KR20200107320A - Membrane Distillation system for treatment of high temperature and high salt groundwater - Google Patents

Abstract

The present invention discloses a membrane distillation system for treatment of high-temperature and high-salt groundwater. A membrane distillation system for treatment of high-temperature and high-salt groundwater according to an embodiment of the present invention includes a groundwater storage unit (100) in which high-temperature and high-salt groundwater (1) is introduced and stored; a vapor separation unit (300) into which the groundwater (1) is introduced from the groundwater storage unit (100), wherein the introduced groundwater (1) is indirectly contacted with air, and the water vapor contained in the groundwater (1) is separated by using the difference in temperature and partial pressure between the groundwater (1) and the air; a cooling unit (400) into which the water vapor is introduced from the vapor separation unit (300), wherein the introduced water vapor is cooled; and an air separation unit (500) into which condensed water (2) generated through condensation by cooling of water vapor from the cooling unit (400) is introduced, wherein the air contained in the concentrated water (2) is separated and discharged to an outside, and the condensed water (2) from which the air is separated is blocked.

Description

Membrane Distillation system for treatment of high temperature and high salt groundwater

The present invention relates to a membrane evaporation system for treatment of high-temperature, high-salt groundwater.

In the membrane distillation method, the surface tension of a solvent or solute (hydrophilic material) is greater than the surface of the separation membrane, so it cannot pass through the membrane pores in a liquid state, and is repelled from the surface of the separation membrane. It means the process of diffusing and permeating into the pores and finally condensing and separating from the treated water side. Such a process may be used in a desalting process to separate and remove nonvolatile substances or substances having relatively low volatility, or may be used to separate organic substances having high volatility in an aqueous solution.

Since this concept of membrane distillation was proposed in 1960, research on membrane distillation has been mainly conducted in the United States, Europe, Japan, and Australia until now. Recently, there is an active movement to replace the membrane distillation separation process with a separation process using a conventional evaporation or reverse osmosis membrane.

However, the evaporation method and the reverse osmosis method, which are used in pure water production or desalination processes, require a lot of energy. In particular, since the reverse osmosis method has to undergo several steps of pretreatment before use due to contamination and fouling, there are difficulties in operation management. In addition, since the reverse osmosis method is operated at a high pressure, there is a problem that the electric energy, which is a power source of the pump, is excessively consumed, resulting in a high management cost.

On the other hand, since the membrane distillation separation method uses a porous membrane, it can be operated at a lower pressure than the ultrafiltration method and the reverse osmosis method, and separation is performed by a difference in vapor pressure partial pressure. In addition, when the membrane distillation separation method is used, it is not necessary to use a filter or a separator that is not entrained in the conventional distillation method and must be turned at a high pressure in separating and removing nonvolatile substances such as salts.

Due to the merits of the membrane distillation separation process, the desalination (desalination) treatment process using the membrane distillation method is emerging as one of the competitive methods in the production of drinking water around the world because it has low operating cost and excellent durability of the separation device.

On the other hand, the water resources treated for water occupy a significant part of the groundwater, and the groundwater to be taken in is in a state of high temperature and high salt.In order to treat high temperature and high salt groundwater, the temperature of the groundwater is first lowered through a cooling process, and then the reverse osmosis process for salt water is performed to treat water. It is common.

However, such a reverse osmosis process for brine requires enormous costs for water treatment, and there is a problem that the production volume is only 50% of the total feed.

Therefore, there is a need for research on a groundwater treatment method that can replace the reverse osmosis process that treats groundwater at high cost and low efficiency.

Korean Patent Registration No. 10-0509321 Korean Patent Registration No. 10-1804485

The present invention was devised to solve the above problems, and the present invention provides a membrane evaporation system capable of treating high-temperature, high-salt groundwater at low cost and high efficiency by replacing the reverse osmosis process for treating groundwater at high cost and low efficiency. It has its purpose to provide.

On the other hand, the technical problem to be achieved in the present invention is not limited to the technical problems mentioned above, and other technical problems not mentioned are clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. Can be.

As a technical means for achieving the above object, the membrane evaporation system for treating high-temperature, high-salt groundwater according to an embodiment of the present invention includes: a groundwater storage unit 100 in which high-temperature, high-salt groundwater 1 is introduced and stored; Groundwater (1) is introduced from the groundwater storage unit (100), and the introduced groundwater (1) is indirectly contacted with air, and water vapor contained in the groundwater (1) by using the difference in temperature and partial pressure between the groundwater (1) and the air. A vapor separation unit 300 for separating; The water vapor is introduced from the water vapor separation unit 300, the cooling unit 400 for cooling the introduced water vapor; And the condensed water 2 generated by condensation by cooling water vapor from the cooling unit 400 is introduced, the air contained in the concentrated water 2 is separated and discharged to the outside, and the air is separated from the condensed water 2 ) Is configured to include; an air separation unit 500 that blocks and stores the discharge.

In one embodiment, the vapor separation unit 300 is a film evaporation chamber 310 that stores air and allows the water vapor separated from the groundwater 1 to flow into the cooling unit 400; A groundwater inlet part 340 installed on one side of the membrane evaporation chamber 310 and connected to the groundwater storage part 100 and into which the groundwater 1 flows; It is installed in the membrane evaporation chamber 310, but one side is connected to the groundwater inlet 340 so that the groundwater 1 is introduced, and the introduced groundwater 1 and the air in the membrane evaporation chamber 310 are indirectly contacted, and indirectly A hydrophobic separation membrane 320 having a plurality of pores formed on the surface so that water vapor separated from the groundwater 1 during contact flows into the membrane evaporation chamber 310; A groundwater discharge unit 350 installed on the other side of the membrane evaporation chamber 310, connected to the other side of the hydrophobic separation membrane 320, and discharging the groundwater 1 from which water vapor is separated; And air circulation connected to the air separation unit 500 and circulating the air discharged from the air separation unit 500 to flow into the membrane evaporation chamber 310 to give flow to the water vapor remaining in the membrane evaporation chamber 310 It is configured to include; unit 330.

In one embodiment, the cooling unit 400 is connected to the steam separation unit 300, the water vapor is introduced, and a cooler 420 provided with a cooling member for cooling the incoming water vapor; And a water block 410 installed on one side of the cooler 420 and for cooling the heated cooler 420 by moving the heat of the cooler 420 that generates heat while cooling water vapor to the cooling water stored therein. Is composed.

In one embodiment, the cooler 420 is provided with at least one of an air-cooled cooler equipped with a heat sink, a water cooled cooler, a thermoelectric cooler equipped with a thermoelectric element, and a vortex cooler using compressed air.

In one embodiment, the cooling unit 400 is configured to include a cooling air supply unit 430 supplying cooling air for cooling the cooling member to the cooling member.

In one embodiment, the air separation unit 500 is connected to the cooling unit 400 so that the concentrated water 2 is introduced, and a separation member for separating the air contained in the concentrated water 2 and the concentrated water 2 Water trap 510 on which 515 is installed; And a storage chamber 520 in which the water trap 510 is installed on one side and stores the concentrated water 2 from which air is separated by the water trap 510.

In one embodiment, the water trap 510 discharges the air separated from the concentrated water 2 to the steam separation unit 300.

On the other hand, the membrane evaporation system for treating high-temperature and high-salt groundwater according to an embodiment of the present invention includes a pump unit 200 for inducing the groundwater 1 to circulate from the groundwater storage unit 100 to the steam separation unit 300; It consists of including.

According to an embodiment of the present invention, the membrane evaporation system uses a membrane evaporation separation method to treat high-temperature, high-salt groundwater at a lower cost and higher efficiency than the reverse osmosis process.

In addition, the membrane evaporation system treats high-temperature, high-salt groundwater based on the membrane evaporation separation method, so that the production of drinking water compared to the total feed can be improved compared to the reverse osmosis process.

On the other hand, the effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those of ordinary skill in the art from the following description. I will be able to.

1 is a schematic diagram of a film evaporation system for treatment of high-temperature, high-salt groundwater according to an embodiment of the present invention.
2 is a graph showing the results of a performance test of a cooling unit according to an embodiment of the present invention.
3 is a cross-sectional view of a cooler provided as a vortex cooler in an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The detailed description to be disclosed hereinafter together with the accompanying drawings is intended to describe exemplary embodiments of the present invention, and is not intended to represent the only embodiments in which the present invention may be practiced. The following detailed description includes specific details to provide a thorough understanding of the present invention. However, those of ordinary skill in the art to which the present invention pertains knows that the present invention may be practiced without these specific details. In addition, throughout the specification, when a part is said to "comprising or including" a certain component, this does not exclude other components, but may further include other components unless otherwise stated. Means that. In addition, when it is determined that detailed descriptions of known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, a film evaporation system (hereinafter referred to as a "film evaporation system") for treating high-temperature and high-salt groundwater according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Composition of membrane evaporation system

The membrane evaporation system according to an embodiment of the present invention is a system that treats high-temperature and high-salt groundwater based on a membrane evaporation separation method, and includes a groundwater storage unit 100, a pump unit 200, a steam separation unit 300, and a cooling unit. It is configured to include 400 and the air separation unit 500. This membrane evaporation system can treat the groundwater 1 at low cost and high efficiency compared to the conventional reverse osmosis process based on the above configuration.

The groundwater storage unit 100 is connected through a pipe (not shown) to the point where the high-temperature and high-salt groundwater 1 flows out, and the high-temperature and high-salt groundwater 1 circulated along the pipe is introduced, and the introduced groundwater 1 Save it. In addition, the groundwater storage unit 100 is connected to the steam separation unit 300 through a separate pipe, and the groundwater 1 from which the steam is separated from the steam separation unit 300 is introduced. Through this configuration, the high-temperature and high-salt groundwater 1 can be repeatedly water-treated in the membrane evaporation system of the present invention. On the other hand, it is preferable that the groundwater storage unit 100 be provided with a chamber made of a material that is not corroded by the high temperature and high salt groundwater 1. In addition, the groundwater storage unit 100 is not shown in the drawing, but a control device (not shown) for controlling the groundwater storage unit 100, a measurement device (not shown) and a measurement device (not shown) for measuring the amount of stored groundwater. An output device (not shown) that outputs the measured amount of groundwater may be installed.

The pump unit 200 is installed in a pipe connecting the storage unit 100 and the steam separation unit 300, and a pipe so that the groundwater 1 stored in the groundwater storage unit 100 is circulated to the steam separation unit 300 Pressure is applied to induce circulation of groundwater (1). Groundwater 1 discharged from the groundwater storage unit 100 through the pump unit 200 flows into the steam separation unit 300.

The vapor separation unit 300 is a configuration for separating the water vapor contained in the groundwater 1 flowing through the pump unit 200, and the membrane evaporation chamber 310, the hydrophobic separation membrane 320, the air circulation unit 330, It is configured to include a groundwater inlet unit 340 and a groundwater discharge unit 350.

The membrane evaporation chamber 310 has a hydrophobic separation membrane 320 installed therein, and is connected to the cooling unit 400 through a tube so that air is stored therein and the separated water vapor is circulated to the cooling unit 400.

The hydrophobic separation membrane 320 is installed in the membrane evaporation chamber 310, and one side is connected to the groundwater inlet 340 so that the groundwater 1 flows into the interior, and the other side is connected to the groundwater discharge unit 350 and Groundwater (1) from which water vapor is separated through indirect contact of is circulated to the groundwater discharge unit (350). The hydrophobic separation membrane 320 separates water vapor contained in the groundwater 1 through the difference in temperature and partial pressure between the groundwater 1 and the air by indirectly contacting the groundwater 1 and the air stored in the membrane evaporation chamber 310. In addition, the hydrophobic separation membrane 320 has a plurality of pores formed on its surface so that the water vapor separated from the groundwater 1 through the separation process flows into the membrane evaporation chamber 310. These pores are preferably formed in a diameter and manner in which the water vapor flows out, but the liquid groundwater 1 does not flow out.

The air circulation unit 330 is connected to the air separation unit 500 through a pipe, and circulates the air separated from the concentrated water and discharged by the air separation unit 500 to be introduced into the film evaporation chamber 310. The air circulation unit 330 introduces air into the membrane evaporation chamber 310 to provide flow to the water vapor flowing out of the hydrophobic separation membrane 320 into the membrane evaporation chamber 310. According to the flow, water vapor circulates from the film evaporation chamber 310 to the cooling unit 400. As such, the air circulation unit 330 is preferably provided as a fan for air circulation. Furthermore, the air circulation unit 330 is connected through a separate pipe with an air injection device (not shown) as well as the air separation unit 500 to circulate the air injected from the air injection device (not shown) to evaporate the film. It may also be introduced into the chamber 310.

The groundwater inlet 340 is installed on one side of the membrane evaporation chamber 310 and is connected to one side of the hydrophobic separation membrane 320 to introduce the groundwater 1 into the hydrophobic separation membrane 320. It is preferable that the groundwater inlet 340 is connected to the groundwater storage unit 100 and the hydrophobic separator 320 through a pipe for inflow of groundwater.

The groundwater discharge unit 350 is installed on the other side of the membrane evaporation chamber 310 and is connected to the other side of the hydrophobic separation membrane 320 to indirectly contact the air to discharge the groundwater 1 from which water vapor is separated. The groundwater discharge unit 350 is connected to the groundwater storage unit 100 and the hydrophobic separator 320 through a pipe to discharge the groundwater 1 from which water vapor is separated to the groundwater storage unit 100. In addition, the groundwater discharge unit 350 may be connected to a water treatment device (not shown) through a separate pipe different from a pipe connected to the groundwater storage unit 100, and the groundwater 1 from which the water vapor is separated is a water treatment device (not shown). ) Can be discharged. Here, the water treatment device (not shown) refers to a device that treats the groundwater 1 from which steam is separated.

The cooling unit 400 is configured to cool the steam discharged from the film evaporation chamber 310 and includes a water block 410 and a cooler 420.

The water block 410 is installed on one side of the cooler 420, and when the cooler 420 generates heat while cooling water vapor, the cooler 420 is cooled by moving the heat of the cooler 420 to the cooling water stored therein. do.

The cooler 420 is connected to the film evaporation chamber 310 through a pipe, so that water vapor discharged from the film evaporation chamber 310 flows in, and cools the introduced water vapor through a cooling member. The cooler 420 is provided with at least one of an air-cooled cooler equipped with a heat sink, a water cooled cooler, a thermoelectric cooler equipped with a thermoelectric element, and a vortex cooler using compressed air. And when the cooler 420 is provided as an air-cooled cooler, the cooling member will be a heat sink, and in the case of a water-cooled cooler, the cooling member will be cooling water, and in the case of a thermoelectric cooler, the cooling member will be a thermoelectric element, and it is a vortex cooler. In this case, it would be desirable for the cooling member to be a vortex tube.

The results of the performance test of the cooler 420 were derived as shown in the graph of FIG. 2. Flux indicated in this graph is the cooling flow rate, and PR (Performance ratio) indicates the performance ratio of the film evaporation system, which means the ratio of the amount of fresh water (kg) that can produce 2.326 kJ of thermal energy in the film evaporation system, which is a thermal process. As a result of the performance test of the cooler 420, it was calculated that the heat sink (FAN in the graph), one of the cooling members, produces a cooling efficiency of 3.6kg/m ² hfh. It is calculated that the heat sink and the thermoelectric element (FAN+TEM in the graph), which is another type of cooler, and the commercially available refrigerator (Chiller in the graph), in turn produce cooling efficiency of 3.4kg/m ² hfh and 3.5kg/m ² hfh. Became. Accordingly, the cooler 420 according to an embodiment of the present invention may be provided as a heat sink-based air-cooled cooler having excellent cooling efficiency among cooling members through performance tests.

In addition, in an embodiment of the present invention, the cooler 420 may be provided with a vortex cooler using a vortex tube as a cooling member, as shown in FIG. 3. Looking specifically at the vortex cooler 420 according to an embodiment, the vortex cooler 420 cools the steam discharged from the film evaporation chamber 310 using a compressor (not shown) to generate concentrated water. At this time, the compressed air may be compressed to 3-10kg/cm² through a compressor (not shown). In addition, compressed air is introduced into the vortex rotation chamber 423 through the inlet pipe 421, and the vortex rotation chamber 423 rotates at super high speed. In addition, the rotating air 422 of the primary vortex rotated at high speed is directed to one side and only partially discharged to the outside through the first outlet 427 by the control valve 425 provided on one side of the cooler 420. Here, the rotating air 422 discharged through the first outlet 427 may be hot air of 100° C. or higher, and may be used to heat the groundwater 1 or the concentrated water 2 to be described later. Meanwhile, the remaining rotary air 428 not discharged through the first discharge port 427 forms a secondary vortex. In addition, the rotational air 428 of the secondary vortex loses heat while passing through a region of lower pressure inside the flow of the rotational air 422 of the primary vortex, and is directed toward the other side of the cooler 420. It is discharged to the outside through the provided second discharge port 429. Here, the rotating air 428 discharged to the second outlet 429 may be cold air of about -40°C, and one of the concentrated water 2 to be described later or the apparatuses 300, 400, 410 of the membrane evaporation system It can be used to cool the above devices.

That is, the cooler 420 of one embodiment is provided with a vortex cooler using a vortex tube as a cooling member, so as to cool the water vapor discharged from the film evaporation chamber 310, as well as to have a heating function, groundwater (1) or to be described later. It has the effect of heating the concentrated water (2) to be used. In the vortex cooler 420 of this embodiment, the temperature drop (rise) of the compressed air varies depending on the cooling ratio (%), the supply pressure, and the temperature of the supply air.

Meanwhile, the cooler 420 is configured to further include an air supply unit 430 that supplies cooling air to the cooling member according to the type of cooler.

It is preferable that the air supply unit 430 is provided with a cooling fan that supplies cooling air for cooling the cooling member. Such a cooling fan cools a heat sink or a thermoelectric element as a cooling member by supplying cooling air to a cooling member of an air-cooled cooler or a thermoelectric element cooler. Alternatively, when the cooler 420 is a vortex cooler, the air supply unit 430 may be used as a device for supplying compressed air to the vortex, which is a cooling member.

The air separation unit 500 is configured to separate air from the concentrated water 2 generated while the cooler 420 cools water vapor, and includes a water trap 510 and a storage chamber 520.

The water trap 510 is connected to the cooler 420 through a pipe so that the concentrated water 2 is introduced from the cooler 420, and a separating member 515 for separating the concentrated water 2 and the air contained in the concentrated water. ) Is installed inside. Here, the separating member 515 refers to a member that separates the concentrated water 2 and air, and circulates the separated concentrated water 2 and air in different configurations. Is not limited to. The water trap 510 discharges the concentrated water from which air is separated into the storage chamber 520, and connects the air separated from the concentrated water 2 to the membrane evaporation chamber 310 in which the air circulation unit 330 is installed. Discharge into the tube. Accordingly, the air discharged from the water trap 510 is introduced into the film evaporation chamber 310 through the air circulation unit 330 to give flow to the water vapor remaining in the film evaporation chamber 310.

The storage chamber 520 is installed on one side of the water trap 510 to allow the concentrated water 2 from which air is separated from the water trap 510 to flow in, and stores the introduced concentrated water 2. In addition, the storage chamber 520 may be connected to the drinking water production device (not shown) through a separate tube, and the stored concentrated water 2 may be discharged to the drinking water production device (not shown) through the tube. Here, the drinking water production device (not shown) refers to a device that treats concentrated water flowing from the storage chamber 520 to produce drinking water.

The above description of the present invention is for illustrative purposes only, and those of ordinary skill in the art to which the present invention pertains will be able to understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

1: groundwater,
2: concentrated water,
100: groundwater storage,
200: pump part,
300: water vapor separation unit,
310: film evaporation chamber,
320: hydrophobic separator,
330: air circulation unit,
340: groundwater inlet,
350: groundwater discharge unit,
400: cooling unit,
410: water block,
420: cooler,
430: cooling air supply,
500: air separation unit,
510: water trap,
515: separating member,
520: storage chamber.

Claims (8)

Groundwater storage unit 100 in which high-temperature and high-salt groundwater 1 is introduced and stored;
The groundwater (1) is introduced from the groundwater storage unit (100), and the groundwater (1) is indirectly contacted with air, and the groundwater (1) using the difference in temperature and partial pressure between the groundwater (1) and the air ( A steam separation unit 300 for separating the steam contained in 1);
A cooling unit 400 to which the steam is introduced from the steam separation unit 300 and cools the introduced steam; And
Concentrated water 2 generated by condensation by cooling of the steam from the cooling unit 400 is introduced, and the air contained in the concentrated water 2 is separated and discharged to the outside, and the air is separated The side water (2) is a membrane evaporation system for treating high-temperature, high-salt groundwater, comprising: an air separation unit 500 that blocks and stores discharge. The method of claim 1,
The water vapor separation unit 300,
A film evaporation chamber 310 for storing the air and allowing water vapor separated from the groundwater 1 to flow into the cooling unit 400;
A groundwater inlet part 340 installed on one side of the membrane evaporation chamber 310 and connected to the groundwater storage part 100 and into which the groundwater 1 is introduced;
It is installed in the membrane evaporation chamber 310, one side is connected to the groundwater inlet 340 so that the groundwater 1 flows in, and the introduced groundwater 1 and the air in the membrane evaporation chamber 310 are A hydrophobic separation membrane (320) having a plurality of pores formed on the surface such that the water vapor separated from the groundwater (1) during the indirect contact flows into the membrane evaporation chamber (310);
A groundwater discharge unit 350 installed on the other side of the membrane evaporation chamber 310, connected to the other side of the hydrophobic separation membrane 320, and discharging the groundwater 1 from which the steam is separated to the outside; And
It is connected to the air separation unit 500 and circulates the air discharged from the air separation unit 500 so that it flows into the membrane evaporation chamber 310 to flow to the water vapor remaining in the membrane evaporation chamber 310. Giving air circulation unit 330; Membrane evaporation system for treatment of high-temperature, high-salt groundwater, comprising: a. The method of claim 1,
The cooling unit 400,
A cooler (420) connected to the steam separation unit (300) to allow the steam to flow therein, and to have a cooling member for cooling the introduced steam; And
A water block 410 installed on one side of the cooler 420 and for cooling the heated cooler 420 by moving heat of the cooler 420 generated while cooling the water vapor to the coolant stored therein; Membrane evaporation system for treatment of high-temperature, high-salt groundwater, comprising: a. The method of claim 3,
The cooler 420,
An air-cooled cooler equipped with a heat sink, a water-cooled cooler, a thermoelectric element cooler equipped with a thermoelectric element, and a vortex cooler using compressed air. The method of claim 3,
The cooling unit 400,
A film evaporation system for treating high-temperature and high-salt groundwater, comprising: a cooling air supply unit 430 supplying cooling air for cooling the cooling member to the cooling member. The method of claim 1,
The air separation unit 500,
A water trap connected to the cooling unit 400 to allow the concentrated water 2 to flow therein, and in which a separating member 515 for separating the concentrated water 2 and the air contained in the concentrated water 2 is installed (510); And
The water trap 510 is installed on one side, and the storage chamber 520 for storing the concentrated water 2 from which air is separated by the water trap 510; Film evaporation system for The method of claim 6,
The water trap 510,
Membrane evaporation system for treating high-temperature and high-salt groundwater, characterized in that the air separated from the concentrated water (2) is discharged to the steam separation unit (300). The method of claim 1,
A membrane evaporation system for treating high-temperature and high-salt groundwater, comprising: a pump unit 200 for guiding the groundwater 1 to circulate from the groundwater storage unit 100 to the steam separation unit 300.

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