KR101572661B1 - Perforated flux pipe for pressure retarded osmosis module and pressure retarded osmosis module having it - Google Patents

Abstract

There is provided a porous drainage tube for pressure delayed osmosis and an osmosis module including the same. The porous outlet pipe for osmosis pressure relief according to an embodiment of the present invention is a porous outlet pipe for winding a plurality of separation membranes in a circumferential direction on an outer surface in a spiral wound form, A hollow tube having a first through hole and a second through hole; And at least one partition wall which is disposed along the longitudinal direction inside the hollow tube and divides the inside of the hollow tube into a first flow path, a second flow path and a third flow path so that different fluids can flow without being mixed with each other The first fluid flows through the first flow path to the inside of the separation membrane through the first through hole and the second fluid flows from the second flow path to the outside of the separation membrane, The second fluid diluted by the osmotic action with the first fluid flows.

Description

TECHNICAL FIELD [0001] The present invention relates to a porous drainage pipe for pressure-delayed osmosis and a pressure-delayed osmosis module including the same.

The present invention relates to a porous drainage pipe for osmosis and an osmosis module including the osmosis porous drainage pipe. More particularly, the present invention relates to a porous drainage pipe for osmosis, The present invention relates to a porous drainage pipe for pressure-delayed osmosis and a pressure-delayed osmosis module including the same, which can prevent the performance of the pressure-delayed osmosis membrane (PRO) from being deteriorated even when a plurality of modules are connected in series.

If a semi-permeable membrane that transmits water but does not substantially permeate the solute (ions and molecules) dissolved in water is installed between the high concentration solution and the low concentration solution, the solvent of the low concentration solution moves to the high concentration solution to achieve the concentration equilibrium Natural phenomena occur and are called "osmotic" or "osmotic phenomena". The osmotic phenomenon was discovered by German chemist M. Traube in 1867, and the osmotic pressure caused by osmosis was first measured by Pepper in 1877.

Such osmotic phenomena are the core of desalination technology using seawater, which is one of the ways to solve the serious water shortage due to climate change due to global warming, increase in industrial use due to industrialization, and increase in water demand due to population increase.

However, the seawater desalination process up to now is a highly energy-intensive process and still has economic limitations unless it is a water-scarce region like the Middle East.

Methods for removing salts in seawater can be roughly divided into evaporation and reverse osmosis.

In the FO method, the membrane is separated by moving the low concentration solution toward the high concentration solution. Since the natural osmosis membrane phenomenon is utilized, no additional pressure is required, so that the reverse osmosis membrane It is economical. Therefore, researches on the development of the osmosis membrane have been actively carried out recently. The reverse osmosis method and the reverse osmosis method, which is a concept opposite to that of the reverse osmosis method, are included in the osmosis membrane and osmosis module, There is a distinction that is different from that used for reverse osmosis. Therefore, it is difficult to apply the membranes, outflow tubes and the like to the reverse osmosis membrane.

On the other hand, osmotic power generation refers to the production of power using the osmotic action at the point where the two flows with the salinity difference meet, and the 27 bar osmotic pressure at the point where the sea water having the osmotic pressure of 27 bar meets the river having the osmotic pressure close to zero Can be used for power generation.

The power generation uses a pressure delayed osmosis (PRO) mode. If the pressure is applied to the seawater at a higher pressure than the osmotic pressure by using the pressure delay osmosis method, the flux of the water permeating the membrane by the osmotic pressure is reduced, and the osmotic pressure is changed to the water pressure. It will produce.

The pressure-delayed osmosis is different from that used in the reverse osmosis method in that the membrane used for the pressure delay osmosis method and the outlet pipe used in the reverse osmosis method are applied to the raw water because the pressure applied to the raw water is lower than that of the reverse osmosis method, Therefore, it is difficult to apply the separation membrane and the outflow pipe applied to the pressure delay osmosis method to the reverse osmosis membrane.

As described above, the positive osmosis method and the pressure delay osmosis method do not apply pressure to the raw water (positive osmosis method) unlike reverse osmosis or apply a pressure lower than the osmotic pressure to the raw water (pressure delay osmosis method) Tubes are distinguished from outlet tubes used in reverse osmosis systems that must withstand high pressures.

Accordingly, there is a problem that the outflow pipe used in the reverse osmosis system designed to have the pressure resistance against high pressure can not be equally used in the forward osmosis or the pressure delay osmosis system. In the conventional outflow pipe 1 Is a structure in which the inflow fluid is osmotic to the fluid flowing between the separators after the flow path is changed by the diaphragm 3 and discharged to the separator side through the outlet hole 2 as shown in Fig. Accordingly, when a plurality of modules are connected in series, the fluid flowing between the separating membranes is gradually diluted by the osmotic action with the fluid flowing in the separating membrane, so that the osmotic gradient is not smooth.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a multi- And a pressure-delayed osmosis membrane module including the porous drainage tube for pressure-delayed osmosis that can prevent the performance of the pressure-delayed osmosis membrane (PRO) from being deteriorated even when the modules are connected in series.

According to an aspect of the present invention, there is provided a porous outflow tube having a plurality of separation membranes wound in a circumferential direction on an outer surface thereof, the porous outflow tube having a first through hole formed in a longitudinal direction thereof, A hollow tube having a hole; And at least one partition wall which is disposed along the longitudinal direction inside the hollow tube and divides the inside of the hollow tube into a first flow path, a second flow path and a third flow path so that different fluids can flow without being mixed with each other The first fluid flows through the first flow path to the inside of the separation membrane through the first through hole and the second fluid flows from the second flow path to the outside of the separation membrane, Wherein the second fluid diluted by the osmotic action with the first fluid is flowed.

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Preferably, the first through-hole and the second through-hole may be communicated with the first flow path.

Preferably, the hollow tube has a diaphragm in the middle of the length of the first flow path, and the first flow path is divided into a first portion in which the first through-hole is disposed and a second portion in which the second through- The flow path of the first fluid can be changed.

Preferably, the hollow tube may be formed with at least one third through-hole communicating with the second flow path so that the second fluid can be supplied from the second flow path to the outer side of the separation membrane.

Preferably, the one end of the hollow tube is provided with a shielding plate having a predetermined area so as to prevent the second fluid diluted by the osmotic action of the first fluid flowing through the separating membrane from flowing out to the outside, And may be arranged in a direction perpendicular to the flow direction of the second fluid.

Preferably, at least one outlet hole is formed in the blocking plate so that the diluted second fluid can be discharged to the outside through the outlet hole.

Preferably, the hollow tube has an inlet communicating with the third flow path at one side thereof, and the inlet may be connected to the outlet hole of the porous outlet tube for pressure delay osmosis disposed adjacent to the front side.

Preferably, a distal end of the hollow tube may be selectively provided with a first obstruction plate for blocking the inflow of the first fluid and the second fluid into the third flow path.

Preferably, a second blocking plate for blocking the second fluid flowing along the second flow path from flowing out to the outside may be selectively provided at a rear end of the hollow tube.

Preferably, the plurality of porous outflow tubes for pressure-delayed osmosis are provided, and the hollow tubes adjacent to each other have a first flow path, a second flow path, and a third flow path, And may be connected in series so as to be connected to each other.

The barrier rib may include a first barrier rib, a second barrier rib, and a third barrier rib extending from a center of the hollow tube to an inner surface of the hollow tube.

Preferably, the first bank, the second bank, and the third bank may be arranged to have an isometric angle.

Preferably, the barrier ribs include first and second barrier ribs each of which is a plate-shaped member having a predetermined area.

The first partition and the second partition may be spaced apart from each other such that the first partition and the second partition are parallel to a virtual plane passing the center point of the hollow tube.

The present invention also relates to a porous drainage tube for pressure delayed osmosis; A plurality of separation membranes wound around the outer circumferential surface of the porous outflow tube in a spiral shape along the circumferential direction; And an outer case into which the outflow pipe and the separation membrane are inserted.

According to the present invention, the partition wall is disposed along the longitudinal direction in the central pipe to form three flow paths in which different fluids do not flow, so that the induction solution is continuously supplied to the separation membrane side, so that even if a plurality of modules are connected in series, It is possible to maintain the performance of the pressure delay osmosis membrane (PRO) by preventing it from being diluted.

1 is a schematic view showing a conventional porous drainage tube for osmosis.
2 is an overall perspective view of a porous outflow tube for pressure delay osmosis according to a first embodiment of the present invention.
Figure 3 is a partial cutaway view of Figure 2;
4 is a cross-sectional view conceptually showing a state in which a porous outlet pipe for pressure delay osmosis is connected in series according to the present invention.
5 is a conceptual view showing a flow path of the fluid in FIG.
FIG. 6 is a view showing a displacement relationship of partition walls in a porous outlet tube for pressure delay osmosis according to the present invention. FIG.
FIG. 7 is a longitudinal sectional view of an osmosis module to which a porous outflow pipe for pressure delay osmosis according to the present invention is applied.
8 is a partial cutaway perspective view of Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

In order to facilitate understanding of the present invention, the same reference numerals will be used to denote the same constituent elements even if they are shown in different drawings.

In addition, although the cross-sectional views of the porous outflow tubes 100, 100 ', 100 "for pressure-delayed osmosis shown in FIGS. 4 and 5 are shown as being sequentially arranged from above to downward for convenience of explanation, It should be understood that the flow paths 111, 112 and 113 do not communicate with each other but form independent flow paths. It should be understood that the three flow paths are not limited to being sequentially stacked from the top to the bottom.

2 to 8, the porous outflow tubes 100, 100 ', 100 "for pressure-delayed osmosis according to the preferred embodiment of the present invention include partition walls 120 along the longitudinal direction inside the hollow tube 110 And the induction solution is continuously supplied to the separation membrane 30 side by forming three flow paths 111, 112, and 113 in which different fluids do not mix, and the performance of the pressure delay osmosis membrane (PRO) deteriorates even when a plurality of modules are connected in series. It is a technical feature that it is possible to prevent it from becoming.

The porous outflow tubes 100, 100 ', 100 "for osmosis according to the present invention include a hollow tube 110 and a partition 120.

7 and 8, the hollow tube 110 is installed so as to cross the center portion along the longitudinal direction of the osmosis module 10, and the fluid introduced from the outside is transferred along the longitudinal direction, To the side of the separating membrane (30) which surrounds the membrane (30).

The hollow tube 110 is provided with a hollow tube member having a predetermined length and includes a plurality of first through holes 115 and second through holes 116 formed on the outer circumferential surface of the hollow tube 110, So that it can be opened and closed.

At this time, the hollow tube 110 is partitioned into the first flow path 111, the second flow path 112 and the third flow path 113 through at least one partition 120 disposed along the longitudinal direction. do.

Accordingly, the porous drainage pipes 100, 100 ', 100 "for pressure-delayed osmosis according to the present invention allow the three different fluids to independently flow along the three flow paths 111, 112, 113 without being mixed with each other.

Here, the first flow path 111 flows through the first through hole 115 and the first fluid A flows into the separation membrane 30, and the second flow path 112 flows through the separation membrane 30, The second fluid B supplied to the outer side of the first fluid A flows and the second fluid B 'diluted by the osmotic action of the first fluid A flows through the third flow path 113.

At this time, a diaphragm 130 is disposed in the middle of the first flow path 111 to change the flow path of the first fluid A flowing into the first flow path 111 side. That is, the first through-hole 115 and the second through-hole 116 are formed at one side of the hollow tube 110 so as to communicate with the first flow path 111, A first portion 111a in which a first through hole 115 is formed and a second portion 111b in which the second through hole 116 is formed are defined with the partition 130 as a boundary.

The first through-hole 115 and the second through-hole 116 are formed so that the first fluid introduced into the first flow path 111 flows out of the first flow path 111, And the flow path of the fluid in the first through hole 115 and the flow direction of the fluid in the second through hole 116 serve as passages for flowing the fluid from the separator 30 to the inside of the first flow path 111, The flow direction of the fluid is opposite to each other.

For example, the first fluid A flowing along the first flow path 111 flows out to the outside only through the first through-hole 115 and flows into the separation membrane 30, more specifically, the separation membrane 30 And the first fluid A flowing into the first flow path 111 from the inside of the separation membrane 30 flows into the first flow path 111 only through the second through hole 116. [

Specifically, the first fluid A flowing into the tip of the first flow path 111 is blocked by a flow path of the fluid by the partition 130 and flows out through the first through hole 115 Thereby allowing a larger amount of fluid to flow toward the separator 30 side. Accordingly, it is possible to increase the amount of the fluid flowing to the separator 30 surrounding the outer surface of the hollow tube 110.

Here, the partition 130 is provided to have an appropriate thickness to withstand the pressure of the fluid flowing along the inside of the first flow path 111, and an epoxy hardening agent can be used, but is usually used for a porous outlet tube for pressure- The material of the diaphragm can be used without limitation, and materials such as silicon and rubber can also be used.

Although the diaphragm 130 is illustrated as being located at a half of the entire length of the first flow path 111, the present invention is not limited to this, / 3, and 1/4 point, respectively.

The second flow path 112 serves as a passage through which the second fluid B flowing through the front end flows. For this purpose, the hollow tube 110 is provided with at least one third through hole 117 communicating with the second flow path 112. The second fluid B flowing through the tip of the second flow path 112 flows out to the outside through the third through hole 117 and is supplied to the plurality of the separation membranes 30. Accordingly, the porous drainage pipes 100, 100 ', 100 "for pressure-delayed osmosis according to the present invention allow the second fluid B flowing along the second flow path 112 to flow through the third through holes 117 Even if a plurality of modules are connected in series by being continuously supplied to the outer side of the separation membrane 30, the second fluid B can be smoothly permeated with the first fluid A flowing in the separation membrane 30 do.

In the case where a plurality of porous outflow pipes 100, 100 ', 100 "for pressure-delayed osmosis according to the present invention are provided and connected in series, the porous outflow pipe 100" A second blocking plate 119 for blocking the second fluid B flowing along the flow path 112 from flowing out to the outside may be additionally provided.

The third flow path 113 is connected to the first fluid A flowing into the separator 30 through the first through hole 115 and the third through hole 117 from the second flow path 112 The second fluid B 'diluted by the osmotic action of the second fluid B supplied to the outside of the separation membrane 30 or the second fluid B supplied directly to the outside of the separation membrane 30 from the outside And serves as a flow passage.

In this case, the porous drainage pipe 100, 100 ', 100 "for pressure-relief osmosis according to the present invention includes a plate-shaped blocking plate 140 having a predetermined area at one end of the hollow tube 110, The second fluid B 'diluted by the osmotic action with the first fluid A is prevented from flowing out to the outside of the diluted second fluid B' And at least one outflow hole 142 is formed at one side thereof so that the diluted second fluid B 'can be discharged to the outside only through the outflow hole 142 do.

In addition, a separate inlet 114 communicating with the third flow path 113 is provided at one side of the hollow tube 110 so that when a plurality of modules are connected in series to each other, the inlet 114 is connected to a pressure delay And is connected to the outflow hole 142 of the osmotic porous outlet pipe 100 '. Accordingly, the second fluid B 'diluted by the osmotic action with the first fluid A is collected by the blocking plate 140 at the rear end of the osmotic module 10, Is moved to the third flow path (113) side of the porous outflow pipe (100) for pressure-delayed osmosis which is connected adjacently through the inlet (114) connected to the first outlet (142).

Here, when the plurality of pressure relief osmosis porous outflow pipes 100, 100 ', 100 "are connected in series to each other, a tip end of the porous outflow pipe 100' A first blocking plate 118 for blocking the introduction of the first fluid A and the second fluid B is provided.

However, the present invention is not limited thereto. The cap may be attached to the cap coupled to the end of the conventional osmotic module, It is also possible to provide them integrally.

4 and 5, when the plurality of porous outflow pipes 100, 100 ', 100 "for pressure-relief osmosis according to the present invention are connected to each other in series, the first flow paths 111 are connected to the first flow paths 111 The second flow path 112 is connected to the second flow path 112 and the third flow path 113 is connected to the third flow path 113. In addition, the porous outflow pipes 100, 100 ', 100' Is connected to the inlet 114 provided in the porous outlet pipes 100, 100 ', and 100 " disposed adjacent to each other.

The first fluid A and the second fluid B supplied from the outside are introduced into the first flow path 111 and the second flow path 112 of the porous outflow pipe 100 ' do. The first fluid A is then transferred to the interior of the separation membrane 30 through the first through hole 115 and a portion of the second fluid B flowing into the second flow path 112 is discharged 3 through-holes 117 and the remainder is directly moved to the second flow path 112 side of the porous outflow pipe 100 connected to the rear side. The second fluid B supplied to the outside of the separation membrane 30 through the third through hole 117 is diluted by the osmotic action with the first fluid A and collected through the blocking plate 140 Flows into the third flow path (113) side of the porous outflow pipe (100) connected adjacent via the outflow hole (142).

The first fluid A transferred to the inside of the separation membrane 30 flows through the second through hole 116 after the osmotic action with the second fluid B flowing outside the separation membrane 30 occurs, And is directly transferred to the first flow path 111 side of the porous outflow pipe 100 arranged adjacent to the first flow path 111. [

Next, the porous outlet pipe 100 disposed second from the firstmost end is also subjected to the same process as that of the porous outlet pipe 100 'disposed at the first stage. That is, the first fluid A directly moved from the first flow path 111 of the first porous outflow pipe 100 'to the first flow path 111 of the second porous outflow pipe 100 flows through the first through holes 115 And the second fluid flowing directly into the second flow path 112 of the second porous outflow pipe 100 from the second flow path 112 of the first porous outflow pipe 100 ' A part of the porous material B is supplied to the outside of the separation membrane 30 through the third through hole 117 and the remainder is directly transferred to the second flow path 112 side of the third porous outflow pipe 100 " The second fluid B supplied to the outside of the separation membrane 30 through the third through hole 117 is diluted by the osmotic action with the first fluid A and collected through the blocking plate 140, To the third flow path 113 side of the third porous outflow pipe 100 ".

As described above, even when a plurality of porous outflow pipes 100, 100 ', 100 "for pressure-relief osmosis according to the present invention are connected in series to each other, the undiluted second fluid B, which is not diluted always through the second flow path 112, The second fluid B flowing to the outside of the separator 30 is prevented from being used again in a diluted state by being continuously supplied to the outside of the separator 30 to maintain the performance of the pressure delay osmosis membrane PRO have.

In the meantime, in the porous outflow tubes 100, 100 ', 100 "for pressure-delayed osmosis according to the present invention, the partition 120 separating the inside of the hollow tube 110 into three flow paths 111, 112, 6, the barrier ribs 120a and 120b include first and second barrier ribs 121 and 121 extending from the center of the hollow tube 110 to the inner surface of the hollow tube 110, The first barrier rib 121, the second barrier rib 122 and the third barrier rib 123 may be formed to have an equiangular angle with respect to each other. (FIG. 6A) and may be arranged to have different angles (FIG. 6B). A center point where the first barrier rib 121, the second barrier rib 122, and the third barrier rib 123 are gathered Or may be provided so as not to coincide with the center point of the hollow tube 110 (Figure 6C)

In addition, the partition 120d may include a first partition 121 and a second partition 122, each of which is a plate-shaped member having a predetermined area, and may be parallel to a virtual plane passing the center of the hollow tube 110 (Fig. 6D)

The barrier ribs 120e and 120f may include a first barrier rib 121 and a second barrier rib 122 formed of a plate-like member having a predetermined area. The first barrier rib 121 and the second rib 122 may be formed of, May be arranged so as not to be parallel to each other (Figs. 6E and 6F)

That is, the first barrier ribs 121 and the second barrier ribs 122 may be arranged so that one ends of the first barrier ribs 121 and the second barrier ribs 122 overlap with each other (FIG. 6E)

Here, it is to be understood that the various forms of the partition 120 shown in FIG. 6 are not limited to the exemplary embodiments in order to understand the invention, but may be provided in various forms including curved lines, which are not straight lines.

As shown in FIGS. 7 and 8, the porous outflow tubes 100, 100 ', 100' 'for pressure-relief osmosis according to the present invention include a plurality of separation membranes 30 wound in a circumferential direction on the outer circumferential surface, Delayed osmosis module 10 is provided with a separate outer case 20 for accommodating the ozone depleted osmosis membrane 10. One end of the porous outlet osmosis tubes 100, 100 ', 100 " A blocking plate 140 is provided to block the second fluid B 'from flowing out to the outside. The blocking plate 140 has an area covering all the ends of the plurality of the separation membranes 30 Respectively. In addition, the blocking plate 140 is hermetically coupled to one end of the outer case 20.

Here, the ozone layer for pressure delay may be used as the separation membrane 30, and the two separation membranes are stacked to form a pocket shape, so that a detailed description will be omitted. In addition, since the outer case 20 is also used in the pressure-delayed osmosis module, a detailed description thereof will be omitted.

While the foregoing is directed in detail to a particular embodiment of the invention with reference to the drawings, it is not intended to limit the invention to this specific construction. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It is to be expressly understood, however, that equivalents, modifications and substitutions through such simple design variations or modifications are expressly included within the scope of the present invention.

10: Osmosis module 20: External case
30: Membrane
100, 100 ', 100 ": porous drainage pipe for pressure delay osmosis
110: hollow tube 111: first flow path
111a: first portion 111b: second portion
112: second flow channel 113: third flow channel
114: inlet port 115: first through hole
116: second through hole 117: third through hole
118: first blocking plate 119: second blocking plate
120, 120a, 120b, 120c, 120d, 120e, 120f:
121: first partition 122: second partition
123: third partition 130: diaphragm
140: blocking plate 142: outlet hole
A: first fluid B: second fluid
B ': diluted secondary fluid

Claims (16)

delete A porous outlet pipe in which a plurality of separation membranes are wound in a spiral shape along a circumferential direction on an outer surface,
A hollow tube having a first through-hole and a second through-hole formed at one side thereof in a longitudinal direction; And
And at least one partition wall which is disposed along the longitudinal direction inside the hollow tube and divides the inside of the hollow tube into a first flow path, a second flow path and a third flow path so that different fluids can flow without mixing
Wherein the first fluid flows through the first through hole and the second fluid flows from the second fluid to the outside of the separation membrane, And the second fluid diluted by the osmotic action with the first fluid flows. 3. The method of claim 2,
Wherein the first through-hole and the second through-hole are communicated with the first channel. The method of claim 3,
Wherein the hollow tube is divided into a first portion in which the first through-hole is disposed and a second portion in which the second through-hole is disposed, wherein the first passage is provided with a diaphragm in the middle of the length of the first flow path, Characterized in that the flow path of the fluid is changed. 3. The method of claim 2,
Wherein the hollow tube is formed with at least one third through-hole communicating with the second flow path so that the second fluid can be supplied from the second flow path to the outer side of the separation membrane. tube. 3. The method of claim 2,
A blocking plate having a predetermined area is provided at one end of the hollow tube so as to prevent the second fluid diluted by the osmotic action of the first fluid flowing through the separation membrane from flowing out to the outside, And is arranged in a direction perpendicular to the flow direction. The method according to claim 6,
Wherein at least one outflow hole is formed in the blocking plate so that the diluted second fluid flows out to the outside through the outflow hole. 8. The method of claim 7,
Characterized in that the hollow tube has an inlet communicating with the third flow path at one side thereof and the inlet port is connected to the outlet hole of the porous outlet tube for pressure delay osmosis arranged adjacent to the front side. Porous effluent tube. 3. The method of claim 2,
And a first blocking plate for selectively blocking the introduction of the first fluid and the second fluid into the third flow path is selectively provided at the distal end of the hollow tube. 3. The method of claim 2,
And a second blocking plate for selectively blocking the second fluid flowing along the second flow path from flowing out to the outside is selectively provided at a rear end of the hollow pipe. 3. The method of claim 2,
Wherein the plurality of porous outlet pipes for pressure-delayed osmosis are provided in plural, and the hollow pipes adjacent to each other are connected in series so that the first flow path is connected to the first flow paths, the second flow path is connected to the second flow paths, Wherein the porous drainage pipe is connected to the drain pipe. 3. The method of claim 2,
Wherein the partition wall comprises a first partition wall, a second partition wall and a third partition wall extending from a center point of the hollow tube to an inner surface of the hollow tube. 13. The method of claim 12,
Wherein the first partition, the second partition, and the third partition are arranged to have an equi-angularity. 3. The method of claim 2,
Wherein the partition wall comprises a first partition and a second partition made of a plate-shaped member having a predetermined area. 15. The method of claim 14,
Wherein the first partition and the second partition are spaced apart from each other such that the first partition and the second partition are parallel to a virtual plane passing the center point of the hollow tube. A porous outlet tube for pressure delayed osmosis according to any one of claims 2 to 15;
A plurality of separation membranes wound around the outer circumferential surface of the porous outflow tube in a spiral shape along the circumferential direction; And
And an outer case into which the outlet pipe and the separation membrane are inserted.

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