KR102260437B1 - Size selective separator for crystalline nano cellulose - Google Patents

Abstract

In the device for size separation of crystalline nano-cellulose according to the present invention, an inlet through which a solution containing crystalline nano-cellulose is introduced; a microchannel that is morphologically separated along the flow of a fluid solution containing crystalline nanocellulose and an external force field to provide a movement path for the nanomaterial solution; a chamber equipped with a microchannel; and an external force fields applying unit that applies one or more of an electric/magnetic field from the outside to separate substances in the chamber.

Description

Separation device by length of crystalline nanocellulose {Size selective separator for crystalline nano cellulose}

The present invention relates to the development of a process for separating crystalline nano-cellulose by length using an electric field and/or a magnetic field, and more particularly, an electric and/or magnetic field from the outside in a solution containing crystalline nano-cellulose having various lengths. It relates to the development of a technology and process for separating crystalline nanocellulose by length using the principle that the direction of flow of a solution and the direction of movement of a material by an external force field are different.

Since the advent of nanoscience and nanotechnology, the importance of technology for separating nano-sized particles by size has been greatly emphasized. In particular, the technology for detecting and separating nanoparticles is very important in fields such as public health and safety. In particular, if the properties of a material vary by size, this separation process is more essential.

In the separation of these nanomaterials, a filtration method using a fluid flow, centrifugal force, an electric field, or the like, or a physical hole or barrier such as a membrane or chromatography is mainly used.

In size separation of substances using the flow of fluid, the separation is performed using the difference in the movement speed in the fluid according to the weight of the substance, and the degree of simple dispersion of the size decreases, and relatively heavy substances accumulate inside the dispersion system and interfere with the flow of the fluid. As a result, the dispersion performance is further degraded. Due to these disadvantages, the flow of the fluid is used for dispersion with an external force such as an electric field rather than being used alone.

As a method of separating particles through an electric field, gel electrophoresis (GE) is known. This is a method that has proven its effectiveness in many cases of successful size and size separation in an electric field. However, the consumption time of the electrophoresis process is long, the separation resolution is limited because the viscous gel affects the mobility of the particles during the electrophoresis process, and the dye required for separation is harmful to the human body; The disadvantage is that an additional process is required to remove the gel and dye after fractionation. (Non-Patent Document 1)

Separation of substances using centrifugation is also a representative method used in separation, which is based on the difference in speed or density that occurs when centrifugal force is applied inside the liquid system depending on the size of the substance. A typical example of using the hydrodynamic behavior according to the size of a substance in a liquid system is centrifugation through an aqueous multiphase system, in which liquids with different densities are layered in a centrifuge tube step by step. ), then centrifuge the nanomaterials to separate the nanomaterials through the density difference according to the size. This has the advantage of high stability after separation and can be processed within a relatively short period of time within 10 minutes, but it is difficult to process large volumes by the complexity of finding a multiphase system suitable for the material and centrifugation. (Non-Patent Document 2)

Representative examples of filtration, which is another method of material size separation, are membrane and chromatography. Chromatography is a method that allows separation of materials by interaction between porous materials and particles filled therein. This is generally aimed at the analysis of specific substances rather than the recovery of the separated substances, and the separation of substances by size through this method seems inappropriate to be used for mass production (Non-Patent Document 1).

In addition, since the separation process for each particle size focuses on separating only spherical particles or rod or whisker-shaped particles with a very short aspect ratio, there is also a disadvantage in that there is a limitation on the shape of the size-separated particles (Patent Document 1 and Patent Document 2).

On the other hand, cellulose is the most abundant polymer material on earth, and can be easily extracted from natural materials such as wood, cotton, seaweed, and microorganisms. Along with the easy accessibility of these raw materials, cellulose also has strengths such as low density, high strength, eco-friendliness, and biocompatibility.

Cellulose is nanoscaled through chemical and/or physical treatment to show the behavior of nanomaterials (anisotropic shape stability and straightness), and has very high crystallinity and liquid crystallinity. These characteristics are particularly prominent in cellulose crystalline particles, fibers, rods, and the like. Nanocellulose has a diameter of about 2 to 20 nm, and has various lengths and crystallinity according to the extracted raw material and nanoization treatment method. According to a crystallinity measuring method (peak-height), the nano-cellulose has a crystallinity of at least 70%, and may have a crystallinity of 90% or more.

There is a big difference in physical properties depending on the aspect ratio and crystallinity of the fiber strands of nanocellulose. Many studies show that nanocellulose fibers with high aspect ratio and high crystallinity have high mechanical strength, thermal dimensional stability, and gas and moisture barrier properties. has been proven by In addition, due to the above-described characteristics, it is not only mentioned as a candidate material to replace general-purpose plastics, but also attracts attention as an industrial use (high-function packaging material, display, battery, electronic material, structural material, etc.).

As such, nanocellulose has different properties depending on the degree of simple dispersion according to the size of its length or diameter, so there have been studies to separate cellulose by length and diameter. However, until now, an efficient technique for separating cellulose by length has not been proposed.

In order to make cellulose with high potential value as a high-functional material, the present invention intends to develop a technology for selectively separating nano-cellulose according to its length by applying an electric/magnetic field.

Such crystalline nanocellulose differs greatly in size, properties, and structure from DNA and proteins that are separated using electric and magnetic fields, and has a significantly lower reaction force compared to inorganic nanomaterials and carbonaceous nanomaterials. It is difficult to apply the technique. On the other hand, under the liquid crystal phenomenon of cellulose, a very low reaction force partially acts to make alignment possible, and when it is placed in a fluid flow (hydro field), it appears as a continuous separation function. Therefore, in the present invention, by using the property of having liquid crystallinity of crystalline nano-cellulose, it is intended to newly present a technology using an electric field and a magnetic field to separate cellulose crystalline materials.

(Patent Document 1) Korean Patent Registration No. 10-0597443 (Patent Document 2) Korean Patent Registration No. 10-1807256

(Non-Patent Document 1) KONA Powder and Particle Journal, No.32,102-114 (2015) (Non-Patent Document 2) Nano Lett., 12, 40604064, (2012)

The present invention relates to the development of a technology for selectively separating according to its length in a solution containing crystalline nano-cellulose having a broad length distribution.

In addition, the present invention can separate a large amount of material through a fast and continuous separation process method, rather than improving the limitations of the separation sample, which is limited to spherical particles, and the method of gel selection and concentration control of the existing invention, and a fluid external force It relates to the development of a process for separating crystalline nano-cellulose by length using an electric field and/or a magnetic field that possesses the advantages of simplicity that can control the length of a material to be separated by controlling the field strength.

In order to achieve the above technical problem, a crystalline nano-cellulose separation device according to an aspect of the present invention includes an inlet through which a nano-cellulose solution is introduced; a microchannel for providing a movement path through which the nanocellulose is separated by length and can be moved to an outlet; an external force field applying unit for applying an electric field and/or a magnetic field to the microchannel so that the nano-cellulose can be separated by length; and an outlet through which the separated nano-cellulose is discharged.

According to one aspect of the present invention, the microchannel has a y-shape, and the outlet of the crystalline nanocellulose has an outlet that is coaxial with the inlet through which the nanocellulose solution is introduced, and an outlet that is coaxial with the inlet. and an outlet located at the end of the parent channel.

In one aspect of the present invention, the crystalline nano-cellulose is a highly crystalline nano-cellulose having high morphological stability with a crystallinity of 70% or more, and includes fibers, whiskers, and rods having a nano or micro-length range. It is crystalline nano-cellulose.

In one aspect of the present invention, the nano-cellulose is characterized in that it is a crystalline material that is morphologically nano- and micro-structured through physical and chemical treatment of at least one selected from wood, cotton, seaweed, and microorganisms.

In one embodiment of the present invention, the y-shaped microchannel has a diameter of 0.1 to 10 μm and a length of 0.1 to 3 cm, and the angle between a channel that is not coaxial with the inlet and a channel located on the coaxial line is It is characterized in that it is 10 to 45˚.

In one aspect of the present invention, the flow direction of the solution flowing inside the microchannel (b) and the flow of charges generated by applying an electric/magnetic field from the external force field application unit form an angle of about 0 - 180 degrees with each other. .

In one aspect of the present invention, the external force field applying unit is characterized in that the intensity of the field (fields) is adjusted by the external force field adjusting device.

In one embodiment of the present invention, the magnitude of the electric field regulated by the external force field adjusting device is 1 V to 100 KV, and the magnitude of the magnetic field is in the range of 0 to 10T.

In addition, in one embodiment of the present invention, a syringe pump may be connected to the solution inlet to enable continuous and stable supply of the solution.

According to one aspect of the present invention, the y-shaped microchannel enables separation of nano-cellulose by length according to the effect of an external force field through separation of fluid flow, and further increases the separation ability of nano-cellulose by length through multiple connection. can be raised

According to one aspect of the present invention, by the difference in mobility in the electric / magnetic field according to the diameter or length (aspect ratio) of the crystalline nano-cellulose, it can be configured to separate and move using the change in the arrangement of substances in the solution. have.

In the present invention, the crystalline nanocellulose is separated by length according to the difference in the mobility of the material by applying an external force field perpendicular to, parallel to, or at an angle of about 0 - 180 degrees from the outside of the y-shaped microchannel to the flow direction of the fluid. can do. In addition, since the strength of an externally applied electric field and/or magnetic field can be flexibly adjusted, nano-cellulose of various lengths can be separated simply and quickly.

1 is a schematic diagram of a material separation apparatus according to an embodiment of the present invention.
FIG. 2 is a plan view of the material separation apparatus of FIG. 1 viewed from an upper direction.
FIG. 3 is a schematic diagram showing the continuity of the process through an additional connection of the same device to the solution outlet of the material separation device of FIG. 2 .
4 is a diagram showing the configuration of the external force field used in this experiment and the range of angles that can be installed with respect to the axis parallel to the inflow direction of the fluid.
5 is a graph showing an expected separation result according to the concept of the present invention.
6 is a TEM photograph showing cellulose of various sizes that can be separated in the present invention. a) represents a long length, and b) represents a short length cellulose.
7 is an SEM photograph showing cellulose of various sizes that can be separated in the present invention. a) represents a long length, and b) represents a short length cellulose.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings, if necessary.

In each drawing of the present invention, the size or dimensions of the structures are shown to be enlarged or reduced than in actuality for the sake of clarity of the present invention, and the known configurations have been omitted so as to reveal a characteristic configuration, so the drawings are not limited thereto. .

In describing the principle of the preferred embodiment of the present invention in detail, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, since the configuration shown in the embodiments and drawings described in this specification is only the most preferred embodiment of the present invention and does not represent all the technical spirit of the present invention, various It should be understood that there may be equivalents and variations.

1 is a block diagram of a material separation apparatus according to an embodiment of the present invention, and FIG. 2 is a plan view of the material separation apparatus of FIG. 1 viewed from the top.

1 and 2, the material separation apparatus of the present invention includes a chamber (e) including a microchannel (b) having a y-shape, a solution inlet (a), and a solution outlet (c, d), etc. It can be composed of an external force field applying unit (f, g).

In the present invention, the separation efficiency can be further increased by separating the flow of the fluid passing through the external force field through the y-shaped channel. The y-shaped microchannel may have a diameter of 0.1 to 10 μm and a length of 0.1 to 3 cm. For a channel that is not coaxial with the inlet, the angle γ with the channel located on the coaxial line can be 10 ~ 45˚. Separation efficiency may be lowered by resistance. However, the above channel dimension is a condition that can be changed according to a user's need.

In addition, as shown in FIG. 3 , the separation efficiency of the y-shaped microchannel can be further increased by adding different y-shaped microchannels to the outlet of the channel. At this time, it is possible to obtain nano-cellulose having different lengths for each h, i, j, and k outlet. In addition, more y-shaped microchannels can be attached to each h, i, j, and k outlet, and the separation efficiency is further increased as the 2nd, 3rd, and 4th stages are progressed in this way.

The solution entering from the solution inlet should avoid cross flow or eddy in the flow of the fluid in order to remove the third influence factor except for the flow direction of the fluid and the influence of the external force field. To this end, the fluid must proceed as a laminar flow, and the flow rate of the fluid must be maintained so that the Reynolds number (Re), which is a dimensionless group, is 2100 or less under the conditions of a given chamber and solution.

(D = diameter of tube, average flow rate of solution, = viscosity of solution, = density of solution)

A syringe pump may be connected to the solution inlet (a) to supply the solution at a constant flow rate.

The syringe pump can be replaced with a peristaltic pump that delivers a certain amount per unit time during the existing process for mass production.

Here, the flow direction of the solution flowing inside the microchannel (b) and the flow of charges generated by applying an electric field and/or a magnetic field in the external force field applying units (f, g) is about 0 - 180 degrees, as shown in FIG. 4 . form the angle of By adjusting the angle of application of the external force field, the flow direction of the cellulose nanofiber solution of the length to be separated can be changed, and the separation efficiency can be adjusted.

The external force field applying unit (f, g) may be located inside or outside the flow of the fluid, and serves to apply an electric field and/or a magnetic field to the fluid.

The shape of the positive electrode and the negative electrode forming the electric field may have a point shape, a linear shape, or a planar shape. Also, the shape of the N pole and the S pole forming a magnetic field may have a point shape, a linear shape, or a planar shape.

The external force field applying unit f, g may flexibly adjust the strength of the electric/magnetic field through the external field strength adjusting device. In addition, this electric/magnetic field control allows different mobility in the electric/magnetic field according to the diameter or length (aspect ratio) of the crystalline nano-cellulose, and enables separation by length.

At this time, the appropriate range of the electric field may be 1 V - 100 KV, and the range of the magnetic field may be in the range of 0 ~ 10T.

The crystalline nano-cellulose fibers to be separated in the present invention have a length range of nano or micro, and show a difference in mobility in an electric/magnetic field according to a length and an amount of charge.

Cellulose fibers may be obtained by treating a natural product, for example, may be obtained by chemically/physically treating wood, cotton, seaweed, microorganisms, and the like.

In the method by the chemical treatment, the properties of the finally obtained cellulose fiber may vary depending on the chemical treatment agent. The cellulose produced through sulfuric acid is N,N-dimethyl formaldehyde, dimethyl sulfoxide, N-methyl pyrrolidone, Formic except for water. While dispersible in solvents of acid and M-cresol, cellulose produced by treating hydrochloric acid can only be dispersed in solvents of formic acid and M-cresol, unlike cellulose treated with sulfuric acid. Therefore, in the case of sulfuric acid-treated nano-cellulose, water, N, N-dimethyl formaldehyde, dimethyl sulfoxide, N-methyl pyrrolidone, Formic acid, M-cresol, in the case of hydrochloric acid-treated nano-cellulose, Formic acid, M-cresol, etc. are used in the present invention It should be selected as a solvent for material separation of

When an electric field is applied to the cellulose fibers, they are arranged in the direction of the electric field, and when a magnetic field is applied, they are arranged at right angles to the direction of the magnetic field, which is due to the dielectric properties and diamagnetic properties of cellulose. There is a difference in the degree depending on the diameter or length (aspect ratio) of the cellulose, and separation by length of the material is possible by the difference in the degree.

When the field applied by the external force field applying unit is an electric field, the degree of reaction (electrophoretic mobility) in the electric field varies according to the difference in charge density according to the difference in the aspect ratio of materials separated in the electric field (electrophoretic mobility), and thus separation becomes possible

In addition, when the field applied by the external force field applying unit is a magnetic field, the strength of the magnetic field in which the arrangement is made is changed according to the difference in the aspect ratio of the materials separated in the magnetic field, and according to this difference, the length of the material in the magnetic field of a certain size is different. makes separation possible.

In the present invention, the following method can be used to calculate the separation efficiency for each length and aspect ratio of cellulose.

Separation of cellulose by length and aspect ratio is conceptually similar to classifying polymer chains by molecular weight.

The molecular weight distribution of a polymer is defined by a number average molecular weight (Mn) and a weight average molecular weight (MW), and the ratio of the two molecular weights is a polydispersity index (PDI).

(Ni: the number of polymer chains having a molecular weight Mi)

If all molecules had the same molecular weight, then Mn=Mw. From this, it can be seen that as the polydispersity index approaches 1, the molecular weight distribution becomes narrower, resulting in monodisperse.

Due to the conceptual similarity between polymer chains and nanocellulose, the molecular weight (polymer polymerization degree) of the polymer chain could be replaced by the length or aspect ratio of the nanocellulose.

(Ni: the number of nano celluloses having an aspect ratio Ri, aspect ratio Ri = length/diameter of cellulose fibers)

Additionally, the polydispersity index can be calculated by analyzing the SEM image of each sample separated by an external force field.

<Example>

In order to indirectly measure the crystalline nano-cellulose separation effect and efficiency according to the present invention, the experiment was constructed as follows.

(a) Preparation of crystalline nanocellulose

To make a natural cellulose solution, tunicate (Halocynthia roretzi), which has undergone a bleaching process, was mixed with 55 vol% sulfuric acid, and then reacted at a temperature of 60° C. and stirring conditions for 1 hour to extract cellulose fibers. After acid treatment, the salt removal result was diluted in distilled water, and then dispersed using an ultrasonic vibrator to prepare a solution in which nano-cellulose fibers were dispersed.

(b) Separation by length through a crystalline nanocellulose separation device

Next, the nano-cellulose solution is introduced into the solution inlet of the material separation device of the present invention. In this case, a microchannel having a diameter of 5 μm and a length of 3 cm was used. A magnetic field was applied at 7 T in a direction orthogonal to the flow of the fluid through an external force field application device to control the range of the length of the separated cellulose fibers. At this time, the applied 7 T is generally the magnetic field strength that successfully enables the orientation of the liquid nanocellulose.

Each separated solution was obtained from a y-shaped microchannel composed of a solution outlet from which the separated substances are discharged, and the y-shaped angle γ was 20˚.

(c) Monodisperse calculation method to confirm the separation result.

In order to indirectly compare the degree of separation of the cellulose nanofibers prepared in Examples and Comparative Examples, the following experiment was performed.

The cellulose solution is coated on the glass substrate using the Layer by Layer method to minimize overlap between fibers during SEM measurement. In order to increase the coatability of the fiber on the glass substrate, the glass substrate is immersed in 1 vol% PEI solution for 10 minutes, then taken out and washed with distilled water. The PEI-coated glass substrate is immersed again in about 0.5 to 1 wt% of a cellulose solution. After that, it is washed and dried in the same way to complete the sample for measurement.

Thereafter, the aspect ratio of the cellulose nanofiber is measured through the SEM image, and the PDI value of the cellulose fiber is calculated by substituting the measured aspect ratio and the number of fibers in Equation 6 above.

It can be determined that the closer the PDI calculated value to 1, the more homogeneous separation and high separation rate.

<Comparative example>

In order to confirm the difference in the separation behavior of cellulose nanofibers according to the presence or absence of an external force field, for example, a magnetic field, (a) and (b) of the embodiment are performed without applying a magnetic field (0 T). In order to confirm the result, each fluid flowing out of the y-shaped tube was collected, and (c) of Example was performed.

As a result of calculating the separation efficiency through a simple dispersion calculation method by obtaining a solution from each outlet pipe in the Example, the coaxial pipe showed 0.7 and the branch pipe 0.8, whereas in the comparative example, the coaxial pipe was 0.3, The branch canal showed a PDI value of about 0.3. Comparing the PDI values of the Examples and Comparative Examples, it can be confirmed that the PDI of the Example is about 2.3 times or more of the PDI of the Comparative Example, and the PDI of the Example is much closer to 1.

This is because the long-length nano-cellulose fiber is more affected by the applied magnetic field than the short-length fiber, so it flows into the bent part of the y-tube without maintaining the flow direction, and it appears that it is eventually separated from the short-length nano-cellulose fiber. lose

The separation efficiency and PDI value will increase as the material separation apparatus is multi-connected, and may be changed by the length or diameter of the micro separation apparatus and the applied external force field.

The present invention is not limited to one system, and the present invention is not limited to a single system as shown in FIG. 3, and the length range of the separated crystalline nano-cellulose can be narrowed by additionally connecting the same device to the solution outlet of the device. have.

One embodiment of the present invention described above should not be construed as limiting the technical spirit of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those of ordinary skill in the technical field of the present invention can improve and change the technical idea of the present invention in various forms. Therefore, such improvements and changes will fall within the scope of the present invention as long as it is apparent to those of ordinary skill in the art.

Claims (8)

In the separation device for separating the crystalline nano-cellulose by length,
The separation device includes an inlet through which the nano-cellulose solution is introduced;
a microchannel for providing a movement path through which the nanocellulose is separated by length and can be moved to an outlet;
an external force field applying unit for applying an electric field and/or a magnetic field to the microchannel so that the nano-cellulose can be separated by length; and
Including an outlet through which the separated nano-cellulose flows out,
The external force field applying unit controls the strength of the fields by the external force field control device, the length of the electric field controlled by the external force field control device is 1 V - 100 KV, the length of the magnetic field is in the range of 0 - 10 T Separation device by length of crystalline nano-cellulose using dielectric and diamagnetic properties of cellulose, characterized in that. The channel of claim 1, wherein the microchannel has a y-shape, and the outlet of the crystalline nano-cellulose is coaxial with the inlet through which the nano-cellulose solution is introduced, and the channel is branched off the coaxial line with the inlet. Separation device by length of crystalline nano-cellulose comprising an outlet located at the end of the. The method of claim 1, wherein the crystalline nano-cellulose is a highly crystalline nano-cellulose having a high morphological stability with a crystallinity of 70% or more, and includes fibers, whiskers, and rods having a nano or micro-length range. Separation device by length of phosphorus crystalline nanocellulose. The length of the crystalline nano-cellulose according to claim 3, wherein the nano-cellulose is a crystalline material that is morphologically nano- and micro-structured through physical and chemical treatment of at least one selected from wood, cotton, seaweed, and microorganisms. Star Separator. The y-shaped microchannel according to claim 2, wherein the y-shaped microchannel has a diameter of 0.1 to 10 μm and a length of 0.1 to 3 cm, and the angle between the inlet and the side-branched channel not coaxial with the coaxial channel is 10 ~ 45˚ separation device by length of crystalline nano-cellulose. The crystal according to claim 1, wherein the flow direction of the solution flowing inside the microchannel (b) and the flow of charges generated by applying an electric/magnetic field from the external force field application unit form an angle of 0 - 180 degrees with each other. Separation device by length of sexual nanocellulose. delete delete

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