KR102046818B1 - Thermally reusable ultrafiltration membrane using boron nitride nano materials and method for fabrication and regeneration thereof - Google Patents

Abstract

A porous ultrafiltration membrane formed of boron nitride nanomaterials is prepared, and foreign substances in the contaminated membrane are removed through thermal sintering to be reusable. Accordingly, it is possible to solve the problem of contamination of the filtration membrane and the resulting increase in operating energy. In addition, since a small amount of the dispersed boron nitride nanomaterial dispersion can be produced by filtration, the manufacturing method is simple and large area can be manufactured at low processing cost. In addition, since it is mechanically stable and thermally and chemically stable, it can be applied to various applications such as high temperature filtration membranes and high temperature fuel cell separators.

Description

Thermally reusable ultrafiltration membrane using boron nitride nano materials and method for fabrication and regeneration according to heat-renewable ultrafiltration membrane using boron nitride nanomaterials

The present invention relates to a heat reproducible ultrafiltration membrane using a boron nitride nanomaterial, and a method for manufacturing and regenerating the same. Specifically, an ultrafiltration membrane is prepared using a boron nitride nanomaterial dispersion, and the prepared ultrafiltration membrane is regenerated by sintering. And techniques for making it recyclable.

 Ultrafiltration membrane is a filtration membrane capable of filtering / removing contaminants at the 10-100 nm level with a pore size of about 10-100 nm.A reverse osmosis membrane or a nano-level filtration membrane having a smaller pore size of less than 10 nm. In contrast, the pore size is relatively large, and the pressure-driven membrane can effectively filter out microorganisms and viruses while significantly reducing the amount of energy used in the filtration process.

The ultrafiltration membrane technology is a high technology separation process that is widely used in various water treatment processes, beverage treatment processes, or food processes for solving the global water shortage phenomenon, and its use is increasing in industrial sites.

However, ultrafiltration membranes also have a chronic problem of permeability reduction due to contamination of the filter membrane, which is one of the issues to be solved in the industrial application of the ultrafiltration membrane.

Membrane contamination is not deterioration of the membrane itself during the separation process using the filtration membrane, but contaminants in the influent are formed by filtering the contaminants in the influent due to clogging of the membrane, clogging of the flow path, or formation of an adhesion layer. This means fouling due to membrane clogging.

There are various kinds of foreign substances causing such membrane contamination, such as organic matter, microorganism, colloid or adsorbent particles, and membrane contamination reduces the permeability of the filtration membrane and thus requires additional pressure for filtration. cause.

Therefore, in order to reduce the energy efficiency and maximize the efficiency of the filtration process, there is a need for a method for more efficiently solving the contaminant and congestion of the filtration membrane or for efficiently regenerating the filtration membrane.

As a method of regenerating the membrane, physical washing and chemical washing are generally used.

Physical cleaning methods include flushing, reverse filtration and air scrubbing. Water washing is a method of removing contaminants on the membrane surface using raw water, and back washing is a method of removing contaminants on the membrane surface by using filtered water or compressed air in a direction opposite to the supply direction. It is a method of removing contaminants using friction between the membrane surfaces (Patent Documents 1 to 4).

This physical cleaning method is generally essential for maintenance cleaning. However, physical cleaning methods are not completely effective in removing all contaminants. This is because, over time, the efficacy is gradually reduced as it is contaminated and damaged by microorganisms or the like which are not easily removed by these physical means. The kinds of fouling bodies generated in water treatment are organic in nature and usually include fouling materials having inorganic properties.

Therefore, chemical cleaning is usually required to completely remove contaminants inside and on the membrane surface. The chemical cleaning method is a method of chemically decomposing contaminants attached to the membrane using a cleaning liquid. In chemical cleaning methods, oxidizing agents and caustic agents are used to remove organic contaminants. The most widely used cleaning agents are sodium hypochlorite (chlorine), hydrogen peroxide and ozone, and acid or chelating agents to remove inorganic contaminants. use. In addition, when grease exists in the film surface, it can remove using a corrosive solution and surfactant (patent documents 5-7).

Chlorine is the most widely used cleaning agent, but it is known as a cause of carcinogenic chlorinated organic byproducts in water treatment systems, and organic ultrafiltration membranes may be damaged by chlorine, which is undesirable for widespread use. By using hydrogen peroxide, problems caused when chlorine is used as a cleaning agent can be avoided, but are generally less effective than chlorine (or hydrochloric acid) (Patent Document 8). Ozone is a more effective cleaning agent than chlorine and hydrogen peroxide, and can avoid environmental problems due to the use of chlorine, but because it is a powerful oxidant, it causes damage to the filtration membrane (Patent Documents 9 and 10).

In addition to the chemical cleaning method described above, the surface is hydrophilically modified to prevent adsorption of fine organic substances before use of the membrane to prevent membrane contamination, thereby generating a negatively charged underwater pollutant including humic acid and an electrostatic repulsive force. Attempts have been made to reduce contamination. In addition, a method of increasing the effective area of the membrane capable of water treatment per unit area by forming a protruding pattern on the surface of the membrane and reducing the contact area with fouling bodies has been attempted to increase the resistance to membrane contamination. Patent documents 11-13).

The ultrafiltration membrane used for general purpose is a polymer filtration membrane, and many studies have been conducted to apply physical / chemical washing methods to prevent clogging and damage caused by contaminants, but due to the low mechanical and chemical durability problems of polymers, The reality is that the law is limited.

In the case of inorganic filtration membranes having high durability, physical / chemical cleaning methods including an acid cleaning method are applicable, but since they are manufactured by pressing and sintering metal or inorganic particles, it is difficult to form pores of uniform size, and is limited in increasing porosity. It is relatively brittle and fragile, so it is manufactured in the form of a thick plate. In addition, the manufacturing process is expensive, and because of the oxide, the use is limited due to the disadvantages such as dissolution during the base washing process and the possibility that the sealing is not completely due to the heterogeneous materials of the filtration membrane and the filtration module.

Another inorganic filtration membrane has been commercialized by presenting Anodic Aluminum Oxide (AAO) with aligned pores on the order of tens to hundreds of nanometers.However, dissolution problems due to base and manufacturing processes such as oxidation and dissolution processes are complicated. And there is a disadvantage that is fragile (Patent Document 14).

On the other hand, there has been recently introduced a filtration membrane manufacturing method for producing a filtration membrane of several tens of nanometers more efficiently without using a sintering and compression process or anodization process that requires high energy. This method is to disperse the nanowires, nanotubes, etc. in the solution and to immerse them in the form of a thin film so that the fluid passes between the densely stacked copper oxide nanowires and copper nanobelts and the particles are filtered out (Non-Patent Document 3) And 4). This process is very easy to control the pore size as well as the process size is simple, it is very likely to be used in the production of industrial ultrafiltration membranes. However, since the metal and the metal oxide are still used, there is a dissolution problem due to acid / base.

As another ultrafiltration membrane production method, there is a method of forming a filtration membrane by randomly immersing carbon nanotubes having both ends open inside a polymer (Patent Document 15). The thickness of the polymer coating film is less than the average length of the nanotubes, characterized in that to provide a channel through the thickness of the carbon nanotubes, thereby providing a layer capable of selective exclusion of molecular species or particles.

The patented technology has the advantage of cleaning with acid / base due to the low chemical reactivity of carbon nanotubes, but it is not stable to strong acid and due to low thermal stability (thermal oxidation), it is possible to fundamentally remove membrane contaminants. It is impossible to remove the organic matter using high temperature sintering and recycling the filtration membrane using the same.

US 8,268,176 US 5,192,456 US 5,248,424 US 2010-0059433 A1 WO 2010-142673 A1 US 3,700,591 US 4,539,117 US 6,113,798 US 7,578,939 KR 10-2008-0056236 (WO 2007-035987) KR 10-2015-0164615 KR 10-2014-0131646 KR 10-2016-0005245 KR 10-2013-0098031 US 2010-0025330 A1

Cohen et al. Physcis Today, 2010 Golberg, Dmitri, et al. ACS nano (2010) 4.6 2979-2993, Boron nitride nanotubes and nanosheets Mao et al. Crystal Engineering Communications, 2013, 15, 265 Pandey et al. Beilstein Journal of Nanotechnology, 2014, 5, 789

An object of the embodiments of the present invention is, in one aspect, to prepare a porous ultrafiltration membrane formed of boron nitride nanomaterials to solve membrane contamination and cleaning problems, and to make it possible to reuse foreign substances in the contaminated membrane by thermal sintering to reuse them. The present invention provides a heat reproducible ultrafiltration membrane using a boron nitride nanomaterial, and a method of manufacturing and regenerating the same.

It is an object of embodiments of the present invention, in another aspect, to provide an ultrafiltration membrane and a method for producing the same, which can be large-scaled by a simple method without containing a chemical reaction and can maintain high-performance filtration after sintering.

In exemplary embodiments of the present invention, an ultrafiltration membrane comprising a boron nitride nanomaterial, comprising: a boron nitride nanomaterial surface layer; And a boron nitride nanomaterial ultrafiltration membrane comprising a porous support under the surface layer.

In exemplary embodiments of the present invention, there is also provided a method of preparing boron nitride nanomaterial dispersions; And immersing the boron nitride nanomaterial dispersion in a porous support to prepare an ultrafiltration membrane. It provides a method for producing a boron nitride nanomaterial ultrafiltration membrane comprising a.

In an exemplary embodiment of the present invention, the method of regenerating the boron nitride nanomaterial ultrafiltration membrane, comprising the step of: sintering the manufactured ultrafiltration membrane while heating to remove organic contaminants to regenerate the ultrafiltration membrane. to provide.

The ultrafiltration membrane including the boron nitride nanomaterial according to exemplary embodiments of the present invention may remove contaminants through thermal sintering and may be recycled since the filtration performance is not degraded even after removal. Therefore, it is possible to fundamentally solve the problem of pollution of the filtration membrane and the increase of operating energy, which is the biggest problem in the industrial application of the existing ultrafiltration membrane.

In addition, the ultrafiltration membrane according to the exemplary embodiments of the present invention can be produced by filtering a small amount of dispersed boron nitride nanomaterial dispersion, so the manufacturing method is simple and can be large-scaled at a low process cost, which is applicable to industry It is possible to provide a filtration membrane.

In addition, the ultrafiltration membrane according to exemplary embodiments of the present invention is thermally and chemically stable while having a mechanical durability corresponding to the conventional oxidized inorganic filtration membrane, and thus may be applied to various applications such as a high temperature filtration membrane and a high temperature fuel cell separator. have.

1 is a photograph showing the manufacturing and regeneration process of the ultrafiltration membrane according to an embodiment of the present invention.
Figure 2a is a SEM cross-sectional view of the ultrafiltration membrane prepared in the embodiment of the present invention.
Figure 2b is a graph showing the thickness of the ultrafiltration membrane prepared in the embodiment of the present invention according to the weight of the boron nitride nano material per unit area through the SEM.
Figure 3a is a graph showing the permeation amount of the ultrafiltration membrane prepared in the embodiment of the present invention according to the weight of the boron nitride nano material per unit area.
Figure 3b is a graph quantifying and plotting the resolution of the ultrafiltration membrane prepared in Examples of the present invention.
Figure 4 is a graph showing the maintenance of filtration performance according to the repeated recycling of the boron nitride nanomaterial ultrafiltration membrane in an embodiment of the present invention.

Term Definition

In the present specification, the “boron nitride nanomaterial” is one in which honeycomb lattice-shaped boron and nitrogen each have three sp2 covalent bonds intersecting with each other adjacent atoms. The boron nitride nanomaterial may be formed in the form of a wall, a layer, or a film having a zero-dimensional, one-dimensional, two-dimensional, or three-dimensional structure.

In particular, each boron and nitrogen is basically formed as a basic repeating unit, but may be formed in a polygonal structure in the manufacturing step. In addition, when forming a layered form in a three-dimensional structure, it may be composed of a plurality of layers, the terminal atoms of boron and nitrogen may exist in the form of a covalent bond as a hydrogen atom.

In the present specification, the "boron nitride nanomaterial ultrafiltration membrane" is an ultrafiltration membrane prepared by immersing a dispersion in which a boron nitride nanomaterial is dispersed in a solution, on a porous support, and is not limited to the boron nitride nanomaterial prepared by the specific method described below. It is meant to include an ultrafiltration membrane prepared by various methods using.

As used herein, "thermal sintering" means heating to a temperature range for removing the organic material of the boron nitride nanotube ultrafiltration membrane, for example, may be heated to 300 ~ 450 ℃.

Illustrative Of embodiments  Explanation

Hereinafter, exemplary embodiments of the present invention will be described in detail.

In exemplary embodiments of the present invention, an ultrafiltration membrane having a pore size of about 10 nm to about 100 nm including a boron nitride nanomaterial is provided.

In an exemplary embodiment, the ultrafiltration membrane is composed of a surface layer made of boron nitride nanomaterial and a porous support under the surface layer.

In an exemplary embodiment, boron nitride nanotubes may be used as the boron nitride nanomaterial. Boron nitride nanotubes are structurally similar to carbon nanotubes in which sp2 covalent bonds between boron and nitrogen form a 1: 1 ratio.

Boron nitride nanomaterials, such as boron nitride nanotubes, may have high mechanical strength (eg, ˜1.18 TPa) and high oxidation resistance (eg, stable to ˜900 ° C.). Thus, the boron nitride nanomaterial ultrafiltration membrane may have high mechanical properties and chemical / thermal stability. Accordingly, it is possible to apply a cleaning method using a strong acid, a strong base that has not been utilized in the existing ultrafiltration membrane.

In addition, the ultrafiltration membrane of the exemplary embodiments of the present invention may recycle the filtration membrane by removing the organic matter causing the blockage of the membrane through thermal sintering (~ 400 ℃). The recycling of ultrafiltration membranes using such thermal sintering not only eliminates the use of toxic chemicals such as strong acids and strong bases, but also a very simple and effective way to fundamentally remove the biological organic matter strongly adsorbed on the filtration membranes. to be.

A method of preparing the boron nitride nanomaterial ultrafiltration membrane of exemplary embodiments of the present invention comprises the steps of preparing a boron nitride nanomaterial dispersion; And immersing the boron nitride nanomaterial dispersion in a porous support to prepare an ultrafiltration membrane.

In an exemplary embodiment of the present invention, the step of regenerating the ultrafiltration membrane by performing a solution filtration including organic contaminants using the prepared ultrafiltration membrane and then sintering with heat to remove the organic contaminants; It provides a method for regenerating the boron nitride nanomaterial filtration membrane comprising a.

In an exemplary embodiment, the boron nitride nanomaterial may be composed of one or two or more mixtures selected from single-walled, double-walled, multi-walled, bundled, rope-type, and bamboo-type boron nitride nanotubes.

In a non-limiting example, preferably, the boron nitride nanotubes may use multiwall boron nitride nanotubes. In addition, a nanotube having an outer wall of the tube made of boron nitride may be used, and may include all boron nitride nanotubes in the case where the impurities of amorphous boron and amorphous boron nitride generated during nanotube synthesis are purified and not purified. .

In an exemplary embodiment, the bundle-type boron nitride nanotubes can be peeled off, for example, to a single tube or substantially equivalent thereto, and dispersed and used in a dispersion as described below. For reference, multi-walled tubes typically have a bundle form.

In an exemplary embodiment, the boron nitride nanotubes may have a diameter of about 5-50 nm.

In an exemplary embodiment, the dispersion of the boron nitride nanotubes may be a dispersion of the boron nitride nanotubes in an organic solvent.

In an exemplary embodiment, the organic solvent for dispersing the boron nitride nanotubes is a solvent capable of dissolving the dispersant described later, such as amines, water, alcohol, acetone, dimethylformamide, dimethyl sulfoxide, tetrahydrofuran Or mixtures of one or two or more selected from the group consisting of dimethyl ether, toluene and dichloromethane.

In an exemplary embodiment, the content of the boron nitride nanomaterial in the organic solvent and the boron nitride nanomaterial may be greater than 0 wt% and less than 4 wt%. Dispersion is well achieved at less than 4 wt% and the viscosity may rise rapidly.

In an exemplary embodiment, the dispersion of the boron nitride nanomaterial may include a dispersant including a Lewis base and an organic solvent capable of dissolving it. Boron nitride nanomaterials, particularly boron nitride nanotubes, have strong hydrophobicity and are difficult to disperse due to van der Waals aggregation. By using a dispersant containing a Lewis base, the Lewis acid-base attraction between the boron nitride nanomaterial and the dispersant may be stably dispersed in an organic solvent at a high concentration while maintaining the intrinsic properties of the boron nitride nanomaterial. Thus, for example, in the case of boron nitride nanotubes, it is possible to produce a high concentration of the dispersion, individualized to the level of a single nanotube.

The dispersant containing the Lewis base may be selected from the group consisting of at least one Lewis base, oligomer, monocomponent polymer, copolymer polymer, crosslinked polymer.

More specifically, in an exemplary embodiment, the dispersion of the boron nitride nanomaterial is a poly (4-vinylpyridine) polymer or oligomer and a polyvinylpyrrolidone which is a surfactant as a dispersant containing a Lewis base. (polyvinylpyrrolidone), and polyvinyl alcohol (polyvinylalcohol) may include one or more dispersants selected from.

In this regard, the boron nitride nanomaterial has a attraction force with 4-vinylpyridine monomer containing a Lewis base, so that not only a polymer but also an oligomeric form can be sufficiently dispersed.

In one exemplary embodiment, the dispersant is at least 10 parts by weight, such as 10 to 100 parts by weight, preferably 10 to 50 parts by weight, relative to 100 parts by weight of the boron nitride nanomaterial. If you use more than that, you will use unnecessary amount without increasing dispersion effect.

In an exemplary embodiment, the immersion of the boron nitride nanotubes is carried out by filtering the boron nitride nanotube dispersion through a porous support, through which an ultrafiltration membrane may be prepared.

The porous support serves as a porous support layer on which the surface layer of the boron nitride nanomaterial is supported, and the boron nitride nanomaterial can be well filtered without dissolving or dissolving in the dispersion of the boron nitride nanomaterial (mainly alcohols, etc.). In addition, it should be a filtration membrane which is not oxidized or burned out by sintering. For example, polymer-based filtration membranes (nylon, cellulose acetate) cannot be used because they are burned away by sintering. For example, ceramic filtration membranes can be used.

Examples of such ceramic filtration membranes include silica and titania ceramic filters, and for example, filtration membranes made of glass fibers can be used. The pore size of the porous support may have a pore size such that the boron nitride nanomaterial is immersed and a solution permeable, and may be, for example, a pore size of 10 nm or more and 1 micrometer or less.

In an exemplary embodiment, by adjusting the boron nitride nanotube area density in the ultrafiltration membrane may be to control one or more of the pore size of the boron nitride nanotube ultrafiltration membrane or the filtration efficiency of the nanoparticles.

In an exemplary embodiment, the area density of the boron nitride nanotubes of the boron nitride nanotube ultrafiltration membrane may be 0.5 to 3.1 mg / cm ² . When the particle size of the particles to be filtered is very small (for example, 25 nm), when the area density of the boron nitride nanotubes is less than 0.5 mg / cm ² , the filtration efficiency may be greatly reduced, and may exhibit a significant filtration efficiency at the area density. If the area density exceeds 3.1 mg / cm ² , smaller particles can be filtered but the boron nitride nanotubes are used too much.

In an exemplary embodiment, the thermal sintering in the regeneration process may be performed for example for 3 or more in the temperature range of 300 ℃ or more, such as 300 ~ 450 ℃.

The boron nitride nanotube ultrafiltration membrane according to the exemplary embodiments of the present invention may not degrade the filtration performance of the filtration membrane even after the contaminant cake filtered by the filtration membrane is removed through thermal sintering.

Hereinafter, specific embodiments according to exemplary embodiments of the present invention will be described in more detail. However, the present invention is not limited to the following examples, and various forms of embodiments can be implemented within the scope of the appended claims, and the following examples are only common in the art while making the disclosure of the present invention complete. It is to be understood that the invention is intended to facilitate the practice of the invention.

[ Example ]

nitrification  Preparation of Boron Nanotube Dispersions

1 is a photograph showing the manufacturing and regeneration process of the filtration membrane according to an embodiment of the present invention.

First, a dispersion of boron nitride nanotubes was prepared by exfoliating the bundle-type boron nitride nanotubes into a single tube (or a corresponding level), followed by dispersion and mixing in an organic solvent and sonication. The boron nitride nanotubes in the form of bundles were made from BNNT LLC.

Specifically, a dispersion solution was prepared by sonication by adding at least 0.1 weight of poly (4-vinylpyridine) per weight of boron nitride nanotubes and adding methanol.

nitrification  Boron Nanotube Dispersion nitrification  Boron Nanotubes Filtration membrane  Produce

The boron nitride nanotube dispersion prepared above may be prepared by filtering the boron nitride nanotube dispersion through a second filtration membrane to prepare an ultrafiltration membrane using the boron nitride nanotube dispersion.

In this embodiment, a pore size 700 nm filtration membrane (Millipore APFF 04700 4.7 cm in diameter) made of glass fiber was used as the second filtration membrane. The dispersion was filtered through this separate filtration membrane to prepare a boron nitride nanotube ultrafiltration membrane.

Figure 2a is a SEM cross-sectional view of the boron nitride nanotube ultrafiltration membrane prepared in the embodiment of the present invention.

As shown in Figure 2a, the ultrafiltration membrane is a boron nitride nanotube surface layer is formed on the glass fiber filter membrane that is a porous support.

The pore size of the boron nitride nanotube ultrafiltration membrane and the filtration efficiency of the nanoparticles can be controlled by the amount of boron nitride nanotubes of the immersed filtration membrane, and preferably, by quantifying the amount of the dispersion when the dispersion is filtered to form the membrane. The area density of the boron nanotube filtration membrane may be adjusted to 0.5 to 3.1 mg / cm ² . Was prepared by the dispersion passes through the total weight 10g on was used to disperse 100mg of the boron nitride nanotubes for the production of (1 wt%) 1mg / cm 2 solution of 900mg the area of membrane in 9cm ² (nanotubes of 9mg) . That is, it was prepared to have the area density by adjusting the amount of solution.

Figure 2b is a graph showing the thickness of the boron nitride nanotubes ultrafiltration membrane in accordance with the weight of the boron nitride nanotubes per unit area through the SEM in the embodiment of the present invention.

nitrification  Boron Nanotubes Ultrafiltration membrane  Permeability Measurement and Pollutant Removal Efficiency Analysis

Figure 3a is a graph showing the permeability of the boron nitride nanotube ultrafiltration membrane prepared in the embodiment of the present invention according to the weight of the boron nitride nanotubes per unit area.

As shown in Figure 3a, in order to measure the permeability of the prepared boron nitride nanotube ultrafiltration membrane permeate pure water through a filter membrane having a different area density of 0.5 ~ 3.1mg / cm ² and permeability per hour, per unit area It was measured and showed a high permeability.

nitrification  Boron Nanotubes Ultrafiltration membrane Area density  Filtration efficiency according to

Figure 3b is a numerical representation of the resolution of the boron nitride nanotube ultrafiltration membrane prepared in the embodiment of the present invention.

Filtration efficiency and foreign matter removal efficiency of the prepared boron nitride nanotube ultrafiltration membrane can be measured by measuring and comparing the fluorescence intensity of the nanoparticle solution before and after filtering the nanoparticles having various sizes of fluorescence through the filtration membrane. .

Specifically, the polystyrene particles containing a fluorescent dye having a diameter of 25 nm are purified by a filtration membrane made of a weight of boron nitride nanotubes per different unit area, and then the permeated filtrate is measured by using fluorescent microscopy. This is measured and compared with the fluorescence intensity of the solution before filtration and plotted by calculating the ratio of polystyrene particles removed by the filtration membrane.

As shown in FIG. 3B, the y-axis is the polystyrene removal efficiency of 25 nm particles calculated based on the fluorescence intensity before and after filtration, the higher the particle removal efficiency is. The x-axis represents the area density of the boron nitride nanotube ultrafiltration membrane. 93.4% 35.5% In various cases the removal efficiency of the boron nitride nanotubes, the ultrafiltration membrane made of the area density of 0.5mg / cm ^2, respectively, 84.5% of ^{1mg / cm 2, 1.6mg / cm} 2, 2.1mg / cm ^In the case of ² , 97%, 2.6, and 3.1mg / cm ² , it can be seen that the filtration efficiency increases as the area density increases.

Through thermal sintering Boron nitride  Nanotube Ultrafiltration membrane  Removal and Regeneration of Contaminants

The organic foreign matter formed on the filtration membrane through filtration of contaminants was removed by heat treatment at 450 ° C. for 6 hours to regenerate the filtration membrane. In such thermal sintering, the dispersant may also be removed.

Filtration efficiency was measured at each repetition while filtration and regeneration were repeated. Figure 4 is a graph showing the maintenance of filtration performance according to the repeated recycling of the boron nitride nanotube ultrafiltration membrane prepared in the embodiment of the present invention.

Specifically, the polystyrene nanotubes formed by filtering the polystyrene latex particles having a diameter of 25 nm containing fluorescent dye with a filtration membrane having a weight of 2.1 mg / cm ² , 2.6 mg / cm ² , and 3.1 mg / cm ² per unit area The particle cake was removed through thermal sintering and again the process of filtering the polystyrene particles showed filtration ability for the polystyrene particles in each cycle.

As shown in FIG. 4, 10 cycles were repeated. When the area density was 3.1 mg / cm ² , the removal efficiency of 100% was maintained according to the repetition of the cycle.

Claims (19)

An ultrafiltration membrane comprising a boron nitride nanomaterial,
Boron nitride nanomaterial surface layer; And
An ultrafiltration membrane comprising a ceramic porous support under the surface layer,
The ultrafiltration membrane is regenerated by heat sintering,
The boron nitride nanotubes ultrafiltration membrane, characterized in that the area density of the boron nitride nanotubes is 1 ~ 3.1 mg / cm ² .
The method of claim 1,
The boron nitride nanomaterial is a boron nitride nanomaterial ultrafiltration membrane, characterized in that the boron nitride nanotubes.
delete The method of claim 2,
The boron nitride nanotubes are boron nitride nanomaterial ultrafiltration membrane, characterized in that made of one or two or more mixtures selected from the group consisting of single-wall, double-walled, multi-walled, bundled, rope-type, bamboo-type boron nitride nanotubes.
The method for producing the boron nitride nanomaterial ultrafiltration membrane of any one of claims 1, 2 and 4,
Preparing a boron nitride nanomaterial dispersion; And
And immersing the boron nitride nanomaterial dispersion in a porous support to prepare an ultrafiltration membrane.
The method of claim 5,
The boron nitride nanomaterial is a boron nitride nanomaterial ultrafiltration membrane manufacturing method, characterized in that the boron nitride nanotubes.
The method of claim 6,
The boron nitride nanotubes are made of one or two or more mixtures selected from the group consisting of single-walled, double-walled, multi-walled, bundled, rope-type, and boron nitride-nitride nanotubes. Way.
The method of claim 6,
A method of manufacturing a boron nitride nanomaterial ultrafiltration membrane, wherein the boron nitride nanotubes in a bundle form are separated and dispersed in a dispersion, and the stripped boron nitride nanotubes comprise a single boron nitride nanotube.
The method of claim 6,
The boron nitride nanotubes are boron nitride nanomaterial ultrafiltration membrane manufacturing method, characterized in that the diameter of 5 ~ 50nm.
The method of claim 5,
The boron nitride nanomaterial dispersion is boron nitride nanomaterial ultrafiltration membrane production method characterized in that the boron nitride nanomaterial dispersed in an organic solvent.
The method of claim 10,
The organic solvent is one or two or more mixtures selected from the group consisting of amines, water, alcohol, acetone, dimethylformamide, dimethyl sulfoxide, tetrahydrofuran, dimethyl ether, toluene, dichloromethane. Boron nitride nanomaterial ultrafiltration membrane production method.
The method of claim 5,
The dispersion of the boron nitride nanomaterial may include at least one dispersant selected from a dispersant consisting of poly 4-vinylpyridine, polyvinylpyrrolidone, and polyvinylalcohol. Boron nitride nanomaterial ultrafiltration membrane production method.
The method of claim 5,
The boron nitride nanomaterial dispersion is a manufacturing method of the boron nitride nanomaterial ultrafiltration membrane, characterized in that it comprises a 4-vinylpyridine (poly (4-vinylpyridine)) oligomer as a dispersant.
The method of claim 5,
The boron nitride nanomaterial immersion method is carried out by filtering the boron nitride nanomaterial dispersion liquid on a ceramic porous support.
The method of claim 5,
The porous support is a boron nitride nanomaterial ultrafiltration membrane production method, characterized in that the filter membrane made of glass fibers.
The method of claim 5,
A method for producing a boron nitride nanomaterial ultrafiltration membrane, characterized in that the pore size or nanoparticle filtration efficiency of the boron nitride nanomaterial ultrafiltration membrane is controlled by controlling the area density of the boron nitride nanomaterial in the ultrafiltration membrane.
The method of claim 10,
A method for producing a boron nitride nanomaterial ultrafiltration membrane, wherein the content of the boron nitride nanomaterial in the organic solvent and the boron nitride nanomaterial is greater than 0 wt% and less than 4 wt%.
Performing a solution filtration comprising organic contaminants using the ultrafiltration membrane of any one of claims 1, 2 and 4;
Regenerating the ultrafiltration membrane by heating and sintering the ultrafiltration membrane after filtration of the solution to remove organic contaminants. The method of regenerating a boron nitride nanomaterial ultrafiltration membrane comprising: a.
The method of claim 18,
In the regeneration process, heat sintering is a regeneration method of the boron nitride nanomaterial ultrafiltration membrane, characterized in that performed in the range of 300 ~ 450 ℃.

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