WO2011155673A1 - Combined structure of a mesh integrated with a piezoelectric transducer, a silicon holder, and a medicine case - Google Patents

Abstract

The present invention relates to a combined structure in which a medicine case is combined with a mesh in order to make a pharmaceutical solution finer. The mesh is integrated with a pair of piezoelectric transducers (PZTs) for spraying the medicine solution in a particle state, via a hollow cylindrical silicon holder. The mesh may be disposed between the pair of the doughnut-shaped PZTs such that the mesh is exposed through the hollow center portion of the doughnut-shaped PZT, and a sterilization module having an opposed electrode to generate a sterilizing substance may be disposed in the hollow center portion. The mesh may include auxiliary components such as a step portion, groove, protrusion, and locking ring so as to fix the mesh effectively. According to the present invention, the spraying of the medicine is made efficient since the silicon does not dampen ultrasonic vibration.

Description

Combined structure of ultrasonic element integrated mesh, silicon holder and medicine container

The present invention is a coupling structure of an ultrasonic element (PZT) integrated mesh, a silicon holder and a medicine container, and more specifically, a silicon ring and a fixing ring are used to couple the ultrasonic element integrated mesh to a silicon holder, The present invention relates to a coupling structure of an ultrasonic element integrated mesh, a silicon holder, and a medicine container, which combines a silicon holder having a medicine moving passage and an air inlet and an inlet of the medicine container so that the drug solution can smoothly flow into the ultrasonic device integrated mesh.

As shown in Figs. 1 and 2, the Applicant has recently been able to use the user freely in any posture, so that the mist of the lotion and / or the pharmaceutical solution is evenly sprayed on the face to obtain a sufficient skin cosmetic effect. Filed for a multifunctional facial device 100 using an ultrasonic wave (application number 10-2009-0080164).

In the configuration of the patented invention, the ultrasonic nebulizer 110 is mechanically coupled with the medicine container 111 and the medicine container 111, the ultrasonic injection nozzle for spraying the drug solution filled in the medicine container 111 with fine particles 114 is provided.

According to the above configuration, the nozzle and the mesh vibrate by ultrasonic waves, and the vibration of the chemical solution inside the medicine container is made into small particles and moved to the mesh through the tube inside the nozzle. The particles deform into smaller particles depending on the size of the holes in the mesh and are sprayed into the air.

However, this structure has a problem that the nozzle and the silicon holder is combined, the structure is complicated, the ultrasonic vibration is reduced, and the manufacturing cost is high.

The present invention has been made to solve the above-mentioned conventional problems, by using an ultrasonic device integrated mesh that is sold in common, has a simpler structure, inexpensive, and can efficiently supply the drug solution to the ultrasonic element integrated mesh An object of the present invention is to provide an ultrasonic device integrated mesh of the ultrasonic nebulizer and a coupling structure of the silicon holder and the medicine container.

In order to achieve the above object, the present invention, a pair of ultrasonic device (PZT) for spraying the drug solution in the form of particles and the ultrasonic device integrated mesh made of a combination of the finer the finer the drug solution, and hollow, It consists of a coupling structure of a cylindrical silicon holder and a medicine container.

In the present invention, both ends of the silicon holder may be made of a structure for coupling with the ultrasonic element-integrated mesh and the medicine container.

For example, if one end of the silicon holder in which the ultrasonic element-integrated mesh is coupled is referred to as an upper end, a stage is formed in the inner wall surface (inner circumferential surface) of the silicon holder, which is larger than the hollow of the middle part. A first hollow having a diameter is formed, a first projection for supporting the ultrasonic element-integrated mesh is formed at the peripheral bottom surface of the first hollow corresponding to the stepped surface, and the ultrasonic element is formed at the inner wall corresponding to the side of the first hollow. A first groove capable of joining the integrated mesh and a second groove formed above the first groove may be formed.

At this time, the second groove is coupled to the fixing ring for pressing and fixing the ultrasonic integrated mesh coupled to the first groove from above. A second protrusion for coupling to the second groove is formed on the outer circumference of the fixing ring, and a silicon ring for fixing the ultrasonic element integrated mesh is mounted on the lower surface of the fixing ring.

In the present invention, the drug movement passage may be formed on the side of the hollow that is the inner wall surface of the silicon holder to move the drug solution smoothly.

In the present invention, the other end of the silicon holder is formed with a stage so that the medicine container can be coupled to the second hollow having a larger diameter than the hollow of the middle portion is formed, the side of the second hollow A third protrusion may be formed to further close the coupling between the medicine container and the silicon holder. In this case, after the silicon holder and the medicine container are coupled to the second hollow side, air flows into the silicon holder. An air inlet may be formed to be able to be, and the drug movement passage and the air inlet may be formed to face each other.

In the present invention, the silicon holder may have a plurality of fixing grooves on the outer circumferential surface to be fixed to the outside.

According to the combined structure of the ultrasonic element integrated mesh, the silicon holder and the medicine container according to the present invention, the drug solution is not easily leaked, and the ultrasonic vibration is not lowered, so that a larger amount of spraying is performed.

In addition, according to the coupling structure of the present invention, the ultrasonic element integrated mesh can be firmly coupled to the silicon holder, and if the air inlet is formed on the coupling portion of the silicon holder and the medicine container, the pharmaceutical solution can be smoothly supplied to the ultrasonic element integrated mesh. have.

In addition, the coupling structure of the present invention is simple and the manufacturing cost is low.

1 is a perspective view showing a multifunction facial device to which the present invention can be mounted.

Figure 2 is a perspective view of a part of the disassembled state showing that the conventional ultrasonic atomizer is equipped with a multifunction facial device.

Figure 3 is a front sectional view showing a coupling structure of the ultrasonic element integrated mesh, the silicon holder and the medicine container according to the present invention.

4 is a front sectional view of a silicon holder according to the present invention.

5 is a front view and a plan cross-sectional view showing an ultrasonic element integrated mesh according to the present invention.

Figure 6 is a front sectional view showing another embodiment of the present invention.

Hereinafter, a preferred embodiment of a coupling structure of an ultrasonic device (PZT) integrated mesh and a silicon holder and a medicine container according to the present invention will be described with reference to the drawings.

Figure 3 is a cross-sectional view showing a coupling structure of the ultrasonic element integrated mesh, the silicon holder and the medicine container according to the present invention, Figure 4 is a cross-sectional view of the silicon holder according to the present invention, Figure 5 is an ultrasonic element integrated mesh according to the present invention It is a figure which shows.

As shown in FIG. 3, the present invention relates to a structure in which an ultrasonic element integrated mesh and a silicon holder and the silicon holder and the medicine container are combined.

As shown in FIG. 5, the ultrasonic element integrated mesh 20 includes a pair of ultrasonic elements 21 and one mesh 22 mounted therebetween. The ultrasonic element 21 is formed in a substantially donut shape so that only the mesh 22 is exposed at the empty center portion of the donut shape, and the ultrasonic element 21 is formed on the outer circumference of the donut shaped ultrasonic element 21. The lead wire 23 for supplying power is connected.

In addition, the mesh 22 allows the pharmaceutical solution to be formed into fine particles, and is coupled between the pair of ultrasonic elements 21. With this configuration, when the pair of ultrasonic elements 21 are vibrated by receiving power from the outside, the mesh 22 may also be vibrated and sprayed with a fine mist of the chemical solution supplied.

In addition, as shown in Figure 4, the silicon holder 10 is made of a cylindrical having an elongated shape, there is a hollow to pass the drug solution therein, preferably one end of the silicon holder 10 The hollow is narrowed toward the part to form a tapered shape.

For convenience, the upper end of the silicon holder 10 is coupled to the ultrasonic element-integrated mesh and the lower side is coupled to the medicine container. A first hollow 11a having a diameter larger than that of the hollow in the longitudinal middle portion of the first hollow 11a is formed, and an ultrasonic element-integrated mesh 20 is formed at the inner end of the circumferential bottom surface of the first hollow 11a forming the stepped surface of the stage. The first protrusion 12 for supporting is formed. The first protrusion 12 preferably has a ring or cone shape having a semi-circular cross section that narrows upward to reduce the contact surface so as not to reduce the vibration of the ultrasonic element-integrated mesh 20.

In addition, a first groove 13 capable of fitting the outer circumferential surface of the ultrasonic element-integrated mesh 20 to the inner wall surface forming the side surface of the first hollow 11a, and a fixing described later above the first groove 13. A second groove 14 for coupling the ring 30 is formed, and a lead wire groove 15 is formed inside the inner wall so that the lead wire of the ultrasonic element may protrude to the outside.

As shown in FIG. 3, a fixing ring 30 for fixing the ultrasonic element-integrating mesh 20 is coupled to an upper portion of the ultrasonic element-integrating mesh 20, and a first ring is formed on an outer circumferential surface of the fixing ring 30. A second protrusion 30a is formed to engage the second groove 14 of the hollow 11a. In addition, the lower surface of the fixing ring 30 is formed with a groove to which the silicon ring 31 for fixing the ultrasonic element-integrated mesh 20 is coupled using a minimum area so as not to reduce the vibration performance of the ultrasonic wave. In addition, the silicon ring 31 and the first protrusion 12 are preferably formed at positions facing each other in order to balance the force applied to the ultrasonic element-integrated mesh 20.

In addition, on the hollow side surface of the silicon holder 10, the drug movement passage 17 for facilitating the movement of the drug solution is formed in a 'V'-shaped groove having a substantially cross section along the longitudinal direction of the cylinder holder 10. The drug movement passage 17 mitigates the cohesive force such as surface tension when the drug solution moves from the drug container 40 to the ultrasonic element-integrated mesh 20, thereby allowing the drug solution to be sucked along the drug movement path 17. Facilitate the flow of pharmaceutical solution. That is, the liquid in the drug movement passage 17 is sprayed and sucked out by the cohesive force so that the drug smoothly flows into the ultrasonic element-integrated mesh 20. The drug movement passage 17 may be formed in an intaglio ('V'-shaped groove), as shown in Figures 3 and 4, may be formed in an embossed.

In addition, a stage is formed at the other end of the silicon holder 10 so that the medicine container 40 can be coupled thereto. 2 hollow 11b is formed. A third projection 19 is formed on the side surface of the second hollow 11b to bring the bond between the medicine container 40 and the silicon holder 10 into close contact with each other.

In addition, after the silicon holder 10 and the medicine container 40 are coupled to the side of the second hollow shape 11b, a groove-shaped air inlet 18 is formed to allow air to flow into the silicon holder 10. It is formed, the air inlet 18 is also formed through the third projection (19). By the air inlet 18, the drug solution is sprayed and ejected, so that a vacuum is formed in the medicine container 40, thereby preventing the movement of the drug solution.

In addition, when the silicone holder 10 and the medicine container 40 are combined, the drug movement path 17 is a general use of the medicine container inlet in the medicine container as shown in Figure 3 to facilitate the flow of the drug solution more smoothly In the state, it is coupled to be located below the inlet of the medicine container 40, the air inlet 18 is preferably coupled to be located above the inlet of the medicine container 40 so that the inflow of air can be smoothly. In other words, the drug movement passage 17 and the air inlet 18 is preferably formed in a position facing each other.

On the other hand, the air may also be introduced into the silicon holder 10 from the outside through the fine hole of the mesh 22 to be guided to the medicine container through the inclined inner wall surface of the silicon holder 10 and the air movement passage 181.

In addition, a plurality of fixing grooves 16 are formed on the outer circumferential surface of the silicon holder 10 so as to be able to be coupled to an external device or an outer case (particularly, the outer case 101 of the multifunction facial device).

Hereinafter, the assembly order and operation for forming the coupling structure of the ultrasonic element-integrated mesh 20, the silicon holder 10, and the medicine container 40 of the present invention will be described.

Ultrasonic nebulizer 110 is equipped with the present invention, as shown in Figure 2, the inlet of the drug container 111 is formed at the bottom.

First, the outer peripheral surface of the ultrasonic element-integrated mesh 20 is inserted into and coupled to the first groove 13 of the first hollow 11a formed at one end of the silicon holder 10, and the lead wire 23 is connected to the lead wire groove 15. Get out through the room. The ultrasonic element-integrated mesh 20 is supported by the first protrusion 12 formed on the bottom surface of the first hollow 11a, and then the second protrusion 30a of the fixing ring 30 is formed in the second groove. The silicon ring 31 coupled to the 14 and mounted on the lower surface of the fixing ring 30 to fix the ultrasonic element-integrated mesh 20. The ultrasonic element integrated mesh 20 is fixed by a silicon ring 31 instead of the entire lower surface area of the fixing ring 30 to be fixed in a narrow area to minimize the reduction of vibration formed in the ultrasonic element integrated mesh 20. Can be.

In addition, the third protrusion 19 of the second hollow shape 11b formed at the other end of the silicon holder 10 and the groove formed at the inlet of the medicine container 40 are combined.

In this combined state, the drug solution of the medicine container flows into the hollow of the silicon holder through the coupling portion of the silicon holder 10 and the medicine container, and reaches the opposite ultrasonic element integrated mesh. Ultrasonic device-integrated mesh has a very tight mesh, so the drug solution cannot pass through the mesh by the surface tension when the ultrasonic device is not operating.

However, when the ultrasonic element operates, the medicinal solution in contact with the mesh becomes a mist state made of fine water droplets by ultrasonic vibration, and is sprayed out through the fine mesh of the mesh, and the fine water droplets forming the mist come into contact with the user's skin. .

At this time, the drug movement path 17 formed in the silicon holder 10 is positioned below the inlet of the medicine container 40 so that the chemical solution is easily introduced into the ultrasonic element-integrated mesh 20, and the air inlet 18 is In order to be positioned above the inlet of the medicine barrel 40, the external air flows into the air inlet 18 to solve the vacuum generated by spraying the drug solution in the silicon holder 10 to the outside. Due to the nature of the silicone material, the air is introduced into the air inlet 18 as the silicone holder 10 extends outward in the chemical container 40.

In addition, when the ultrasonic element 21 vibrates, the mesh 22 vibrates to spray the chemical solution or water in the silicon holder 10 in the form of fine particles, and at the same time, outside air flows into the inside through minute holes of the mesh 22. do. At this time, the introduced air may interfere with the injection by forming an air layer near the mesh when the inner wall surface of the silicon holder 10 is horizontally installed. Therefore, the diameter of the hole at the end of the ultrasonic vibrator side is small and the diameter of the hole at the side of the ultrasonic vibrator is reduced as shown in the silicon holder 10 so as to smoothly guide the air around the introduced mesh into the medicament while not interfering with the injection of the medicinal solution or water. The diameter of the hole is preferably formed in a trumpet shape to be enlarged. In this case, an inclination occurs on the inner wall surface in the installation state of the silicon holder so that the light air layer is naturally led to the medicine container as shown in FIG. In this case, a groove may be formed at an upper side opposite to the drug movement passage 17 to guide the air layer, and may be used as the air movement passage 181.

Figure 6 shows another embodiment of the present invention.

In this embodiment, a sterilizing module 50 having electrodes 51 and 52 facing each other is provided in the hollow of the silicon holder. The two electrodes 51 and 52 constituting the sterilizing module 50 have a gap of 0.5 to 3.0 mm and form a rectangular electrode plate or mesh. A direct current of 3 to 24 volts V is alternately applied between the two electrodes 51 and 52. For alternating current, a current alternating device portion is provided on the circuit. The alternating current may serve to prevent a scale formed by depositing a specific material on the electrode plate constituting the sterilization module 50 or the silicon holder hollow surface around the current plate when the current flows only in one direction.

Therefore, the drug that is moved to the ultrasonic element-integrated mesh through the hollow of the silicon holder in the medicine container may be electrolyzed by a current around the two electrodes of the sterilization module 50. Through such an electrolytic action, a chlorine acid group (HClO) may be formed in the drug due to electrolysis of a hydroxyl group (OH—) by electrolysis of water or an aqueous salt solution containing chlorine in a solution. Since these functional groups have strong bactericidal properties, when the liquid medicine is sprayed in the form of a mist by the ultrasonic element-integrated mesh, they exist in the mist particles and come into contact with the skin, and the bactericidal action can be performed on the skin.

In the above description of the preferred embodiment of the present invention, the present invention is not limited thereto, and a person of ordinary skill in the art may have various modifications without departing from the technical spirit of the present invention described in the claims of the present invention. Changes will be possible.

Claims (10)

1. Ultrasonic element-integrated mesh 20 is formed by integrally combining the ultrasonic element for spraying the drug solution in the form of particles and the mesh 22 to finer the drug solution,

   Pass through the drug containing the drug solution,

   One end is connected to the inlet of the medicine container, the other end is coupled to the ultrasonic element integrated mesh is a hollow cylinder-shaped silicone holder 10 which is a passage for moving the drug solution of the medicine container to the ultrasonic element integrated mesh (10) A coupling structure of the ultrasonic element integrated mesh and the silicon holder and the medicine container having a.
2. The method of claim 1,

   The ultrasonic element-integrated mesh 20 is composed of a pair of ultrasonic elements 21 and one mesh 22 mounted between the pair of ultrasonic elements 21, and the ultrasonic element 21 is in a donut shape. Composed structure of the ultrasonic element integrated mesh, the silicon holder and the medicine container, characterized in that the hollow portion of the ultrasonic element is installed so that only the mesh 22 is exposed.
3. The method of claim 1,

   An end is formed at one end of the silicon holder 10 to form a first hollow 11a having a larger diameter than the hollow.

   The first projection 12 for supporting the ultrasonic element-integrated mesh 20 is formed on the circumferential bottom surface of the first hollow 11a forming the stepped surface of the stage,

   A first groove 13 capable of coupling the ultrasonic element-integrated mesh 20 to the inner side wall forming the side surface of the first hollow 11a, and a second groove 14 located above the first groove. Is formed,

   Fixing ring 30 is mounted to the second groove,

   The fixing ring 30 is formed on the outer circumference of the second projection (30a) for coupling to the second groove 14, the lower surface of the silicon ring 31 for fixing the ultrasonic element-integrated mesh 20 It is mounted, the ultrasonic device integrated mesh, characterized in that placed on top of the integrated mesh 20, the structure of the ultrasonic device integrated mesh and the silicon holder and the medicine container.
4. The method of claim 1,

   A coupling structure of an ultrasonic element integrated mesh, a silicon holder, and a medicine container is formed on the inner wall surface corresponding to the hollow side of the silicon holder 10 so that the medicine solution passage can be smoothly moved. .
5. The method according to claim 1 or 4,

   The other end of the silicon holder 10 has a stage formed so that the medicine container 40 can be coupled to form a second hollow 11b having a diameter larger than that of the hollow,

   Ultrasonic element-integrated mesh, characterized in that the third projection 19 is formed on the inner wall surface forming the side of the second hollow (11b) in close contact with the combination of the medicine container 40 and the silicon holder 10. And silicone holder and medicine container.
6. The method of claim 5,

   After the silicon holder 10 and the medicine container 40 are coupled to the inner side wall forming the side surface of the second hollow 11b, the air inlet 18 allows air to flow into the silicon holder 10. ) Is a coupling structure of the ultrasonic element-integrated mesh, the silicon holder and the medicine container.
7. The method of claim 1,

   The silicon holder 10 has a plurality of fixing grooves 16 on the outer circumferential surface to be fixed to the outside, characterized in that the coupling structure of the mesh and the silicon holder and the medicine container.
8. The method of claim 4, wherein

   The other end of the silicon holder 10 has a stage formed so that the medicine container 40 can be coupled to form a second hollow 11b having a diameter larger than that of the hollow,

   On the side of the second hollow (11b), after the silicon holder 10 and the medicine container 40 is coupled, an air inlet 18 is formed so that air can be introduced into the silicon holder (10) ,

   The drug movement passage (17) and the air inlet (18) is formed so as to face each other, the ultrasonic structure of the integrated mesh, the silicon holder and the medicine container.
9. The method of claim 1,

   The sterilization module having electrodes facing each other is installed in the hollow of the silicon holder,

   The two electrodes (51, 52) constituting the sterilization module 50 has an electrode plate or a mesh form, the coupling structure of the ultrasonic element integrated mesh, silicon holder and the medicine container, characterized in that the gap is 0.5 to 3.0mm.
10. The method of claim 9,

    A coupling structure of an ultrasonic element integrated mesh, a silicon holder, and a medicine container, wherein direct current is alternately applied to the two electrodes.

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