KR200439116Y1 - Droplet generation apparatus - Google Patents

Abstract

Droplet generators are applied to nebulizers. The droplet generating apparatus includes a vibrating member, a nozzle disc, a housing and a connecting member or both a fastening plate or a connecting member and a fastening plate. The vibrating member has a first through hole. The nozzle disk has a plurality of openings facing the first through hole and is coupled to the vibration member. The connecting member is disposed between the vibrating member and the nozzle disk and has a second through hole corresponding to the first through hole. Alternatively, the fastening plate is engaged with the nozzle disk. The housing covers the combination of the vibrating member, the nozzle disk and the connecting member or fastening plate. The efficiency of the vibration generated by the vibrating member is improved through the connecting member. An accommodation space is formed by the fastening plate and the nozzle disk.

Droplet, chemical sprayer, mist, droplet generator

Description

Droplet generating device {DROPLET GENERATION APPARATUS}

1 is a cross-sectional view of a conventional droplet generating apparatus.

2 is an exploded view of the droplet generating apparatus of the present invention.

3 is a cross-sectional view of the droplet generating apparatus of the present invention.

4 is a cross-sectional view of another droplet generating device of the present invention.

5 is an exploded view of another droplet generating apparatus of the present invention.

6 is a cross-sectional view of another droplet generating device of the present invention.

7 is a cross-sectional view of another droplet generating device of the present invention.

8 is a cross-sectional view of another droplet generating device of the present invention.

The present invention relates to a droplet generating apparatus, and more particularly to a droplet generating apparatus with improved droplet generating efficiency.

Atomizers currently used in the market generally consist of a vibrating element and a nozzle disc made of piezoelectric material, which are arranged in a chamber containing liquid or connected to the nozzle disc. When the piezoelectric material is connected to electricity, a high speed repetitive motion is generated, thereby allowing liquid to pass through the nozzle disk. Alternatively, the nozzle disk is driven to generate vibrations, thereby allowing liquid to be squeezed out of the nozzle disk and sprayed. In addition, the liquid is sprayed from the micro-opening of the nozzle disk to become fine droplets, thereby achieving the goal of spraying through the misting of the liquid.

Reference is made to FIG. 1, which is an assembly cross sectional view of a conventional micro-droplet generator. The micro-droplet generating apparatus 1 has a nozzle disk 11 and a vibrating element 12. The nozzle disc 11 has a micro-opening 111 and a specified distance is maintained between the vibrating element 12 and the nozzle disc 11. The reciprocating motion is then generated by the drive of the vibratory element 12 to squeeze the liquid to spray it from the opening 111 of the nozzle disc 11, thereby forming micro-droplets.

However, in this case, for efficient micro-droplet division, the spacing between the nozzle disk and the vibrating element should be controlled and designed. It is difficult for the manufacturer to easily carry out such control. Accordingly, the inventors of the present invention have conducted intensive research and experimentation based on years of experience in related fields, and finally developed a droplet generating apparatus as a method or concept for overcoming the above problems.

The main object of the present invention is to provide a droplet generating apparatus with improved droplet generating efficiency.

To achieve the above object, the droplet generating device of the present invention includes a vibration member, a connecting member, a nozzle disk and a housing. The vibrating member has a first through hole. The nozzle disk has a plurality of openings facing the first through hole. A connecting member is disposed between the vibration member and the nozzle disk and has a second through hole corresponding to the first through hole. The housing covers the vibrating member, the nozzle disk and the connecting member. The vibration efficiency generated by the vibration member is improved through the connecting member.

In addition, the droplet generating apparatus of the present invention includes a vibrating member, a nozzle disk, a fastening plate and a housing, the vibrating member having a first through hole and coupled to the fastening plate. The nozzle disc is disposed between the vibration member and the fastening plate and has a plurality of openings facing the first through hole. The housing covers the vibrating member, the nozzle disk and the fastening plate. Thus, the accommodation space is formed by the fastening plate and the nozzle disk.

Alternatively, the droplet generating device of the present invention includes a vibrating member, a connecting member, a nozzle disk, a fastening plate and a housing. The vibrating member has a first through hole. The nozzle disk has a plurality of openings facing the first through hole. The connecting member is disposed between the vibrating member and the nozzle disk and has a second through hole corresponding to the first through hole. The fastening plate is engaged with the plane of the nozzle disk. The housing covers the vibrating member, the connecting member, the nozzle disk and the fastening plate. The efficiency of the vibration generated by the vibrating member is improved through the connecting member, and the receiving space is formed by the fastening plate and the nozzle disk.

Thus, the vibration efficiency of the droplet generating apparatus is increased by using the housing by the connecting member or the fastening plate or by both the connecting member and the fastening plate and as the O-shaped ring. The efficiency and accuracy of the liquid mist performed by the nozzle disc can be enhanced without gap control.

In order to facilitate understanding of the present invention, the following describes the innovative features and performance of the present invention, the technical features and specific description of the present invention with reference to the accompanying drawings in detail.

Reference is made to the drawings relating to a droplet generating apparatus according to a preferred embodiment of the present invention, in which like elements are denoted by the same reference numerals.

2 and 3, Figure 2 is an exploded view showing the droplet generating apparatus of the present invention, Figure 3 is a cross-sectional view of the droplet generating apparatus. As shown in FIG. 2, a droplet generating apparatus 2 is applied to an atomizer and includes a vibrating member 21, a connecting member 22, a nozzle disk 23 and a housing 24. The vibrating member 21 includes a first through hole 211, and the nozzle disc 23 includes a plurality of openings 231 facing the first through hole 211. The connection member 22 is disposed between the vibration member 21 and the nozzle disk 23, and has a second through hole 221 corresponding to the first through hole 211, and the vibration member 21. ) And the nozzle disc 23. The housing 24 covers the vibrating member 21, the connecting member 22 and the nozzle disc 23. In addition, an extension wall 222 is provided in the second through hole 221 of the connecting member 22 and disposed in the first through hole 211 of the vibration member 21.

Referring to FIG. 4, another droplet generating device of the present invention is shown in cross section, the droplet generating device 4 being applied to an atomizer, and having a vibrating member 21, a connecting member 22, and a nozzle disk 41. ) And a housing 24. The vibrating member 21 has a first through hole 211, and the nozzle disc 41 has a plurality of openings 231 facing the first through hole 211. The connecting member 22 is disposed between the vibrating member 21 and the nozzle disk 41 and has a second through hole 221 corresponding to the first through hole 211, and the vibrating member 21 and It is coupled with the nozzle disk 41. The housing 24 covers the vibrating member 21, the connecting member 22 and the nozzle disc 41. In addition, an extension wall 222 disposed in the first through hole 211 of the vibration member 21 is provided in the second through hole 221 of the connection member 22. The plane of the nozzle disc 41 forms a protrusion-shaped portion 411 having the opening 231. The protruding-shaped portion 411 faces the first through hole 211 and the second through hole 221.

5 and 6, FIG. 5 is an exploded view of another droplet generating apparatus of the present invention, and FIG. 6 is a cross-sectional view of another droplet generating apparatus. As shown in FIG. 5, a droplet generating apparatus 5 is applied to an atomizer and includes a vibrating member 21, a nozzle disk 23, a fastening plate 51 and a housing 24. The vibrating member 21 has a first through hole 211 and is coupled to the fastening plate 51. The nozzle disc 23 is disposed between the vibrating member 21 and the fastening plate 51 and has a plurality of openings 231 facing the first through hole 211. The housing 24 covers the vibrating member 21, the fastening plate 51 and the nozzle disk 23. In addition, the fastening plate 51 forms a hollow protrusion 512 from the plane 511, which is located behind the nozzle disc 23. When the fastening plate 51 is coupled to the nozzle disk 23, the accommodation space 52 is formed by the hollow protrusion 512 and the nozzle disk 23.

Reference is made to FIG. 7, which is a cross-sectional view of another droplet generating device of the present invention. The droplet generating device 7 is applied to an atomizer and comprises a vibrating member 21, a nozzle disk 41, a fastening plate 51 and a housing 24. The vibrating member 21 has a first through hole 211 and is coupled to the fastening plate 51. The nozzle disc 41 is disposed between the vibrating member 21 and the fastening plate 51 and includes a plurality of openings 231 facing the first through hole 211. The housing 24 covers the vibrating member 21, the fastening plate 51 and the nozzle disk 41. In addition, the fastening plate 51 forms a hollow protrusion 512 from the plane 511, which is located behind the nozzle disc 23. When the fastening plate 51 is engaged with the nozzle disk 41, the plane of the nozzle disk 41 forms a protrusion-shaped portion 411 having an opening 231. The protruding-shaped portion 411 faces the first through hole 211 and the second through hole 221. The protrusion-shaped portion 411 and the hollow protrusion 512 form a receiving space 71.

5 and 7, the size of the nozzle disk 23 or 41 is generally equal to the vibrating member 21 and the fastening plate 51 or smaller than the vibrating member 21 or the fastening plate 51. When the size of the nozzle disc 23 is smaller than the vibrating member 21 and the fastening plate 51, the vibrating member 21 is directly coupled with the fastening plate 51 so that the nozzle disc 23 is the vibrating member 21. And the fastening plate 51.

Reference is made to FIG. 8, which is a cross-sectional view of another droplet generating device of the present invention. A droplet generating device 8 is applied to an atomizer and includes a vibrating member 21, a connecting member 22, a nozzle disk 41, a fastening plate 51 and a housing 24. The vibrating member 21 has a first through hole 211. The connection member 22 includes a second through hole 221 corresponding to the first through hole 211 and is coupled to the vibration member 21. The nozzle disc 41 has a plurality of openings 231 facing the first through hole 211 and the second through hole 221, and is coupled to the connection member 22. The fastening plate 51 is coupled with the nozzle disk 41. The housing 24 covers the vibrating member 21, the connecting member 22, the nozzle disk 41 and the fastening plate 51. In addition, an extension wall 222 disposed in the first through hole 211 of the vibration member 21 is provided in the second through hole 221 of the connection member 22. The plane of the nozzle disc 41 forms a protrusion-shaped portion 411 having the opening 231. The protruding-shaped portion 411 faces the first through hole 211 and the second through hole 221. The fastening plate 51 forms a hollow projection 512 from the plane 511, which is located behind the nozzle disc 23. When the fastening plate 51 is engaged with the nozzle disk 41, the receiving space 71 is formed by the protrusion-shaped portion 411 of the nozzle disk 41 and the hollow protrusion 512 of the fastening plate 51. Is formed.

In FIG. 8, the size of the nozzle disc 41 is equal to or smaller than the connecting member 22 and the fastening plate 51. When the size of the nozzle disc 41 is smaller than the connecting member 22 and the fastening plate 51, the connecting member 22 is directly engaged with the fastening plate 51 such that the nozzle disc 41 is connected to the connecting member 22. And the fastening plate 51. In addition, the connecting member 22 and the fastening plate 51 are formed by insert molding. Insert molding is such that a rigid member is first placed in a mold, and the member is joined to the plastic material by injection, or the plastic material surrounds the rigid member.

Therefore, the vibration member of the droplet generating apparatus of the present invention is preferably a piezoelectric member. Preferably, the housing is an O-shaped ring. In addition, a jelly-like material is filled between the extending wall of the connecting member and the first through hole.

Although the present invention has been described with reference to the preferred embodiments, the present invention is not limited to such description. On the contrary, the description is intended to cover various modifications and similar apparatuses and methods, and thus, the scope of utility model claims should be interpreted in the broadest scope to encompass all such modifications and similar apparatuses and methods. Should be.

The present invention provides a droplet generating apparatus with improved droplet generating efficiency.

Claims (19)

As a droplet generating device that can be applied to a chemical sprayer: A vibrating member having a first through hole; A nozzle disk having a plurality of openings facing the first through hole; A connection member disposed between the vibration member and the nozzle disc and having a second through hole corresponding to the first through hole; And And a housing for covering the combination of the vibrating member, the nozzle disk, and the connecting member. The droplet generating apparatus of claim 1, wherein the vibration member comprises a piezoelectric member. The droplet generating apparatus according to claim 1, wherein an extension wall further extends from inside of the second through hole of the connection member, and the extension wall is disposed in the first through hole of the vibration member. 4. The droplet generating apparatus of claim 3, wherein a jelly-like material is further filled between the extending wall and the first through hole. The droplet generating apparatus according to claim 1, wherein the plane of the nozzle disk forms a protrusion-shaped portion having openings, wherein the protrusion-shaped portion faces the first through hole and the second through hole. The droplet generating apparatus of claim 1, wherein the housing comprises an O-shaped ring. The liquid crystal generating apparatus of claim 1, wherein the droplet generating apparatus further comprises a fastening plate coupled to the nozzle disk, wherein the fastening plate forms a hollow protrusion located at a rear side of the nozzle disk from a plane, and the fastening plate is the nozzle disk. And an accommodation space is defined by the hollow protrusion and the nozzle disk when combined with the hollow projection. 8. The droplet generating apparatus according to claim 7, wherein the fastening plate is further coupled with the connecting member. The droplet generating apparatus of claim 7, wherein the fastening plate and the connecting member are formed by insert molding. As a droplet generating device that can be applied to a chemical sprayer: A vibrating member having a first through hole; A fastening plate coupled to the vibration member; A nozzle disc disposed between the vibration member and the fastening plate and having a plurality of openings facing the first through hole; And And a housing for covering the combination of the vibration member, the nozzle disk, and the fastening plate. The droplet generating apparatus of claim 10, wherein the vibration member comprises a piezoelectric member. The droplet generating apparatus according to claim 10, wherein a plane of the nozzle disk forms a protrusion-shaped portion having openings, wherein the protrusion-shaped portion faces the first through hole. The droplet generating apparatus of claim 10, wherein the housing comprises an O-shaped ring. The method of claim 10, wherein the fastening plate is formed from the plane hollow projections located behind the nozzle disk from the plane, the receiving space is formed by the hollow projections and the nozzle disk when the fastening plate is combined with the nozzle disk Droplet generating device. The droplet generating apparatus of claim 10, wherein the droplet generating apparatus further comprises a connecting member disposed between the vibrating member and the nozzle disk, wherein the connecting member has a second through hole corresponding to the first through hole. Device. The droplet generating apparatus according to claim 15, wherein an extension wall extends from the inside of the second through hole of the connection member, and the extension wall is disposed in the first through hole of the vibration member. The droplet generating device of claim 15, wherein the fastening plate is coupled to the connection member. The droplet generating apparatus of claim 15, wherein the fastening plate and the connecting member are formed by insert molding. 17. The droplet generating apparatus of claim 16, wherein a jelly-like material is further filled between the extending wall and the first through hole.

Images