KR102087232B1 - Anti-fouling member utilizing magnetic field-responsive dynamic surface - Google Patents

Abstract

An anti-fouling member according to the present invention can effectively prevent bacteria from forming a biofilm on the surface because the surface itself is repeatedly and continuously deformed in a wave form by a magnetic field. In addition, since the size, position, and shape of the wave form generated on the surface can be controlled differently by controlling the intensity of the magnetic field, it is possible to suppress settling of bacteria and more effectively prevent formation of the biofilm.

Description

Anti-fouling member utilizing magnetic field-responsive dynamic surface

The present invention relates to an antifouling member utilizing a magnetically responsive dynamic surface, and more particularly, to an antifouling member using a magnetically responsive dynamic surface capable of preventing bacteria from forming a biofilm by flowing the surface itself using a magnetic field. It is about.

In general, microorganisms including bacteria are grown in stagnant water or fluid, and then multiply. The microorganisms are classified into fungi, bacteria, protozoa, algae, etc. and inhabit in the fluid.

Bacteria multiply and form a protective film when they are disadvantageous to self reproduction and are called biofilms or bacterial biofilms. When bacteria form biofilms on internal tissues or medical devices of the human body, there is a problem in that the antimicrobial effects of antibiotics and chemicals are reduced. In addition, when formed in the hull, the ship's performance is reduced and fuel flow rate is increased.

Recently, in order to suppress the generation and proliferation of microorganisms, an antifouling paint or a pollution inhibitor is added to a fluid, or a method of irradiating a radiation source such as ultraviolet rays is used. However, there is a problem in that the proliferation of microorganisms cannot be fundamentally prevented.

Korean Patent Registration No. 10-1297531

An object of the present invention is to provide an antifouling member utilizing a magnetically responsive dynamic surface capable of preventing the bacteria from forming a biofilm by modifying the surface by a magnetic field.

An antifouling member utilizing a self-reactive dynamic surface according to the present invention includes a base layer formed of an elastic material; A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field; A nano film layer laminated on the magnetic reaction layer and having a nano pattern formed thereon; An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer; A magnetic field generating unit is provided to be capable of reciprocating under the base layer and changes at least a portion of the surface of the magnetic reaction layer into a wave shape by changing a magnetic field around the base layer.

An antifouling member utilizing a self-reactive dynamic surface according to another aspect of the present invention includes a base layer formed of an elastic material and formed in a hollow tubular shape; A magnetic reaction layer laminated on an inner circumferential surface of the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field; A nano film layer laminated on an inner circumferential surface of the magnetic reaction layer and having a nano pattern formed thereon; An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer; It is provided on the outer circumferential side of the base layer to include a magnetic field generating unit for changing at least a portion of the magnetic reaction layer to the wave shape by changing the magnetic field around the base layer.

An antifouling member utilizing a self-reactive dynamic surface according to another aspect of the present invention includes a base layer formed of an elastic material; A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field; A nano film layer stacked on the magnetic reaction layer and having a plurality of magnetic fillers moving in the direction of the magnetic field; An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer; A magnetic field generating part provided to be capable of reciprocating under the base layer to change a magnetic field around the base layer to deform at least a portion of the surface of the magnetic reaction layer into the wave shape, wherein the magnetic field generating part includes: It is arranged at a predetermined interval apart from the base layer, the magnet portion for generating the magnetic field, the drive portion for reciprocating the magnet portion, and the position of the deformation to the wave shape by changing the direction of the reciprocating motion by controlling the drive portion It includes a control unit for controlling to change.

An antifouling member utilizing a self-reactive dynamic surface according to another aspect of the present invention includes a support layer; A base layer laminated on the support layer and formed of an elastic material; A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field; A nano film layer laminated on the magnetic reaction layer and having a nano pattern formed thereon; An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer; It is provided to the reciprocating motion of the lower side of the support layer, and by changing the magnetic field around the support layer includes a magnetic field generating portion for transforming at least a portion of the surface of the magnetic reaction layer into the wave shape.

In the antifouling member according to the present invention, since the surface itself is repeatedly and continuously deformed into a wave shape by a magnetic field, it is possible to effectively prevent bacteria from forming a biofilm on the surface.

In addition, by controlling the intensity of the magnetic field, it is possible to control the size, position, and shape of the wave shape generated on the surface differently, there is an advantage that can effectively prevent the settlement of bacteria and prevent the formation of the biofilm.

1 is a view showing an antifouling member utilizing a self-reactive dynamic surface according to a first embodiment of the present invention.
2 is a view showing the action of the antifouling member shown in FIG.
3 is a view showing an antifouling member utilizing a magnetically responsive dynamic surface according to a second embodiment of the present invention.
4 is a view showing an antifouling member utilizing a magnetically responsive dynamic surface according to a third embodiment of the present invention.
FIG. 5 is a diagram illustrating an antifouling member utilizing a magnetically responsive dynamic surface according to a fourth embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing an antifouling member utilizing a self-reactive dynamic surface according to a first embodiment of the present invention. 2 is a view showing the action of the antifouling member shown in FIG.

Referring to FIGS. 1 and 2, the antifouling member 10 includes a base layer 11, a magnetic reaction layer 12, a nano film layer 13, and an antifouling layer 14 sequentially stacked on a magnetically responsive dynamic surface. And a magnetic field generator 15 for modifying the magnetically responsive dynamic surface.

The base layer 11 is a layer having a predetermined first thickness and having a constant thickness. The base layer 11 is formed of an elastic material having a low Young's modulus so that the magnetic reaction layer 12 may be deformed together when deformed by a magnetic field.

The elastic material is described as an example using a material in which Polydimethylsiloxane (PDMS) and silicone oil (Silicon oil) are mixed at an appropriate ratio, but is not limited thereto.

The magnetic reaction layer 12 is laminated on one surface of the base layer 11 and formed of a magnetic material. The magnetic reaction layer 12 is a layer having a predetermined second predetermined thickness and having a constant thickness. At least a portion of the magnetic reaction layer 12 is deformed into a wave shape by a magnetic field generated by the magnetic field generating unit 15. That is, the magnetic reaction layer 12 may protrude convexly in the direction toward the magnet unit described later by the magnetic field.

The magnetic reaction layer 12 is formed of a magnetic material mixed with magnetic particles and an elastic material.

The magnetic particles may be carbonyl iron (CI) microparticles, but are not limited thereto.

The nanofilm layer 13 is a thin film formed to be laminated on the surface of the magnetic reaction layer 12. The nano pattern is formed on the surface of the nano film layer 13 so that microorganisms such as bacteria are difficult to deposit. The thickness of the nanofilm layer 13 is less than about 50 μm.

The antifouling layer 14 is a thin film formed by coating an antifouling material on the surface of the nanofilm layer 13. The antifouling material is described as an example using MPC (Methacryloyloxyethyl phosphorylcholine), but is not limited thereto.

The magnetic field generating unit 15 is provided on the other side of the base layer 11 to change the magnetic field around the base layer 11 so that at least a portion of the magnetic reaction layer 12 deforms into a wave shape.

The magnetic field generator 15 includes a magnet 16, a driver 17, and a controller (not shown).

The magnet part 16 can use a permanent magnet or an electromagnet. The magnet part 16 may be arranged in a plurality of array form.

The magnet part 16 is disposed to be spaced apart from the base layer 11 by a predetermined distance to generate the magnetic field. The distance between the magnet part 16 and the base layer 11 is set so that the magnetic reaction layer 12 is deformed into a wave shape so that no interference with the magnet part 16 occurs when a part of the magnet reaction layer 12 protrudes.

The drive unit 17 may be any structure as long as the drive unit 17 can reciprocate the magnet unit 16. The drive unit 17 may be configured to enable two-axis or three-axis movement.

The controller (not shown) may control the driving unit 17 to change the direction of the reciprocating motion. The controller (not shown) may control the magnet unit 16 to move according to a preset period.

When the magnet part 16 is an electromagnet, the controller (not shown) may control the magnet part 16 to change the intensity of the magnetic field to change the size or shape of the wave shape.

Referring to the operation according to the first embodiment of the present invention configured as described above are as follows.

Referring to FIG. 2, the controller (not shown) controls the operation of the driving unit 17 to reciprocate the magnet unit 16.

When the magnet part 16 is moved, the surface shape of the magnetic reaction layer 12 is changed.

A portion of the magnetic reaction layer 12 that faces the magnet portion 16 is deformed into a wave shape, and a position where the magnet portion 16 is deformed into the wave shape changes along the moving direction of the magnet part 16.

When the shape of the magnetic reaction layer 12 is deformed by the magnetic field generated by the magnet part 16, the base layer 11, the nanofilm layer 13, and the antifouling layer 14 are integrally formed. Is deformed.

The controller (not shown) may control the operation of the driving unit 17 to control the position of the wave shape by changing the position of the magnet unit 16.

In addition, when the magnet part 16 is an electromagnet, the controller (not shown) may control the magnet part 16 to adjust the strength of the magnetic field, thereby controlling the size or shape of the wave shape differently. .

As shown in Figures 2a to 2c, the position of the wave shape is changed as the position of the magnet portion 16 moves.

Therefore, since the self-reactive dynamic surface itself flows, microorganisms such as bacteria can be prevented from forming a biofilm on the surface. That is, since the bending is formed on the surface and the surface bending is continuously and repeatedly moved, not only the biofilm formation can be prevented, but also the settlement of bacteria can be suppressed.

In the present invention, rather than changing the fluid flow around the self-reactive dynamic surface, the self-reactive dynamic surface itself is flowing, it is possible to more actively suppress the formation of biofilm on the surface of bacteria.

Thus, an active and original antifouling effect can be obtained against bacteria.

3 is a view showing an antifouling member utilizing a magnetically responsive dynamic surface according to a second embodiment of the present invention.

Since the antifouling member 20 according to the second embodiment of the present invention is formed in a hollow tubular shape, the first embodiment differs from the first embodiment, and the rest of the configuration and operation are similar to those of the first embodiment. It demonstrates in detail centering.

The antifouling member 20 is formed by laminating the base layer 21, the magnetic reaction layer 22, the nanofilm layer 23, and the antifouling layer 24 in order, and then rolling the tube to form a magnetic reaction dynamic surface. It is formed to achieve. However, the present invention is not limited thereto, and after the base layer 21a is previously formed of a hollow base tube, the magnetic reaction layer 22, the nano film layer 23, and the antifouling layer may be formed on an inner circumferential surface or an outer circumferential surface of the base tube. It is also possible for 24) to be laminated in sequence.

The base layer 21 is formed by forming a sheet having a predetermined first predetermined thickness and having a constant thickness rolled up like a tube. The base layer 21 is formed of an elastic material having a low Young's modulus so that the magnetic reaction layer 22 may be deformed with the magnetic field.

The magnetic reaction layer 22 is laminated on the inner circumferential surface of the base layer 21 and formed of a magnetic material. However, the present invention is not limited thereto, and the magnetic reaction layer 22 may be formed on an outer circumferential surface of the base layer 21.

The magnetic reaction layer 22 is a layer having a predetermined second predetermined thickness and having a constant thickness. The magnetic reaction layer 22 is at least partially deformed into a wave shape by the magnetic field generated by the magnetic field generating unit.

The magnetic reaction layer 22 is formed of a magnetic material mixed with magnetic particles and an elastic material.

The nanofilm layer 23 is a thin film formed to be laminated on the surface of the magnetic reaction layer 2. The nano pattern is formed on the surface of the nano film layer 23 so that microorganisms such as bacteria are difficult to deposit. The thickness of the nanofilm layer 23 is less than about 50 μm.

The antifouling layer 24 is a thin film formed by coating an antifouling material on the surface of the nanofilm layer 23. The antifouling material is described as an example using MPC (Methacryloyloxyethyl phosphorylcholine), but is not limited thereto.

The magnetic field generating unit is provided on an outer circumferential side of the base layer 21 to change a magnetic field around the base layer 21 so that at least a portion of the magnetic reaction layer 22 protrudes in a radial direction and deforms into a wave shape. do.

The magnetic field generating unit includes a magnet unit 25, a driving unit (not shown), and a control unit (not shown).

The magnet part 25 is disposed radially spaced apart from the outer circumferential surface of the base layer 21 by a predetermined interval, and is described by way of example as being formed in a ring shape. The magnet part 25 can use a permanent magnet or an electromagnet.

The driving unit (not shown) causes the magnet part 25 to reciprocate at a predetermined period along the longitudinal direction of the base layer 21.

The controller (not shown) may control the driving unit (not shown) to change the speed of the reciprocating motion. The controller (not shown) may control the magnet part 25 to move according to a preset period.

When the magnet part 25 is an electromagnet, the controller (not shown) may control the magnet part 25 to change the strength of the magnetic field to deform the size or shape of the wave shape.

However, the present invention is not limited thereto, and a plurality of the magnet parts 25 may be disposed in the longitudinal direction of the base layer 21.

In addition, the magnetic field generating unit, a driving ring (not shown) disposed in the radial direction from the outer circumferential surface of the base layer 21 to move along the longitudinal direction of the base layer 21, and the driving ring ( It is also possible to be composed of a plurality of magnet parts (not shown) coupled to be spaced apart by a predetermined interval in the circumferential direction.

In addition, in the second embodiment, for example, the base layer 21 is provided at the outermost portion. However, the present invention is not limited thereto, and a magnetic field or deformation of the base layer 21 is formed on the outer circumferential surface of the base layer 21. In addition, a support layer (not shown) that is not deformed because of no influence is further provided to prevent the base layer 21 from being deformed in the direction toward the magnet part 25.

4 is a view showing an antifouling member utilizing a magnetically responsive dynamic surface according to a third embodiment of the present invention.

4, in the antifouling member 30 according to the third embodiment of the present invention, the base layer 31, the magnetic reaction layer 32, the nanofilm layer 33, and the antifouling layer 34 are sequentially stacked. And a magnetic field generating part 35 for deforming the magnetically responsive dynamic surface, wherein the nanofilm layer 33 has a plurality of magnetic fillers moving along the direction of the magnetic field. Different from the first embodiment, the rest of the configuration and operation is similar to the first embodiment, and thus only a different configuration will be described in detail.

The plurality of magnetic fillers 33a may be formed in a needle shape such that the cross-sectional area of the magnetic fillers 33a decreases toward the tip, and microorganisms such as bacteria may suppress the settlement.

The antifouling layer 34 is a nanostructured coating layer formed on the surfaces of the magnetic pillars 33a. The antifouling layer 34 may be coated with nanoparticles such as carbon nanoparticles (CNP), and may also be formed by nanoimprinting or nanomoulding.

The magnetic field generator 35 includes a magnet 36, a driver 37, and a controller (not shown).

The magnet part 36 can use a permanent magnet or an electromagnet. The magnet part 36 may be arranged in a plurality of array form.

The magnet part 36 is disposed to be spaced apart from the base layer 31 by a predetermined distance to generate the magnetic field. The distance between the magnet part 36 and the base layer 31 is set so that the magnetic reaction layer 32 is deformed into a wave shape so that interference with the magnet part 36 does not occur when a part thereof protrudes.

The controller (not shown) may control the driving unit 37 to change the direction of the reciprocating motion. The controller (not shown) may control the magnet part 36 to move according to a preset period.

When the magnet part 36 is an electromagnet, the controller (not shown) may control the magnet part 36 to change the magnitude or shape of the wave shape by changing the intensity of the magnetic field.

The antifouling member 30 configured as described above changes the surface shape of the magnetic reaction layer 32 when the magnet part 36 is moved.

A portion of the magnetic reaction layer 32 opposite to the magnet portion 36 is deformed into a wave shape, and a position of the magnetic reaction layer 32 deformed into the wave shape is changed along the moving direction of the magnet part 36.

When the shape of the magnetic reaction layer 32 is deformed by the magnetic field generated by the magnet part 36, the base layer 31, the nanofilm layer 33, and the antifouling layer 34 are integrally formed. Is deformed.

In addition, when the magnet part 16 is an electromagnet, the controller (not shown) may control the magnet part 16 to adjust the strength of the magnetic field, thereby controlling the size or shape of the wave shape differently. .

In addition, the magnetic pillars 33a of the nanofilm layer 33 move by the magnetic field generated by the magnet part 36. The magnetic pillars 33a move according to the magnetic field, and the fluid around the magnetically responsive dynamic surface can flow without stagnation, and thus microorganisms such as bacteria can be suppressed.

In addition, in the third embodiment, the base layer 31 is provided at the lowermost side, for example. However, the present invention is not limited thereto, and a magnetic field or deformation of the base layer 31 is formed on the outer circumferential surface of the base layer 31. In addition, a support layer (not shown) which is not affected and is not deformed may be further provided to prevent the base layer 31 from being deformed in the direction toward the magnet part 36.

FIG. 5 is a diagram illustrating an antifouling member utilizing a magnetically responsive dynamic surface according to a fourth embodiment of the present invention.

Referring to FIG. 5, in the antifouling member 10 ′ according to the fourth embodiment of the present invention, the base layer 11, the magnetic reaction layer 12, the nanofilm layer 13, and the antifouling layer 14 are in turn. Although the base layer 11 is stacked on the support layer 100, the base layer 11 is different from the first embodiment, and the rest of the configuration and operation are similar. It demonstrates in detail centering on a structure.

For example, the support layer 100 is formed of a hard material so that the support layer 100 is not deformed by the magnetic field generated by the magnetic field generating unit 15 and is not affected by the deformation of the magnetic reaction layer 12.

Therefore, the antifouling member 10 ′ is deformed only in the remaining layers except for the support layer 100 when deformation occurs by the magnetic field generating unit 15.

Since the wave shape does not occur on the surface of the support layer 100, the support layer 100 may be disposed to contact the magnet part 16.

However, the present invention is not limited thereto, and the support layer 100 may be a flexible film formed of a PET material or the like, and any one may be used so that the base layer 11 and the magnet part 16 do not stick together. .

Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10,20,30: antifouling member 11,21,31: base layer
12,22,32: magnetic reaction layer 13,23,33: nano film layer
14,24,34: antifouling layer 15,35: magnetic field generating unit

Claims (14)

A base layer formed of an elastic material;
A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field;
A nano film layer laminated on the magnetic reaction layer and having a nano pattern formed thereon;
An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer;
It is provided to reciprocate under the base layer, utilizing a magnetic reaction dynamic surface including a magnetic field generating portion for changing at least a portion of the surface of the magnetic reaction layer to the wave shape by changing the magnetic field around the base layer No antifouling. The method according to claim 1,
The magnetic field generating unit,
A magnet part provided below the base layer to generate the magnetic field;
A driving part for reciprocating the magnet part;
And a control unit for controlling the driving unit to change the direction of the reciprocating motion so as to change the position to be transformed into the wave shape. The method according to claim 2,
The control unit,
An antifouling member utilizing a magnetically responsive dynamic surface that controls the magnet part to change the intensity of the magnetic field so as to change the size or shape of the wave shape. The method according to claim 1,
The nanopattern is an antifouling member utilizing a magnetic reaction dynamic surface including a plurality of nanofillers. The method according to claim 4,
The nano-pillars, antifouling member using a magnetic reaction dynamic surface formed of a magnetic material to move in the direction of the magnetic field. A base layer formed of an elastic material and formed into a hollow tubular shape;
A magnetic reaction layer laminated on an inner circumferential surface of the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field;
A nano film layer laminated on an inner circumferential surface of the magnetic reaction layer and having a nano pattern formed thereon;
An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer;
It is provided on the outer circumferential side of the base layer, antifouling using a magnetic reaction dynamic surface including a magnetic field generating unit for changing at least a portion of the magnetic reaction layer to the wave shape by changing the magnetic field around the base layer absence. The method according to claim 6,
And a support layer disposed between the base layer and the magnetic field generator, the support layer preventing the base layer from being deformed in the direction toward the magnetic field generator. The method according to claim 6,
The magnetic field generating unit,
A magnet portion formed in a ring shape to be spaced apart from the outer peripheral surface of the base layer by a predetermined interval, and generating a magnetic field;
A driving part for reciprocating the magnet part along a length direction of the base layer;
And a control unit for controlling the driving unit to change the direction of the reciprocating motion so as to change the position to be transformed into the wave shape. The method according to claim 8,
The control unit,
An antifouling member utilizing a magnetically responsive dynamic surface that controls the magnet part to change the intensity of the magnetic field so as to change the size or shape of the wave shape. The method according to claim 6,
The nanopattern is an antifouling member utilizing a magnetic reaction dynamic surface including a plurality of nanofillers. The method according to claim 10,
The nano-pillars, antifouling member using a magnetic reaction dynamic surface formed of a magnetic material to move in the direction of the magnetic field. A base layer formed of an elastic material;
A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field;
A nano film layer stacked on the magnetic reaction layer and having a plurality of magnetic fillers moving in the direction of the magnetic field;
An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer;
A magnetic field generator configured to reciprocate below the base layer to change a magnetic field around the base layer to deform at least a portion of the surface of the magnetic reaction layer into the wave shape,
The magnetic field generating unit,
A position spaced apart from the base layer by a predetermined interval, the magnet generating the magnetic field, the driving part reciprocating the magnet, and the driving part controlling the direction of the reciprocating motion to change the wave shape, thereby deforming the wave shape. Antifouling member utilizing a magnetic reaction dynamic surface including a control unit for controlling the change. A support layer;
A base layer laminated on the support layer and formed of an elastic material;
A magnetic reaction layer laminated on the base layer and formed of a magnetic material, the magnetic reaction layer being at least partially deformed into a wave shape by a magnetic field;
A nano film layer laminated on the magnetic reaction layer and having a nano pattern formed thereon;
An antifouling layer formed by coating an antifouling material on the surface of the nanofilm layer;
Antifouling member utilizing a magnetic reaction dynamic surface is provided on the lower side of the support layer to include a magnetic field generating portion for changing the magnetic field around the support layer to transform at least a portion of the surface of the magnetic reaction layer into the wave shape . The method according to claim 13,
When the magnetic reaction layer is deformed into the wave shape by the magnetic field generated by the magnetic field generating unit, the base layer, the nanofilm layer, and the antifouling layer are integrally deformed with the magnetic reaction layer, and the support layer is shaped. Antifouling member utilizing this self-reacting dynamic surface is maintained.

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