JP2011255312A - Forward osmosis device and forward osmosis method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress a concentration polarization produced in a forward osmosis membrane and improve the membrane strength of the forward osmosis membrane in a forward osmosis device.SOLUTION: In the forward osmosis device, the forward osmosis membrane in which a semipermeable membrane is supported by a mesh is used. The forward osmosis device satisfies all of formula (1) Z≤0.09 X/Y, formula (2) X≤1,000, and formula (3) Y≤500 (wherein X represents the thickness (nm) of the semipermeable membrane, Y represents the pore diameter (μm) of the mesh, and Z represents the intermembrane pressure Z(MPa) of the forward osmosis membrane).

Description

  The present invention relates to a forward osmosis method (FO method) and a forward osmosis device (FO device) capable of performing separation and / or concentration by the FO method.

  Water shortages are a serious problem in dry and densely populated areas around the world. Thus, there is a need for seawater treatment technology that removes salt from seawater.

As a seawater treatment technique, a membrane treatment method is known, and a semipermeable membrane is usually used in the membrane treatment method. The semipermeable membrane is known as a membrane that allows only molecules and ions having a specific size or less to permeate. For example, the semipermeable membrane is a membrane that allows water in seawater to permeate but does not permeate salt. When two kinds of solutions having different solute concentrations are brought into contact with each other across the semipermeable membrane, an osmotic pressure difference is generated between the two solutions, and the solvent of the solution having the lower solute concentration, that is, the lower osmotic pressure side, is It penetrates to the higher solute concentration side, that is, the higher osmotic pressure side. This osmosis phenomenon theoretically continues until the osmotic pressure difference becomes zero. For example, when seawater and water are brought into contact with each other across a semipermeable membrane, the water permeates into the seawater and tries to form an equilibrium state.
As membrane treatment methods using such a semipermeable membrane, a reverse osmosis method (RO method) and a forward osmosis method (FO method) are known.

  The RO method is a technique in which low molecular components such as water are permeated in reverse from a high osmotic pressure side to a low osmotic pressure side. In order to cause such reverse osmosis, in the RO method, a high pressure exceeding the osmotic pressure difference between the two solutions is applied to the side where the osmotic pressure is high. For example, when separating water from seawater, seawater and water are brought into contact with each other across a semipermeable membrane, and the seawater side is subjected to a pressure exceeding the osmotic pressure difference, usually far above the osmotic pressure difference. Apply and allow water in seawater to permeate into the water side.

On the other hand, as disclosed in Patent Document 1 and Patent Document 2, the FO method artificially creates an osmotic pressure difference between two types of solutions using a draw solution having a high osmotic pressure. This is a method of causing the solvent to move. Specifically, a feed solution (feed solution) that is a raw material solution and a draw solution having an osmotic pressure higher than that of the feed solution are brought into contact with each other across a semipermeable membrane. If it does so, the solvent of a feed solution osmose | permeates the draw solution side by the osmotic pressure difference of both solutions. Thereafter, the solvent of the feed solution is collected by volatilizing and collecting the solute components in the draw solution. Conversely, a concentrated feed solution may be collected.
Below, an example in the case of isolate | separating water from seawater is demonstrated according to FIG.
FIG. 1 shows an example of a seawater treatment apparatus using the FO method, where solid arrows indicate the flow of water 11 separated from seawater or seawater, and dotted lines indicate the draw solution or the solute 12 of the draw solution. Each flow is shown. First, the seawater 11 and the draw solution 12 come into contact with each other through the semipermeable membrane 13. Water in the seawater 11 permeates the draw solution 12 side through the semipermeable membrane 13. Then, in the distillation tower 14, the solute component of the draw solution is volatilized from the draw solution diluted with seawater water, thereby separating the water 16 and the solute component 15 of the draw solution. The solute component 15 of the draw solution is gasified by obtaining the gas absorber 17, and then dissolved in the diluted draw solution and reused as the draw solution 12. Reference numeral 18 denotes a pressure gauge.

Thus, the RO method and the FO method are common in that a semipermeable membrane is used, but their mechanisms are completely different. Therefore, the functions required for the reverse osmosis membrane (RO membrane) used in the RO method and the forward osmosis membrane (FO membrane) used in the FO method are also greatly different.
As for the semipermeable membrane portion, the thinner the film thickness, the higher the water permeation rate. In order to achieve a practical permeation rate, the thickness of the semipermeable membrane is 1 μm or less. Here, since the semipermeable membrane is extremely thin, it is necessary to hold the semipermeable membrane by the support.
In this RO method, in the RO method, a high pressure far exceeding the osmotic pressure difference is applied to cause reverse osmosis, so it is necessary to give the semipermeable membrane a high pressure resistance by applying the support. Therefore, the support is required to have a very small pore diameter and a large film thickness like a laminated structure of a microfiltration membrane and a nonwoven fabric.
On the other hand, in the FO method, the concentration gradient in the vicinity of the semipermeable membrane is an important point because the concentration difference of the solution becomes the driving force for permeation. FIG. 2 is a schematic view showing a general configuration of the FO membrane, in which 21 is a feed solution side, 22 is a draw solution side, 23 is a semipermeable membrane, and 24 is a support. Moreover, the arrow has shown the flow of the solvent of feed solution. In FIG. 2, the support 24 is provided on the draw solution side 22, but may be provided on the feed solution side 21 or on both sides. Here, when the same material as the RO membrane is used for the support 24, the diffusion of the solute component is greatly reduced in the support. This diffusion delay causes a further decrease in solute concentration in the support. This phenomenon is called concentration polarization, and as a result, the osmotic pressure difference between the feed solution and the draw solution is greatly reduced, and the water permeation flow rate is also reduced. For example, when seawater is treated with a draw solution containing carbon dioxide and ammonia, the concentration of sodium ions and chloride ions derived from the salt increases in the vicinity of the semipermeable membrane on the seawater side, and the semipermeable membrane on the draw solution side In the vicinity, particularly in the support, the concentration of carbon dioxide-derived carbonate ions and ammonia-derived ammonium ions is reduced, the osmotic pressure difference is reduced, and water in seawater is less likely to penetrate the semipermeable membrane.
Therefore, on both sides of the semipermeable membrane, there is a need for an FO membrane that suppresses such concentration polarization and has the required strength.

  On the other hand, Patent Document 3 is known for the FO method. This discloses the basic technology of the FO film, and a forward osmosis method is performed using a classic copper ferrocyanide film. In this usage, the above-mentioned concentration polarization problem becomes remarkable, and the permeation flow rate is inferior. Since then, little research has been conducted on the FO method. However, in recent years, environmental issues have come to be regarded as important, and the FO method is being demanded from the viewpoint of energy reuse. That is, in the FO method, the energy is substantially only the thermal energy used in the distillation stage for separating the draw solution described above, and compared with the RO method in which the pressure is applied to promote the penetration, Uses little electrical energy. Therefore, the energy used in the FO method can be expected to utilize waste energy, and further development of the FO method is desired.

US Pat. No. 6,391,205 US Patent Application Publication No. 2005/0145568 US Pat. No. 3,216,930

  The present invention solves the above-described problems, and an object of the present invention is to solve problems related to concentration polarization generated in the FO film and film strength of the FO film in the FO apparatus and the FO method.

  Under such a problem, the present inventor tried to improve the forward osmosis system in addition to the improvement of the FO membrane itself. That is, the present inventors have considered that the above problem occurring in the FO film can be solved by reexamining the FO method as a whole instead of using only the FO film. And as a result of earnest examination from all directions, when the mesh is used as the support for the semipermeable membrane, and further, when the pore diameter of the mesh and the intermembrane pressure of the FO membrane satisfy a certain relationship, the permeation flow rate does not decrease, It has been found that stable operation by the FO method is possible over a long period of time, and the present invention has been completed. Specifically, it was achieved by the following means.

(1) A forward osmosis device using a forward osmosis membrane in which a semipermeable membrane is supported by a mesh, which satisfies all of the following formulas (1) to (3).
Formula (1) Z <= (0.09 * X) / Y
Formula (2) X <= 1000
Formula (3) Y <= 500
(In the formula, X represents the thickness (nm) of the semipermeable membrane, Y represents the pore size (μm) of the mesh, and Z represents the intermembrane pressure Z (MPa) of the forward osmosis membrane.)
(2) The forward osmosis device according to (1), wherein the transmembrane pressure satisfies the formula (1) even during unsteady operation.
(3) The forward osmosis device according to (1) or (2), wherein Formula (2) is X ≦ 500.
(4) The forward osmosis device according to (1) or (2), wherein Formula (2) satisfies X ≦ 350.
(5) The forward osmosis device according to any one of (1) to (4), wherein the liquid feeding pressure is 6 atm or less.
(6) The forward osmosis membrane is in a non-adhered state with the mesh in a portion where the liquid on the membrane surface of the semipermeable membrane can permeate is 99% or more of the membrane surface of the semipermeable membrane when observed by orthographic projection. The forward osmosis device according to any one of (1) to (5), characterized in that:
(7) In the forward osmosis membrane, the membrane surface of the semipermeable membrane and the mesh are partially bonded with regularity, and the semipermeable membrane is observed when the bonding ratio of the semipermeable membrane and the mesh is observed by orthographic projection. The forward osmosis device according to any one of (1) to (5), characterized in that it is more than 0% and less than 30% of the membrane surface.
(8) The forward osmosis device according to any one of (1) to (7), wherein the mesh is provided on both sides of the semipermeable membrane.
(9) The forward osmosis device according to any one of (1) to (8), which is used for seawater treatment.
(10) A forward osmosis method using a forward osmosis membrane in which a semipermeable membrane is supported by a mesh and satisfying all of the following formulas (1) to (3).
Formula (1) Z <= 0.09 * X / Y
Formula (2) X <= 1000
Formula (3) Y <= 500
(In the formula, X represents the thickness (nm) of the semipermeable membrane, Y represents the pore size (μm) of the mesh, and Z represents the intermembrane pressure Z (MPa) of the forward osmosis membrane.)
(11) The forward osmosis method according to (10), wherein the transmembrane pressure satisfies the formula (1) even during unsteady operation.
(12) The forward osmosis method according to (10) or (11), wherein Formula (2) is X ≦ 500.
(13) The forward osmosis method according to (10) or (11), wherein Formula (2) satisfies X ≦ 350.
(14) The forward osmosis method according to any one of (10) to (13), wherein the liquid feeding pressure is 6 atm or less.
(15) The forward osmosis membrane is in a non-adhering state with the mesh in a portion where the liquid on the membrane surface of the semipermeable membrane can permeate is 99% or more of the membrane surface of the semipermeable membrane when observed by orthographic projection. The forward osmosis method according to any one of (10) to (14), wherein:
(16) In the forward osmosis membrane, the membrane surface of the semipermeable membrane and the mesh are partially adhered with regularity, and the semipermeable membrane when the bonding ratio of the semipermeable membrane and the mesh is observed by orthographic projection. The forward osmosis method according to any one of (10) to (15), characterized in that it is more than 0% and less than 30% of the membrane surface.
(17) The forward osmosis method according to any one of (10) to (16), wherein the mesh is provided on both sides of the semipermeable membrane.
(18) The forward osmosis method according to any one of (10) to (16), which is used as a seawater treatment method.

  According to the present invention, concentration polarization of the FO film is suppressed, the permeation flow rate does not decrease, and the FO film is less likely to be damaged, so that it is possible to operate with a stable FO method over a long period of time.

FIG. 1 is a schematic diagram showing a conventional technique when seawater is processed using the FO method. In FIG. 1, 1 is a dilution means, 2 is a dissolution means, and 3 is a separation means. FIG. 2 is a schematic view showing a case where a FO method is performed using a conventional FO film. FIG. 3 is a schematic view showing an example of the manufacturing process of the FO film used in the present invention. FIG. 4 is a schematic view showing an example of the structure of the FO film used in the present invention.

  Hereinafter, the contents of the present invention will be described in detail. In the present specification, “to” is used to mean that the numerical values described before and after it are included as a lower limit value and an upper limit value.

The FO method of the present invention uses an FO membrane in which a semipermeable membrane is supported by a mesh, and satisfies all of the following formulas (1) to (3).
Formula (1) Z <= (0.09 * X) / Y
Formula (2) X <= 1000
Formula (3) Y <= 500
(In the formula, X represents the thickness (nm) of the semipermeable membrane, Y represents the pore size (μm) of the mesh, and Z represents the intermembrane pressure Z (MPa) of the forward osmosis membrane.)
By adopting such a configuration, the FO film does not break while maintaining the permeation flow rate necessary for the FO method, and thus a long-term safe operation is possible.

Here, the transmembrane pressure refers to the difference in pressure between the draw solution side and the feed solution side in the FO membrane. The transmembrane pressure in the present invention refers to the transmembrane pressure during steady operation, but in the present invention, it is further preferable that the transmembrane pressure satisfies the above formula (1) even during non-steady operation. Here, the steady operation refers to the transmembrane pressure when the operation is on the track, and the non-steady operation refers to the transmembrane pressure at the stage where the start is not started or stopped. Say.
In this invention, it is preferable that Formula (2) is 50 <= X <= 500, and it is more preferable that it is 50 <= X <= 350. In the formula (3), 20 ≦ Y ≦ 500 is preferable, and 50 ≦ Y ≦ 350 is more preferable.
By setting it as such a range, it becomes possible to exhibit the effect of this invention more effectively. Here, the pore diameter of the mesh refers to the diameter of a region constituted by four mesh threads, and commercially available products are usually described in catalogs and the like.

The FO membrane used in the present invention has a semipermeable membrane supported by a mesh.
Here, the semipermeable membrane in the present invention refers to a membrane that allows only molecules, ions, and hydrates of ions not larger than a certain size to pass through and does not allow large molecules to pass through. For example, when it is desired to pass only a solvent such as water from a solution such as seawater, such as when removing salt from seawater, a membrane that passes only the solvent and does not pass a solute such as an ion hydrate derived from salt is used. Say.
The density of the semipermeable membrane used in the present invention is preferably a ^{1.0g / cm 3 ~2.5g / cm 3} , more preferably ^{1.1g / cm 3 ~1.8g / cm 3} .
The material of the semipermeable membrane is not particularly defined, but examples thereof include regenerated cellulose, cellulose ester, polyacrylonitrile, Teflon (registered trademark), polyester polymer alloy, polyamide, polyimide, polysulfone, cellulose ester, polyamide, Polyimide is preferable, and cellulose ester, aromatic polyamide, and aromatic polyimide are more preferable.
As the cellulose, cellulose acetate is preferable, and the substitution degree of the hydroxyl group of the cellulose acetate to the acetyl group is preferably 2.0 to 3.0.

  In the present invention, the mesh functions to increase the membrane breaking strength (pressure resistance) of the semipermeable membrane. As preferred embodiments of the FO membrane in the present invention, (1) When the portion of the semipermeable membrane where the liquid can permeate is observed by orthographic projection in 99% or more of the membrane surface of the semipermeable membrane, (2) The membrane surface of the semipermeable membrane and the mesh are partially adhered with regularity, and the adhesion ratio between the semipermeable membrane and the mesh is observed by orthographic projection. An FO film that is more than 0% and less than 30% of the film surface of the film can be mentioned.

(1) The FO film which is in a non-adhering state with the mesh in 99% or more of the film surface of the semipermeable membrane when the portion of the semipermeable membrane where the liquid can permeate is observed by orthographic projection The portion where the liquid can permeate means a portion where the liquid may permeate in a normal state when the semipermeable membrane is installed so as to separate two kinds of liquids having different osmotic pressures. That is, a portion where the semipermeable membrane is covered with a holder or the like that holds the semipermeable membrane does not correspond to a portion where the liquid of the semipermeable membrane can permeate. On the contrary, the portion other than the portion where the penetration of the liquid is completely inhibited corresponds to the portion where the liquid can penetrate even if the liquid does not actually penetrate.
The orthogonal projection refers to a trajectory of a perpendicular foot that drops the FO film on a plane perpendicular to the film surface. Therefore, when the mesh is formed by folding a plurality of yarns or fibers, if the overlapping portion is bonded to any of the overlapping yarns, the portion is in an adhesive state. And Further, in the present invention, 99% or more of the membrane surface of the semipermeable membrane where the liquid of the semipermeable membrane can permeate is in a non-adhered state with the mesh, preferably 99.5% or more. Yes, more preferably 100% non-adhered state.
Here, the non-adhered state means that the portion where the semipermeable membrane and the mesh are in contact is not fixed. Specifically, it means that the semipermeable membrane and the mesh are not intentionally attached with an adhesive or the like. On the other hand, the case where the semipermeable membrane and the mesh are naturally bonded by intermolecular force, static electricity, adsorption via water, or the like is not included in the fixation in the present invention.

  In the present invention, a known method can be adopted as a method of bringing the mesh into contact with the semipermeable membrane. For example, as shown in FIG. 3, a semipermeable membrane 31 is formed in advance on a base material 33 via a sacrificial layer (not shown), and the sacrificial layer is dissolved in a liquid. The method of making it contact with the mesh 32 by separating 33 is mentioned. Further, a solution capable of dissolving the sacrificial layer and the adhesive component after previously forming the semipermeable membrane on the base material via the sacrificial layer and further contacting the semipermeable membrane and the mesh using the adhesive component Among them, it is possible to dissolve the sacrificial layer and the adhesive component.

(2) The membrane surface of the semipermeable membrane and the mesh are partially adhered with regularity, and the adhesion ratio between the semipermeable membrane and the mesh is 0% of the membrane surface of the semipermeable membrane when observed by orthographic projection. FO film exceeding 30% and less than 30% In the FO film in this embodiment, the semipermeable membrane and the mesh are partially bonded with regularity. For example, the case where it adheres in dot shape, line shape, or mesh shape is said. The adhesion method is not particularly defined, but usually, adhesion by an adhesive or adhesion by heat fusion is preferably employed.
As adhesion by thermal fusion, for example, a material that is fused by heat as a mesh can be used and thermal fusion can be performed. If the entire membrane surface of the mesh is heat-sealed, since the mesh has a mesh shape, the mesh-like partial adhesion can be easily performed.
In the case of bonding with an adhesive, the type and the like are not particularly defined, but for example, a latex adhesive can be employed.

  In the present invention, when observed by orthographic projection, bonding is performed at a ratio of more than 0% and less than 30% of the film surface of the semipermeable membrane. The adhesion ratio between the membrane surface of the semipermeable membrane and the mesh is preferably more than 1% and less than 30% of the membrane surface of the semipermeable membrane, and more than 5% and less than 30% of the membrane surface of the semipermeable membrane. Preferably, it is 20% or more and less than 30% of the film surface of the semipermeable membrane. By setting it as such a range, it becomes possible to exhibit the effect of this invention more effectively.

As the FO film used in the present invention, both the above aspects (1) and (2) can be preferably used, and the FO film of the above (1) is more preferable.
The mesh in the present invention may be provided on one side of the semipermeable membrane, but it is preferable that the mesh 42 is provided on both sides of the semipermeable membrane 41 as shown in FIG. By setting it as such a structure, the effect of this invention can be exhibited more effectively.

In the mesh used in the present invention, the pore diameter of 80% or more of the pores is preferably distributed within ± 10 μm of the average pore diameter, and more preferably within ± 5 μm.
Further, the porosity of the mesh in the present invention is preferably 0.05 or more, more preferably 0.2 or more, still more preferably 0.5 or more, more preferably 0.6 or more. is there. By setting the porosity to 0.05 or more, the mass transfer resistance in the mesh can be reduced, and the permeation flow rate can be improved. The upper limit value is not particularly defined, but can be set to 0.9 or less, for example.
The porosity (ε) in the present invention refers to the ratio of the volume of the gap contained therein to the total volume in the support.

  The material of the mesh is not particularly defined as long as it does not depart from the spirit of the present invention, but at least one selected from natural polymers, synthetic polymers, metals, glass fibers, ceramics, carbon fibers, and composites thereof. Species are exemplified. Examples of natural polymers include cellulose, and synthetic polymers include polyethylene, polypropylene, polyethylene terephthalate (PET), nylon (registered trademark), polytetrafluoroethylene, polyvinylidene fluoride, polysulfone, polyethersulfone, and the like. Examples of the metal include zinc, copper, iron, stainless steel (SUS), and aluminum. In the present invention, in consideration of processing suitability, cost, and the like, a synthetic polymer is preferable, and PET is more preferable.

The mesh used in the present invention preferably has resistance to a solution containing at least one of ammonium carbonate, ammonia, carbonic acid, and amines. The FO film of the present invention is used in the FO method, and the draw solution used in the FO method usually contains one or more of ammonium carbonate, ammonia, carbonic acid, and amines. Therefore, having resistance to the components of such a draw solution is preferable from the viewpoint of improving the durability of the apparatus.
Here, having resistance means that the weight change rate is 20% or less when the support is immersed in these solutions at 25 ° C. for one day.

The shape of the mesh used in the present invention is not particularly defined as long as it does not depart from the gist of the present invention, and examples thereof include non-woven fabric, mesh (woven fabric), punching metal, etc., and uniform pore size, porosity, and processing. Considering appropriateness and cost, a mesh (woven fabric) is preferable. Since the mesh constitutes the flow path of the solvent, there is also an advantage that the permeation becomes smoother.
The average opening diameter (thread diameter) of the mesh is 10 μm to 1000 μm, preferably 10 μm to 300 μm, and more preferably 30 μm to 200 μm.
By setting the average opening diameter to 10 μm or more, it is possible to more effectively suppress a decrease in the permeation flux due to concentration polarization, and by setting the average opening diameter to 1000 μm or less, the destruction of the semipermeable membrane can be more effectively prevented. be able to.
The average aperture diameter can be measured as a DIAMETER having a value of 50% in the CUMLATIVE FILTER FLOW VS DIAMETER graph using an optical microscope or a porometer.

The basis weight of the nonwoven fabric and woven fabric is not particularly limited and may be appropriately selected depending on the intended purpose, but is preferably ^{1g / m 2 ~1kg / m 2} , is 10g / m ² ~500g / m ² more ^{preferably, 10g / m 2 ~100g / m} 2 is particularly preferred.
By setting it to 1 g / m ² or more, the strength tends to be improved as a mesh, and by setting it to 1 kg / m ² or less, the specific gravity of the fiber becomes low as a layer having openings, and the permeation flux decreases due to concentration polarization. Can be more effectively suppressed.

  In the present invention, since the mesh is non-adhered or partially adhered to the semipermeable membrane, the semipermeable membrane layer may move slightly on the mesh during use. Therefore, it is desirable that the portion constituting the mesh is a surface having no protrusions and smooth and having a small friction.

  The thickness (t) of the mesh in the present invention is preferably 1 μm ≦ t ≦ 500 μm, more preferably 10 μm ≦ t ≦ 300 μm, and further preferably 50 μm ≦ t ≦ 200 μm. By setting the film thickness to 500 μm or less, the mass transfer resistance in the mesh can be reduced, and by setting it to 1 μm or more, the strength can be improved.

  The FO method of the present invention usually has a dilution step, a separation step, and a dissolution step, and further includes other steps as necessary. The FO method of the present invention can be preferably carried out by the FO apparatus of the present invention.

<Dilution process>
The dilution step is a step of bringing the draw solution and the feed solution into contact with each other through a semipermeable membrane and diluting the draw solution with the solvent separated from the feed solution by the semipermeable membrane. In this invention, it is preferable that the liquid feeding pressure of the feed solution at this time is 6 atmospheres or less, and it is more preferable that it is 1-3 atmospheres. By setting it as such a pressure, the danger that the transmembrane pressure will be abnormal can be removed.

Feed solution The feed solution is not particularly limited and may be appropriately selected depending on the intended purpose. For example, water obtained from the natural world such as seawater, brackish water, rivers, lakes, swamps, ponds, factories and various industries. Examples include industrial wastewater discharged from facilities, general wastewater discharged from households and general facilities, fruit juices and vegetable juices. Among these, seawater is particularly preferable from the viewpoints of availability that can be obtained stably and in large quantities and the necessity of purification.

Draw Solution The draw solution contains a solute that is more volatile than water at least at a specific temperature, and the solute is appropriately set depending on the application. Examples of the volatility index include that the Henry's constant and the saturated vapor pressure at each temperature of the substance are larger than the saturated vapor pressure of water. The Henry constant is a physical property value that indicates the relationship between the molar fraction of a substance and the saturated vapor partial pressure in a solution in which the substance is dissolved in a large amount of solvent. The larger this value, the higher the volatility in the solution. , The book “Chemical Handbook (issued by Maruzen Co., Ltd.)” and the book “Augmented Gas Absorption (issued by Chemical Industries, Ltd.)”.

The draw solution usually contains anions and cations.
The anion is not particularly limited and may be appropriately selected depending on the purpose, for example, carbon dioxide (CO _2), sulfur dioxide (SO _2), and the like. Among these, carbon dioxide (CO ₂ ) is particularly preferable in terms of high volatility, stability, low reactivity, and availability. The anion is hydrated (carbonic acid) by dissolving in water, and subsequently becomes anion (HCO ₃ −, CO ₃ ²⁻ , HSO ₃ −, SO ₃ ²⁻ ) by deprotonation.
There is no restriction | limiting in particular as a cation, Although it can select suitably according to the objective, Ammonia and amines are mentioned suitably. The cation is protonated by being dissolved in water to be a cation (NH ⁴⁺ ).

  The contents of the anion and cation in the draw solution are not particularly limited and can be appropriately selected according to the purpose. A high concentration is preferable from the viewpoint of increasing the rate of separating the solvent from the feed solution. For example, the mixing ratio is preferably such that the pH when the anion and cation are mixed is 8 or more.

<Separation process>
The separation step is a step in which a volatile solute of the draw solution is separated from the draw solution diluted in the dilution step to obtain a target solution such as a separation liquid or a concentrated liquid.
The separation step is not particularly limited in principle and configuration as long as the volatile solute can be at least partially separated from the aqueous solution diluted in the dilution step, and can be appropriately selected according to the purpose. Examples include separation using an outer filtration membrane (UF membrane), electrodialysis using an ion exchange membrane, magnetic separation, diffusion dialysis using an ion exchange membrane, and distillation. In the present invention, distillation is preferably employed. There is no restriction | limiting in particular as a distillation tower used for distillation, According to the objective, it can select suitably, For example, a plate tower, a packed tower, etc. are mentioned.

<Dissolution process>
The dissolution step is a step in which the volatile solute of the draw solution separated in the separation step is returned to the draw solution and dissolved. There is no restriction | limiting in particular as a melt | dissolution process, It can select suitably according to the objective from the apparatuses used for general gas absorption, for example, a book "a supplement gas absorption (Chemical Industry Co., Ltd. issue)" P49-p54, p83-p144, the equipment, parts, conditions, etc. can be selected arbitrarily. Specifically, the absorber, packed tower, plate tower, spray tower, fluid packed tower The method used, the liquid film cross flow contact method, the high-speed swirl flow method, the mechanical force utilization method, and the like can be mentioned. Further, a thin gas-liquid layer may be constructed and absorbed using a microfluidic control mechanism such as a microreactor or a membrane reactor.

Other processes Examples of other processes include a control process and a driving process.

  In addition to the above, the present invention includes techniques described in US Pat. No. 6,391,205, US Patent Application Publication No. 2005/0145568, and International Publication No. WO 2007/146094 without departing from the present invention. Can be adopted.

  The present invention will be described more specifically with reference to the following examples. The materials, amounts used, ratios, processing details, processing procedures, and the like shown in the following examples can be changed as appropriate without departing from the spirit of the present invention. Therefore, the scope of the present invention is not limited to the specific examples shown below.

Preparation of semipermeable membrane 1 On a polyethylene terephthalate (PET) sheet, a 6% polyvinyl alcohol (PVA) solution was applied to a dry film thickness of about 2 μm and dried at 100 ° C. A solution obtained by dissolving cellulose acetate (substitution degree 52%) in acetone: cyclohexanone = 1: 1 mixed solvent at a weight concentration of 1.65% on the PVA surface of the obtained sheet so that the dry film thickness becomes 0.35 μm. And dried at 100 ° C. This was immersed in ion-exchanged water at 70 ° C. for 5 minutes to dissolve PVA, whereby the PET sheet and the cellulose acetate film were peeled off to obtain a semipermeable membrane 1.

Single-sided support by mesh A semi-permeable membrane 1 in ion-exchanged water was scrubbed with a mesh using heat-fusible polyester as a thread, brought into contact with the mesh, and the end was fixed with a fixture to obtain an FO membrane. The portion of the semipermeable membrane where the liquid can penetrate is 100% non-adhering.

Double-sided support by mesh A semi-permeable membrane 1 in ion-exchanged water is sandwiched from both sides with a mesh using heat-fusible polyester as a thread, brought into contact with the semi-permeable membrane, and an end is secured with a fixture to obtain an FO membrane. . The portion of the semipermeable membrane where the liquid can penetrate is 100% non-adhering.

Heat Fusion by Mesh A mesh using a heat-fusible polyester having a core-sheath structure as a thread was adhered to the dried semipermeable membrane by heat fusion (130 ° C.). This was immersed in ion-exchanged water at 70 ° C. for 5 minutes to dissolve PVA, whereby the PET sheet and the cellulose acetate film were peeled off to obtain an FO film. The adhesion ratio between the support and the mesh is 26% of the membrane surface of the semipermeable membrane.

The meshes using the heat-fusible polyester used in this example or the comparative example as yarns are as follows. The material of the mesh 7 is a low melting point polyester.

In Comparative Example 5, a commercially available RO membrane (GE Water & Process Technologies, GE Sepa memberane CE (CA)) was used instead of the FO membrane. The support used in the RO membrane is a porous membrane, not a mesh.
Comparative Example 6 is a ferrocyanide copper film produced in accordance with USP 3,216,930. The support here is a porous membrane, not a mesh.

(Forward osmosis system evaluation)
The forward osmosis system shown in FIG. 1 was assembled. A 3.5 mass% sodium chloride aqueous solution was used as the feed solution. Carbon dioxide was used as the anion source for the draw solution. Ammonia was used as the cation source for the draw solution. The draw solution contained 3 mol / L of carbon dioxide and 4.2 mol / L of ammonia.
In the forward osmosis system shown in FIG. 1, after 55 minutes of steady operation, the operation of stopping for 5 minutes and then performing 55 minutes of steady operation was repeated for one week. The feed pressure of the feed solution was 6 atm. As the transmembrane pressure (during steady operation), the transmembrane pressure measured by the pressure gauge 18 of FIG. 1 was measured. The transmembrane pressure (when starting and stopping) was the maximum pressure difference between the transmembrane pressures measured by the pressure gauge 18 of FIG. 1 when starting and stopping. The results are shown in the table below.

As is apparent from the above table, when the conditions of the present invention were satisfied, the membrane was not damaged and a high permeation flow rate could be maintained after one week of operation. Moreover, in the said Example and comparative example, when the cation source of the draw solution was replaced with trimethylamine and others were performed similarly, the same tendency was recognized.
On the other hand, when the conditions of the present invention were not satisfied, the film was damaged within one week.

DESCRIPTION OF SYMBOLS 1 Dilution means 2 Dissolution means 3 Separation means 11 Seawater 12 Draw solution 13 Semipermeable membrane 14 Distillation tower 15 Draw solution volatile component 16 Water 17 Gas absorber 18 Pressure gauge 21 Feed solution 22 Draw solution 23 Semipermeable membrane 24 Mesh 31 Half Permeable membrane 32 Mesh 33 Base material 41 Semi-special membrane 42 Mesh

Claims (18)

A forward osmosis device using a forward osmosis membrane in which a semipermeable membrane is supported by a mesh, wherein all of the following formulas (1) to (3) are satisfied.
Formula (1) Z <= (0.09 * X) / Y
Formula (2) X <= 1000
Formula (3) Y <= 500
(In the formula, X represents the thickness (nm) of the semipermeable membrane, Y represents the pore size (μm) of the mesh, and Z represents the intermembrane pressure Z (MPa) of the forward osmosis membrane.) The forward osmosis device according to claim 1, wherein the transmembrane pressure satisfies the formula (1) even in the unsteady operation. The forward osmosis device according to claim 1, wherein the formula (2) is X ≦ 500. The forward osmosis device according to claim 1 or 2, wherein the formula (2) satisfies X≤350. The forward osmosis device according to any one of claims 1 to 4, wherein the liquid feeding pressure is 6 atm or less. The forward osmosis membrane is characterized in that the portion of the semipermeable membrane where the liquid can permeate is in an unbonded state with the mesh in 99% or more of the membrane surface of the semipermeable membrane when observed by orthographic projection. The forward osmosis device according to any one of claims 1 to 5. In the forward osmosis membrane, the membrane surface of the semipermeable membrane and the mesh are partially adhered with regularity, and the membrane surface of the semipermeable membrane when the bonding ratio of the semipermeable membrane and the mesh is observed by orthographic projection The forward osmosis device according to claim 1, wherein the forward osmosis device is greater than 0% and less than 30%. The forward osmosis device according to claim 1, wherein the mesh is provided on both sides of the semipermeable membrane. The forward osmosis device according to any one of claims 1 to 8, which is used for seawater treatment. A forward osmosis method characterized by using a forward osmosis membrane in which a semipermeable membrane is supported by a mesh and satisfying all of the following formulas (1) to (3).
Formula (1) Z <= 0.09 * X / Y
Formula (2) X <= 1000
Formula (3) Y <= 500
(In the formula, X represents the thickness (nm) of the semipermeable membrane, Y represents the pore size (μm) of the mesh, and Z represents the intermembrane pressure Z (MPa) of the forward osmosis membrane.) The forward osmosis method according to claim 10, wherein the transmembrane pressure satisfies formula (1) even during non-steady operation. The forward osmosis method according to claim 10 or 11, wherein the formula (2) is X≤500. The forward osmosis method according to claim 10 or 11, wherein the formula (2) is X≤350. The forward osmosis method according to any one of claims 10 to 13, wherein the liquid feeding pressure is 6 atm or less. The forward osmosis membrane is characterized in that the portion of the semipermeable membrane where the liquid can permeate is in an unbonded state with the mesh in 99% or more of the membrane surface of the semipermeable membrane when observed by orthographic projection. The forward osmosis method according to any one of claims 10 to 14. In the forward osmosis membrane, the membrane surface of the semipermeable membrane and the mesh are partially adhered with regularity, and the membrane surface of the semipermeable membrane when the bonding ratio of the semipermeable membrane and the mesh is observed by orthographic projection The forward osmosis method according to any one of claims 10 to 15, characterized in that it is more than 0% and less than 30%. The forward osmosis method according to any one of claims 10 to 16, wherein the mesh is provided on both sides of the semipermeable membrane. The forward osmosis method according to any one of claims 10 to 16, wherein the forward osmosis method is used as a seawater treatment method.

Images