KR102588362B1 - Apparatus for coating nano-powder on materials - Google Patents

Abstract

The present invention provides an insulating nanopowder injection device (100), a binder resin atomization spray device (300), a high voltage generator (800), a base plate (700), and an object to be coated (500), and an insulating nanopowder injection device (300). The device 100 and the binder resin atomizing device 300 spray the charged insulating nanopowder and the charged binder resin into the mixing space (S), so that they are mixed and settled on the object 500 by electrostatic force, providing sufficient The density allows the insulating nanopowder to be applied to the object 500.

Description

Apparatus for coating nano-powder on materials}

The present invention relates to a device for applying nanopowder to an object to be coated, and more specifically, to a device for applying nanopowder to an object to be coated. According to the present invention, for example, an apparatus capable of producing insulating materials such as insulating sheets and insulating fabrics by applying insulating nanopowder to sheets, fabrics, etc. is provided.

The present invention relates to a device for applying nanopowder to an object to be coated. The application of heat-insulating nanopowder to an object to be coated will be described as an example.

Insulating nanopowder refers to nano-sized particles that have insulating properties formed into a powder.

Republic of Korea Patent Publication No. 10-2012-0021526 introduces insulating materials such as Prehnite, Celestite, Apatite, and Natrolite, and pulverizes these materials into nano-sized powders. It shows a method of manufacturing an insulation material by mixing it with a binder resin and pressing it. Prehnite, celestite, apatite, and soda arsenite are pulverized to the size of nanoparticles and powdered. (Natrolite) or a combination thereof may become an insulating nanopowder.

Ceramic materials have insulating properties, and these ceramic materials can be powdered to nanoparticle size and used as insulating nanopowders.

It would be desirable if such an insulating nanopowder could be mixed with a binder resin and applied to a film, sheet, or fabric to produce an insulating film, insulating sheet, or insulating fabric.

For example, if insulating nano powder can be applied to the surface of wallpaper, tinting film, parasol fabric, etc., it would be very desirable to manufacture insulating wallpaper, insulating tinting film, insulating parasol, etc.

In other words, wallpaper, tinting film, and parasols have insulating properties.

However, the problem is that the nanopowder particles are too fine in nano size, so when mixed with binder resin, the fine nano-sized powder cannot be mixed evenly at high density. As a result, when applied to sheets, films, fabrics, etc., the insulating nano powder cannot be mixed evenly. This means that the desired insulation effect cannot be achieved because the particles are not applied at an appropriate density and thickness.

Therefore, there is a need for a method that can evenly apply insulating nanopowders to sheets, films, or fabrics at high density.

While researching to solve this problem, the present inventor focused on electrostatic powder coating.

Electrostatic powder coating utilizes the phenomenon of Coulomb force acting between charged charges of different polarities and pulling them together. When the powder coating particles are charged and the object to be coated is grounded, the coating is applied between the powder coating gun and the object to be coated. This refers to a method of painting by spraying and applying charged powder coating in the direction of the object using the generated electric field and pressure, and allowing the charged powder coating to settle on the surface of the object using electrostatic force.

By applying electrostatic powder coating, the present inventor has created a device that can apply insulating nanopowder, which is a collection of fine nanoparticles, to sheets, films, fabrics, etc. at a desired thickness at even density. This device is only used for insulating nanopowder. Rather than being applied, it allows nanopowders to be applied to sheets, films, fabrics, etc. at a uniform density and to a desired thickness.

The purpose of the present invention is to provide a device that can apply nanopowder, which is a collection of fine nanoparticles, to sheets, films, fabrics, etc. at a uniform density and to a desired thickness.

This invention

(a1) a storage unit for nanopowder,

(a2) a spray pressure generator for the nanopowder,

(a3) a nanopowder injection device having a spray unit that sprays the nanopowder into the mixing space using the pressure of the nanopowder spray pressure generator;

(b) a high voltage generator with a single electrode connected to the injection unit of the nanopowder injection device to charge the nanopowder sprayed through the injection unit;

(c1) a binder resin storage unit that stores binder resin and is connected to the one electrode of the high voltage generator to receive electric charge from the binder resin;

(c2) a binder resin atomization spray device having an atomizing spray unit that atomizes the binder resin of the binder resin storage unit and sprays it into the mixing space;

(d) a base plate to which the other pole of the high voltage generator is connected and grounded;

(e) It provides a nanopowder application device, characterized in that it includes a coating material disposed on the upper surface of the base plate toward the mixing space.

According to the present invention, the object to be coated is preferably any one of a sheet, film, or fabric.

According to the present invention, it is preferable that the object to be coated is capable of moving in the horizontal direction with respect to the mixing space.

According to the present invention, it is preferable that the nanopowder is an insulating nanopowder.

This invention

(a) a nanopowder spraying device connected to the single electrode of a high voltage generator to charge and spray nanopowder, spraying the charged nanopowder into a mixing space;

(b) storing the binder resin, spraying it, and spraying it, wherein the stored binder resin is connected to the one pole of the high voltage generator and supplied with an electric charge to be charged, and the binder resin thus charged is sprayed and sprayed. spraying the charged binder resin into the mixing space using an atomizing spray device;

(c) a step in which the charged binder resin sprayed into the mixing space is nanoscaled by a repulsive force between these charged charges and a sudden pressure drop;

(d) mixing the charged nanopowder and the charged nanobinder resin in the mixing space;

(d) The mixed charged nanopowder and the charged nanobinder resin follow the electrostatic force formed on the object disposed toward the mixing space on the upper surface of the base plate connected to the other pole of the high voltage generator and grounded. A method of applying nanopowder is provided, which includes the step of placing it on the object to be coated.

According to the present invention, it is preferable to further include a horizontal movement step in which the coated object is moved in the horizontal direction with respect to the mixing space as a sheet, film, or fabric.

According to the present invention, it is preferable that the nanopowder is an insulating nanopowder.

The present invention provides a nanopowder spraying device, a binder resin atomizing spraying device, a high voltage generator, a base plate, and a coated object, and the nanopowder spraying device and the binder resin atomizing spraying device provide charged nanopowder and a charged binder, respectively. The resin is sprayed into the mixing space, mixed, and settled on the object to be coated with electrostatic force, allowing the nanopowder to be applied to the object at a sufficient density.

1 is a view showing a device for applying heat insulating nanopowder according to the present invention;
Figure 2 is a diagram showing the process of applying the insulating nanopowder according to the present invention to an adherend.

Now, preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 1 shows a device 1000 for applying heat insulating nanopowder according to an embodiment of the present invention.

As shown, the insulating nanopowder application device 1000 according to the present invention has an insulating nanopowder spraying device 100.

This is a device that is connected to the one electrode (for example, cathode) of the high voltage generator 800 to charge the insulating nanopowder and spray it into the mixing space (S).

In the present invention, the mixing space (S) is the same as the charged insulating nanopowder and charged binder resin sprayed by the above-described insulating nanopowder spraying device 100 and the binder resin atomization spraying device 300 described later, respectively. It refers to space (S).

That is, the insulating nanopowder spraying device 100 and the binder resin atomization spraying device 300, which will be described later, spray toward the same space, and in this space, these sprayed charged insulating nanopowders and the charged binder resin interact with each other. Mixing takes place to form a mixing space (S).

The insulating nanopowder injection device 100 includes an adiabatic nanopowder storage unit 130 that stores the adiabatic nanopowder, a spray pressure generator 160 that generates pressure to spray the adiabatic nanopowder, and the adiabatic nanopowder. It includes a spray unit 190 that sprays the insulating nanopowder into the mixing space (S) using the pressure of the powder spray pressure generator 160.

That is, the adiabatic nanopowder stored in the adiabatic nanopowder storage unit 130 passes through the injection unit 190 having a nozzle 198 under the pressure of the injection pressure generator 160, such as a compressor, into the mixing space (S). is sprayed as

In this case, an electrode 1988 connected to the one electrode 801a of the high voltage generator 800 is disposed in the nozzle 198, and the insulating nanopowder passing through the nozzle 198 is charged and injected.

Meanwhile, the other pole 802 of the high voltage generator 800 is connected to the base plate 700 and is grounded.

Therefore, an electrostatic force is formed between the base plate 700 and the charged insulating nanopowder sprayed from the insulating nanopowder injection device 100 into the mixing space S.

The insulating nanopowder application device 1000 according to the present invention also has a binder resin atomization injection device 300.

This is to store binder resin, spray it, and spray it. The stored binder resin is connected to the single electrode (801b) of the high voltage generator 800 and supplied with electric charge, and is charged, and the charged binder resin is atomized. It is sprayed into the mixing space (S).

The binder resin atomization injection device 300 has a binder resin storage portion 310, to which the one electrode 801b of the high voltage generator 800 is connected, and the binder resin stored there is connected to the binder resin storage portion 310. The resin receives electric charge from the high voltage generator 800.

The binder resin in the binder resin storage unit 310 is atomized through the ultrasonic vibrator 350 under the pressure of the pump 330 and then into the mixing space (S) through the spray unit 390 having a nozzle 398. It is sprayed.

In the binder resin storage unit 310, charges in the opposite direction to the electrode 801b are collected on the electrode 3108 connected to the electrode 801b of the high voltage generator 800, and the atomized product is atomized through the pump 330. The binder resins have a charge of the same polarity as the monopole (801b).

When the binder resin charged to the same polarity as the single pole (801b) of the high voltage generator 800 is sprayed and sprayed through the nozzle 398, the binder resin is sprayed due to the repulsive force between these charges and a sudden pressure drop during spraying. is broken down into fine particles. In other words, it becomes nano.

As described above, the other pole 802 of the high voltage generator 800 is connected to the base plate 700 and grounded, and an electrostatic force is formed between the nanocharged binder resin and the base plate 700.

According to the present invention, an object 500 in the form of a sheet, film, or fabric is disposed on the upper surface of the base plate 700 toward the mixing space S.

The object 500 is capable of moving in the horizontal direction with respect to the mixing space (S).

In this embodiment, the object 500 is rolled in the form of a roll and then moves as it is unwound.

According to the present invention, the charged insulating nanopowder sprayed from the insulating nanopowder spraying device 100 and the charged binder resin sprayed from the binder resin atomization spraying device 300 into nano particles are mixed in the mixing space (S ), they are mixed with each other by the force with which they are sprayed.

The mixed charged nanopowder and the nanocharged binder resin move toward the base plate 700 according to the electrostatic force formed on the base plate 700 and settle on the adherend 500.

In this case, since the adherend 500 moves, the transfer speed can be adjusted to adjust the thickness at which the mixed charged nanopowder and the nanoized and charged binder resin are laminated.

In this way, the insulating nanopowder and the binder resin of nanoparticle size are mixed and settled on the adherend 500 by electrostatic force. The amount per hour of the insulating nanopowder sprayed, the amount per hour of the binder resin sprayed, and the adherend 500 ) By adjusting variables such as the transfer speed, the density and thickness of the insulating nanopowder applied to the adherend 500 can be adjusted.

Afterwards, the adherend 500 is transferred to the curing unit 900 and hardened.

The curing unit 900 has a built-in heat ray or ultraviolet ray lamp to cure the mixed insulating nanopowder and binder resin applied to the adherend 500.

Figure 2 is a diagram showing the process of applying insulating nanopowder to an adherend 500 in the form of a sheet, film, or fabric according to the present invention.

First, the insulating nanopowder injection device 100 sprays the charged insulating nanopowder into the mixing space (S). (Step S201)

Next, the binder resin atomization spray device 300 atomizes the charged binder resin and sprays it into the mixing space (S). (Step S202)

The charged binder resin sprayed into the mixing space (S) in step S202 is nanosized due to the repulsion between charges and a sudden pressure drop. (Step S203)

And the charged nanopowder and the nano-ized binder resin sprayed into the mixing space (S) are mixed with each other. (Step S204)

Thereafter, the mixed charged nanopowder and the nano-ized binder resin follow the electrostatic force formed on the object 500 disposed on the upper surface of the base plate 700 where the electrostatic force is formed toward the mixing space S. ) is settled on. (Step S205)

As described above, the object 500 is a sheet, film, or fabric that can be moved in the horizontal direction with respect to the mixing space (S), and its moving speed is adjusted to mix the mixed charged nanopowder and the nanoized nanopowder. The thickness with which the binder resin is applied to the object can be adjusted.

The present invention provides an insulating nanopowder spraying device 100, a binder resin atomization spraying device 300, a high voltage generator 800, a base plate 700, and an object to be coated 500, and provides an insulating nanopowder. The spraying device 100 and the binder resin atomizing spraying device 300 spray the charged insulating nanopowder and the charged binder resin into the mixing space (S), so that they are mixed and settled on the object 500 by electrostatic force. , so that the insulating nanopowder can be applied to the object 500 to be coated at a sufficient density, and thus the object 500 to be coated can have a sufficient insulating effect.

Up to now, we have shown a device and method for applying insulating nanopowder to an object to be coated at a sufficient density, but the present invention is not necessarily limited to insulating nanopowder and can be used to apply nanopowder to an object to be coated.

1000: Apparatus for applying insulating nanopowder
100: Insulating nanopowder injection device
300: Binder resin atomization spray device
800: High voltage generator
S: mixed space
500: adherend
700: Base plate

Claims (7)

(a1) a storage part of nanopowder,
(a2) a spray pressure generator for the nanopowder,
(a3) a nanopowder injection device having a spray unit that sprays the nanopowder into the mixing space using the pressure of the nanopowder spray pressure generator;
(b) a high voltage generator with a single electrode connected to the injection unit of the nanopowder injection device to charge the nanopowder sprayed through the injection unit;
(c1) a binder resin storage unit that stores binder resin and is connected to the one electrode of the high voltage generator to receive electric charge from the binder resin;
(c2) a binder resin atomization spray device having an atomizing spray unit that atomizes the binder resin of the binder resin storage unit and sprays it into the mixing space;
(d) a base plate to which the other pole of the high voltage generator is connected and grounded;
(e) A nanopowder application device comprising an object disposed on the upper surface of the base plate toward the mixing space. According to paragraph 1,
A nanopowder application device, wherein the object to be coated is any one of a sheet, film, or fabric. According to paragraph 2,
A nanopowder application device, characterized in that the object can be moved horizontally with respect to the mixing space. According to any one of paragraphs 1 to 3,
A nanopowder application device, characterized in that the nanopowder is an insulating nanopowder. (a) a nanopowder spraying device connected to the single electrode of a high voltage generator to charge and spray nanopowder, spraying the charged nanopowder into a mixing space;
(b) storing the binder resin, spraying it, and spraying it, wherein the stored binder resin is connected to the one pole of the high voltage generator and supplied with an electric charge to be charged, and the binder resin thus charged is sprayed and sprayed. spraying the charged binder resin into the mixing space using an atomizing spray device;
(c) a step in which the charged binder resin sprayed into the mixing space is nanoscaled by a repulsive force between these charged charges and a sudden pressure drop;
(d) mixing the charged nanopowder and the charged nanobinder resin in the mixing space;
(d) The mixed charged nanopowder and the charged nanobinder resin follow the electrostatic force formed on the object disposed toward the mixing space on the upper surface of the base plate connected to the other pole of the high voltage generator and grounded. A method of applying nanopowder, comprising the step of placing it on the object to be coated. According to clause 5,
The nanopowder application method further comprising a horizontal movement step in which the coated object is moved as a sheet, film, or fabric in a horizontal direction with respect to the mixing space. According to claim 5 or 6,
A method of applying nanopowder, characterized in that the nanopowder is an insulating nanopowder.

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