WO2022114534A1 - Apparatus for preparing nano-coating solution - Google Patents

Abstract

The present invention relates to an apparatus for preparing a nano-coating solution and, more specifically, to an apparatus for preparing a nano-coating solution for forming a film with excellent durability, that is, a robust silicon oxide thin film. The apparatus for preparing a nano-coating solution, of the present invention, has a simple structure and coating solution preparation process to enable improvement in work efficiency, and allows a fluid to be repeatedly passed through a composite cylinder through circulation, and thus a coating solution with improved durability and strength can be prepared. In addition, the apparatus for preparing a nano-coating solution, of the present invention, uses circulation to complete a coating solution, thereby enabling a space for preparing the coating solution to be decreased, and thus has a relatively small volume so as to be readily moved, thereby enabling improvement in use efficiency.

Description

Nano coating solution manufacturing device

The present invention relates to an apparatus for producing a nano coating liquid, and more particularly, to an apparatus for producing a coating liquid for forming a thin film of silicon oxide having excellent durability.

Solar power generation is a power generation method using a solar cell that receives sunlight and generates photovoltaic power by the photoelectric effect, and generally consists of a solar panel in which the solar cell is modularized, a storage battery, and a power conversion device.

Photovoltaic power generation is classified into fixed type, fixed variable type, single axis tracking type, and double axis tracking type according to the fixed installation of the solar panel or the different direction and angle of the solar panel according to the movement path of the sun.

Solar power generation is trying to develop various technologies for higher efficiency at lower installation costs.

Since solar panels must be installed outside where they can receive sunlight well, they are inevitably exposed to all kinds of external pollutants. These contaminants contaminate the surface of the glass installed on the top surface of the photovoltaic panel, thereby greatly reducing the photovoltaic power generation efficiency.

On average, it is known that the amount of power generation decreases by more than 10% even if the amount of light transmission decreases by only 3%.

In particular, scattering dust is micro-sized fine dust that is accumulated on the surface of the glass, and when it comes into contact with rain, it spreads on the surface of the solar panel glass by the surface tension of water and dries and solidification occurs. It is essential to clean the glass with a cleaning solution. Therefore, companies operating solar power plants request cleaning service companies and periodically use detergent to wipe and clean the glass surfaces of solar panels. However, there is a problem in that the surface of the solar panel is scratched in the process of wiping it with a rag or brush.

In order to solve the above inconvenience, a method for reducing the cleaning cycle or improving the durability of a solar panel by coating the surface of a solar panel is being developed, but a coating solution with improved durability while being easier to coat and having excellent strength development is required.

The present invention was created to solve the above problems, and an object of the present invention is to provide an apparatus for manufacturing a nano coating solution capable of increasing work efficiency by simplifying the structure and process for manufacturing the coating solution.

In addition, an object of the present invention is to provide an apparatus for manufacturing a nano coating solution, which can reduce the working space for manufacturing the coating solution by completing the coating solution using the circulation method, and has a small volume and is easy to move, so that the use efficiency is improved.

An apparatus for producing a nano coating solution of the present invention for achieving the above object includes: a chamber open upward and having an internal space in which a fluid is stored; A fluid pumping space in which the fluid pumped from the inner space to the outside of the chamber is stored; a plurality of partition walls partitioning into a fluid circulation space that is moved to be discharged to the outside or circulated to the fluid pumping space, wherein the fluid circulation space communicates with the fluid pumping space and the fluid re-introduction space; a fluid circulation pump installed on the side of the fluid pumping space to pump the fluid to a fluid pumping pipe extending outside the chamber; a complex cylinder mounted on one side of the chamber and connected to the fluid pumping pipe, in which a complex for a composition of a coating solution is accommodated; a fluid circulation pipe extending from the composite cylinder to the fluid re-introduction space; an ultraviolet irradiation unit mounted on one side of the fluid circulation pipe to irradiate ultraviolet rays to the fluid in which the complex is discharged from the complex cylinder; a coating solution discharge pipe for discharging the coating solution generated by circulating the fluid inlet space, the fluid pumping space, and the fluid reintroduction space for a predetermined time or longer; It is preferable to include a pumping amount totalizer installed on one side of the fluid pumping pipe to accumulate the amount of fluid supplied to the composite cylinder.

The plurality of partition walls extend in the longitudinal direction of the chamber to connect a first partition wall dividing the inner space into the fluid circulation space and the remaining space, and an inner circumferential surface of the chamber facing the first partition wall and the first partition wall and a second partition wall extending in a direction crossing the longitudinal direction of the first partition wall to divide the remaining space into the fluid pumping space and the fluid re-introduction space, wherein the first partition wall intersects the second partition wall A first communication hole through which the fluid circulation space and the fluid pumping space communicate is formed on one side, and a second communication hole through which the fluid circulation space and the fluid re-introduction space communicate with each other is formed on the other side. desirable.

The composite cylinder includes: a cylinder body having an inner space and having first and second openings through which central sides of both longitudinal ends communicate with the inner space; The first opening extends into the inner space and protrudes with respect to the cylinder body to be detachably coupled to the fluid pumping pipe, and one side coupled to the fluid pumping pipe is open and extends into the cylinder body in the longitudinal direction a fluid inlet pipe having a closed other end and having a plurality of discharge holes formed along the longitudinal direction on the side extending into the cylinder body; a fluid outlet pipe formed to have a smaller diameter than the cylinder body, the other end being connected to the second opening of the cylinder body, and protruding from the cylinder body to be detachably coupled to the fluid circulation pipe; a plurality of filters spaced apart from each other in the longitudinal direction of the cylinder body within the cylinder body at a location on the other side of the cylinder body with respect to the fluid inlet pipe to form a filtering space; It is preferable to include a plurality of complexes filled in the filtration space.

And, the nano-coating liquid manufacturing apparatus of the present invention includes a fluid supply pipe for supplying a fluid to the fluid pumping space; a first opening/closing valve for opening and closing the fluid supply pipe; a second opening/closing valve for opening and closing the coating solution discharge pipe; It is connected to the pumping amount accumulator so that it is possible to determine the number of times the fluid supplied into the chamber has been circulated to the composite cylinder through the fluid pumping pipe when the first and second on/off valves are closed, and the fluid for a set time After the circulation pump, the second on-off valve is opened, and a control unit for controlling the coating liquid generated while passing through the composite cylinder to be discharged to the outside; may be further provided.

In addition, the nano-coating liquid manufacturing apparatus of the present invention is supported by the chamber and is formed to cover the upper side of the fluid pumping space and the fluid re-introduction space, and the fluid pumping pipe is located on one side located above the fluid pumping space. A pumping pipe through-hole penetrating up and down, and a support plate having a circulation pipe through-hole through which the fluid circulation tube penetrates up and down on the other side located above the fluid re-introduction space, and between the pumping pipe through-hole and the circulation pipe through-hole and a support bracket installed on the support plate to support the composite cylinder so that the composite cylinder extends lengthwise in the horizontal direction, and the fluid pumping pipe has one side extending up and down through the pumping pipe through hole and the other side is The ultraviolet rays extending horizontally from above the support plate and detachably connected to one side of the composite cylinder, the fluid circulation tube having one side connected to the other longitudinal side of the composite cylinder and the other side extending parallel to the composite cylinder A first circulation pipe extending to one side in the longitudinal direction of the irradiation unit, and a second circulation pipe connected to the other side in the longitudinal direction of the ultraviolet irradiation unit and extending through the circulation pipe through-hole to the fluid re-introduction space; and the complex A cylinder, the ultraviolet irradiation unit, and a cover unit having an inner space open downward to cover the fluid pumping pipe and the fluid circulation pipe positioned above the support plate, wherein the pumping amount accumulator is the fluid pumping pipe It is preferable that it is supported by a branch pipe branching upward from one side of the cover part passing through the cover part and protruding upward with respect to the cover part.

In the nano coating solution manufacturing apparatus of the present invention, the chamber is divided into a fluid pumping space, a fluid re-introduction space, and a fluid circulation space by first and second partition walls, and the fluid pumped from the fluid pumping space above the chamber is a composite cylinder The structure is provided to flow into the fluid re-introduction space after passing through, so the circulation efficiency and the coating solution manufacturing process are simple to increase the working efficiency. Therefore, there is an advantage that the use efficiency can be improved.

And, the nano coating solution manufacturing apparatus of the present invention can manufacture a uniform coating solution because the fluid is repeatedly circulated by driving the fluid circulation pump for a set time.

1 is a perspective view of an apparatus for manufacturing a nano coating solution according to a first embodiment of the present invention;

Figure 2 is a partial perspective view of the nano coating solution manufacturing apparatus of Figure 1,

Figure 3 is a cross-sectional view of the composite cylinder of the nano coating solution manufacturing apparatus of Figure 1,

4 is a schematic block diagram of a coating solution manufacturing method using the nano coating solution manufacturing apparatus of FIG. 1;

5 is a cross-sectional view of a composite cylinder of a nano-coating solution manufacturing apparatus according to a second embodiment of the present invention;

6 is a cross-sectional view of a composite cylinder of a nano coating solution manufacturing apparatus according to a third embodiment of the present invention.

Hereinafter, an apparatus for manufacturing a nano coating solution according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 show a nano coating solution manufacturing apparatus 1 according to an embodiment of the present invention.

The nano coating solution manufacturing apparatus 1 according to an embodiment of the present invention includes a chamber 10 that is opened upward and has an internal space 11 in which a fluid is stored, and the internal space 11 is formed by a fluid pumping space 12 and , a fluid re-introduction space 13, a plurality of partition walls 16 and 23 partitioning the fluid circulation space 14, and a fluid pumping pipe installed on the side of the fluid pumping space 12 and extending to the outside of the chamber 10 (25), and a fluid circulation pump (27) mounted at the end of the fluid pumping pipe (25) in the fluid pumping space (12) to pump the fluid to the upper part of the fluid pumping pipe (25), and the upper side of the chamber (10) A complex cylinder 30 mounted on and connected to the fluid pumping pipe 25 and containing a complex 36 for the composition of the coating solution therein, and a fluid circulation pipe extending from the complex cylinder 30 to the fluid re-introduction space 13 ( 51), an ultraviolet irradiation unit 58 mounted on one side of the fluid circulation pipe 51 to irradiate ultraviolet rays to the fluid discharged from the complex cylinder 30, a fluid inlet space 13, a fluid pumping space 12, and A coating solution discharge pipe 60 for discharging the coating solution generated by circulating the fluid circulation space 14 for more than a certain time, and a pumping that is installed on one side of the fluid pumping pipe 25 to accumulate the amount of fluid supplied to the composite cylinder 30 A quantity totalizer 62 is provided.

And, the nano coating solution manufacturing apparatus 1 according to an embodiment of the present invention is connected to one side of the chamber 10 and a fluid supply pipe 64 for supplying a fluid to the fluid pumping space 12, and a fluid supply pipe 64. The first on-off valve 66 to open and close, the second on-off valve 68 to open and close the coating liquid discharge pipe 60, and the pumping amount accumulator 62 are connected, and the first and second on-off valves 66 and 68 In the closed state, it is possible to determine the number of times the fluid supplied into the chamber 10 is circulated to the composite cylinder 30 through the fluid pumping pipe 25, and after driving the fluid circulation pump 27 for a set time, the second opening and closing A control unit (not shown) that opens the valve 68 and controls the coating solution generated while passing through the composite cylinder 30 to be discharged to the outside is provided.

The chamber 10 is formed in a rectangular parallelepiped shape having an internal space 11 opened upward, and a plurality of wheels 47 that roll in contact with the ground are mounted on the lower surface, and an operator is installed on one side to move the chamber. A gripping portion 49 formed to be gripped is mounted.

A plurality of partition walls dividing the internal space of the chamber 10 extend in the longitudinal direction of the chamber 10 to divide the internal space 11 of the chamber 10 into the fluid circulation space 14 and the remaining spaces 12 and 13 . A direction crossing the longitudinal direction of the first partition wall 16 so as to connect the plate-shaped first partition wall 16 dividing the partition wall 16 with the longitudinal center of the first partition wall 16 and the inner circumferential surface of the chamber 10 facing the center is divided into a second partition wall 23 that extends to and divides the remaining spaces 12 and 13 into a fluid pumping space 12 and a fluid re-introduction space 13 .

The fluid pumping space 12 is a space in which the fluid introduced through the fluid supply pipe 64 and pumped upwards of the chamber 10 is stored, and the fluid re-introduction space 13 is a space in which the fluid discharged from the composite cylinder is introduced. . And, the fluid circulation space 14 is a space connecting the fluid pumping space 12 and the fluid re-introduction space 13, and the coating solution discharge pipe 60 is connected.

The first partition wall 16 has the second partition wall 23 interposed therebetween, and a first communication hole (not shown) through which the fluid circulation space 14 and the fluid pumping space 12 communicate with each other is formed on one side, A second communication hole (not shown) through which the fluid circulation space 14 and the fluid re-introduction space 13 are communicated is formed on the other side.

First and second filter plates (19, 20) are formed in the first partition wall to cover the first and second communication holes that are passed through in a rectangular shape, respectively, and have a plurality of through holes through which a fluid passes but filters the weaning constitution, respectively. ) is installed.

And, the nano coating solution manufacturing apparatus 1 according to the first embodiment of the present invention is supported by the chamber 10 to cover the fluid pumping space 12 and the fluid re-introduction space 13. A rectangular plate-shaped support plate ( 70) and; a plurality of support brackets 76 installed on the support plate 70 to support the composite cylinder 30 so that the composite cylinder 30 extends longitudinally in the horizontal direction; A cover part having an internal space open downward so as to cover the composite cylinder 30, the ultraviolet irradiation part 58, the fluid pumping pipe 25 and the fluid circulation pipe 51 positioned above the support plate 70 ( 80) is provided.

The support plate 70 has a pumping pipe through hole 72 through which the fluid pumping pipe 25 penetrates up and down on one side in the longitudinal direction located above the fluid pumping space 12, and above the fluid reintroduction space 13. A circulation pipe through-hole 74 through which the fluid circulation pipe 51 penetrates vertically is formed on the other side in the longitudinal direction.

A plurality of support brackets 76 are installed on the support plate 70 between the pumping pipe through-hole and the circulation pipe through-hole, and the pumping pipe through-hole 72 and the circulation pipe through-hole 74 are spaced apart from each other in a direction in which they are spaced apart from each other. and extends lengthwise in the width direction of the support plate 70 .

The support bracket 76 has an upper portion concave downward to correspond to the curvature of the outer circumferential surface of the composite cylinder 30 so as to support the composite cylinder 30 formed in a cylindrical shape.

The cover part 80 is formed in a rectangular parallelepiped shape having an internal space that is extended in a direction in which the fluid re-introduction space 13 and the fluid pumping space 12 are arranged and is opened downward.

The cover part 80 is branched upward from one side of the fluid pumping pipe 25 at the upper end of one side in the longitudinal direction, and the branch pipe through hole 81 through which the branch pipe 26 supporting the pumping amount totalizer 62 passes is formed. do. The pumping amount accumulator 62 is supported by the branch pipe 26 and protrudes upward with respect to the cover part 80 .

One side of the fluid pumping pipe 25 extends up and down and passes through the pumping pipe through hole 72 of the support plate 70 , and the other side extends horizontally above the support plate 70 to separate from one side of the composite cylinder 30 . possible to connect The branch pipe 26 branches upward from the other side of the fluid pumping pipe 25 .

The fluid circulation pipe 51 is a first circulation pipe ( 52), and a second circulation pipe 57 connected to the other side in the longitudinal direction of the ultraviolet irradiation unit 58 and penetrating through the circulation pipe through-hole 74 and extending into the fluid re-introduction space 23;

The first circulation pipe 52 is spaced apart from the first extension 53, one side extending in the longitudinal direction of the composite cylinder 30 and detachably connected to the other side of the composite cylinder, and the first extension 53, and A second extension 54 extending longer than the complex cylinder 30 in parallel to the complex cylinder 30 in the fluid pumping space 12 direction from the fluid reintroduction space 13, and the first extension 53 Located at the rear of the composite cylinder 30 from the other side of the third extension 55 bent in a 'U' shape to connect the other side and one side of the second extension 54 , and the second extension 54 . It includes a fourth extension 56 extending in a direction crossing the second extension to extend to one side of the ultraviolet irradiation unit 58 .

The composite cylinder 30 includes a cylinder body 31 , a fluid inlet pipe 38 , a fluid outlet pipe 41 , a plurality of filters 43 and 45 , and a plurality of composites 36 .

The cylinder body 31 is supported by a support bracket and is formed in a cylindrical shape having an internal space 32 extending horizontally, and the diameter of both sides in the longitudinal direction decreases toward the ends. The cylinder body 31 has first and second openings 33 and 34 through which the central sides of both ends in the longitudinal direction are in communication with the inner space are formed.

The fluid inlet pipe 38 extends into the inner space 32 of the cylinder body 31 through the first opening 33 and protrudes from one end of the cylinder body 31 to be separated from the fluid pumping pipe 25 . are tightly coupled The fluid inlet pipe 38 protruding from one end of the cylinder body 31 may be inserted and coupled to the fluid pumping pipe 25, and differently from the figure, the fluid pumping pipe 25 by a separate clamp (not shown). ) and may be separably combined with

One side of the fluid inlet pipe 38 coupled to the fluid pumping pipe 25 is open and the other longitudinal end extending into the cylinder body 31 is closed, and along the longitudinal direction on the side extending into the cylinder body 31 . A plurality of discharge holes 39 are formed.

The fluid outlet pipe 41 is formed with a smaller diameter than the cylinder body 31, the other end is connected to the second opening 34 of the cylinder body 31, and protrudes with respect to the cylinder body 31, so that the fluid circulation pipe 51 and detachably combined with The fluid outlet pipe 41 protruding from the other end of the cylinder body 31 may be inserted and coupled to the fluid circulation pipe 51, and differently from the illustration, the fluid circulation pipe 51 by a separate clamp (not shown). ) and may be separably combined with

The plurality of filters 43 and 45 are spaced apart from each other in the longitudinal direction of the cylinder body 31 at a location on the other side of the cylinder body 31 with respect to the fluid inlet pipe 38 in the cylinder body 31, A filtration space (32a) in which the remix complex is filled is formed.

The inner space 32 of the cylinder body 31 is divided into a discharge space 32b, a filtration space 32a, and a discharge space 32c by a plurality of filters 43 and 45.

The composite 36 includes titanium dioxide (TiO ₂ ) and silicon dioxide (SiO ₂ ).

Titanium dioxide has an organic matter decomposition function to decompose an organic mixture by UV irradiation and a photo-excitation hydrophilization function to make the surface super-hydrophilic, and is mainly used as a coating material to prevent dust, bacteria, organic contaminants, etc. It is also used as a representative photocatalyst material because it is very abundant in resources, has a low price, is biologically stable against acids and alkalis, and has excellent durability and abrasion resistance.

In addition, silicon dioxide is a porous material having a high surface area and provides an excellent function as a carrier of the composite 36 of the present invention by adsorbing and removing odors and volatile organic compounds in a relatively quick time.

The method for manufacturing the composite 36 including titanium dioxide (TiO ₂ ) and silicon dioxide (SiO ₂ ) is not limited, but a titanium material such as titanium alkoxide or titanium tetrachloride is added to an aqueous solution containing silicon dioxide to form a metal. One produced by heat-treating the doped may be applied.

Alternatively, the composite 36 is a titanium dioxide (TiO ₂ ) precursor, an aniline monomer as a conductive polymer, and an inorganic material silica ion (silicate) by irradiating gamma rays at the same time by radical polymerization to form a nano-sized sphere TiO ₂ -PANI -Silica or polyaniline(PANI)-TiO ₂ -Silica nanocomposites may be applied.

A solution in which silicon oxide and titanium oxide are eluted can be obtained by dispersing a number of the resulting complexes in a fluid and applying a mechanical stimulus. In addition, by circulating the solution, a solution in which silicon oxide and titanium oxide are concentrated can be obtained.

The UV irradiator 40 has a built-in UV lamp (not shown) so as to irradiate UV rays to the solution containing titanium dioxide while being discharged from the composite cylinder to attach the coating solution to the object to be coated (not shown).

The control unit is mounted on one side of the chamber 10 , the amount of fluid supplied to be introduced into the internal space of the chamber through the fluid supply pipe 64 may be set. To this end, the nano-coating manufacturing apparatus according to the first embodiment of the present invention is connected to the fluid supply pipe 64 and further includes an inflow amount accumulator (not shown) for accumulating the amount of fluid flowing into the fluid pumping space through the fluid supply pipe. can

The control unit is connected to the inflow totalizer, and when the amount of fluid introduced into the internal space 11 through the inflow totalizer reaches the set fluid supply amount, the first and second on/off valves 66 and 68 are closed, and the fluid circulation pump 27 to drive Then, the control unit may detect the amount pumped by the fluid circulation pump 27 through the pumping amount totalizer to determine how many times the fluid stored in the internal space 11 in the chamber 10 has been circulated.

The pumping amount accumulator 62 may be provided with a first display unit 63 that displays the amount of fluid pumped from the fluid pumping pipe 25 to the composite cylinder 30 by the fluid circulation pump 27 . In addition, the inflow amount accumulator may also be provided with a second display unit for displaying the amount of fluid moved into the chamber from the fluid supply pipe ( ) by the fluid circulation pump ( 27 ).

Alternatively, the nano coating solution manufacturing apparatus 1 according to the first embodiment of the present invention is connected to the control unit and mounted on one side of the chamber 10 to display the amount of fluid pumped and the number of times the fluid has been circulated through the pumping amount totalizer 62 Alternatively, a main display unit for displaying the amount of fluid introduced into the chamber interior space through the inflow amount totalizer may be separately provided.

In addition, the control unit is set for a driving time of the fluid circulation pump 27 between 5 and 10 minutes, so that the fluid continuously circulates within the set time and reacts with the complex, leading to a coating solution, which is a concentrated, non-aqueous silicon oxide solution. After the set time, the second on-off valve 68 is opened so that it is supplied to the outside of the chamber through the coating tank discharge pipe 60 . The coating tank discharge pipe 60 extends to a predetermined length and, although not shown, is connected to a cortic liquid injection pipe equipped with a spray nozzle at the end.

And, the nano coating solution manufacturing apparatus 1 according to the first embodiment of the present invention is provided with an operation unit (not shown) having at least one switch or button that transmits an operation command for driving the fluid circulation pump 27 to the control unit do. The operator drives the fluid circulation pump 27 through the operation unit, so that the fluid in the fluid pumping space 12 is pumped into the composite cylinder 30 and discharged to the fluid re-introduction space 13, and the fluid through the fluid circulation space 14 It can be circulated to the pumping space 12 .

In the nano coating solution manufacturing apparatus 1 according to the first embodiment of the present invention, the chamber is divided into a fluid pumping space, a fluid re-introduction space, and a fluid circulation space by first and second partition walls, and the chamber is pumped with a fluid There is provided a structure in which the fluid pumped into the space passes through the composite cylinder and then flows into the fluid re-introduction space; The circulation efficiency and the coating solution manufacturing process are simple, so that the working efficiency can be increased, and the space for manufacturing the coating solution can be reduced, so that the volume is relatively small, so it is easy to move, so there is an advantage that the use efficiency can be improved.

And, the nano coating solution manufacturing apparatus 1 according to the first embodiment of the present invention can manufacture a uniform coating solution because the fluid is circulated by driving the fluid circulation pump for a set time.

5 is a nano-coating liquid manufacturing apparatus 101 according to a second embodiment of the present invention is shown. In the drawings shown above, components having the same structure and function are denoted by the same reference numerals.

The nano coating liquid manufacturing apparatus 101 according to the second embodiment of the present invention has the same structure as the nano coating liquid manufacturing apparatus according to the first embodiment of the present invention, except for the composite cylinder 130 .

Composite cylinder 130 includes a cylinder body 31, a fluid inlet pipe 38, a fluid outlet pipe 41, a disk-shaped filter 43, a plurality of complexes 36, and a reaction path extension. A guide tube 150 is provided.

The filter 43 is located on the other side of the cylinder body 31 with respect to the fluid inlet pipe 38 in the cylinder body 31, so that the inner space 32 of the cylinder body 31 is filled with a plurality of ceramic composites. It is divided into a filling filtration space (32a) and a discharge space (32c).

The reaction path extension guide pipe 150 has a central side closed at the end of the fluid inlet pipe 38 and is formed to have a larger diameter than the fluid inlet pipe 38, and is a fluid pumping pipe around the fluid inlet pipe 38 . A first flow path (a) extending in the direction (25) and spaced apart from one end in the longitudinal direction of the cylinder body (31) in which the fluid discharged to the discharge hole (39) is moved in the fluid pumping pipe (25) direction; A second flow path (b) is formed in which the fluid moved to one end side of the cylinder body (31) through the first flow path (a) moves in the direction of the fluid outlet pipe (41) from the outside of the first flow path (a).

The reaction path extension guide pipe 150 is formed in a tubular shape with one end closed in the longitudinal direction, and one end side facing the fluid outlet pipe 41 is formed in a convex shape such that the diameter decreases toward the end. The reaction path extension guide pipe 150 is spaced at the same distance from the side outer circumferential surface of the fluid inlet pipe 38 and the side inner circumferential surface of the cylinder body.

In the nano-coating liquid manufacturing apparatus 101 according to the second embodiment of the present invention, the movement path of the fluid in the cylinder body 31 is expanded by the reaction path extension guide pipe 150, so the reaction efficiency between the fluid and the complex is improved. can be

On the other hand, although not shown, the nano coating liquid manufacturing apparatus 101 according to the second embodiment of the present invention may further include a tubular filter (not shown) surrounding the fluid inlet pipe 38 extending into the cylinder body 31 . can The tubular filter is formed to have an inner diameter corresponding to the outer diameter of the fluid inlet tube 38 so as to be in close contact with the outer peripheral surface of the side of the fluid inlet tube 38 .

6 is a nano-coating liquid manufacturing apparatus 201 according to a third embodiment of the present invention is shown. In the drawings shown above, components having the same structure and function are denoted by the same reference numerals.

The nano-coating liquid manufacturing apparatus 201 according to the third embodiment of the present invention has the same structure as the nano-coating liquid manufacturing apparatus according to the first embodiment of the present invention, except for the composite cylinder 130 .

The composite cylinder 230 includes a cylinder body 31 , a fluid inlet pipe 38 , a fluid outlet pipe 41 , a first filter 243 installed adjacent to the fluid inlet pipe 41 , and a first a second filter 245 in the shape of a circular disk positioned on the other side of the cylinder body 31 with respect to the filter 243 to form a filtration space 32a together with the first filter 243; A plurality of complexes 36 and a reaction path extension inducing member 250 are provided.

The first filter 243 is formed in the form of a disk disk, but one end of the fluid inlet pipe 38 is penetrated toward the center. The discharge hole 39 of the fluid inlet pipe 38 is formed on one side of the cylinder body 31 rather than the first filter 243 .

The reaction path extension member 250 extends in the longitudinal direction of the cylinder body 31 in the filtration space 32a, and one end of the support shaft 251 in the shape of a polygonal column is inserted and fixed to the longitudinal end of the fluid inlet pipe 38. and a spiral blade 253 protruding from the outer circumferential surface of the support shaft 251 and extending spirally so that the fluid introduced through the first filter 243 moves in a spiral direction to induce extension of the contact path with the composite.

In the nano-coating liquid manufacturing apparatus 201 according to the third embodiment of the present invention, the movement path of the fluid in the cylinder body 31 is expanded by the reaction path extension inducing member 250, so the reaction efficiency between the fluid and the complex is improved. can be

Above, the nano coating solution manufacturing apparatus of the present invention has been described with reference to an embodiment shown in the drawings, but this is only an example, and various modifications and equivalent embodiments are possible therefrom by those skilled in the art. will understand that Therefore, the scope of protection of the present invention should be determined only by the appended claims.

Claims (7)

A chamber open upward and having an internal space in which a fluid is stored; A fluid pumping space in which the fluid pumped from the inner space to the outside of the chamber is stored; a plurality of partition walls partitioning the fluid circulation space to be moved and discharged to the outside or circulated to the fluid pumping space, wherein the fluid circulation space communicates with the fluid pumping space and the fluid re-introduction space; a fluid circulation pump installed on the side of the fluid pumping space to pump the fluid to a fluid pumping pipe extending outside the chamber; A composite cylinder mounted on one side of the chamber and connected to the fluid pumping pipe, in which the complex for the composition of the coating solution is accommodated; a fluid circulation pipe extending from the composite cylinder to the fluid re-introduction space; And an ultraviolet irradiation unit mounted on one side of the fluid circulation pipe to irradiate ultraviolet rays to the fluid in which the complex discharged from the complex cylinder is dissolved; A coating solution discharge pipe for discharging the coating solution generated by circulating the fluid inlet space, the fluid pumping space, and the fluid re-introduction space for a predetermined time or longer; Nanocoating solution manufacturing apparatus, characterized in that it is installed on one side of the fluid pumping pipe and comprising a pumping amount totalizer for accumulating the amount of fluid supplied to the composite cylinder. According to claim 1, wherein the plurality of partition walls a first partition wall extending in the longitudinal direction of the chamber and dividing the inner space into the fluid circulation space and the remaining space; extending in a direction crossing the longitudinal direction of the first partition wall to connect the first partition wall and the inner circumferential surface of the chamber facing the first partition wall to divide the remaining space into the fluid pumping space and the fluid re-introduction space a second bulkhead; The first partition wall With the second partition wall therebetween, a first communication hole through which the fluid circulation space and the fluid pumping space communicate is formed on one side, and the fluid circulation space and the fluid re-introduction space are penetrated to communicate with each other on the other side. A device for manufacturing a nano coating solution, characterized in that two through-holes are formed. According to claim 1, wherein the composite cylinder is a cylinder body having an inner space and having first and second openings through which central sides of both ends in the longitudinal direction communicate with the inner space; The first opening extends into the inner space and protrudes with respect to the cylinder body to be detachably coupled to the fluid pumping pipe, and one side coupled to the fluid pumping pipe is open and extends into the cylinder body in the longitudinal direction a fluid inlet pipe having a closed other end and having a plurality of discharge holes formed along the longitudinal direction on the side extending into the cylinder body; a fluid outlet pipe formed to have a smaller diameter than the cylinder body, the other end being connected to the second opening of the cylinder body, and protruding from the cylinder body to be detachably coupled to the fluid circulation pipe; a plurality of filters spaced apart from each other in the longitudinal direction of the cylinder body within the cylinder body at a location on the other side of the cylinder body with respect to the fluid inlet pipe to form a filtering space; Nano coating solution manufacturing apparatus comprising a; a plurality of complexes filled in the filtration space. The method of claim 1, a fluid supply pipe for supplying a fluid to the fluid pumping space; a first opening/closing valve for opening and closing the fluid supply pipe; a second opening/closing valve for opening and closing the coating solution discharge pipe; It is connected to the pumping amount accumulator so that it is possible to determine the number of times the fluid supplied into the chamber is circulated to the composite cylinder through the fluid pumping pipe when the first and second on/off valves are closed, and the fluid circulates for a set time Nano coating solution manufacturing apparatus, characterized in that it further comprises a control unit that opens the second on-off valve after pumping, so that the coating solution generated while passing through the composite cylinder is discharged to the outside. 3. The method of claim 2, A pumping pipe through-hole supported by the chamber and formed to cover the fluid pumping space and the fluid re-introduction space upward, and through which the fluid pumping pipe penetrates up and down on one side positioned above the fluid pumping space; A support plate in which a circulation pipe through hole through which the fluid circulation pipe passes vertically is formed on the other side located above the fluid re-introduction space; Further comprising a support bracket installed on the support plate between the pumping pipe through-hole and the circulation pipe through-hole to support the composite cylinder so that the composite cylinder extends longitudinally in the horizontal direction, One side of the fluid pumping pipe extends up and down and passes through the pumping pipe through hole, and the other side extends horizontally above the support plate and is detachably connected to one side of the composite cylinder, The fluid circulation pipe has a first circulation pipe having one side connected to the other side in the longitudinal direction of the composite cylinder and the other side extending to one longitudinal side of the UV irradiation unit extending in parallel to the composite cylinder, and the other side in the longitudinal direction of the UV irradiation unit and a second circulation pipe connected to and penetrating through the circulation pipe through-hole and extending into the fluid re-introduction space; Further comprising a cover part having an internal space open downward to cover the complex cylinder, the ultraviolet irradiation part, between the fluid pumping pipe and the fluid circulation located above the support plate, The pumping amount accumulator is branched upward from one side of the fluid pumping pipe, is supported by a branch pipe passing through the cover part, and protrudes upward with respect to the cover part. According to claim 1, wherein the composite cylinder is a cylinder body having an inner space and having first and second openings through which central sides of both ends in the longitudinal direction communicate with the inner space; It extends into the inner space through the first opening and protrudes with respect to the cylinder body to be detachably coupled to the fluid pumping pipe, and one side coupled to the fluid pumping pipe is open and extends into the cylinder body in the longitudinal direction a fluid inlet pipe having a closed other end and having a plurality of discharge holes formed along the longitudinal direction on the side extending into the cylinder body; a fluid outlet pipe formed to have a smaller diameter than the cylinder body, the other end being connected to the second opening of the cylinder body, and protruding from the cylinder body to be detachably coupled to the fluid circulation pipe; a filter positioned on the other side of the cylinder body with respect to the fluid inlet pipe in the cylinder body to partition the inner space into a filtration space and a discharge space in which the fluid inlet pipe extends; a plurality of complexes filled in the filtration space; A central side of one end closed at the end of the fluid inlet pipe is fixed and is formed with a larger diameter than the fluid inlet pipe, extends from the circumference of the fluid inlet pipe in the direction of the fluid pumping pipe, and is spaced apart from the longitudinal end of the cylinder body a first flow path through which the fluid discharged through the discharge hole moves in the direction of the fluid pumping pipe, and the fluid moved to one end side of the cylinder body through the first flow path from the outside of the first flow path toward the fluid outlet pipe Nano coating solution manufacturing apparatus comprising a; reaction path extension guide pipe forming a second flow path to be moved. According to claim 1, wherein the composite cylinder is a cylinder body having an inner space and having first and second openings through which central sides of both longitudinal ends communicate with the inner space; It extends into the inner space through the first opening and protrudes with respect to the cylinder body to be detachably coupled to the fluid pumping pipe, and one side coupled to the fluid pumping pipe is open and extends into the cylinder body in the longitudinal direction a fluid inlet pipe having a closed other end and having a plurality of discharge holes formed along the longitudinal direction on the side extending into the cylinder body; a fluid outlet pipe formed to have a smaller diameter than the cylinder body, the other end being connected to the second opening of the cylinder body, and protruding from the cylinder body to be detachably coupled to the fluid circulation pipe; a first filter installed adjacent to the fluid inlet pipe, and a second filter positioned on the other side of the cylinder body with respect to the first filter to form a filtration space with the first filter; a plurality of complexes filled in the filtration space; A support shaft extending in the longitudinal direction of the cylinder body in the filtration space and having one end fixedly coupled to the fluid inlet pipe, protruding from the outer circumferential surface of the support shaft and spirally extending the fluid introduced through the first filter in a spiral direction Nano coating solution manufacturing apparatus comprising a; reaction path extending member including a spiral blade for inducing extension of the contact path with the composite while moving.

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