This non-provisional application claims priority under 35 U.S.C. § 119(a) on Patent Application No(s). 101220206 filed in Taiwan, R.O.C. on Oct. 19, 2012, the entire contents of which are hereby incorporated by reference.
1. Field of the Invention
The present invention relates to the field of liquid nebulization devices, and more particularly to a nebulization device with a spray orifice plate having at least one first stepped penetrating hole to improve the nebulization effect.
2. Description of the Related Art
A nebulization device with a spray orifice plate is commonly used in nebulizers or ink cartridges and the device produces high-frequency vibration waves based on the principle of electron vibration to break down the molecular structure of a solution such as a medicine, perfume or ink solution into nebulized molecules and sprays out the nebulized molecules.
In general, a conventional nebulization device with a spray orifice plate comprises a driving element and a spray orifice plate, wherein the driving element is installed on a side of a first penetrating orifice plate which is made of metal and has a plurality of nebulization holes formed on a surface of the first penetrating orifice plate. After the driving element is provided with power, high-frequency vibration waves are produced, so that the first penetrating orifice plate is deformed and bent by resonance to break down the molecular structure of a liquid to be nebulized into smaller nebulized molecules, and then the nebulized molecules are sprayed out from the nebulization holes. However, the first penetrating orifice plate is made of metal, and the distance between the nebulization holes is fixed. Since the nebulization holes cannot be manufactured freely, the liquid to be nebulized has a poor chemical resistance which affects the characteristic and performance of the nebulization of the nebulization device with a spray orifice plate. Furthermore, the nebulization plate made of metal may become embrittled and fatigue easily after experiencing the high-frequency vibrations of a long time, so that an energy transfer element may crack or break easily, and the reduced vibration effect will lower the nebulization effect.
Therefore, the structural design of a composite nebulization plate as disclosed in R.O.C. Utility Model No. M425720 entitled “nebulization structure” was introduced, wherein the nebulization structure comprises a driving element, a structural plate and a nebulization plate. The structural plate is installed on a side of the driving element, and the structural plate is substantially in the shape of a circular disk and has a plurality of through holes, and at least one rib formed between the through holes to form a water guiding passage. The nebulization plate is clamped between the driving element and the structural plate and made of a macromolecular polymer to overcome the problems of the metal nebulization plate becoming fatigue, embrittled and corroded easily. The structural plate is combined with the nebulization plate and the driving element by an adhesive to overcome the insufficient rigidity of the nebulization plate which is made of the macromolecular polymer, so as to overcome the problem of the vibration energy failing to achieve the expected nebulization efficiency.
In view of the nebulization plate with a single nebulization hole unable to improve nebulization efficiency, the inventor of the present invention improved the design of the nebulization holes by providing a nebulization plate with stepped nebulization holes to improve the nebulization effect significantly.
In view of the problems of the prior art, it is a primary objective of the present invention to provide a nebulization device with a spray orifice plate, wherein the spray orifice plate has a plurality of stepped orifices including at least one through hole and at least one recess for temporarily storing a liquid, such that after the spray orifice plate is vibrated, the liquid is nebulized and sprayed out through the through hole to improve the nebulization effect.
Another objective of the present invention is to provide a nebulization device with a spray orifice plate comprising an energy transfer element used as a device for transferring energy of a driving element and as a structural support of the spray orifice plate, and the energy transfer element serves as a transportation channel of the liquid, so as to enhance the availability after the assembling process and improve the nebulization effect effectively.
To achieve the aforementioned objectives, the present invention provides a nebulization device with a spray orifice plate, comprising: an energy transfer element, with two sides defined as an inlet side and an outlet side, and having at least one first penetrating hole formed on the energy transfer element for inputting a liquid from the inlet side; a spray orifice plate, installed on at least one side of the energy transfer element for sealing the first penetrating hole, and the energy transfer element supporting the spray orifice plate, and the spray orifice plate having at least one stepped orifice which is formed at a position corresponding to the first penetrating hole and serves as a transportation channel of the liquid; and a driving element, installed on at least one side of the energy transfer element, for providing the vibration energy required by the energy transfer element after the driving element is provided with power, such that the liquid passing through the first penetrating hole is temporarily stored in the stepped orifice, and then vibrated and nebulized, and finally sprayed out from the outlet side through the stepped orifice. Wherein, is a ring structure made of metal, and the driving element is substantially a ring structure having a second penetrating hole formed thereon, and the second penetrating hole has a diameter greater than or equal to the diameter of the first penetrating hole, and the spray orifice plate is clamped between the energy transfer element and the driving element. Wherein, the spray orifice plate is made of a macromolecular polymer selected from the collection of polyimide, polyethylene (PE), polypropylene (PP) and polyether ether ketone (PEEK).
In different embodiments, the stepped orifice may be in one-step configuration or a multi-step form, and the number of steps is directly related to the thickness of the spray orifice plate.
In a preferred embodiment of the present invention, the stepped orifice has a first groove and at least one through hole, and the first groove is disposed on a side of the spray orifice plate opposite to the inlet side, and the through hole is disposed in the first groove to make the cross-section of the stepped orifice into a one-step configuration. In addition, the first groove has a shape selected from the collection of circular, rectangular, strip, star and cross shapes, and the first groove and the through hole have a depth ratio falling within a range from 1:1 to 4:1.
In another preferred embodiment of the present invention, the stepped orifice has a first groove, at least one second groove and at least one through hole, and the first groove is disposed on a side of the spray orifice plate opposite to the inlet side, and the second groove is disposed in the first groove, and the through hole is disposed in the second groove to make the cross-section of the stepped orifice into a two-step configuration. In addition, the first groove and the second groove have a shape selected from the collection of circular, rectangular, strip, star and cross shapes, and the first groove, the second groove and the through hole have a depth proportion falling within a range from 1:1:1 to 6:5:4.
In a further preferred embodiment of the present invention, the stepped orifice has a first groove, at least one second groove, at least one third groove and at least one through hole, and the first groove is disposed on a side of the spray orifice plate opposite to the inlet side, and the second groove is disposed in the first groove, and the third groove is disposed in the second groove, and the through hole is disposed in the third groove to make the cross-section of the stepped orifice into a three-step form. The first groove, the second groove and the third groove have a shape selected from the collection of circular, rectangular, strip, star and cross shapes. The first groove, the second groove, the third groove and the through hole have a depth proportion falling within a range from 1:1:1:1 to 5:4:3:3. It is noteworthy that the through hole is a conical hole.
The technical content of the present invention will become apparent with the detailed description of preferred embodiments and the illustration of related drawings as follows.
With reference to
Wherein, the energy transfer element 11 is a ring structure made of metal and has an inlet side 111 and an outlet side 112 defined on both sides, and the energy transfer element 11 further has a first penetrating hole 113 for inputting a liquid 2 from the inlet side 111.
The spray orifice plate 12 is made of a macromolecular polymer selected from the collection of polyimide, polyethylene (PE), polypropylene (PP) and polyether ether ketone (PEEK), and the spray orifice plate 12 is installed on a side of the energy transfer element 11 for sealing the first penetrating hole 113. The energy transfer element 11 supports the spray orifice plate 12, and the spray orifice plate 12 has at least one stepped orifice 121 formed at a position corresponding to the first penetrating hole 113 to serve as a transportation channel of the liquid 2. The stepped orifice 121 has a first groove 1211 and at least one through hole 1212, wherein the first groove 1211 is disposed on a side of the spray orifice plate 12 opposite to the inlet side 111, and the through hole 1212 is disposed in the first groove 1211 to make the cross-section of the stepped orifice 121 into a one-step configuration. It is noteworthy that the first groove 1211 has a shape selected from the collection of circular, rectangular, strip, star and cross shapes, and the first groove 1211 and the through hole 1212 have a depth ratio falling within a range from 1:1 to 4:1. Due to the manufacturing process, the through hole 1212 is substantially a conical hole. With reference to
The driving element 13 is also a ring structure having a second penetrating hole 131 formed at the center of the driving element 13, and the second penetrating hole 131 has a diameter greater than or equal to the diameter of the first penetrating hole 113. The driving element 13 is installed on a side of the energy transfer element 11, and the spray orifice plate 12 is clamped between the energy transfer element 11 and the driving element 13, such that the vibration energy required by the energy transfer element 11 can be provided after the driving element 13 is provided with power. The liquid 2 passing through the first penetrating hole 113 is temporarily stored in the stepped orifice 121, and then vibrated and nebulized, and finally sprayed out from the outlet side 112 through the through hole 1211.
With reference to
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With reference to
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Number | Date | Country |
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M425720 | Nov 2011 | TW |
Number | Date | Country | |
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20140110499 A1 | Apr 2014 | US |