KR20150012578A - Water Treatment Apparatus using Membrane Distillation Method - Google Patents

Abstract

The present invention relates to a membrane distillation water treatment device comprising a membrane distillation unit which has an inlet part installed on the upper part on a separation membrane to receive raw water and a treatment water part with at least one cooling channel installed on the lower part on the separation membrane to capture treated water; a solar heat vacuum pipe which is formed by penetrating one side of the inlet part and collects and delivers the solar heat to the raw water in the inlet part; and a floating body to surround the membrane distillation unit.

Description

[0001] The present invention relates to a membrane-distilling water treatment apparatus having a vacuum tube and a cooling channel,

The present invention relates to a water treatment apparatus using a membrane distillation technique among water treatment techniques.

Membrane Distillation is a process in which a phase change occurs on the surface of a hydrophobic polymer membrane and condensation and separation are performed by permeating the steam through the surface micropores of the membrane. As a result, a nonvolatile material or a substance having a relatively low volatility is separated and removed It can be used for the desalting process or for separating organic substances having high volatility in an aqueous solution.

Since the concept of membrane distillation was proposed in 1940, studies on membrane distillation have been conducted mainly in the United States, Europe, Japan and Australia. Recently, there is a trend to replace the membrane distillation separation process with a conventional evaporation or separation process using a reverse osmosis membrane.

At present, the evaporation method and the reverse osmosis method which are used in the pure water production and desalination processes require a lot of energy. In particular, since the reverse osmosis method is subjected to various stages of pretreatment before use due to contamination and fouling, In addition, since the pump operates at a high pressure, there is a problem that a large amount of electric energy, which is a pump power source, is used, which requires a large administrative cost.

On the other hand, membrane distillation is operated at a lower pressure than that of ultrafiltration and reverse osmosis using a porous membrane, and is separated by the difference in partial pressure of vapor pressure. Further, when the above-mentioned membrane distillation separation method is used, it is not necessary to use a filter or separation membrane that operates at high pressure without entrainment of a conventional distillation method in separating and removing nonvolatile substances such as salts.

Due to the advantages of this membrane distillation separation process, the desalination process using the membrane distillation method is emerging as one of the competitive methods in the production of drinking water all over the world because of the durability of low-cost utility and separator.

Membrane distillation utilizes a hydrophobic polymer membrane. The membrane or membrane (hydrophilic material) has a surface tension greater than that of the membrane, so that it can not pass through the membrane pore in the liquid state and is repelled on the surface of the membrane. At the pore inlet, the substance to be separated is phase-converted into a vapor phase, diffused and permeated into pores, and finally condensed and separated at the permeation side.

This membrane distillation method is carried out through a separator module composed of an influent side through which the influent solution passes through the separator and a treated water side where the separating material condenses and separates.

However, since the membrane distillation method necessarily uses the thermal energy to induce the difference in the vapor pressure between the influent side and the treated water side in spite of the advantages as described above, And there is a cost disadvantage compared to other water treatment methods due to the energy cost burden.

Generally, in the membrane distillation process, electric energy or fossil energy has been used as a heat energy source for heating raw water, and there is a problem that energy cost is high. However, after the raw water is heated from the outside, the raw water heated to the influent side of the membrane distillation module There is also a problem that heat loss occurs in the process of transferring the wafer.

In addition, a separate cooling device is used to cool the process water circulating through the treated water side of the membrane distillation module, which also requires a separate energy cost.

Thus, in the membrane distillation process, it is possible to substitute high-cost electric energy or fossil energy for ensuring thermal energy, and to minimize the loss of heat energy, thereby reducing the energy cost, while continuously heating the influent water and cooling the treated water To improve the water treatment performance.

The present invention relates to a membrane distillation apparatus capable of reducing the energy cost by minimizing the loss of heat energy while securing thermal energy in place of the use of high-cost electric energy or fossil energy in heating the incoming water during the membrane distillation process The purpose is to provide.

Still another object of the present invention is to provide a separate cooling apparatus and a membrane distillation apparatus which do not require energy consumption in cooling the process water.

The present invention relates to a membrane distillation water treatment apparatus, and more particularly, to a membrane distillation water treatment apparatus which comprises a separator and a treatment water side in which at least one cooling channel for collecting treated water is formed on an inflow water side, , A solar vacuum tube which is formed to penetrate one region of the influent water side and collects the solar heat and then transfers the heat to the raw water on the influent water side and a body surrounding the membrane distillation unit .

In the present invention, in order to improve the cooling efficiency of the treated water by the external raw water, the treated water side of the membrane distillation unit is characterized in that one or two or more cooling channels are formed such that external raw water can flow through the treated water side to be. By forming a cooling channel through which raw water can freely flow in the treated water side as described above, the cooling surface area on the treated water side can be remarkably increased, so that the steam passing through the separation membrane can be quickly cooled and condensed, The production amount can be improved. In the present invention, the cross-sectional shape of the cooling channel is not particularly limited, and may be any shape as long as it is a single closed curve such as a circle, a square, or a triangle.

In the membrane distillation water treatment apparatus according to the present invention, a raw water inflow hole for automatically introducing raw water into one area of the inflow water side may be formed. In some cases, the raw water inflow hole is combined with a pre- May be primarily filtered.

In the present invention, the type of the solar tube is not particularly limited, but a double vacuum glass tube type solar tube may be preferable, and a heat pipe type solar tube may be preferable in terms of heat transfer.

In one embodiment of the present invention, a reflector may be coupled to improve solar collecting efficiency. The shape of the reflection plate is not particularly limited, and a reflector having an appropriate shape may be used according to the shape and structure of the membrane distillation water treatment apparatus of the present invention. For example, it may be a flat plate or a curved reflecting plate.

The membrane distillation water treatment apparatus of the present invention includes a floating body surrounding the membrane distillation unit and is used in a floating form on the raw water of the raw water source. The influent water side of the membrane distillation unit is located above the water surface of the raw water And the incoming water in the inflow water side is heated by receiving the solar heat collected through the solar heating tube. Further, the treated water side of the membrane distillation unit is submerged below the water surface of the raw water, and the treated water in the treated water side is cooled by the cold raw water. Thereby, a vapor pressure difference due to a temperature difference occurs between the inflow side and the treated water side of the membrane distillation unit, and only the vapor in the raw water heated through the hydrophobic separation membrane located between the inflow water side and the process water side is selectively moved toward the process water side And the vapor moving toward the treated water is condensed by the cold treated water to become pure water.

According to the present invention, it is possible to minimize the heat loss by directly heating the raw water flowing into the influent water side of the membrane distillation water treatment apparatus, not directly from the outside of the membrane distillation unit but directly inside the influent water side of the membrane distillation unit, It is possible to remarkably reduce the energy cost for heating the influent water by using the solar energy without using the existing high-cost electric energy or fossil energy.

In addition, the membrane distillation water treatment apparatus of the present invention uses cold raw water as a cooling medium to cool treated water on the treated water side which is submerged below the water surface of the raw water due to the floating structure on the raw water, It is not necessary to use a device, and thus the energy cost for cooling the process water can be remarkably reduced. Particularly, according to the membrane distillation water treatment apparatus of the present invention, since the cooling channel is formed on the treated water side of the membrane distillation unit, the contact area with respect to the external raw water acting as the cooling medium on the treated water side can be widened, The outer raw water can pass through the inner surface of the treated water side, so that the treated water in the treated water side can be cooled faster and more uniformly, and thus the cooling efficiency of the treated water side by the outer raw water can be improved.

1 is a perspective view of a membrane distillation water treatment apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of a membrane distillation water treatment apparatus according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail.

The present invention relates to a membrane distillation water treatment apparatus, and more particularly, to a membrane distillation water treatment apparatus which comprises a separator and a treatment water side in which at least one cooling channel for collecting treated water is formed on an inflow water side, , A solar vacuum tube which is formed to penetrate one region of the influent water side and collects the solar heat and then transfers the heat to the raw water on the influent water side and a body surrounding the membrane distillation unit .

In the present invention, the shape of the membrane distillation unit is not particularly limited, and any structure may be employed as long as the structure is such that the inflow side is located at the upper part of the separation membrane and the treated water side is located at the lower part of the separation membrane. For example, a rectangular parallelepiped shape, a cylindrical shape, an octagonal columnar shape, or the like.

In the present invention, the influent water side is a part where raw water flows in from the outside of the structure of the membrane distillation unit, and the raw water introduced from the outside flows through the separating membrane through the separating membrane due to the difference in vapor pressure between the influent water side and the treated water side, . The difference in vapor pressure between the inflow water side and the treated water side is caused by the temperature difference and the temperature of the raw water in the inflow water side is relatively higher than the temperature of the treated water side space and the treated water. The temperature difference between the influent water side and the treated water side is not particularly limited, and the larger the temperature difference is, the larger the difference in the vapor pressure between the influent water side and the treated water side increases, and the flux of the treated water increases. The temperature difference between the influent side and the treated water side is preferably 20 to 60 캜, more preferably 35 to 45 캜. This is because when the temperature difference between the influent side and the treated water side is less than 20 ° C, the difference in the vapor pressure between the influent side and the treated water side is too small and the flux of the treated water is extremely small. When the temperature difference exceeds 60 ° C, In particular, when the incoming raw water is heated by using solar heat as in the present invention, the amount of solar energy required is large, so that the heating time is excessively long, and the average sunshine hours are short or average This is because water treatment performance may be difficult to achieve in areas with low solar radiation.

In the present invention, the raw water may be any water as long as pure water needs to be separated, for example, contaminated surface water, contaminated groundwater, and the like.

Further, in the membrane distillation unit of the present invention, the method of supplying the inflowing water on the influent water side is not particularly limited. For example, the user may directly supply the contaminated water to the influent water side by periodically pouring the water. However, since the membrane distillation water treatment apparatus of the present invention adopts a method of floating on the contaminated raw water, the method of periodically pouring the raw water by the user may be difficult or cumbersome depending on the situation. Therefore, in the membrane distillation unit of the present invention, it is most preferable that the raw water supply to the inflow water side is automatically performed. To this end, in one region of the influent water side of the membrane distillation unit of the present invention, It may be desirable to form the raw water inflow hole so that the external contaminated raw water automatically flows into the inflow water side.

In addition, the raw water inflow hole may be combined with a pretreatment filter capable of preliminarily pre-treating volumetric contaminants contained in the contaminated raw water flowing into the inflow water side. The preprocessing filter is not particularly limited in kind, and may be, for example, a mesh network. When the pretreatment filter is coupled to the raw water inflow hole, contaminants of the contaminated raw water can be pretreated in a primary process, so that the burden of pollution of the separation membrane in the membrane distillation unit can be reduced. As a result, And the management cost for replacement can be reduced.

In the membrane distillation unit of the present invention, the separation membrane is preferably a hydrophobic polymer separation membrane. The reason for using the hydrophobic polymer membrane as the separator is that the surface tension of the solvent or solute (hydrophilic material) is larger than the surface of the separator membrane, so that it can not pass through the membrane pore in the liquid state and is repelled at the surface of the separator membrane, The material to be separated is phase-converted into a vapor phase at the pore inlet, diffused and permeated into the pores, and finally condensed and separated at the treated water side. The hydrophobic polymer separation membrane may be any water-treated polymer having hydrophobic properties. Examples of the hydrophobic polymer separation membrane include polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), polysulfone, (PSF), polyether sulfone (PES), polyetherimide (PEI), polyimide (PI), polyethylene (PE), polypropylene , PA) can be selected and used.

In the membrane distillation unit of the present invention, the treated water is collected as pure water separated from the raw water through the separation membrane as a region where the steam passing through the separation membrane is condensed and separated. The treated water in the treated water side has a lower temperature than the raw water on the influent water side. The treated water collected on the treated water side can be collected and used as water for various purposes such as drinking water and domestic water. There is no particular method for collecting the treated water from the treated water side. For example, Alternatively, a separate pipe connected to an external water tank may be connected to one area of the treated water side for collection. Particularly, in the present invention, on the treated water side of the membrane distillation unit, in order to improve the cooling efficiency of the treated water by the external raw water, one or two or more cooling channels are formed such that external raw water can flow through the treated water side . As described above, by forming the cooling channel through which the raw water can freely flow in the treated water side, the cooling surface area on the treated water side can be remarkably increased, and the steam passing through the separation membrane can be quickly cooled and condensed, Can be increased. In the present invention, the cross-sectional shape of the cooling channel is not particularly limited, and may be any shape as long as it is a single closed curve such as a circle, a square, or a triangle.

In the film distillation water treatment apparatus according to the present invention, the solar heating tube is formed so as to penetrate through one region of the inflow water side, and collects the solar heat and transfers it to the raw water on the inflow water side. In general, the inside of the tube is in a vacuum state, the heat collecting plate is located inside the tube, the outside solar heat is collected, and the collected solar heat is insulated from the outside of the solar heat tube in a vacuum environment to maximize the solar heat collection efficiency can do. As the type of the solar tube, there is a single vacuum glass tube type or a double vacuum glass tube type. In the present invention, a double vacuum glass tube type is preferable. This is because the double vacuum glass tube type can perform heat treatment between the inner glass tube and the outer glass tube to minimize heat loss than a single vacuum glass tube type.

In the present invention, the type of the solar-heating tube is not particularly limited in the sorting by the heat transfer method. For example, a water tube type solar tube or a heat pipe type solar tube having a heat medium circulation tube inserted therein can be used . In the present invention, a heat pipe type solar heat tube may be preferable. Since the solar heat tube of the present invention is formed so as to penetrate through one region of the influent water side and transfers solar heat to the raw water on the influent water side after collecting the solar heat, The heat pipe type solar battery tube which can heat only the water around the separation membrane by moving only the heat energy around the separation membrane can efficiently utilize the energy. The heat pipe type solar heat tube of the present invention has a structure in which an absorption plate subjected to selective absorption treatment and a heat pipe filled with a working fluid are combined in a vacuum sealed glass tube, The heat pipe transfers the heat energy to the target site.

In the present invention, the shape and size of the solar battery tube are not particularly limited, and a solar battery tube having an appropriate shape and size can be used according to the external structure of the membrane distillation water treatment apparatus of the present invention. Generally, the shape of a solar vacuum tube is a rod shape.

In the present invention, the end portion of the solar-heating tube for transferring the solar heat to the target portion is in contact with the raw water on the influent water side through one region of the influent water side of the membrane distillation unit. The number of the solar- And it is possible to use an appropriate number of solar tube according to circumstances of the use area such as climate environment.

In the present invention, the solar-heating tube has a thermal conduction direction. It is preferable that the end portion of the solar-heating tube for transferring the solar heat to the target portion penetrates one region of the inflow water side in a state of being tilted toward the opposite direction of gravity, At least a horizontal state must be maintained for thermal conductivity. This is due to the property that the heat transfer medium in the solar tube is moved in the opposite direction of gravity when vaporized.

In the present invention, when a raw water inflow hole is formed on the influent water side of the membrane distillation unit, the region where the solar heat tube passes through the inflow side of the membrane distillation unit should not overlap with the raw water inflow hole, Or more. It is preferable that the region where the solar heat pipe passes through the inflow water side of the membrane distillation unit is equal to or lower than the water surface of the raw water filled in the inflow water side even when the raw water inflow hole is not formed in the membrane distillation unit. This is to allow the solar heat transfer end portion of the solar heat tube to contact the raw water in the influent water side to transfer the solar heat to the raw water.

The floating body in the present invention functions to float the membrane distillation water treatment apparatus of the present invention on the surface of raw water. The substance is not particularly specified in bonding position or shape, but may be attached, for example, in the form of being attached to the bottom of the solar heating tube and surrounding the membrane distillation unit. The present invention can control the degree to which the membrane distillation water treatment apparatus of the present invention is immersed in water by adjusting the bonding height of the above-mentioned subject. In the present invention, the attachment height of the subject is not particularly limited. However, when the raw water inflow hole is formed in one region of the inflow side of the membrane distillation unit, it is preferable that the height is equal to or higher than the height of the raw water inflow hole. This is because the raw water inflow hole of the membrane distillation water treatment apparatus of the present invention is exposed above the water surface of the raw water when the attachment height of the subject is lower than the height of the raw water inflow hole, so that the raw water is not automatically introduced into the inflow water side. However, the joining position of the main body may be any position as long as it does not hinder the automatic introduction of the raw water from the raw water inflow hole formed on the inflow side of the membrane distillation unit.

The material of the body is not particularly defined, and any material may be used as long as it is commonly used to float on the surface of the water.

In the present invention, a reflector may be coupled to one side of the substrate. The reflector functions to collect solar light toward the solar tube, and the condensing efficiency of sunlight can be improved in the present invention. The material of the reflector is not particularly limited, and may be, for example, aluminum. The shape of the reflection plate is not particularly limited, and any shape may be used. For example, it may be flat or curved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The above embodiments are merely examples for illustrating the present invention, and thus the scope of the present invention is not limited thereto.

1 is a perspective view of a membrane distillation water treatment apparatus according to an embodiment of the present invention. 1, the membrane distillation water treatment apparatus according to the present invention comprises a central membrane distillation unit 100, eight solar battery tubes (not shown) each penetrating through the side of the inflow side 110 of the membrane distillation unit 100 200), and a reflector (400) attached to the bottom of the solar-heating tube. The light collecting rate of the solar heating tube 200 can be increased by the reflection plate 400 and the heat collecting efficiency of the solar heating tube 200 can be improved. The treated water side 120 of the membrane distillation unit 100 is characterized in that a cooling channel 121 through which raw water acting as a cooling medium of the treated water side 120 flows can be formed.

FIG. 2 is a sectional view of a membrane distillation water treatment apparatus according to an embodiment of the present invention. FIG. 2 illustrates the structure of the present invention in more detail.

2, the membrane distillation unit 100 of the membrane distillation water treatment apparatus according to an embodiment of the present invention includes a separating membrane 130 for membrane distillation between the upper influent side 110 and the lower treated water 120 Is located. The inflow water side 110 is a space filled with external raw water. In the method of filling the inflow water side 110 with raw water, raw water may be directly poured by a user, and external raw water may be supplied through a separate pipe You can also drag and fill it.

2, a membrane distillation water treatment apparatus according to an embodiment of the present invention includes a solar battery 200 connected to the periphery of the inflow side 110 of the membrane distillation unit 100, Is connected to the side of the inflow water side 110 so as to pass through the side of the inflow water side 110 so that the solar heat energy collected through the solar heating tube 200 is transferred to the raw water in the inflow water side 110 to heat the inflow water.

2, a membrane distillation water treatment apparatus according to an embodiment of the present invention includes a body 300 to which a curved reflector 400 surrounding the membrane distillation unit 100 is attached, And the influent water 110 in the membrane distillation unit 100 is exposed on the water surface of the raw water and the influent water in the influent water side 110 flows into the solar heat pipe 200 through the solar heat pipe 200, And is heated. Further, the treated water side 120 of the membrane distillation unit 100 is submerged below the water surface of the raw water, so that the treated water in the treated water side 120 is cooled by the cold raw water. A difference in vapor pressure due to a temperature difference is generated between the inflow side 110 and the treated water side 120 of the membrane distillation unit 100 and a hydrophobic separation membrane 130 located between the inflow water side 110 and the treated water side 120 Only the vapor in the raw water heated through the heating water 120 is selectively moved toward the treated water side 120 and the vapor moved to the treated water side 120 is cooled and condensed by the external cold water, water.

Particularly, the treated water side 120 is formed with three cooling channels 121 through which raw water can freely flow, so that the contact area with respect to the external raw water serving as the cooling medium of the treated water side 120 And the outer raw water can pass through the inner surface of the treated water side through the cooling channel 121. This makes it possible to cool the treated water in the treated water side 120 more quickly and uniformly. When the cooling efficiency of the treated water side 120 is improved as described above, the temperature difference between the incoming water in the influent water side 110 and the treated water in the treated water side 120 in the membrane distillation water treatment apparatus of the present invention, So that the difference in vapor pressure between the inflow water side 110 and the treated water side 120 can be maintained to be greater, and thus the vapor flux of the membrane distillation water treatment apparatus of the present invention can be improved.

As described above, those skilled in the art will understand that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It will be understood by those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention as defined by the appended claims and their equivalents. .

100: Membrane distillation unit 110: Inflow water side
120: Process water side 121: Cooling channel
130: separator 200: solar tube
300: floating body 400: reflector

Claims (7)

A membrane distillation unit including a treated water side located on an inflow water side where raw water flows in at an upper portion with a boundary of a separation membrane and in which at least one cooling channel for collecting treated water is formed;
A solar battery tube which is formed to penetrate through one region of the inflow water side and collects solar heat and then transfers heat to raw water on the inflow side; And
And a body surrounding the membrane distillation unit.
The method according to claim 1,
And a raw water inflow hole for automatically introducing raw water into one region of the inflow water side is formed.
3. The method of claim 2,
And a pretreatment filter is coupled to the raw water inflow hole.
The method according to claim 1,
Wherein the solar-heating tube is a double-vacuum glass-tube solar-type vacuum tube.
The method according to claim 1,
Wherein the solar-heating tube is a heat pipe type solar-heating tube.
The method according to claim 1,
And a reflector is coupled to one side of the body.
The method according to claim 6,
Wherein the reflection plate has a flat plate shape or a curved shape.

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