse osmosis process unit for water treatment of the first treated water is reduced, thereby reducing the amount of energy consumed for operating the first reverse osmosis process unit.

In the present invention, since concentrated water is water-treated through a water treatment process after completion of the washing process of the forward osmosis process part, the washing process of the forward osmosis process part can be performed in an environment-friendly manner, and it is possible to minimize the amount of washing waste solution, so that the operation of the entire facility is stable Operation and maintenance costs can be reduced.

1 shows a water treatment flow for desalination of seawater in a conventional seawater desalination system.
Figure 2 shows the flow of water treatment when cleaning the membrane of the forward osmosis process in the conventional seawater desalination system.
3 is a block diagram of a water treatment system capable of backwashing a separation membrane according to an embodiment of the present invention.
4 schematically shows a water treatment flow in a configuration diagram of a water treatment system capable of backwashing a separator according to an embodiment of the present invention.
5 is a water treatment flow diagram when the first forward osmosis process unit performs the washing process and the second forward osmosis process unit performs the water treatment process in one embodiment of the present invention.
6 is a water pressure-water permeability graph.
7 is a water pressure-reverse diffusion water permeability graph.

Hereinafter, with reference to the accompanying drawings, a water treatment system capable of backwashing a separator according to an embodiment of the present invention will be described.

Referring to FIG. 3 , a water treatment system 100 capable of backwashing a separator according to an embodiment of the present invention includes a plurality of forward osmosis process units 110a and 110b, a first pressure pump 120 , and a first reverse osmosis process. It includes a process unit 130 , a second reverse osmosis process unit 150 , a concentrated water supply unit 160 , a brine line 190a and an influent water line 190b .

The present invention is to wash the separation membrane of the forward osmosis process by using the concentrated water produced in the process of desalination of brine as washing water.

In this embodiment, with respect to the plurality of forward osmosis process units (110a, 110b), the first forward osmosis process unit (110a) and the second forward osmosis process unit (110b) will be referred to separately.

The first forward osmosis process unit 110a and the second forward osmosis process unit 110b are connected in parallel to the first reverse osmosis process unit 130 . The first forward osmosis process unit 110a and the second forward osmosis process unit 110b are each operated individually, and through the forward osmosis process, brine water treatment or washing of the separation membrane 113a is performed.

The first forward osmosis process unit 110a and the second forward osmosis process unit 110b have the same structure. Accordingly, in the following, in order to avoid repetition of the description, the first forward osmosis process unit 110a will be described as a reference.

In the first forward osmosis process unit 110a, an internal space is divided into a first space 111a and a second space 111b by a separation membrane 113a. The first inlet 114a is an inlet communicating with the first space 111a. The second inlet 115a is an inlet communicating with the second space 111b. As the separation membrane 113a, a filtration membrane capable of moving the fluid due to a concentration difference and blocking the flow of foreign substances may be used.

A brine line 190a and a concentrated water line 161 are connected to the first inlet 114a. Here, the salt water line 190a is a pipe through which salt water flows. And, the concentrated water line 161 is a pipe through which the concentrated water flows. The concentrated water line 161 connected to the first inlet 114a is the second branch line 161b and 161c. The concentrated water line 161 and the second branch lines 161b and 161c will be described later.

The first switching valve 114a is a 3-way valve that selectively connects either the brine line 190a or the second branch line 161b to the first inlet 114a. The first switching valve 114a connects the brine line 190a and the first inlet 114a during brine water treatment, and connects the concentrated water line 161 and the first inlet 114a when the separation membrane is washed. .

The second switching valve 115a is a 3-way valve that selectively connects either the salt water line 190a or the influent water line 190b to the second inlet port 115a. The second switching valve 115a is operated to connect the inflow water line 190b and the second inlet 115a during brine water treatment, and to connect the brine line 190a and the second inlet 115a when cleaning the separation membrane.

The influent line 190b is a pipe through which the influent flows. The influent is a fluid with a lower salinity than the brine. In the present invention, seawater may be used as brine, and wastewater may be used as feed water.

When washing the separation membrane, the first forward osmosis process unit 110a receives the concentrated water from the concentrated water supply unit, and uses the pressure of the concentrated water to wash the separation membrane in a pressurized forward osmosis method, using the concentrated water as washing water.

On the other hand, the first reverse osmosis process unit 130 receives the first treated water discharged from the forward osmosis process unit, through the reverse osmosis process, freshwater treatment of the first treated water as second treated water. The first treated water treated by the first forward osmosis process unit 110a is pressurized by the first pressure pump 120 and supplied to the first reverse osmosis process unit 130 . The first pressure pump 120 pressurizes the first treated water to a pressure required for the reverse osmosis process of the first reverse osmosis process unit 130 .

The second reverse osmosis process unit 150 receives the second treated water and desalinates the second treated water as the third treated water through the reverse osmosis process. Then, the second reverse osmosis process unit 150 discharges the third concentrated water having a pressure higher than that of the brine to the concentrated water line 161 while undergoing the reverse osmosis process. The third concentrated water has a pressure higher than the pressure of the brine and lower than the pressure of the second treated water, approx. 10 bar.

The second treated water is pressurized by the second pressure pump 140 and provided to the second reverse osmosis process unit 150 . The second pressure pump 140 provides the pressure required for the reverse osmosis process of the second reverse osmosis process unit 150 to the second treated water.

Depending on the intended use of the third treated water, for example, industrial water, industrial water, agricultural water or edible beverage, the reverse osmosis process may be further performed several times.

The concentrated water supply unit 160 is for supplying the third concentrated water discharged from the second reverse osmosis process unit 150 to the forward osmosis process unit.

The concentrated water supply unit 160 includes a concentrated water line 161 , a first branch line 161a , second branch lines 161b and 161c , and a concentrated water valve 162 . The concentrated water line 161 is connected to the second reverse osmosis process unit 150, and is a pipe through which the third concentrated water flows. The first branch line 161a and the second branch lines 161b and 161c are pipes branched from the concentrated water line 161 .

The first branch line 161a is a pipe branched from the concentrated water line 161 and connected to the first outlet (not shown) of the first forward osmosis process unit 110a. The first outlet of the first forward osmosis process refers to an outlet through which the first treated water is discharged from the first space 111a.

The second branch lines 161b and 161c are pipes branched from the concentrated water line 161 and connected to the first inlet 114a of the forward osmosis process unit. The second branch lines 161b and 161c branch from the concentrated water line 161 with the number of the forward osmosis process units, and are connected in parallel to the first inlets 114a and 114b of the forward osmosis process units. Reference numeral 161b denotes a second branch line connected to the first inlet 114a of the first forward osmosis process unit. Reference numeral 161c denotes a second branch line connected to the first inlet 114b of the second forward osmosis process unit.

The concentrated water valve 162 is installed at a branch point where the concentrated water line 161 is branched into the first branch line 161a and the second branch line 161b, 161c, the first branch line 161a or the second branch line Any one of the lines (161b, 161c) is selectively connected to the concentrated water line (161). The concentrated water valve 162 may be a 3-way valve.

The concentrated water valve 162 is operated to connect the concentrated water line 161 and the second branch lines 161b and 161c when the separation membrane is washed. When washing the separation membrane, the third concentrated water flows through the concentrated water line 161 and the second branch line 161b into the first space 111a in which the separation membrane is washed.

The concentrated water valve 162 is operated to connect the concentrated water line 161 and the first branch line 161a during brine water treatment. In the case of brine water treatment, the third concentrated water is provided to the first outlet via the concentrated water line 161 and the first branch line 161a, mixed with the first treated water, and then to the first reverse osmosis process unit 130. is provided

The present invention mixes the first treated water discharged from the forward osmosis process part during the brine water treatment with the third concentrated water having a pressure higher than the pressure of the first treated water through the reverse osmosis process with the first treated water, By increasing the pressure of the first treated water, the pressure required to drive the first reverse osmosis process unit for water treatment of the first treated water is reduced, thereby reducing the amount of energy consumed for operating the first reverse osmosis process unit. In addition, since the salinity of the third concentrated water is lower than that of the first treated water, the pressure required to operate the reverse osmosis process is reduced.

Hereinafter, with reference to FIG. 4 , in the first forward osmosis process unit 110a and the second forward osmosis process unit 110b, a water treatment flow during brine water treatment will be described. The first forward osmosis process unit 110a and the second forward osmosis process unit 110b have the same structure as each other, and in both the first forward osmosis process unit 110a and the second forward osmosis process unit 110b, the brine is used. When the water treatment is performed, the first forward osmosis process unit 110a and the second forward osmosis process unit 110b perform the brine water treatment in the same manner. Hereinafter, in order to avoid repetition of the description, the description of the brine water treatment process in the second forward osmosis process unit 110b will be omitted.

When the brine water is treated in the first forward osmosis process part 110a, brine flows into the first inlet 114a of the first forward osmosis process part 110a, and the influent flows into the second inlet 115a. When the brine water is treated in the first forward osmosis process unit 110a, the first switching valve 114a blocks the flow of the third concentrated water to the first inlet 114a. And, the second switching valve (115a) blocks the flow of salt water to the second inlet (115a).

In the first forward osmosis process unit 110a, when the brine flows into the first space 111a and the influent flows into the second space 111b, the forward osmosis process occurs due to a concentration difference between the salinity and the influent water. . As mentioned above, the brine is a fluid with a higher salinity than the salinity of the influent.

In the first forward osmosis process unit 110a, the influent flows through the separation membrane 113a in the second space 111b toward the first space 111a in the F1 direction due to the difference in concentration with the brine. In this process, foreign substances contained in the influent are accumulated on the separation membrane 113a. In this embodiment, the foreign material accumulated on the separation membrane 113a is referred to as an “attachment 114”. These deposits 114 cause fouling of the separation membrane 113a, so that the membrane performance of the separation membrane 113a is deteriorated, and the forward osmosis process cannot be efficiently performed.

The cleaning of the separation membrane 113a will be described later with reference to FIG. 5 .

Through the forward osmosis process in the first forward osmosis process unit 110a, the brine is treated with the first treated water, and the influent is concentrated with the first concentrated water. The first concentrated water is discharged from the second space 111b to the wastewater line. Here, the first concentrated water is a fluid in which only water has escaped from the influent, and has a higher salinity than the influent.

The first treated water is discharged from the first space 111a and is provided to the first reverse osmosis process unit 130 in a state in which the pressure is increased via the first pressure pump 120 . The first treated water is a dilution of the influent with brine, and has a lower salinity than that of brine.

In the first reverse osmosis process unit 130, the first treated water is treated with the second treated water and the second concentrated water through the reverse osmosis process. The second treated water is a fluid from which salt has escaped from the first treated water, and has a lower salinity than the first treated water. And, the second concentrated water is a concentration of the salinity of the first treated water, and has a higher salinity than the first treated water.

The second treated water and the second concentrated water are fluids discharged from the first reverse osmosis process unit 130 through the reverse osmosis process, and have a higher pressure than the first treated water and the brine. The second concentrated water is discharged to the wastewater line 180 after energy is recovered by the energy recovery unit 170 .

The present invention recovers the energy of the second concentrated water through the energy recovery unit 170 , the first pressure pump 120 , the second pressure pump 140 , the first reverse osmosis process unit 130 , or the second reverse osmosis It may be used as energy to operate the through process unit 150 .

In the second reverse osmosis process unit 150 , the second treated water is treated with the third treated water and the third concentrated water through the reverse osmosis process. The third treated water is a fluid having a lower salinity than the second treated water, and is a fluid that can be used as industrial water, industrial water, agricultural water, or edible water depending on the salinity.

The third concentrated water is concentrated water discharged without penetrating the reverse osmosis membrane of the second reverse osmosis process unit 150, and is a fluid having a lower salinity than the second concentrated water, but higher in salinity than the second treated water. The third concentrated water is discharged from the second reverse osmosis process unit 150 to the concentrated water line 161 at a pressure of 10 bar or less.

The third concentrated water is provided to the first branch line (161a) or the second branch line (161b, 161c) by the operation of the concentrated water valve (162) while flowing along the concentrated water line (161). Concentrated water valve 162 allows the third concentrated water to flow to the first branch line 161a during brine water treatment, and the third concentrated water to flow to the second branch line 161b and 161c when washing the separation membrane 113a, Control the flow of the third concentrated water.

The present invention mixes the third concentrated water having a higher pressure than the first treated water with the first treated water when treating the brine, by increasing the pressure of the first treated water before flowing into the first pressure pump 120, By reducing the strength of the first pressure pump 120 pressurizing the first treated water, it is possible to ultimately improve the operating efficiency of the first pressure pump 120 . In addition, the present invention can also lower the operating pressure because the salinity of the third concentrated water is lower than that of the first treated water.

Hereinafter, with reference to FIG. 5 , a water treatment flow at the time of washing the separation membrane 113a will be described. 5 illustrates a water treatment flow when the separation membrane 113a is washed in the first forward osmosis process unit 110a and the brine water treatment is performed in the second forward osmosis process unit 110b.

The present invention is to wash the deposits 114 accumulated on the separation membrane 113a during the brine water treatment by using the concentrated third concentrated water as washing water during the brine water treatment.

Referring to FIG. 5 , when the separation membrane 113a in the first forward osmosis process unit 110a is washed, the concentrated water valve 162 controls the flow of the third concentrated water to the second branch lines 161b and 161c. allow And, the first switching valve 114a allows the flow of the third concentrated water to the first inlet 114a, and blocks the flow of the brine to the first inlet 114a. And, the second selector valve 115a allows the flow of salt water to the second inlet 115a, and blocks the flow of the influent water to the second inlet 115a.

When the separation membrane 113a is washed, the third concentrated water is introduced into the first space 111a in which the brine of high salinity was accommodated during the brine treatment. In addition, high salinity brine flows into the second space 111b in which the low salinity inflow water was accommodated during brine treatment. The third concentrated water is concentrated water generated in the process of desalination of brine, and has a lower salinity than brine.

For example, assuming that brine having a concentration of approximately 35,000 ppm is water-treated with the third treated water and the third concentrated water after one forward osmosis process and two reverse osmosis processes, the third concentrated water is approximately It has a concentration of 2,000 ppm. However, the third concentrated water has a pressure higher than the pressure of the brine and lower than the pressure of the second treated water, Daerak, 10 bar while undergoing two reverse osmosis processes.

When the separation membrane 113a is washed, the third concentrated water having a lower salinity than the brine passes through the separation membrane 113a from the first space 111a toward the second space 111b, and the deposits 114 accumulated on the separation membrane 113a. ) while pushing in the F2 direction, the separation membrane 113a is washed.

The third concentrated water goes through two reverse osmosis processes, has a pressure higher than the pressure of the brine, and has a pressure of about 10 bar or less, compared to the prior art, without a pressure pump for washing (see FIGS. In the forward osmosis method, the separation membrane 113a may be washed. Accordingly, the present invention can wash the separation membrane 113a through a pressurized forward osmosis process without the use of an existing pressurized pump for washing, thereby reducing the installation cost, maintenance cost, and operating cost of the washing pressurized pump, which is economical. am.

In addition, in the case of using conventionally produced water as washing water, the produced water has a pressure of 0 to 2 bar even if it is pressurized through a pressure pump for washing, whereas the third concentrated water concentrated according to the water treatment process of the present invention is 10 bar. It has the following pressure. That is, the conventional washing water has a pressure of 2 bar or less, whereas the washing water of the present invention has a high pressure of 10 bar or less, thereby increasing the washing efficiency of the separation membrane 113a.

6 and 7 , it can be seen that the water permeability is proportional to the water pressure, and the reverse diffusion water permeability is inversely proportional to the water pressure. 6 is a water pressure-water permeability graph (Evolution of experimental and modeled permeation flux (Blandin et al. 2013)). And, Figure 7 is a water pressure-reverse diffusion water permeability graph (Reverse solute flux for the PAO experiments (Oh et al. 2014).

That is, in the present invention, in the process of washing the separation membrane 113a, the maximum concentrated water flows from the first space 111a to the second space 112a through the separation membrane 113a, It is possible to reduce the reverse diffusion and improve the water permeability of the separation membrane 113a.

On the other hand, after completion of the washing process of the first forward osmosis process unit 110a, the third concentrated water is concentrated in the washing treatment water through the pressurized forward osmosis process. The washing treatment water has a higher salinity than the salinity of the third concentrated water.

The washing treated water discharged from the first forward osmosis process unit 110a goes through the first reverse osmosis process unit 130 and the second reverse osmosis process unit 150, and is treated with the third treated water and the third concentrated water. do.

In the present invention, since the third concentrated water is water-treated through a water treatment process after completion of the washing process of the forward osmosis process part, the washing process of the forward osmosis process part can be performed in an environment-friendly manner, and it is possible to minimize the amount of washing waste.

The washing treatment water is a fluid in which the third concentrated water is concentrated, and the third concentrated water has a pressure that is not consumed in the washing process. The present invention reduces the energy consumption used to pressurize the washing treated water to the pressure at which the first pressure pump 120 performs the reverse osmosis process of the first reverse osmosis process unit 130, thereby stably operating and maintaining the operation of the entire facility. It is possible to achieve the economical effect of reducing the management cost.

During the washing process of the first forward osmosis process unit 110a, a water treatment process may be performed in the second forward osmosis process unit 110b. At this time, the concentrated water supply unit 160 supplies the third concentrated water to the first forward osmosis process unit 110a through the opening and closing of the concentrated water valve 162 , and the third concentrated water to the second forward osmosis process unit 110b. Shut off the supply of concentrated water.

The second forward osmosis process unit 110b treats the brine as the first treated water. When the brine water is treated in the second forward osmosis process unit 110b, the first switching valve 116b installed in the second forward osmosis process unit 110b allows the flow of the brine water to the first inlet 114b, and 3 Block the flow of the concentrated water to the first inlet (114b). And, the second switching valve 117b installed in the second forward osmosis process unit 110b permits the flow of the influent to the second inlet 115b and blocks the flow of the brine to the second inlet 115b.

During water treatment of brine in the second forward osmosis process unit 110b, the brine flows into the first space 111b, and the influent flows into the second space 112b. Through the forward osmosis process, the influent flows in the F1 direction. While flowing through the separation membrane 113b into the first space 111b, the brine is treated with the first treated water, and the influent is treated with the first concentrated water.

The first treated water may be mixed with the washing treated water, and may be treated with the third treated water and the third concentrated water while sequentially passing through the first reverse osmosis process unit 130 and the second reverse osmosis process unit 150 . have.

The present invention desalinates high-salinity brine (eg, seawater) with the third treated water through a forward osmosis-reverse osmosis hybrid process, and uses the third concentrated water concentrated in the process of treating the brine as a washing water for pressurized purification The separation membrane of the forward osmosis process part is washed through the osmosis process. Accordingly, in the present invention, as the third concentrated water is used as the washing water, the final production amount of the produced water can be increased compared to using the produced water as the washing water in the conventional forward osmosis-reverse osmosis hybrid process.

In addition, according to the present invention, as the high-pressure third concentrated water is used as washing water, the pressure of the washing treated water discharged from the forward osmosis process unit after washing of the separation membrane is increased after using the previously produced water as washing water. It is higher than the pressure of the washing treatment water discharged by the government. Accordingly, the present invention reduces the pressure required to operate the first reverse osmosis process unit 130 in order to water-treat the washing-treated water, and the energy consumption used to operate the reverse osmosis process unit is reduced, so that the separation membrane backwashing is possible. can reduce operating costs.

In addition, in the present invention, a plurality of forward osmosis process units (110a, 110b) is individually water treatment process or washing process, even if the washing process of any one forward osmosis process unit proceeds, other forward osmosis process units perform the water treatment process. By doing so, it is possible to continuously produce production water.

In addition, in the present invention, since the third concentrated water is water-treated through a water treatment process after completion of the washing process of the forward osmosis process part, the washing process of the forward osmosis process part can be performed in an environment-friendly manner, and it is possible to minimize the amount of washing waste, Stable operation of the entire facility operation and maintenance costs can be reduced.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it is common in the technical field to which the present invention pertains that various substitutions, modifications and changes are possible within the scope without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of

100: water treatment system capable of membrane backwashing
110a: first forward osmosis process unit 110b: second forward osmosis process unit
111a, 111b: first space 1112a, 112b: second space
113a, 113b: separator 114: attached
114a, 114b: first inlet 115a, 115b: second inlet
116a, 116b: 1st selector valve 117a, 117b: 2nd selector valve
120: first pressure pump 130: first reverse osmosis process unit
140: second pressure pump 150: second reverse osmosis process unit
160: concentrated water supply unit 161: concentrated water line
162; Concentrated water valve 180: wastewater line
190a: brine line 190b: influent line

Claims (6)

A separation membrane, a first inlet and a second inlet are provided, brine flows into the first inlet, and influent flows into the second inlet, forward osmosis for treating the brine with the first treated water through a forward osmosis process Ministry of Justice;
a first reverse osmosis process unit for producing second treated water through a reverse osmosis process in which the first treated water is introduced;
a second reverse osmosis process unit for producing third treated water through a reverse osmosis process in which the second treated water is introduced; and
and a concentrated water supply unit for supplying concentrated water discharged from the second reverse osmosis unit to the forward osmosis unit;
When washing the separation membrane, in the forward osmosis process unit, the concentrated water discharged from the second reverse osmosis process unit through the concentrated water supply unit flows into the first inlet, and the flow of the brine flowing into the first inlet This is switched so that the brine is introduced into the second inlet to wash the separation membrane;
while the second reverse osmosis process unit undergoes the reverse osmosis process, discharging the concentrated water having a pressure higher than that of the brine to the concentrated water supply unit;
When washing the separation membrane, the forward osmosis process unit receives the concentrated water from the concentrated water supply unit, and uses the pressure of the concentrated water to pressurize forward osmosis to wash the separation membrane using the concentrated water as washing water. A water treatment system capable of backwashing the separation membrane. delete According to claim 1, wherein the concentrated water supply unit,
a concentrated water line connected to the second reverse osmosis process unit;
a first branch line branched from the concentrated water line and connected to the first outlet of the forward osmosis process unit;
a second branch line branched from the concentrated water line and connected to the first inlet of the forward osmosis process unit;
The concentrated water line is installed at a branch point branching into the first branch line and the second branch line, and selectively connects any one of the first branch line or the second branch line to the concentrated water line including a valve;
The concentrated water valve is a water treatment system capable of backwashing a separation membrane, characterized in that when the separation membrane is washed, the concentrated water line and the second branch line are connected. 4. The method of claim 3,
The concentrated water valve connects the concentrated water line and the first branch line during the brine water treatment so that the concentrated water is provided to the first outlet via the concentrated water line and the first branch line, A water treatment system capable of backwashing a separation membrane, characterized in that it is mixed with the first treated water discharged from the first outlet and provided to the first reverse osmosis process unit. 4. The method of claim 3,
The brine flows but a brine line connected in parallel to the first inlet and the second inlet;
The inflow water flows, but an inflow water line connected to the second inlet;
a first switching valve selectively connecting any one of the brine line or the concentrated water line to the first inlet; and
A second switching valve selectively connecting any one of the brine line or the influent line to the second inlet,
The first switching valve is operated to connect the brine line and the first inlet when treating the brine, and to connect the concentrated water line and the first inlet when the separation membrane is washed,
The second switching valve connects the influent line and the second inlet when treating the brine, and connects the brine line and the second inlet when the separation membrane is washed. water treatment system. 6. The method of claim 5,
The plurality of first outlets of the forward osmosis process part are connected in parallel to the first reverse osmosis process part,
Each of the forward osmosis process units receives the brine and the influent water during the brine water treatment by opening and closing the first switching valve and the second switching valve, or the concentrated water and the concentrated water when the separation membrane is washed A water treatment system capable of backwashing a separation membrane, characterized in that receiving brine, the forward osmosis process is operated individually.

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