KR101063469B1 - Liquid injector and nano ion sprayer using it - Google Patents

Abstract

In order to nano-particle the particles of the lotion so that the active ingredient more effectively penetrates the face skin, scalp and hair, a nano part for nanoparticles of the solution and an opening for installing the nano part and discharging the nanoparticles at the tip is provided. It includes a body formed.

Nano part, main body, reservoir, spraying body, nanoplate

Description

Solution spraying body and nano ion spraying device using the same {LIQUID INJECTOR AND NANO ION SPRAYER USING IT}

The present invention relates to a beauty appliance for dispensing a lotion. More specifically, the present invention relates to a solution injector and a nano ion atomizer using the same, which can increase skin permeability by spraying nanoparticles at high speed or by spraying functional particles.

In general, various skin lotions are used to maintain skin's anti-aging, softness, elasticity, and moisture by moisturizing, softening, nourishing, soothing, whitening, and improving wrinkles. The user rubs or rubs the necessary lotion on his face or the like using his hand. The active ingredient contained in the lotion penetrates the skin.

However, this method is difficult and inconvenient to apply the lotion only where needed. In addition, the skin permeability of the lotion is also not satisfactory. This will increase the amount of lotion used.

Therefore, the development of a device that can penetrate the skin more effectively the active ingredient contained in the lotion is a long situation.

The present invention provides a solution spray body and nano ion spraying device using the same, in which particles of the lotion are nanonized so that the active ingredient can more effectively penetrate the facial skin or hair.

In addition, it provides a solution spray body and a nano ion spray device using the same to reduce the waste of the lotion.

In addition, the present invention provides a solution spraying body and a nano ion spraying device using the same, which enable high-speed spraying of the lotion to increase utilization.

To this end, the present spraying apparatus may include a nano-part for forming a nano-particle into a solution, and a body in which the nano-part is installed and an opening for discharging nanoparticles at a tip thereof is formed.

The apparatus may further comprise a reservoir in communication with the injector and in which the solution is stored.

The reservoir may be integrally installed on the body.

The reservoir may be provided separately from the main body and detachably coupled to the main body.

In addition, the apparatus may further include a filter installed in the opening of the main body to filter out a solution other than nanoparticles.

The nano part may include an injector for high-speed injection of a solution, and a nanoplate in which a solution to be injected spaced apart from the injector collides.

On the other hand, the present injection body has an appearance in which the compressed fluid is circulated, the injection nozzle which is formed at the front end of the injection fluid to inject the compressed fluid, an inner tube installed in the exterior and the solution is flowed into the inside, connected to the inner tube tip and the injection nozzle It may include a solution nozzle is extended to the solution is ejected.

When the high pressure compressed fluid is ejected to the injection nozzle through the inner tube and the external, the solution is discharged from the solution nozzle by the pressure difference, and is injected at high speed together with the compressed fluid. In addition, when the injector is combined with the main body, the high-speed injection solution collides with the nanoplate and finely nanoparticles.

Here, the injector may have a structure detachable from the main body.

In addition, the inner tube of the injecting body may protrude outward of the exterior, and may have a structure in communication with the reservoir of the main body when the main body is fastened.

The nanoplate may have a structure in which protrusions protrude in the center thereof.

In addition, the nanoplate may have a structure in which ring-shaped protrusions are continuously formed at intervals from the center.

In addition, the apparatus may further include a driver for supplying a compressed fluid connected to the injector via a hose.

In addition, the driver may further include an oxygen generator capable of compressively supplying oxygen.

The spray device may include a pulse imparting unit to impart a pulse of a specific waveform such as low frequency, medium frequency or high frequency to the nanoparticles to be sprayed.

The spray device may include an oxygen supply unit for supplying oxygen to the nanoparticles to be sprayed.

The spray device may include a laser irradiation unit for putting a low power laser wavelength into the nanoparticles along with the nanoparticles to be sprayed.

In this way, the device can be nano-particles to be sprayed on the skin to maximize the skin penetration rate of the active ingredient contained in the lotion, it is possible to maintain the action of the lotion for a long time.

In addition, it is possible to obtain a satisfactory effect even with a small amount of use by nano-particles make up the lotion.

In addition, a massage effect is obtained by flowing a current of a predetermined waveform to the nanoparticles sprayed into the skin, and the nanoparticles penetrate into the skin through the massage effect, thereby further increasing the skin penetration rate.

In addition, the oxygen is sprayed into the skin along with the lotion, so that the skin absorbs the lotion while breathing with oxygen, showing an excellent effect on the moisturizing effect and skin aging.

In addition, it is possible to obtain a high-speed jet of the lotion to obtain an additional effect.

In addition, it is possible to separate the operating chain components from the main body, which improves the convenience of use, and has the advantage of easy product repair and maintenance.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the term "comprising" embodies a particular characteristic, region, integer, step, operation, element, and / or component, and other specific characteristics, region, integer, step, operation, element, component, and / or group. It does not exclude the presence or addition of.

Unless defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Commonly defined terms used are additionally interpreted to have a meaning consistent with the related technical literature and the presently disclosed contents, and are not interpreted in an ideal or very formal sense unless defined.

Embodiments of the invention described with reference to a perspective view specifically illustrate an ideal embodiment of the invention. As a result, various variations of the illustration, for example variations in the manufacturing method and / or specification, are expected. Thus, the embodiment is not limited to the specific form of the illustrated region, but includes, for example, modification of the form by manufacture. For example, the regions shown or described as being flat may have characteristics that are generally coarse / rough and nonlinear. Also, the portion shown as having a sharp angle may be rounded. Thus, the regions shown in the figures are merely approximate, and their shapes are not intended to depict the exact shape of the regions, nor are they intended to limit the scope of the present invention.

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures have been exaggerated or reduced in size for clarity and convenience in the figures and any dimensions are merely exemplary and not limiting. And the same structure, element or part that appears in more than one figure the same reference numerals are used in different embodiments to indicate corresponding or similar features.

1 is a schematic perspective view of a spray apparatus according to the present embodiment.

As shown, the present spray device is a reservoir 10 in which a solution is stored therein, a main body 20 in which an opening 21 is formed so as to communicate with the reservoir 10 and come out of nanoparticles at the front end thereof. It is installed in the main body 20 includes a nano part for nano-particles the solution.

Hereinafter, the present embodiment will be described as an example in which the solution stored in the reservoir 10 is a lotion. In the following description, the lotion is defined as a liquid solution containing ingredients useful for moisturizing, softening, nourishing, soothing, whitening, and improving wrinkles of the skin.

The nano part includes an injection body 40 for high-speed injection of the lotion, and a nanoplate (see 30 in FIG. 2) to which the lotion injected is spaced apart from the injection body 40. The structure of the nano part will be described in detail later. In the present embodiment, the injector 40 is configured to be detachably mounted to the main body 20. The rear end of the main body 20 is connected with a wire 61 for supplying power required for the main body. A hose 62 for supplying a compressed fluid is installed at the rear end of the injector 40. The wire 61 and the hose 62 is connected to the driver 60 provided separately from the main body to receive the necessary power or compressed fluid.

The driver 60 is for supplying necessary power and compressed fluid to the present spraying apparatus, and is provided separately from the main body 20 in this embodiment.

The driver 60 includes a driver 63 for supplying a compressed fluid through the hose 62, a power supply 64 for supplying necessary power through the wire 61, and a pulse part 65 for generating and outputting a pulse signal. ), A controller 66 for controlling each component, and a switch unit 67 and a display unit 68 connected to the controller 66.

The drive unit 63 may be formed of a high speed fan, a blower, or a compressor. The power supply unit 64 and the pulse unit 65 are for performing additional functions of the apparatus, which will be described later. The user can operate the switch unit 67 connected to the controller 66 to control the controller 66. As a result, the controller 66 controls and controls each component in accordance with the switch operation of the switch unit. The control state of each component by the controller 66 is displayed to the outside through the display unit 68 connected to the controller 66.

2 is a cross-sectional view showing a state in which the injector is removed in the present apparatus.

According to the above drawings, the reservoir 10 has a lotion stored therein in the form of a container in which the upper one side is opened. The upper end of the reservoir 10 is provided with a supply pipe 17 in communication with the injector 40, the supply pipe 17 extends to the bottom of the reservoir. In addition, the upper end of the reservoir 10, the locking jaw 19 for fastening with the injection body is further formed. The locking jaw 19 will be described again when explaining the coupling structure with the spraying body. The toilet water stored in the reservoir 10 is introduced into the injection body 40 through the supply pipe 17.

In this embodiment, the reservoir 10 is detachably coupled to the main body 20 to form a lower structure of the spray device. Of course, in addition to this structure, the reservoir 10 may be integrally formed in the body 20 to form a body.

The lower body 38 communicates with the inside of the lower portion of the central portion of the main body 20 is installed. The lower body 38 has a structure in which the rear front is opened so that the reservoir can be fitted. The reservoir 10 is coupled to the main body while being inserted into the lower body 38.

Here, the spray device has a reservoir 10 coupled to the lower body 38 and the lower body 38 to make use of the handle more convenient. That is, the lower body 38 is the front of the handle, the reservoir 10 coupled to the rear of the lower body 38 forms the back of the handle. The main body 20 is installed almost horizontally on the handle so that the opening 21 of the main body 20 protrudes in a direction substantially perpendicular to the handle. Accordingly, the user can easily spray the nanoparticles to the skin by holding the lower body 38 and the reservoir 10, which are handles, with the tip of the protruding main body 20 toward the skin. Of course, the overall structure of the spray device can be implemented in various ways in addition to the above form, it is not particularly limited to this embodiment.

As shown in FIG. 2, the lower body 38 and the reservoir 10 constituting the handle have a structure in which an end thereof is bent toward the opening of the main body 20.

This structure prevents the lotion stored in the reservoir 10 from flowing out through the opening 21 of the body 20. That is, even when the main body 20 is inclined so that the opening 21 is downward, the storage 10 maintains the vertical state. Thus, the lotion stored in the storage 10 will not flow to the opening 21. In addition, the above structure is so that even when the main body 20 is tilted to face the opening 21, the lotion stays at the bottom of the reservoir so that it can be smoothly supplied to the injection body 40 through the supply pipe 17. do.

As shown in FIG. 1, a side of the reservoir 10 is provided with a confirmation window 13 made of a transparent material capable of confirming the storage amount of the lotion in the reservoir 10.

The main body 20 is a hollow cylindrical structure, the lower body 38 is formed integrally with a handle at the bottom. One end of the main body 20 is opened to form an opening 21 for spraying nanoparticles. The other end of the main body 20 is closed.

In addition, the main body 20 has a supply port 23 for supplying the lotion to the reservoir 10 is in communication with the upper end is formed. And the supply port 23 is provided with a stopper 24 for opening and closing the supply port as needed.

When the lotion is injected through the supply port 23, the lotion flows into the lower body 38 which is in communication with the main body 20, and is filled in the reservoir 10 through the upper part of the open reservoir 10.

In addition, the apparatus includes a filter 22 installed in the opening 21 of the main body 20 to filter out solutions other than nanoparticles. As the nanoparticles generated by the nano-parts come up toward the main body 20, the lotion of the larger particles contained in the nano-particles aggregates and falls into the reservoir 10, and most of the nano-particles flow out toward the opening 21. do. In this process, the filter 22 installed in the opening 21 filters out larger particles that are finally included in the nanoparticles. The nanoparticles only go out through the opening 21.

The front cover 25 is provided on the main body 20 outside the opening 21 to substantially contact the user's skin.

The front cover 25 is formed with a plurality of holes (26) that comes out of the nanoparticles on the front, the projection 27 is formed between the hole and the hole protrudes outward. The protrusion 27 stimulates and massages the skin by pressurizing the skin when the tip cover 25 is in close contact with the skin. Therefore, the nanoparticles coming out of the hole 26 of the tip cover 25 can more easily penetrate the skin.

2 and 3, the space between the main body 20 and the reservoir 10 constituting the handle forms a mounting hole 14 into which the injection unit 40 of the nano part is fitted.

The mounting hole 14 has a shape and size corresponding to that of the sprayer 40. The mounting hole 14 has a stepped portion 15 which is formed as a stopper by engaging with the injector 40 at the bottom thereof, so that the injector 40 can be fixed in position.

4 and 5 illustrate the structure of the present injector. The structure of the jetting body will be described with reference to these drawings.

As mentioned, the injector 40 is provided separately from the main body 20 so as to be detachably installed in the main body 20.

The injector 40 has a long cylindrical shape. The injector 40 has an outer shape and an exterior 41 in which a compressed fluid is circulated therein, an injection nozzle 42 formed at a tip of the exterior 41 to inject a compressed fluid, and inside the exterior 41. It is installed and connected to the inner tube 43, the lotion is distributed to the inner tube 43, and connected to the tip of the inner tube 43 and extending to the injection nozzle 42 includes a solution nozzle 44 to eject the lotion.

When the high pressure compressed fluid is ejected to the injection nozzle 42 through the inner tube 43 and the outer 41, the solution is discharged from the solution nozzle 44 by the pressure difference, and is injected at high speed with the compressed fluid.

In this embodiment, the injection body 40 has a structure in which the compressed fluid is supplied through the rear end. At the rear end of the injector 40, a hose 62 to which a compressed fluid is supplied is installed.

Here, the injector 40 is connected to the drive unit 63 for supplying a high pressure compressed fluid via the hose 62. As mentioned, the driver 63 may be installed in the driver 60 provided separately from the main body 20.

Hereinafter, the compressed fluid in the present embodiment will be described by using air as an example. According to a further embodiment of the device it is possible to supply oxygen to the injector 40 via the hose 62 in addition to air. To this end, the apparatus further includes an oxygen generator (see 69 in FIG. 1) for generating oxygen in the driver 60 and supplying the oxygen to the driver 63. Therefore, when the oxygen generator 69 is driven, oxygen is supplied to the driver 60, and the driver 60 can supply oxygen to the injector 40 through a hose. Oxygen is injected into the exterior 41 through the hose so that oxygen along with the lotion is injected through the injection nozzle 42. The nanoparticles nanoparticles are sprayed into the skin through the opening 21 of the body 20 together with the oxygen. Thus, it is possible to supply a higher amount of oxygen to the skin, thereby preventing skin aging and allowing the lotion to be rapidly absorbed deep into the skin, thereby increasing the natural moisturizing effect.

The injector 40 is further provided with a flange member 45 to supply the lotion to the injector 40 on the outer surface and to increase the fastening force with the main body 20. The flange member 45 is integrally formed on the exterior 41. For the supply of the lotion, the flange member 45 is connected to the front end of the inner tube 43, the hole 46 is formed in the center is in communication with the inner tube 43. In order to fasten with the main body 20, the flange member 45 has a size and shape corresponding to the stepped portion 15 formed in the mounting hole 14 of the main body 20 and is fitted to the stepped portion 15. In order to more securely fasten the stepped portion 15 and the flange member 45, the flange 47 protrudes outward from the lower end of the flange member 45. In addition, the stepped portion 15 has a flange insertion groove 16 formed at a position corresponding to the flange 47. When the injection body 40 is inserted into the mounting hole 14, the flange member 45 is fitted into the stepped portion 15, and the flange 47 is engaged with the groove 16 of the stepped portion 15. Therefore, the injection body 40 can be firmly mounted to the main body 20.

In addition, the injector 40 is coupled to communicate with the reservoir 10 through the flange member 45.

As mentioned herein, the locking jaw 19 is formed at the upper end of the reservoir 10 so that both side ends of the flange 47 of the flange member 45 are fitted. And the upper end of the reservoir 10 is provided with an O-ring 18 for maintaining the airtight between the contact surface and the flange member (45).

When the engaging jaw 19 of the reservoir 10 is coupled to the flange 47 of the sprayer 40, the supply pipe 17 of the reservoir communicates with the hole 46 formed in the flange member 45.

In the present embodiment, the injection body 40 is separated from the main body 20 to form an independent lotion high speed injection mechanism. That is, the injector 40 sprays the lotion introduced into the inner tube 43 through the flange member 45 at high speed using high pressure air. In order to supply the lotion to the flange member 45, a separate reservoir or supply hose is connected. Reference numeral 48 that is not described in Figure 4 is a separate connector fitted into the hole 46 of the flange member 45. A supply hose (not shown) for supplying a lotion may be connected to the connector 48.

With the above structure, supplying high pressure air to the exterior 41 causes the lotion to be sucked into the inner tube 43 by the negative pressure applied to the tip of the inner tube. The lotion sucked into the inner tube is ejected through the solution nozzle 44 at the tip of the inner tube 43. The lotion sprayed through the solution nozzle 44 is sprayed to the outside through the spray nozzle 42 at the tip of the exterior 41 together with the air sprayed at high speed.

In this way, when the injection body 40 is used separately from the main body 20, it is possible to spray the lotion at high speed. This can obtain the same effect as the hydro massage by hydraulic pressure. In addition, a special effect is obtained, such as air washing peeling by high pressure air or shampoo massage using only a small amount of water.

6 shows another embodiment of the present injector.

According to the above drawings, the main injection body 50 has an outer shape and has an outer appearance 51 through which the compressed fluid is distributed, and an injection nozzle 52 formed at the tip of the outer appearance 51 to inject the compressed fluid, The inner tube 53 is installed in the exterior 51 and the inner portion of the toilet is distributed therein, and a solution nozzle 54 connected to the tip of the inner tube 53 and extended to the injection nozzle 52 to eject the lotion. The exterior 51 has an elongated cylindrical shape. The flange member 55 protrudes from the side surface of the exterior 51. The flange member 55 is formed therein with a hole 56 communicating with the inside of the exterior 51. The hole 56 is fitted with a connector 57 and a hose (not shown) for supplying a compressed fluid through the connector 57 is connected to the hole. The inner tube 53 extends to the rear end of the outer tube 51. The rear end of the appearance 51 is fitted with a connector 58, the hose (not shown) for supplying the lotion through the connector 58 is fastened.

In the present embodiment, the flange member 55 is configured to be inclined with respect to the exterior 51 as shown. The inclination angle and the mounting position of the flange member 55 with respect to the appearance 51 are not particularly limited.

In the structure described above, the injection body 50 is supplied with a pressurized fluid through the flange member 55 and the lotion through the rear end of the injection body 50 is supplied to the inner tube (53). The supply position of the compressed fluid and the lotion is different, and the action is the same as in the above-mentioned embodiment.

7 illustrates a structure in which the jetting body of the present embodiment is mounted to the main body.

As shown, the cylindrical injection body 40 is fitted into the main body 20 through the mounting hole 14 in the rear of the main body 20. The mounting hole 14 is formed in a cylindrical shape like the injector 40 so that the injector 40 is naturally guided and entered.

When the flange member 45 contacts the inner surface of the stepped portion 15 formed in the mounting hole 14, the injection body 40 is completely fitted into the mounting hole 14. And the flange 47 formed in the flange member 45 is fixed to the front end is fitted into the groove 16 formed in the stepped portion (15). In addition, both side ends of the flange 47 are fitted to the engaging jaw (19) formed on the upper end of the reservoir (10) are mutually coupled.

The upper end of the reservoir 10 is provided with an O-ring 18 for maintaining the airtight outside the supply pipe 17, the bottom surface of the flange member 45 is in close contact with the O-ring 18. As the hole 46 formed in the flange member 45 and the supply pipe 17 communicate with each other, airtightness between the two members is maintained. Therefore, the injector 40 is in communication with the reservoir 10 via the supply pipe 17 connected to the inner pipe 43. As the inner tube 43 of the injector 40 communicates with the reservoir 10, the injector 40 may be supplied with the toilet water stored in the reservoir 10 and sprayed.

On the other hand, when the injection body 40 is completely mounted in the mounting hole 14, the injection nozzle 42 at the tip of the injection body 40 is close to the nanoplate 30 provided inside the main body 20 at a predetermined interval. . And the hole 46 formed in the center of the flange member 45 is exactly in communication with each other in line with the supply pipe 17 installed on the stepped portion (15).

When the injector 40 is combined with the main body 20, the injector 40 forms a nano part together with the nanoplate 30 installed in the main body 20. As mentioned, when the injector 40 is completely coupled to the main body 20, the injection nozzle 42 at the tip of the injector 40 is closely spaced at a predetermined interval toward the nanoplate 30 installed in the main body 20. do. The nanoplate 30 is a plate structure for colliding the lotion ejected with high-pressure compressed air. The lotion sprayed from the spray nozzle 42 is broken while colliding with the nanoplate 30 to become nanoparticles.

In this case, the nanoplate 30 should be able to be broken into a nano particle size in a greater amount of lotion during the collision of the lotion.

To this end, as shown in FIG. 8, the nanoplate 30 of the present embodiment is formed with a protruding portion 31 having a convex hemispherical shape in the center. In addition, the protruding portion protrudes from an outer surface of the protrusion 32 having a circular ring shape in the radial direction from the center at intervals. The protrusions 31 formed on the nanoplate 30 may be applied in various ways in addition to the hemispherical shape.

9 is another embodiment of a nanoplatelet. In the present embodiment, the nanoplate 35 has a flat plate structure, and has ring-shaped protrusions 36 and 37 protruding at intervals from the center along the radial direction. The protrusions 36 and 37 may have a circular ring or a rectangular ring shape. In the present embodiment, as shown in FIG. 9, the projection 36 in the form of a square ring and the projection 37 in the form of a circular ring are formed in combination.

In the case of the nanoplate 35 protruding the ring-shaped protrusions 36 and 37, finer nanoparticles may be ejected compared to the nanoplate 30 shown in FIG. 8.

Referring to the operation of the nano-part as follows.

The high pressure air supplied to the exterior 41 through the hose is injected at high speed through the injection nozzle 42 at the tip of the exterior 41. As a result, a negative pressure is generated in the inner tube 43 due to the flow rate of the fluid, and the lotion in the storage 10 is sucked up into the inner tube 43 along the supply pipe 17.

The lotion sucked into the inner tube 43 is ejected through the solution nozzle 44 at the tip of the inner tube 43 and is sprayed at high speed to the outside through the spray nozzle 42 together with the air.

As shown in FIG. 10, the diameter D of the injection nozzle 42 of the appearance 41 from which the lotion is ejected may be 0.5 mm to 0.9 mm. When the diameter D of the injection nozzle 42 is 0.5 mm or less, it is difficult to manufacture and there is a problem that the ejection amount is lowered. And when the diameter (D) is larger than 0.9mm, it can not perform the function of the injection nozzle.)

In addition, in the present embodiment, the distance L between the tip of the protruding portion 31 of the nanoplate 30 and the tip of the injection nozzle 42 may be 8 mm to 12 mm. When the nanoplate 30 is used, the size of the generated nanoparticles becomes larger than 0.4 micron, but it is possible to generate a larger amount of nanoparticles. When the distance L between the tip of the protruding portion 31 and the tip of the injection nozzle 42 of the nanoplate 30 is 8 mm or less, the ejection amount is lowered, and when larger than 12 mm, the particles become thicker and the amount is also lowered. have.

In the case of the nanoplate 35 according to the embodiment of FIG. 9, the distance between the protrusions 36 and 37 of the nanoplate 35 and the tip of the injection nozzle 42 may be 0.5 mm to 1.5 mm. When the nanoplate 35 is used, the amount of nanoparticles generated is reduced, but the size of the nanoparticles is reduced to 0.4 microns or less. When the distance between the projections 36 and 37 of the nanoplate 35 and the tip of the injection nozzle 42 is 0.5 mm or less, the ejection amount is lowered.

As such, when the amount of nanoparticles is prioritized, the nanoplate 30 shown in FIG. 8 is used, and when a finer particle size is given priority than the amount of nanoparticles generated, the nanoplate 35 shown in FIG. By using it, desired conditions can be satisfied.

In this way, the lotion ejected at high speed with the air by the injector 40 collides into the protrusions 31 of the nanoplate 30 spaced apart from the injection nozzle 42 by a predetermined distance, and is crushed into smaller particles. Become At this time, the lotion is negatively charged because the hydrogen bond is broken. Nano-particles lotion is moved toward the body 20. Therefore, the nanoparticles containing a large amount of anions can be sprayed to the outside through the opening 21 of the main body 20.

In this process, the fine mist-like lotion having a larger particle size than the nanoparticles among the lotions collided with the nanoplate 30 is agglomerated into water droplets. The lotion that has become heavy with water drops falls back and returns to the reservoir 10.

The nanoparticles generated through the above process are moved along the air flow injected from the injector 40 and introduced into the main body 20. The nanoparticles introduced into the main body 20 are sprayed to the outside after the larger particles are removed while passing through the filter 22 installed in the opening 21 at the tip of the main body 20.

On the other hand, the spray device includes a pulse imparting unit for applying a current of a specific waveform, such as low frequency to the nanoparticles sprayed through the main body 20 opening 21.

As shown in FIG. 1, the pulse applying unit outputs a pulse unit 65 for generating a pulse output signal having a specific waveform and a pulse output signal directly applied to the nanoparticles electrically connected to and sprayed with the pulse unit 65. Contains wealth.

In the present embodiment, the output unit uses a filter 22 installed in the opening 21. To this end, the filter 22 is made of a conductor and is electrically connected to the pulse unit 65 via a wire 61.

The wire 61 electrically connected to the pulse part 65 is installed into the main body 20 through the rear end of the main body 20. And the side of the main body 20 is formed with the hole (not shown) in the longitudinal direction so that the wire can pass. Accordingly, the electric wire 61 entered into the rear end of the main body 20 is inserted into the hole and electrically connected to the filter 22.

The pulse part 65 is provided in the driver 60 provided separately from the main body 20 as shown in FIG. The pulse part 65 is provided with an oscillation part to generate a pulse output signal from a DC power supply. Since many techniques have already been disclosed for the low frequency generation structure, the following description is omitted.

Accordingly, the output pulse generated by the pulse unit 65 is applied to the filter 22 which is an output unit through the wire 61. Accordingly, the filter 22 applies an output pulse such as a low frequency to the nanoparticles in the form of fog passing through the filter 22.

Therefore, the low frequency pulse transmitted through the nanoparticles applies low frequency pulses to the skin as the nanoparticles touch the user's skin. The tapping, kneading, and pressing action caused by the low frequency pulse is applied to the skin, so that the nanoparticles can penetrate deeper into the skin.

In addition, the present spraying apparatus further includes a laser irradiation unit for irradiating a low power laser to the skin.

1 and 2, the laser irradiation unit is installed in the center of the rear end of the main body 20, the laser diode 70 for irradiating a low power laser toward the opening 21 of the main body 20, and It is connected to the laser diode 70 and a wire and includes a power supply unit 64 for supplying power. The power supply unit 64 is provided in the driver 60 provided separately from the main body 20.

Here, the low power laser output from the laser diode 70 refers to an infrared wavelength of up to 1000 nm from the red visible light having a wavelength of 600 nm or more, the output intensity is about 100 mW ~ 500 mW and the amount of energy per unit area is 0.05 ~ 5.0 W / Cm 2.

In addition, according to the present embodiment, the low-power laser irradiated from the laser diode 70 should be able to irradiate the skin of the user past the opening. To this end, the tip cover 25 installed in the opening 21 has a hole 28 in the center, and the hole 29 is further formed in the center of the filter 22.

When the power supply unit 64 is driven and the power is applied to the laser diode 70, a low output laser is output from the laser diode 70, and the irradiated light is radiated from the center hole 29 and the tip cover 25 of the filter 22. Irradiated to the user's skin through the central hole (28).

In this way, the laser is irradiated to the skin together with the nanoparticles sprayed through the opening, thereby stimulating the skin so that the nanoparticles can penetrate deeper into the skin.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

1 is a schematic diagram of a nano ion atomizer according to an embodiment of the present invention.

2 is a cross-sectional view of a state in which the injector is removed with a nano ion spray device according to an embodiment of the present invention.

Figure 3 is a view showing the back of the nano ion spray device according to an embodiment of the present invention.

4 is a perspective view showing an injector according to an embodiment of the present invention.

5 is a cross-sectional view of the injector in accordance with an embodiment of the present invention.

6 is a cross-sectional view showing an injection body in another embodiment of the present invention.

Figure 7 is a cross-sectional view showing a nano ion spray device coupled to the spray according to an embodiment of the present invention.

8 is a perspective view showing a nanoplate of the nano-ion spray device according to an embodiment of the present invention.

9 is a perspective view showing a nanoplate according to another embodiment of the present invention.

10 is a schematic view for explaining the operation of the nano ion spray device according to an embodiment of the present invention.

Claims (21)

A nano part for nanoparticle-forming a solution, and a main body having the nano part installed therein and having an opening for discharging nanoparticles at a tip end thereof, The nano-ion spray apparatus comprising an injector for high-speed injection of the solution, and a nano plate to collide with the solution to be spaced apart from the injector. delete The method of claim 1, And a reservoir installed in the main body, the reservoir storing the solution therein and supplying the solution to the spraying body. The method of claim 1, The injection body has an appearance in which the compressed fluid is distributed, and an injection nozzle formed at the front end of the injection fluid to inject the compressed fluid at high pressure, an inner tube installed inside the exterior and in which the solution is distributed, and connected to the inner tube tip and the injection nozzle Nano ion spray apparatus comprising a solution nozzle is extended to the solution is ejected. The method of claim 4, wherein Nano-ion atomizer further comprises a driver for supplying a compressed fluid is connected to the injector via a hose. The method of claim 5, The driver further comprises a nano-ion generator capable of generating and supplying oxygen. The method of claim 4, wherein The injector is a nano ion spray device detachably installed on the body. The method of claim 7, wherein The injector has a flange member protruding from the outer side, the flange member is formed in the center is connected to the inner tube hole, the nano ion atomizer of the structure in communication with the reservoir installed in the main body when the main body is fastened. The method of claim 8, The reservoir is coupled to the upper side is open so as to communicate with the body, the upper end of the nano ion atomizer of the structure is provided with a supply pipe extending to the bottom of the reservoir. The method of claim 1, The nanoplate is a nano ion spray device formed with a hemispherical protrusion in the center. 11. The method of claim 10, The protruding portion is a nano ion spray device formed by protruding at intervals in the form of a ring-shaped protrusion in the radial direction from the center. The method of claim 1, The nano-plate is a nano ion spray device formed by protruding at intervals in the form of a ring-shaped projection in the radial direction from the center. The method of claim 4, wherein The spray nozzle is a nano ion spray device of 0.5mm ~ 0.9mm in diameter. The method of claim 4, wherein The nanoplate has a hemispherical protrusion formed at the center thereof, and a distance between the protrusion of the nanoplate and the tip of the injection nozzle is 8 mm to 12 mm. The method of claim 4, wherein The nanoplates are formed in a radially protruding ring-shaped protrusion along the radial direction from the center, the distance between the projections of the nanoplates and the tip of the injection nozzle is 0.5mm ~ 1.5mm nano ion spraying device. The method according to any one of claims 1 or 3 to 15, The main body opening including a pulse unit for generating a pulse output signal of a specific waveform, and an output unit for applying a pulse output signal to the nano-particles that are electrically connected to the pulse and located in the opening of the main body sprayed Nano ion atomizing device further comprising a pulse imparting for applying a current of a specific waveform to the nanoparticles sprayed through. The method of claim 16, And a laser diode installed at the rear end of the main body to irradiate a low power laser toward an opening of the main body, and a power supply unit connected to the laser diode and a wire to supply power. Injector for high speed injection of solution, The appearance that the compressed fluid is distributed, A spray nozzle which is formed at the front end and sprays the compressed fluid at a high pressure; An inner tube installed inside the exterior and having a solution circulated therein; A solution nozzle connected to the tip of the inner tube and extending to a spray nozzle to eject a solution Solution injector comprising a. The method of claim 18, The exterior is connected to the pressurized fluid supply hose through the connector is mounted on the end, the flange member is formed protruding on the outer surface, the inner tube is connected to the flange member to the solution via the connector mounted on the flange member Solution spray connected to the supply hose. The method of claim 18, The outer surface is protruded to form a flange member on the outer surface is connected to the compressed fluid supply hose via a connector mounted on the flange member, the inner tube is extended to the end of the appearance is connected to the compressed fluid supply hose via the connector Solution spray. The method of claim 18, The spray nozzle is a solution injector having a diameter of 0.5mm ~ 0.9mm.

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