KR20170072840A - a funtional glass membrane filter - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a filter for separating viruses and fungi, and relates to a functional glass membrane filter using a hollow fiber filter and having excellent convenience in the interior of the main body and excellent solvent resistance.
The present invention provides a functional glass membrane filter including a body 110, a filter 120, an inlet 130, and an outlet 140.
In addition, in the present invention, the main body 110 has a hollow space formed therein, and the filter unit 120 is inserted into the hollow space,
The functional glass membrane filter is characterized in that the filter unit (120) comprises a hollow fiber filter (121).
The functional glass membrane filter according to the present invention is characterized in that the inflow section 130 includes an inflow section 131 and an inflow surface section 132.
In addition, the present invention provides a functional glass membrane filter having a body 110, a filter 120, an inlet 130, and an outlet 140 that are excellent in convenience and solvent resistance.

Description

A functional glass membrane filter < RTI ID = 0.0 >

TECHNICAL FIELD The present invention relates to a filter for separating viruses and fungi, and relates to a functional glass membrane filter using a hollow fiber filter and having excellent convenience in the interior of the main body and excellent solvent resistance.

In the bio-market, there is a very high economic value separation and purification market when viruses or fungus isolates at 100 nm (0.1 μm) size.

Generally, the cost of 100ml virus or fungus is 50 ~ 100 thousand won / 100 ml, and the cost of 50 liter separation / purification is 3 ~ 40 million won / 50 liters.

 Separation and purification of these viruses and fungi are carried out by using a membrane filter.

Hollow fiber membranes are tubular filaments that include an inner diameter, an outer diameter, and a wall thickness that is generally porous between them. The inner diameter is defined as the hollow portion of the fiber and is used to carry the infusion fluid or permeate fluid to be filtered when the fluid being filtered touches the outer surface. The inner hollow portion is sometimes referred to as a lumen.

Hollow fiber membranes are used in a variety of applications including gas separation, reverse osmosis, ultrafiltration and removal of particulates and bacteria using micro-porous membranes. In these applications, the membrane acts as a permeation barrier, allowing it to pass through the carrier fluid and some dissolved or dispersed species, and retains a select species due to the size of the species, the rate of permeation rate, and other physical and chemical properties .

In practical applications, the fibers are cut or otherwise made to a specific length, and a large number of fibers are gathered to form a bundle. The portion of one or both ends of the fiber bundle is encapsulated with a material that fills the interstitial space between the fibers and forms a tube sheet. This process is sometimes referred to as potting fibers, and the material used to port the fibers is called a potting material.

The tube sheet is bonded to the filter device and serves as a seal. If the encapsulation process closes and seals the fiber ends, one or both ends of the potted fiber bundle is cut across the diameter or otherwise open. In some cases, the open fiber ends are closed and sealed prior to encapsulation to prevent the encapsulating material from entering the open ends. If only one end is open to allow fluid flow, the other end is left closed or sealed. The filter device supports the potted fiber bundle and provides space for its concentrate, separated from the fluid to be filtered and the permeate fluid.

In use, the fluid flow contacts a surface, and separation takes place either on its surface or deep within the fiber wall. When the outer surface of the fiber contacts, the permeate fluid and species pass through the fiber wall and collect in the lumen to move to the open ends or ends of the fibers. When the inner surface of the fiber is contacted, the fluid stream to be filtered is introduced into the open ends or ends, and the permeate and species penetrate the fiber wall and are collected from the outer surface.

Various materials are used to form the seal. Epoxy resins and urethanes are commonly used as sealants. Thermoplastic polymers are another important class. These are polymers that can flow and form when heated and recover their inherent solid properties when cooled. As the application conditions in which the filter device is used become more stringent, the materials that can be used to form the seal are limited. For example, solutions based on organic solvents used for water coating in the microelectronics industry dissolve, swell or weaken urethane or epoxy-based seals. In the same industry, high temperature stripping baths consist of highly acidic oxidizing compounds that destroy sealings made of conventional polymers. Seals made from overfilled thermoplastic resins have excellent resistance to chemical and thermal degradation and provide excellent sealing materials.

As a result of the membrane filter technique using such a conventional hollow fiber, as disclosed in Patent No. 10-1331056 (antithrombotic hollow fiber membrane and filter), a hollow fiber having a lumen, a first fiber end set and a second fiber end set Wherein the first set of fiber ends are potted in potting resin defining a first inner wall near the first end of the vessel, Wherein the fiber end set is potted in a potting resin defining a second inner wall near the second end of the vessel and wherein the lumen of the hollow fiber membrane is in fluid communication with the blood flow from the first inner wall to the second inner wall And the potting resin comprises 0.005% to 10% (w / w) of a surface-deforming macromolecule. &Quot;

The present invention can separate and purify viruses, and silica particles having a size of 0.1 μm are concentrated and separated by dynamic light scattering (DLS) measurement. Particle size measurement 100 nm, effective ingredient measurement (0.1 wt.% -> 10 wt.%) To provide a functional glass membrane filter capable of providing a functional glass membrane filter.

Further, in the case of a conventional membrane filter according to the prior art and prior art, since the body portion is made of PE (polyethylene) or PP (polypropylene), it is opaque and the inside is not visible, It is difficult to confirm the problem, and a functional glass membrane filter for solving the problem is provided.

In addition, the present invention provides a functional membrane membrane filter that solves the problem of erosion when ethyl acetate, which is a solvent, is poor in solvent resistance in general membrane filters of the prior art and prior art.

In order to solve the above problems and needs,

The functional glass membrane filter includes a body 110, a filter 120, an inlet 130, and an outlet 140.

In addition, in the present invention, the main body 110 has a hollow space formed therein, and the filter unit 120 is inserted into the hollow space,

The functional glass membrane filter is characterized in that the filter unit (120) comprises a hollow fiber filter (121).

The functional glass membrane filter according to the present invention is characterized in that the inflow section 130 includes an inflow section 131 and an inflow surface section 132.

In addition, the present invention provides a functional glass membrane filter having a body 110, a filter 120, an inlet 130, and an outlet 140 that are excellent in convenience and solvent resistance.

The functionalized glass membrane filter according to the present invention is capable of virus isolation and purification. The silica particles having a size of 0.1 μm are concentrated and separated by dynamic light scattering (DLS) measurement. % -> 10wt.%).

Further, in the case of the conventional membrane filter of the prior art and the prior art, since the body portion is made of PE (polyethylene) or PP (polypropylene), it is opaque and the inside is not visible. Thus, whether the filtration is well- The filter unit 120, the inflow unit 130, and the outflow unit 140 are formed of acrylic, polycarbonate, or glass components, which are materials in which the inside is visible, It is easy to check whether the filter is closed or not, and the filtration efficiency is improved.

In addition, the conventional membrane filter of the prior art and prior art has a problem of poor solvent resistance, so that when using ethyl acetate as a solvent, erosion may occur. The present invention may be applied to a membrane filter having a main body 110, a filter 120, The portion 130 and the outlet portion 140 are made of glass components. Even when ethyl acetate is used as a solvent, no erosion phenomenon occurs at all, and the inside is visible.

1 is a structural schematic view of a functional glass membrane filter according to the present invention;
FIG. 1B is a conceptual view of a hollow fiber filter of a functional glass membrane filter according to the present invention. FIG.
2 is a detailed structural view of an inlet of a functional glass membrane filter according to the present invention.
FIG. 2B is a conceptual view of an inlet surface and an inlet of an inlet of the functional glass membrane filter according to the present invention. FIG.
FIG. 2c is a view showing a coupling structure of an inlet portion and an inlet connection portion of the functional glass membrane filter according to the present invention. FIG.
3 is a structural view of an outlet of a functional glass membrane filter according to the present invention.
FIG. 3B is a view showing a coupling structure of an outlet portion and an outlet connection portion of the functional glass membrane filter according to the present invention. FIG.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

The present invention provides a functional glass membrane filter having an inner body that is formed of a body 110, a filter 120, an inlet 130, and an outlet 140, and which is easy to see and has excellent solvent resistance.

The technical feature of the present invention is that the virus can be separated and purified, and silica particles having a size of 0.1 μm are concentrated and separated by Dynamic Light Scattering (DLS) 10 wt.%). ≪ / RTI >

The body 110 of the present invention has a space in which the filter unit 120 can be inserted and the inlet 130 and the outlet 140 are connected to each other, Quot; means an apparatus or means in which the function of introducing the substance to be filtered through is performed.

The filter unit 120 of the present invention means an apparatus or means for performing a function of filtering a substance that is inserted into the inside of the main body 110 and filtered.

As shown in FIG. 1, the main body 110 has a hollow space therein, and the filter unit 120 is inserted into the hollow space.

The technical feature of the present invention is that the above-mentioned filter unit 120 is made of the hollow fiber filter 121.

The hollow fiber filter 121 of the present invention means a hollow fiber filter, that is, a hollow fiber having the shape of a tube and having a hole in the outer wall thereof, which means a filter using "hollow fibers" . The size of the hole depends on the intended use of the hollow fiber filter.

As shown in FIG. 1B, the filter unit 120 of the present invention means that a plurality of bundle hollow fiber filters 121 are gathered together.

The hollow fiber of the present invention may be a polymer resin used as a conventional hollow fiber filter.

The hollow fiber of the present invention may employ a polymer resin such as polysulfonic acid or polyacrylonitrile.

In addition, the hollow fiber of the present invention is a perfluorinated thermoplastic resin that is a polymer resin such as poly (tetrafluoroethylene-co-perfluoro (alkyl vinyl ether)) or poly (tetrafluoroethylene-co-hexafluoropropylene) . ≪ / RTI >

The hollow fibers of the present invention are also provided with a polymeric blend of poly (vinyl acetate) (PVAc) and poly (acrylic acid) (PAA) wherein the poly (vinyl acetate), based on 100 parts by weight of the blend, And poly (acrylic acid) are mixed with about 20 to 80 parts by weight of a polymer resin.

Preferred embodiments of the polymeric blends of poly (vinyl acetate) (PVAc) and poly (acrylic acid) (PAA) include blends of 20 wt% PVAc and 80 wt% PAA, blends of 40 wt% PVAc and 60 wt% A blend of 50 wt% PVAc and 50 wt% PAA, a blend of 80 wt% PVAc and 20 wt% PAA, a blend of 60 wt% PVAc and 40 wt% PAA, and a blend of 80 wt% PVAc and 20 wt% PAA .

That is, there is provided a polymeric resin fiber produced from a polymeric blend of a hydrophilic polymer and a hydrophobic polymer, such as PVAc and PAA, wherein the fibers are melt-spinned and have cells therein, Thereby forming a connected network.

In certain embodiments, the fibers are hollow. In another particularly preferred embodiment, at least some of these interconnected networks connect between the fiber interior and the fiber exterior. In another particularly preferred embodiment, at least some of the interconnected networks of cells connect between the hollow core of the fibers and the exterior.

The hollow fiber made of the polymer resin of the present invention is excellent in chemical resistance (acid resistance and basicity) and remarkably durable, and is particularly characterized in that there is no contamination damage due to a biomaterial, and thus is optimized for filtering the biomedia .

An inlet 130 is formed at the end of the main body 110 of the present invention.

As shown in FIG. 1, the inlet 130 of the present invention may be formed at both ends of the main body 110, and one end may be closed and the other end only.

The inlet 130 functions to allow the material to be filtered to flow into the plurality of bundled hollow fiber filters 121 of the filter unit 120.

The inflow section 130 of the present invention includes an inflow coupling section 131 and an inflow surface section 132.

2, the inflow coupling portion 131 of the inflow portion 130 has a structure or shape that allows the inflow coupling portion 133 to be coupled therewith, so that the inflow coupling portion 131 is coupled to the inflow coupling portion 133. [

Accordingly, the inlet joint 131 may have a coupling structure or function such as a screw shape.

The inlet surface portion 132 may have a structure in which the inlet port 132-1 is formed to allow the material to be filtered into the plurality of or bundle hollow fiber filters 121 of the filter portion 120, Shape.

The inlet port 132-1 is connected to each of the multiple or bundle hollow fiber filters 121. The inlet port surface 132 is closed at a portion other than the inlet port 132-1, The material to be filtered is introduced into the hollow fiber filter 121 only through the filter 132-1.

The inlet connection part 133 of the present invention has a structure that can be coupled to the inlet connection part 131 of the inlet part 130 and has a function of guiding and introducing the substance to be filtered, And is connected to the pipe 134 and functions to connect the inlet pipe to the inlet.

Therefore, the inflow connection portion 133 is formed with a coupling structure or function such as a screw or the like which has a structure such as a screw or the like of the inflow coupling portion.

The inflow pipe 134 is connected to the inflow connection portion 133 and functions to introduce the material to be filtered into the inflow portion.

The outlet 140 of the present invention is formed on the side surface of the main body 110 and performs a function of discharging the liquid after the material to be filtered is filtered.

As shown in FIG. 1, one or more outlet portions 140 of the present invention may be formed on the side surface of the main body portion.

The outflow section 140 includes an outflow coupling section 141 and an outflow port 142.

As shown in FIGS. 1 to 3, the outflow coupling portion 141 has a structure or a shape that allows the outflow connection portion 143 to be coupled therewith, so that the outflow connection portion 141 is coupled to the outflow connection portion 143.

Accordingly, the outflow coupling part 141 has a coupling structure or function such as a screw shape or the like.

The outlet 142 described above means a structure or means for performing a function of discharging holes or discharging liquid after the material to be filtered is filtered.

As shown in FIG. 3B, the outflow connection part 143 of the present invention has a structure or function to be coupled to the outflow coupling part 141. The outflow connection part 143 guides the filtrate after filtration of the material to be filtered, And is connected to the outflow pipe 144 and functions to connect the outflow pipe to the outflow pipe.

The outflow pipe 144 refers to an apparatus or device that performs a function of discharging the filtrate after the material to be filtered is filtered.

In general biotechnology, ethyl acetate (ethyl acetate), THF, hexane and the like are used in many cases as a solvent in filtration. In the case of a conventional membrane filter, the body part is made of PE (polyethylene) or PP (polypropylene) It is very difficult to confirm whether the filter is blocked because the inside is not visible and the filter is clogged.

The technical feature of the present invention is that the body 110, the filter 120, the inlet 130, and the outlet 140 are made of acrylic, polycarbonate, or glass.

The body portion 110, the filter portion 120, the inlet portion 130, and the outlet portion 140 of the present invention are made of acrylic, polycarbonate, or glass components, It is easy to see whether the filtration is good and whether the filter is closed or not, so that the filtration efficiency is improved.

In addition, when the acrylic resin or the polycarbonate, which is a material in which the body portion 110, the filter portion 120, the inlet portion 130, and the outlet portion 140 are seen, is poor in solvent resistance, When ethyl is used, the problem of erosion occurs.

Therefore, it is more preferable that the main body 110, the filter 120, the inlet 130, and the outlet 140 of the present invention are made of a glass material having an inner appearance and an excellent solvent resistance .

Since the main body 110, the filter 120, the inlet 130, and the outlet 140 are made of glass components as described above, even when ethyl acetate is used as a solvent, erosion does not occur at all And the inside is visible, thereby improving the convenience of checking the performance of the filtration.

The glass component of the present invention means glass or quartz.

According to the present invention, there is provided an environmentally friendly functional glass membrane filter excellent in durability against erosive organic solvents such as THF, ethyl acetate and hexane.

With this feature of the present invention, a material of 100 nm (0.1 μm) is selectively separated and concentrated in the filtration membrane of the functional glass membrane filter of the present invention, and the active ingredient is permeated and extracted.

The present invention provides an environmentally friendly functional glass membrane filter having the above-described structure and function.

The present invention is very useful in an industry for producing, manufacturing, processing and researching a filter or a filtering device, which is an industry that requires various separation and purification such as bio.

Particularly, the present invention is very useful in an industry for producing, manufacturing, processing and researching an apparatus for an industry that requires biodegradable tablets requiring biopreparation.

The body 110,
The filter unit 120, the hollow fiber filter 121,
The inlet portion 130, the inlet fitting portion 131, the inlet surface portion 132, the inlet 132-1,
The inlet connection 133, the inlet pipe 134,
The outlet 140,
The outflow coupling portion 141, the outlet 142,
The outflow connection portion 143, the outflow pipe 144,

Claims (2)

A functional glass membrane filter comprising a body part (110), a filter part (120), an inlet part (130), and an outlet part (140).
The method according to claim 1,
The main body 110 has a hollow space therein, and the filter unit 120 is inserted into the hollow space,
Wherein the filter unit (120) comprises a hollow fiber filter (121).

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