Nothing Special   »   [go: up one dir, main page]

TWM465471U - Micro-gas transmission apparatus - Google Patents

Micro-gas transmission apparatus Download PDF

Info

Publication number
TWM465471U
TWM465471U TW102211827U TW102211827U TWM465471U TW M465471 U TWM465471 U TW M465471U TW 102211827 U TW102211827 U TW 102211827U TW 102211827 U TW102211827 U TW 102211827U TW M465471 U TWM465471 U TW M465471U
Authority
TW
Taiwan
Prior art keywords
plate
hole
gas
air inlet
piezoelectric actuator
Prior art date
Application number
TW102211827U
Other languages
Chinese (zh)
Inventor
Ta-Wei Hsueh
Ying-Lun Chang
Hsiang-Dyi Wu
Rong-Ho Yu
Shih-Chang Chen
Tsung-Pat Chou
Yau-Ji Lee
jia-yu Liao
Original Assignee
Microjet Technology Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Microjet Technology Co Ltd filed Critical Microjet Technology Co Ltd
Priority to TW102211827U priority Critical patent/TWM465471U/en
Publication of TWM465471U publication Critical patent/TWM465471U/en

Links

Landscapes

  • Reciprocating Pumps (AREA)

Abstract

A micro-gas transmission apparatus is disclosed and comprises a gas inlet board, a fluid channel board, a resonance plate and an actuator, the gas inlet board has at least one gas inlet hole, the fluid channel has at least one gas converge groove and a central hole, a resonance plate has a hollow hole, the actuator has a suspension plate, a frame and at least one support portion coupling with the suspension plate and the frame, and a piezoelectric ceramic is stuck on one surface of the suspension plate, wherein a gap between the resonance plate and the actuator forms a first chamber, when the actuator is driven, the gas goes in from the gas inlet hole of the gas inlet board, flows through the gas converge groove and into the central hole, then through the hollow hole of the resonance plate to flow into the first chamber, and transmits downwardly through the intervals between the support portion of the actuator, thereby to form a pressure gradient to continued push gas.

Description

微型氣體傳輸裝置Micro gas transmission device

本案係關於一種氣體傳輸裝置,尤指一種微型超薄且靜音之微型氣體傳輸裝置。The present invention relates to a gas transmission device, and more particularly to a micro-ultra-thin and silent micro-gas transmission device.

目前於各領域中無論是醫藥、電腦科技、列印、能源等工業,產品均朝精緻化及微小化方向發展,其中微幫浦、噴霧器、噴墨頭、工業列印裝置等產品所包含之流體輸送結構為其關鍵技術,是以,如何藉創新結構突破其技術瓶頸,為發展之重要內容。At present, in various fields, such as medicine, computer technology, printing, energy and other industries, the products are developing in the direction of refinement and miniaturization. Among them, products such as micro-pumps, sprayers, inkjet heads, industrial printing devices, etc. The fluid transport structure is its key technology, which is how to break through its technical bottleneck with innovative structure and be an important part of development.

舉例來說,於醫藥產業中,許多需要採用氣壓動力驅動之儀器或設備,通常採以傳統馬達及氣壓閥來達成其氣體輸送之目的。然而,受限於此等傳統馬達以及氣體閥之體積限制,使得此類的儀器設備難以縮小其整體裝置的體積,即難以實現薄型化之目標,更無法使之達成可攜式之目的。此外,該等傳統馬達及氣體閥於作動時亦會產生噪音之問題,導致使用上的不便利及不舒適。For example, in the pharmaceutical industry, many instruments or equipment that require pneumatic power drive are usually used with conventional motors and pneumatic valves to achieve their gas delivery. However, limited by the volume limitations of conventional motors and gas valves, it is difficult for such instruments to reduce the size of their overall devices, that is, it is difficult to achieve the goal of thinning, and it is impossible to achieve portable purposes. In addition, these conventional motors and gas valves also cause noise problems when they are actuated, resulting in inconvenience and discomfort in use.

因此,如何發展一種可改善上述習知技術缺失,可使傳統採用氣體傳輸裝置的儀器或設備達到體積小、微型化且靜音,進而達成輕便舒適之可攜式目的之微型氣體傳輸裝置,實為目前迫切需要解決之問題。Therefore, how to develop a micro gas transmission device that can improve the above-mentioned conventional technology and can make the instrument or device using the gas transmission device small, miniaturized and muted, thereby achieving a portable and portable purpose, is There is an urgent need to solve the problem.

本案之目的在於提供一種適用於可攜式、或穿戴式儀器或設 備中之微型氣體傳輸裝置,藉由壓電板高頻作動產生的氣體波動,於設計後之流道中產生壓力梯度,而使氣體高速流動,且透過流道進出方向之阻抗差異,將氣體由吸入端傳輸至排出端,俾解決習知技術之採用氣體傳輸裝置的儀器或設備所具備之體積大、難以薄型化、無法達成可攜式之目的,以及噪音大等缺失。The purpose of this case is to provide a portable or wearable instrument or device. In the micro gas transmission device, the gas generated by the high-frequency operation of the piezoelectric plate fluctuates, and a pressure gradient is generated in the designed flow channel, so that the gas flows at a high speed, and the impedance difference between the flow path and the flow direction is inhaled. The end is transmitted to the discharge end, and the apparatus or equipment using the gas transmission device of the prior art has a large volume, is difficult to be thinned, cannot achieve a portable type, and has a large noise.

為達上述目的,本案之一較廣義實施態樣為提供一種微型氣體傳輸裝置,適用於一微型氣壓動力裝置,至少包括:進氣板,具有至少一進氣孔,供導入氣體;流道板,具有至少一匯流排孔及中心孔洞,匯流排孔對應進氣板之進氣孔,且引導進氣孔之氣體匯流至中心孔洞;共振片,具有中空孔洞,對應流道板之中心孔洞;以及壓電致動器,具有懸浮板及外框,懸浮板及外框之間以至少一支架連接,且於懸浮板之表面貼附壓電陶瓷板;其中,上述之進氣板、流道板、共振片及壓電致動器依序對應堆疊設置定位,且共振片與壓電致動器之間具有一間隙形成之一第一腔室,以使壓電致動器受驅動時,氣體由進氣板之至少一進氣孔導入,經流道板之至少一匯流排孔匯集至中心孔洞,再流經共振片之中空孔洞,以進入第一腔室內,再由壓電致動器之至少一支架之間之空隙向下傳輸,以形成壓力梯度流道持續推出氣體。In order to achieve the above object, a broader aspect of the present invention provides a micro gas transmission device suitable for a micro pneumatic power device, comprising at least: an air inlet plate having at least one air inlet for introducing a gas; and a flow channel plate Having at least one bus bar hole and a center hole, the bus bar hole corresponding to the air inlet hole of the air inlet plate, and the gas guiding the air inlet hole converging to the center hole; the resonance piece having a hollow hole corresponding to the center hole of the flow channel plate; And a piezoelectric actuator having a suspension plate and an outer frame, wherein the suspension plate and the outer frame are connected by at least one bracket, and the piezoelectric ceramic plate is attached to the surface of the suspension plate; wherein the air inlet plate and the flow channel are The plate, the resonator plate and the piezoelectric actuator are sequentially positioned corresponding to the stack, and a gap is formed between the resonator piece and the piezoelectric actuator to form a first chamber, so that when the piezoelectric actuator is driven, The gas is introduced from at least one air inlet hole of the air inlet plate, and is collected into the center hole through at least one bus bar hole of the flow channel plate, and then flows through the hollow hole of the resonance piece to enter the first cavity, and then is actuated by the piezoelectric At least one bracket The space between the transmission down to a pressure gradient of the gas flow channel continuously introduced.

為達上述目的,本案之另一較廣義實施態樣為提供一種微型氣體傳輸裝置,適用於微型氣壓動力裝置,至少包括:進氣板,具有至少一進氣孔,供導入氣體;流道板,具有至少一匯流排孔及中心孔洞,匯流排孔對應進氣板之進氣孔,且引導進氣孔之氣體匯流至中心孔洞;共振片,具有中空孔洞,對應流道板之中心孔洞;以及壓電致動器,具有懸浮板及 外框,懸浮板及外框之間以至少一支架連接,且於懸浮板之表面貼附壓電陶瓷板;其中,上述之進氣板、流道板、共振片及壓電致動器依序對應堆疊設置定位,以使壓電致動器受驅動時,氣體由進氣板之至少一進氣孔進入,並由流道板之至少一匯流排孔匯集至中心孔洞,再流經共振片之中空孔洞以進入共振片及壓電致動器之間,再由壓電致動器之至少一支架之間之空隙向下傳輸,以形成壓力梯度流道持續推出氣體。In order to achieve the above object, another broad aspect of the present invention provides a micro gas transmission device suitable for a micro pneumatic power device, comprising at least: an air inlet plate having at least one air inlet for introducing a gas; and a flow channel plate Having at least one bus bar hole and a center hole, the bus bar hole corresponding to the air inlet hole of the air inlet plate, and the gas guiding the air inlet hole converging to the center hole; the resonance piece having a hollow hole corresponding to the center hole of the flow channel plate; And a piezoelectric actuator having a suspension plate and The outer frame, the suspension plate and the outer frame are connected by at least one bracket, and the piezoelectric ceramic plate is attached to the surface of the suspension plate; wherein the air inlet plate, the flow channel plate, the resonance plate and the piezoelectric actuator are The sequence is arranged corresponding to the stack, so that when the piezoelectric actuator is driven, the gas enters from at least one air inlet hole of the air inlet plate, and is collected by at least one bus hole of the flow channel plate to the center hole, and then flows through the resonance. The hollow holes of the sheet enter between the resonator piece and the piezoelectric actuator, and then are transported downward by the gap between the at least one bracket of the piezoelectric actuator to form a pressure gradient flow path to continuously push out the gas.

1、2‧‧‧微型氣壓裝置1, 2‧‧‧ miniature air pressure device

1A、2A‧‧‧微型氣體傳輸裝置1A, 2A‧‧‧Micro gas transmission device

1B、2B‧‧‧微型閥門裝置1B, 2B‧‧‧ miniature valve device

10、20‧‧‧進氣板10, 20‧‧‧ air intake plate

100、200‧‧‧進氣孔100, 200‧‧‧ intake holes

11、22‧‧‧共振片11, 22‧‧‧ Resonant

12、23‧‧‧壓電致動器12, 23‧‧‧ Piezoelectric actuators

120、230‧‧‧懸浮板120, 230‧‧‧suspension plate

121、233‧‧‧壓電陶瓷板121, 233‧‧‧ Piezoelectric ceramic plates

13、24‧‧‧絕緣片13, 24‧‧‧Insulation

14、25‧‧‧導電片14, 25‧‧‧ conductive sheet

15、26‧‧‧集氣板15, 26‧‧‧ gas collecting plate

16、27‧‧‧閥門片16, 27‧‧‧ valve pieces

17、28‧‧‧出口板17, 28‧‧‧ export board

170、285‧‧‧連通流道170, 285‧‧‧ connected flow channels

21‧‧‧流道板21‧‧‧Channel board

211‧‧‧匯流排孔211‧‧‧ bus bar hole

210‧‧‧中心孔洞210‧‧‧ center hole

220‧‧‧中空孔洞220‧‧‧ hollow holes

221、234、251‧‧‧導電接腳221, 234, 251‧‧‧ conductive pins

222‧‧‧第一腔室222‧‧‧ first chamber

230a‧‧‧懸浮板之上表面230a‧‧‧Over the surface of the suspension plate

230b‧‧‧懸浮板之下表面230b‧‧‧Under the surface of the suspension plate

230c‧‧‧凸部230c‧‧‧ convex

231‧‧‧外框231‧‧‧Front frame

231a‧‧‧外框之上表面231a‧‧‧Top surface of the outer frame

231b‧‧‧外框之下表面231b‧‧‧Under the outer frame

232‧‧‧支架232‧‧‧ bracket

232a‧‧‧支架之上表面232a‧‧‧Top surface of the bracket

232b‧‧‧支架之下表面232b‧‧‧Under the surface of the bracket

235‧‧‧空隙235‧‧‧ gap

260‧‧‧集氣板之第一表面The first surface of the 260‧‧ ‧ gas plate

261‧‧‧集氣板之第二表面261‧‧‧ second surface of the gas gathering plate

262‧‧‧集氣腔室262‧‧‧Gas chamber

263‧‧‧第一貫穿孔263‧‧‧first through hole

264‧‧‧第二貫穿孔264‧‧‧Second through hole

265‧‧‧第一卸壓腔室265‧‧‧First pressure relief chamber

266‧‧‧第一出口腔室266‧‧‧First out of the chamber

267、286‧‧‧凹槽結構267, 286‧‧‧ groove structure

268、287‧‧‧密封環268, 287‧‧ ‧ seal ring

269、281a‧‧‧凸部結構269, 281a‧‧ ‧ convex structure

270‧‧‧閥孔270‧‧‧ valve hole

271‧‧‧定位孔洞271‧‧‧ Positioning holes

280‧‧‧出口板之第一表面280‧‧‧ first surface of the exit plate

281‧‧‧第三貫穿孔281‧‧‧ third through hole

282‧‧‧第四貫穿孔282‧‧‧fourth through hole

283‧‧‧第二卸壓腔室283‧‧‧Second pressure relief chamber

284‧‧‧第二出口腔室284‧‧‧Second out of the chamber

288‧‧‧卸壓孔288‧‧‧Recharge hole

289‧‧‧出口板之第二表面289‧‧‧Second surface of the exit plate

29‧‧‧出口29‧‧‧Export

g0‧‧‧間隙G0‧‧‧ gap

(a)~(1)‧‧‧導電致動器之不同實施態樣(a)~(1)‧‧‧Different implementations of conductive actuators

a0、i0、j0‧‧‧懸浮板A0, i0, j0‧‧‧ suspension board

a1、i1、j1‧‧‧外框A1, i1, j1‧‧‧ frame

a2、i2‧‧‧支架A2, i2‧‧‧ bracket

a3‧‧‧空隙A3‧‧‧ gap

第1圖係為本案第一較佳實施例之微型氣壓動力裝置之正面分解結構示意圖。Fig. 1 is a front exploded view showing the micro pneumatic power device of the first preferred embodiment of the present invention.

第2A圖係為本案為第二較佳實施例之微型氣壓動力裝置之正面分解結構示意圖。2A is a front exploded view showing the micro pneumatic power device of the second preferred embodiment.

第2B圖係為本案為第二較佳實施例之微型氣壓動力裝置之背面分解結構示意圖。2B is a schematic view showing the back side exploded structure of the micro pneumatic power device of the second preferred embodiment.

第3A圖係為第2A圖所示之微型氣壓動力裝置之壓電致動器之正面結構示意圖。Fig. 3A is a front structural view showing the piezoelectric actuator of the micro pneumatic power device shown in Fig. 2A.

第3B圖係為第2A圖所示之微型氣壓動力裝置之壓電致動器之背面結構示意圖。Fig. 3B is a schematic view showing the structure of the back surface of the piezoelectric actuator of the micro pneumatic power device shown in Fig. 2A.

第3C圖係為第2A圖所示之微型氣壓動力裝置之壓電致動器之剖面結構示意圖。Fig. 3C is a schematic cross-sectional view showing the piezoelectric actuator of the micro pneumatic power device shown in Fig. 2A.

第4圖係為第3A圖所示之壓電致動器之多種實施態樣示意圖。Fig. 4 is a schematic view showing various embodiments of the piezoelectric actuator shown in Fig. 3A.

第5A圖至第5E圖係為第2A圖所示之微型氣壓動力裝置之 微型氣體傳輸裝置之作動示意圖。5A to 5E are the micro pneumatic power devices shown in Fig. 2A Schematic diagram of the operation of the micro gas transmission device.

第6A圖係為第2A圖所示之微型氣壓動力裝置之微型閥門裝置之集壓作動示意圖。Fig. 6A is a schematic diagram of the collective pressure operation of the microvalve device of the micro pneumatic power device shown in Fig. 2A.

第6B圖係為第2A圖所示之微型氣壓動力裝置之微型閥門裝置之卸壓作動示意圖。Fig. 6B is a schematic view showing the pressure relief operation of the microvalve device of the micro pneumatic power device shown in Fig. 2A.

第7A至第7E圖係為第2A圖所示之微型氣壓動力裝置之集壓作動示意圖。7A to 7E are schematic diagrams showing the collective pressure operation of the micro pneumatic power device shown in Fig. 2A.

第8圖係為第2A圖所示之微型氣壓動力裝置之降壓或是卸壓作動示意圖。Figure 8 is a schematic diagram of the step-down or pressure relief operation of the micro-pneumatic power unit shown in Figure 2A.

體現本案特徵與優點的一些典型實施例將在後段的說明中詳細敘述。應理解的是本案能夠在不同的態樣上具有各種的變化,其皆不脫離本案的範圍,且其中的說明及圖示在本質上係當作說明之用,而非用以限制本案。Some exemplary embodiments embodying the features and advantages of the present invention are described in detail in the following description. It is to be understood that the present invention is capable of various modifications in the various aspects of the present invention, and the description and illustration are in the nature of

本案之微型氣壓動力裝置1係可應用於醫藥生技、能源、電腦科技或是列印等工業,俾用以傳送氣體,但不以此為限。請參閱第1圖,其係為本案第一較佳實施例之微型氣壓動力裝置之正面分解結構示意圖。如圖所示,本案之微型氣壓動力裝置1係由微型氣體傳輸裝置1A以及微型閥門裝置1B所組合而成,其中微型氣體傳輸裝置1A至少具有進氣板10、共振片11、壓電致動器12、絕緣片13、導電片14等結構,其係將壓電致動器12對應於共振片11而設置,並使進氣板10、共振片11、壓電致動器12、絕緣片13、導電片14等依序堆疊設置定位,且該壓電致動器12係由一懸浮板120 以及一壓電陶瓷板121組裝而成;以及微型閥門裝置1B則由集氣板15、閥門片16以及出口板17等依序堆疊組裝而成,但不以此為限。藉由此微型氣體傳輸裝置1A以及微型閥門裝置1B之組裝設置,以使氣體自微型氣體傳輸裝置1A之進氣板10上之至少一進氣孔100進氣,並透過壓電致動器12之作動,而流經多個壓力腔室(未圖示),並向下傳輸,進而可使氣體於微型閥門裝置1B內單向流動,並將壓力蓄積於與微型閥門裝置1B之出口端相連之一裝置(未圖示)中,且當需進行洩壓時,則調控微型氣體傳輸裝置1A之輸出量,使氣體經由微型閥門裝置1B之出口板17上的連通流道170而排出,以進行洩壓。The micro-pneumatic power unit 1 of this case can be applied to industries such as medical technology, energy, computer technology or printing, and is used for conveying gas, but not limited thereto. Please refer to FIG. 1 , which is a front exploded view of the micro pneumatic power device of the first preferred embodiment of the present invention. As shown in the figure, the micro pneumatic power unit 1 of the present invention is composed of a micro gas transmission device 1A and a micro valve device 1B, wherein the micro gas transmission device 1A has at least an air inlet plate 10, a resonance plate 11, and piezoelectric actuation. The structure of the device 12, the insulating sheet 13, the conductive sheet 14, and the like, which is provided by the piezoelectric actuator 12 corresponding to the resonator piece 11, and the air bearing plate 10, the resonance plate 11, the piezoelectric actuator 12, and the insulating sheet 13. The conductive sheets 14 and the like are sequentially stacked and positioned, and the piezoelectric actuator 12 is composed of a suspension plate 120. And the piezoelectric ceramic plate 121 is assembled; and the micro valve device 1B is assembled by the gas collecting plate 15, the valve piece 16 and the outlet plate 17 in sequence, but is not limited thereto. By the assembly of the micro gas transmission device 1A and the micro valve device 1B, the gas is introduced from the at least one air inlet hole 100 of the air intake plate 10 of the micro gas transmission device 1A, and transmitted through the piezoelectric actuator 12. The operation flows through a plurality of pressure chambers (not shown) and is transmitted downward, thereby allowing the gas to flow in one direction in the microvalve device 1B, and accumulating the pressure in the outlet end of the microvalve device 1B. In one of the devices (not shown), and when pressure relief is required, the output of the micro gas transmission device 1A is regulated so that the gas is discharged through the communication flow path 170 on the outlet plate 17 of the micro valve device 1B to Pressure relief.

請同時參閱第2A圖及第2B圖,其係分別為本案第二較佳實施例之微型氣壓動力裝置之正面分解結構示意圖以及背面分解結構示意圖。如圖所示,微型氣壓動力裝置2係同樣由微型氣體傳輸裝置2A以及微型閥門裝置2B所組合而成,其中微型氣體傳輸裝置2A係依序由進氣板20、流道板21、共振片22、壓電致動器23、絕緣片24、導電片25等結構堆疊組裝而成,於本實施例中,共振片22與壓電致動器23之間係具有一間隙g0(如第5A圖所示),然而於另一些實施例中,共振片22與壓電致動器23之間亦可不具有間隙,故其實施態樣並不以此為限。於一些實施例中,進氣板20與流道板21亦可為一體成型之結構,即如本案之第一較佳實施例所示,但不以此為限,以下係以本實施例之進氣板20與流道板21分離設置之實施態樣詳加說明。以及,微型閥門裝置2B則同樣由集氣板26、閥門片27以及出口板28等依序堆疊組裝而成,但不以此為限。Please refer to FIG. 2A and FIG. 2B simultaneously, which are respectively a front exploded structure diagram and a rear exploded structure diagram of the micro pneumatic power device of the second preferred embodiment of the present invention. As shown in the figure, the micro pneumatic power unit 2 is also composed of a micro gas transmission device 2A and a micro valve device 2B, wherein the micro gas transmission device 2A is sequentially composed of an air inlet plate 20, a flow path plate 21, and a resonance plate. 22, the piezoelectric actuator 23, the insulating sheet 24, the conductive sheet 25 and the like are stacked and assembled. In the embodiment, the resonator piece 22 and the piezoelectric actuator 23 have a gap g0 (such as the 5A). In other embodiments, the resonator element 22 and the piezoelectric actuator 23 may not have a gap therebetween, and thus the implementation manner is not limited thereto. In some embodiments, the air inlet plate 20 and the flow channel plate 21 may be integrally formed, as shown in the first preferred embodiment of the present invention, but not limited thereto. The embodiment in which the air inlet plate 20 and the flow channel plate 21 are separated from each other is described in detail. The microvalve device 2B is also stacked and assembled by the gas collecting plate 26, the valve plate 27, and the outlet plate 28, but is not limited thereto.

於本實施例中,微型氣體傳輸裝置2A之進氣板20係具有至 少一進氣孔200,用以供氣體自裝置外順應大氣壓力之作用而自該至少一進氣孔200流入微型氣體傳輸裝置2A內。流道板21上則具有至少一匯流排孔211,用以與進氣板20之該至少一進氣孔200對應設置,並可將自該至少一進氣孔200進入之氣體引導並匯流集中至一中心孔洞210,以向下傳遞。共振片22係由一可撓性材質所構成,但不以此為限,且於共振片22上具有一中空孔洞220,係對應於流道板21之中心孔洞210而設置,以使氣體可向下流通。In the present embodiment, the air intake plate 20 of the micro gas transmission device 2A has An air intake hole 200 is provided for the gas to flow from the at least one air inlet hole 200 into the micro gas transmission device 2A from the outside of the device in response to atmospheric pressure. The flow channel plate 21 has at least one bus bar hole 211 for corresponding to the at least one air inlet hole 200 of the air inlet plate 20, and can guide and integrate the gas entering from the at least one air inlet hole 200. To a central hole 210, to pass downward. The resonator piece 22 is formed of a flexible material, but not limited thereto, and has a hollow hole 220 on the resonance piece 22, which is disposed corresponding to the central hole 210 of the flow path plate 21, so that the gas can be Circulate downwards.

請同時參閱第3A圖、第3B圖及第3C圖,其係分別為第2A圖所示之微型氣壓動力裝置之壓電致動器之正面結構示意圖、背面結構示意圖以及剖面結構示意圖,如圖所示,壓電致動器23係由一懸浮板230、一外框231、至少一支架232以及一壓電陶瓷板233所共同組裝而成,其中,該壓電陶瓷板233貼附於懸浮板230之下表面230b,以及該至少一支架232係連接於懸浮板230以及外框231之間,且於支架232、懸浮板230及外框231之間更具有至少一空隙235,用以供氣體流通,且該懸浮板230、外框231以及支架232之型態及數量係具有多種變化。另外,外框231更具有一向外凸設之導電接腳234,用以供電連接之用,但不以此為限。Please also refer to FIG. 3A, FIG. 3B and FIG. 3C, which are schematic diagrams of the front structure, the back structure and the cross-sectional structure of the piezoelectric actuator of the micro-pneumatic power device shown in FIG. 2A, respectively. As shown, the piezoelectric actuator 23 is assembled by a suspension plate 230, an outer frame 231, at least one bracket 232, and a piezoelectric ceramic plate 233, wherein the piezoelectric ceramic plate 233 is attached to the suspension. The lower surface 230b of the plate 230 and the at least one bracket 232 are connected between the suspension plate 230 and the outer frame 231, and further have at least one gap 235 between the bracket 232, the suspension plate 230 and the outer frame 231 for The gas circulates, and the type and number of the suspension plate 230, the outer frame 231, and the bracket 232 have various changes. In addition, the outer frame 231 has a conductive pin 234 protruding outward for power connection, but is not limited thereto.

於本實施例中,懸浮板230係為一階梯面之結構,意即於懸浮板230之上表面230a更具有一凸部230c,請同時參閱第3A圖及第3C圖即可見,懸浮板230之凸部230c係與外框231之上表面231a共平面,且懸浮板230之上表面230a及支架232之上表面232a亦為共平面,且該懸浮板230之凸部230c及外框231之上表面231a與懸浮板230之上表面230a及支架232之上表面232之間係具有一特定深度。至於懸浮板230之下表面230b,則如第3B圖及 第3C圖所示,其與外框231之下表面231b及支架232之下表面232b為平整之共平面結構,而壓電陶瓷板233則貼附於此平整之懸浮板230之下表面230b處。於一些實施例中,懸浮板230、支架232以及外框231係可由一金屬板所構成,但不以此為限,故壓電致動器23由壓電陶瓷板233與金屬板黏合而成。In this embodiment, the suspension plate 230 is a stepped surface structure, that is, the upper surface 230a of the suspension plate 230 further has a convex portion 230c. Please refer to FIG. 3A and FIG. 3C at the same time, the suspension plate 230 is visible. The convex portion 230c is coplanar with the upper surface 231a of the outer frame 231, and the upper surface 230a of the suspension plate 230 and the upper surface 232a of the bracket 232 are also coplanar, and the convex portion 230c and the outer frame 231 of the suspension plate 230 are The upper surface 231a has a specific depth between the upper surface 230a of the suspension plate 230 and the upper surface 232 of the bracket 232. As for the lower surface 230b of the suspension plate 230, as shown in FIG. 3B and As shown in FIG. 3C, it is flush with the lower surface 231b of the outer frame 231 and the lower surface 232b of the bracket 232, and the piezoelectric ceramic plate 233 is attached to the lower surface 230b of the flat suspension plate 230. . In some embodiments, the suspension plate 230, the bracket 232, and the outer frame 231 can be formed by a metal plate, but not limited thereto, so that the piezoelectric actuator 23 is bonded by the piezoelectric ceramic plate 233 and the metal plate. .

請續參閱第4圖,其係為第3A圖所示之壓電致動器之多種實施態樣示意圖。如圖所示,則可見壓電致動器23之懸浮板230、外框231以及支架232係可有多樣之型態,且至少可具有第4圖所示之(a)~(1)等多種態樣,舉例來說,(a)態樣之外框a1及懸浮板a0係為方形之結構,且兩者之間係由多個支架a2以連結之,例如:8個,但不以此為限,且於支架a2及懸浮板a0、外框a1之間係具有空隙a3,以供氣體流通。於另一(i)態樣中,其外框i1及懸浮板i0亦同樣為方形之結構,惟其中僅由2個支架i2以連結之;另外,於(j)~(1)態樣,則其懸浮板j0等係可為圓形之結構,而外框j0等亦可為略具弧度之框體結構,但均不以此為限。故由此多種實施態樣可見,懸浮板230之型態係可為方形或圓形,而同樣地,貼附於懸浮板230之下表面230b的壓電陶瓷板233亦可為方形或圓形,並不以此為限;以及,連接於懸浮板230及外框231之間的支架232之型態與數量亦可依實際施作情形而任施變化,並不以本案所示之態樣為限。且該等懸浮板230、外框231及支架232係可為一體成型之結構,但不以此為限,至於其製造方式則可由傳統加工、或黃光蝕刻、或雷射加工、或電鑄加工、或放電加工等方式製出,均不以此為限。Please refer to FIG. 4, which is a schematic diagram of various embodiments of the piezoelectric actuator shown in FIG. 3A. As shown in the figure, it can be seen that the suspension plate 230, the outer frame 231, and the bracket 232 of the piezoelectric actuator 23 can have various types, and at least (a) to (1) shown in FIG. In a plurality of aspects, for example, the frame a1 and the suspension plate a0 of the (a) aspect are square structures, and the two are connected by a plurality of brackets a2, for example: 8 but not For this reason, a gap a3 is provided between the bracket a2 and the suspension plate a0 and the outer frame a1 for gas circulation. In another (i) aspect, the outer frame i1 and the suspension plate i0 are also square-shaped, but only two brackets i2 are connected; in addition, in the (j)~(1) aspect, Then, the suspension plate j0 and the like may have a circular structure, and the outer frame j0 or the like may also be a slightly curved frame structure, but are not limited thereto. Therefore, it can be seen from various embodiments that the shape of the suspension plate 230 can be square or circular, and similarly, the piezoelectric ceramic plate 233 attached to the lower surface 230b of the suspension plate 230 can also be square or round. The type and number of the brackets 232 connected between the suspension plate 230 and the outer frame 231 may be changed according to actual implementation conditions, and are not in the manner shown in the present case. Limited. The suspension plate 230, the outer frame 231 and the bracket 232 may be integrally formed, but not limited thereto, and the manufacturing method may be conventional processing, or yellow etching, laser processing, or electroforming. Processing, or electrical discharge machining, etc., are not limited to this.

此外,請續參閱第2A圖及第2B圖,於微型氣體傳輸裝置2A中更具有絕緣片24及導電片25,絕緣片24及導電片25係對應設置於壓電致 動器23之下,且其形態大致上對應於壓電致動器23之外框之形態。於一些實施例中,絕緣片24即由可絕緣之材質所構成,例如:塑膠,但不以此為限,以進行絕緣之用;於另一些實施例中,導電片25即由可導電之材質所構成,例如:金屬,但不以此為限,以進行電導通之用。以及,於本實施例中,共振片22上係可具有一導電接腳221,但不以此為限,而導電致動器23之外框231上亦具有與共振片22之導電接腳221相對應設置的導電接腳224,亦不以此為限,另外,在導電片25上亦可設置一導電接腳251,以進行電導通之用。In addition, please refer to FIGS. 2A and 2B, and further include an insulating sheet 24 and a conductive sheet 25 in the micro gas transmission device 2A. The insulating sheet 24 and the conductive sheet 25 are correspondingly disposed on the piezoelectric body. Below the actuator 23, the shape substantially corresponds to the shape of the outer frame of the piezoelectric actuator 23. In some embodiments, the insulating sheet 24 is made of an insulating material, such as plastic, but not limited thereto for insulation; in other embodiments, the conductive sheet 25 is electrically conductive. The material is composed of, for example, metal, but not limited to it for electrical conduction. In the present embodiment, the resonant pad 22 can have a conductive pin 221, but not limited thereto, and the conductive frame 23 of the conductive actuator 23 also has a conductive pin 221 with the resonant plate 22. The conductive pins 224 are not limited thereto. In addition, a conductive pin 251 may be disposed on the conductive sheet 25 for electrical conduction.

請同時參閱第2A圖及第5A圖至第5E圖,其中第5A圖至第5E圖係為第2A圖所示之微型氣壓動力裝置之微型氣體傳輸裝置之作動示意圖。首先,如第5A圖所示,可見微型氣體傳輸裝置2A係依序由進氣板20、流道板21、共振片22、壓電致動器23、絕緣片24、導電片25等堆疊而成,且於共振片22與壓電致動器23之間係具有一間隙g0,於本實施例中,係於共振片22及壓電致動器23之外框231之間的間隙g0中填充一材質,例如:導電膠,但不以此為限,以使共振片22與壓電致動器23之懸浮板230之凸部230c之間可維持該間隙g0之深度,進而可導引氣流更迅速地流動,且因懸浮板230之凸部230c與共振片22保持適當距離使彼此接觸干涉減少,促使噪音產生可被降低;於另一些實施例中,亦可藉由加高壓電致動器23之外框231之高度,以使其與共振片22組裝時增加一間隙,但不以此為限,另外,於另一些實施例中,該共振片22與壓電致動器23之間亦可不具有間隙g0,即其實施態樣並不以此為限。Please refer to FIG. 2A and FIG. 5A to FIG. 5E simultaneously, wherein FIG. 5A to FIG. 5E are diagrams showing the operation of the micro gas transmission device of the micro pneumatic power device shown in FIG. 2A. First, as shown in FIG. 5A, it can be seen that the micro gas transmission device 2A is sequentially stacked by the air intake plate 20, the flow channel plate 21, the resonance plate 22, the piezoelectric actuator 23, the insulating sheet 24, the conductive sheet 25, and the like. A gap g0 is formed between the resonator piece 22 and the piezoelectric actuator 23, and is in the gap g0 between the resonator piece 22 and the outer frame 231 of the piezoelectric actuator 23 in this embodiment. Filling a material, for example, a conductive paste, but not limited thereto, so that the depth of the gap g0 can be maintained between the resonator piece 22 and the convex portion 230c of the suspension plate 230 of the piezoelectric actuator 23, thereby guiding The airflow flows more rapidly, and because the convex portion 230c of the suspension plate 230 is kept at an appropriate distance from the resonant plate 22, the mutual contact interference is reduced, so that the noise generation can be reduced; in other embodiments, the high voltage can also be applied. The height of the outer frame 231 of the actuator 23 is increased to a gap when assembled with the resonant plate 22, but not limited thereto. In addition, in other embodiments, the resonant plate 22 and the piezoelectric actuator There may be no gap g0 between the 23, that is, the implementation aspect thereof is not limited thereto.

請續參閱第5A圖至第5E圖,如圖所示,當進氣板20、流道 板21、共振片22與壓電致動器23依序對應組裝後,則於流道板21之中心孔洞210處可與其上的進氣板20以及共振片22共同形成一匯流氣體的腔室,且在共振片22與壓電致動器23之間更形成一第一腔室222,用以暫存氣體,且第一腔室222係透過共振片22之中空孔洞220而與流道板21之中心孔洞210處的腔室相連通,且第一腔室222之兩側則由壓電致動器23之支架232之間的空隙235而與設置於其下的微型閥門裝置2B相連通。Please continue to refer to Figures 5A to 5E, as shown in the figure, when the air inlet plate 20, the flow path After the plate 21, the resonator piece 22 and the piezoelectric actuator 23 are sequentially assembled, the cavity 20 of the flow channel plate 21 can form a chamber for the confluent gas together with the air inlet plate 20 and the resonance plate 22 thereon. A first chamber 222 is further formed between the resonator piece 22 and the piezoelectric actuator 23 for temporarily storing gas, and the first chamber 222 is transmitted through the hollow hole 220 of the resonator piece 22 and the flow path plate. The chambers at the central hole 210 of the 21 are in communication, and the two sides of the first chamber 222 are connected to the microvalve device 2B disposed thereunder by the gap 235 between the brackets 232 of the piezoelectric actuator 23. .

當微型氣壓動力裝置2之微型氣體傳輸裝置2A作動時,主要由壓電致動器23受電壓致動而以支架232為支點,進行垂直方向之往復式振動。如第5B圖所示,當壓電致動器23受電壓致動而向下振動時,則氣體由進氣板20上的至少一進氣孔200進入,並經由流道板21上的至少一匯流排孔211以匯集到中央的中心孔洞210處,再經由共振片22上與中心孔洞210對應設置的中央孔洞220向下流入至第一腔室222中,其後,由於受壓電致動器23振動之帶動,共振片22亦會隨之共振而進行垂直之往復式振動,如第5C圖所示,則為共振片22亦隨之向下振動,並貼附抵觸於壓電致動器23之懸浮板230之凸部230c上,藉由此共振片22之形變,以壓縮第一腔室222之體積,並關閉第一腔室222中間流通空間,促使其內的氣體推擠向兩側流動,進而經過壓電致動器23之支架232之間的空隙235而向下穿越流動。至於第5D圖則為其共振片22回復至初始位置,而壓電致動器23受電壓驅動以向上振動,如此同樣擠壓第一腔室222之體積,惟此時由於壓電致動器23係向上抬升,因而使得第一腔室222內的氣體會朝兩側流動,進而帶動氣體持續地自進氣板20上的至少一進氣孔200進入,再流入流道板21上的中心孔洞210所形成之腔室中,再如第5E圖所示,該共振片22受壓電致動器23向上抬升 的振動而共振向上,進而使流道板21的中心孔洞210內的氣體再由共振片22的中央孔洞220而流入第一腔室222內,並經由壓電致動器23之支架232之間的空隙235而向下穿越流出微型氣體傳輸裝置2A。由此實施態樣可見,當共振片22進行垂直之往復式振動時,係可由其與壓電致動器23之間的間隙g0以增加其垂直位移的最大距離,換句話說,於該兩結構之間設置間隙g0可使共振片22於共振時可產生更大幅度的上下位移,因而可促進氣體更快速的流動,並可達到靜音之效果。如此,在經此微型氣體傳輸裝置2A之流道設計中產生壓力梯度,使氣體高速流動,並透過流道進出方向之阻抗差異,將氣體由吸入端傳輸至排出端,且在排出端有氣壓之狀態下,仍有能力持續推出氣體。When the micro gas transmission device 2A of the micro air pressure power unit 2 is actuated, the piezoelectric actuator 23 is mainly actuated by the voltage and the reciprocating vibration in the vertical direction is performed with the holder 232 as a fulcrum. As shown in FIG. 5B, when the piezoelectric actuator 23 is vibrated downward by the voltage, the gas enters from at least one of the intake holes 200 on the air intake plate 20 and passes through at least one of the flow path plates 21. A bus bar hole 211 is collected at the central hole 210 in the center, and flows downward into the first chamber 222 via the central hole 220 disposed on the resonator plate 22 corresponding to the center hole 210, and thereafter, is subjected to piezoelectric When the actuator 23 vibrates, the resonator piece 22 will resonate to perform vertical reciprocating vibration. As shown in FIG. 5C, the resonator piece 22 also vibrates downward and adheres to the piezoelectricity. The convex portion 230c of the suspension plate 230 of the actuator 23 is deformed by the resonance piece 22 to compress the volume of the first chamber 222, and close the intermediate circulation space of the first chamber 222 to promote the gas pushing therein. It flows to both sides and passes through the gap 235 between the holders 232 of the piezoelectric actuator 23 to flow downward. As for the 5D figure, the resonator piece 22 is returned to the initial position, and the piezoelectric actuator 23 is driven by the voltage to vibrate upward, so that the volume of the first chamber 222 is also pressed, but at this time due to the piezoelectric actuator The 23 series is lifted upwards, so that the gas in the first chamber 222 flows toward both sides, thereby driving the gas continuously from at least one of the intake holes 200 on the air inlet plate 20, and then into the center on the flow path plate 21. In the chamber formed by the hole 210, as shown in Fig. 5E, the resonator piece 22 is lifted up by the piezoelectric actuator 23. The vibration is resonant and upward, so that the gas in the central hole 210 of the flow channel plate 21 flows into the first chamber 222 from the central hole 220 of the resonator piece 22, and between the brackets 232 via the piezoelectric actuator 23. The gap 235 passes downwardly out of the micro gas transmission device 2A. It can be seen from this embodiment that when the resonant piece 22 performs vertical reciprocating vibration, it can be increased by the gap g0 between it and the piezoelectric actuator 23 to increase the maximum distance of its vertical displacement, in other words, in the two The provision of the gap g0 between the structures allows the resonance piece 22 to generate a larger displacement up and down at the time of resonance, thereby promoting a faster gas flow and achieving a silent effect. Thus, a pressure gradient is generated in the flow path design of the micro gas transmission device 2A, so that the gas flows at a high speed, and the gas is transmitted from the suction end to the discharge end through the difference in impedance of the flow path in and out of the flow path, and the gas is discharged at the discharge end. In this state, there is still the ability to continuously introduce gas.

另外,於一些實施例中,共振片22之垂直往復式振動頻率係可與壓電致動器23之振動頻率相同,即兩者可同時向上或同時向下,其係可依照實際施作情形而任施變化,並不以本實施例所示之作動方式為限。In addition, in some embodiments, the vertical reciprocating vibration frequency of the resonant plate 22 can be the same as the vibration frequency of the piezoelectric actuator 23, that is, both can be simultaneously upward or downward, which can be implemented according to actual conditions. Any change is not limited to the mode of operation shown in this embodiment.

請同時參閱第2A圖、第2B圖及第6A圖、第6B圖,其中第6A圖係為第2A圖所示之微型氣壓動力裝置之微型閥門裝置之集壓作動示意圖,第6B圖則為第2A圖所示之微型氣壓動力裝置之微型閥門裝置之卸壓作動示意圖。如第6A圖所示,本案之微型氣壓動力裝置2之微型閥門裝置2B係依序由集氣板26、閥門片27以及出口板28堆疊而成,於本實施例中,集氣板26之第一表面260上係凹陷以形成一集氣腔室262,由微型氣體傳輸裝置2A向下傳輸之氣體則暫時蓄積於此集氣腔室262中,且於集氣板26中係具有第一貫穿孔263及第二貫穿孔264,第一貫穿孔263及第二貫穿孔264之一端係與集氣腔室262相連通,另一端則分別與集氣板26之第二表面261上的 第一卸壓腔室265及第一出口腔室266相連通。以及,在第一出口腔室266處更進一步增設一凸部結構269,例如可為但不限為一圓柱結構,且其係與閥門片27之閥孔270對應設置;另外,在集氣板26上更具有複數個環繞於集氣腔室262、第一卸壓腔室265及第一出口腔室266而設置之凹槽結構267,用以供一密封環268設置於其上。Please also refer to FIG. 2A, FIG. 2B, and FIG. 6A and FIG. 6B. FIG. 6A is a schematic diagram of the collective pressure operation of the micro-valve device of the micro-pneumatic power device shown in FIG. 2A, and FIG. Fig. 2A is a schematic view showing the pressure relief operation of the microvalve device of the micro pneumatic power device. As shown in FIG. 6A, the microvalve device 2B of the micro pneumatic power device 2 of the present invention is sequentially formed by stacking the gas collecting plate 26, the valve piece 27 and the outlet plate 28. In the present embodiment, the gas collecting plate 26 is The first surface 260 is recessed to form a gas collection chamber 262. The gas transported downward by the micro gas transmission device 2A temporarily accumulates in the gas collection chamber 262, and has a first gas collection plate 26 The through hole 263 and the second through hole 264, one end of the first through hole 263 and the second through hole 264 are in communication with the gas collecting chamber 262, and the other end is respectively connected to the second surface 261 of the gas collecting plate 26 The first pressure relief chamber 265 and the first outlet chamber 266 are in communication. And a protrusion structure 269 is further added to the first outlet chamber 266, for example, but not limited to a cylindrical structure, and is disposed corresponding to the valve hole 270 of the valve piece 27; 26 further includes a plurality of groove structures 267 disposed around the gas collection chamber 262, the first pressure relief chamber 265 and the first outlet chamber 266 for providing a sealing ring 268 thereon.

出口板28亦具有兩貫穿設置之第三貫穿孔281以及第四貫穿孔282,且該第三貫穿孔281及第四貫穿孔282係分別對應於集氣板26之第一貫穿孔263以及第二貫穿孔264而設置,且於出口板28之第一表面280上對應於第三貫穿孔281處係凹陷形成一第二卸壓腔室283,而對應於第四貫穿孔282處則凹陷形成一第二出口腔室284,且於第二卸壓腔室283與第二出口腔室284之間更具有一連通流道285,用以供氣體流通。該第三貫穿孔281之一端與第二卸壓腔室283相連通,且其端部可進一步增設一凸出而形成之凸部結構281a,例如可為但不限為圓柱結構,另一端則連通於出口板28之第二表面289之卸壓孔288;而第四貫穿孔282之一端與第二出口腔室284相連通,另一端則與出口29相連通,於本實施例中,出口29係可與一裝置(未圖示),例如:壓力機,但不以此為限,相連接。同樣地,在出口板28上亦具有複數個環繞於第二卸壓腔室283及第二出口腔室284而設置之凹槽結構286,用以供一密封環287設置於其上,於一些實施例中,密封環268、287之材質係為可耐化性佳之橡膠材料,但不以此為限,其主要用以對應設置於凹槽結構267、286中,以輔助集氣板26、出口板28與閥門片27之間更緊密的接合,並防止氣體外洩。The outlet plate 28 also has two through holes 281 and a fourth through hole 282 extending therethrough, and the third through hole 281 and the fourth through hole 282 respectively correspond to the first through hole 263 of the gas collecting plate 26 and the first The second through hole 264 is disposed on the first surface 280 of the outlet plate 28 to form a second pressure relief chamber 283 corresponding to the third through hole 281, and the recess is formed corresponding to the fourth through hole 282. A second outlet chamber 284 has a communication passage 285 between the second pressure relief chamber 283 and the second outlet chamber 284 for gas circulation. One end of the third through hole 281 is in communication with the second pressure relief chamber 283, and a convex portion structure 281a formed by the protrusion may be further added to the end portion thereof, for example, but not limited to a cylindrical structure, and the other end is a pressure relief hole 288 communicating with the second surface 289 of the outlet plate 28; and one end of the fourth through hole 282 is in communication with the second outlet chamber 284, and the other end is in communication with the outlet 29, in this embodiment, the outlet The 29 series can be connected to a device (not shown), such as a press, but not limited thereto. Similarly, the outlet plate 28 also has a plurality of groove structures 286 disposed around the second pressure relief chamber 283 and the second outlet chamber 284 for providing a sealing ring 287 thereon. In the embodiment, the material of the sealing ring 268, 287 is a rubber material with good chemical resistance, but not limited thereto, and is mainly used to be correspondingly disposed in the groove structure 267, 286 to assist the gas collecting plate 26, The outlet plate 28 is more tightly engaged with the valve piece 27 and prevents gas from leaking out.

閥門片27上具有一閥孔270以及複數個定位孔洞271,當閥門 片27與集氣板26及出口板28定位組裝時,係將其閥孔270對應於集氣板26之第一出口腔室266之凸部結構269而對應設置,藉由此單一之閥孔270之設計,以使氣體可因應其壓差而達到單向流動之目的。The valve piece 27 has a valve hole 270 and a plurality of positioning holes 271, when the valve When the sheet 27 is assembled and assembled with the gas collecting plate 26 and the outlet plate 28, the valve hole 270 is correspondingly disposed corresponding to the convex portion structure 269 of the first outlet chamber 266 of the gas collecting plate 26, whereby the single valve hole is formed. The 270 is designed so that the gas can reach a one-way flow in response to its differential pressure.

當微型閥門裝置2B集壓作動時,主要如第6A圖所示,其係可因應來自於微型氣體傳輸裝置2A向下傳輸之氣體所提供之壓力,又或是當外界的大氣壓力大於與出口29連接的裝置(未圖示)的內部壓力時,則氣體會自微型氣體傳輸裝置2A傳輸至微型閥門裝置2B的集氣腔室262中,再分別經第一貫穿孔263以及第二貫穿孔264而向下流入第一卸壓腔室265及第一出口腔室266內,此時,向下的氣體壓力係使可撓性的閥門片27向下彎曲形變,進而使第一卸壓腔室265的體積增大,且對應於第一貫穿孔263處向下平貼並抵頂於第三貫穿孔281之端部,進而可封閉出口板28之第三貫穿孔281,故於第二卸壓腔室283內的氣體不會自第三貫穿孔281處流出。當然,本實施例,可利用第三貫穿孔281端部增設之凸部結構281a,以加強閥門片27快速抵觸封閉第三貫穿孔281,並達到一預力抵觸作用完全密封之效果。另一方面,由於氣體係自第二貫穿孔264而向下流入第一出口腔室266中,且對應於第一出口腔室266處之閥門片27亦向下彎曲形變,故使得其對應的閥孔270向下打開,氣體則可自第一出口腔室266經由閥孔270而流入第二出口腔室284中,並由第四貫穿孔282而流至出口29及與出口29相連接之裝置(未圖示)中,藉此以對該裝置進行集壓之作動。When the microvalve device 2B is pressurized, as shown in Fig. 6A, it can be based on the pressure supplied by the gas from the micro gas transmission device 2A, or when the external atmospheric pressure is greater than the outlet. When the internal pressure of the connected device (not shown) is 29, the gas is transferred from the micro gas transmission device 2A to the gas collection chamber 262 of the micro valve device 2B, and then passes through the first through hole 263 and the second through hole, respectively. 264 flows downward into the first pressure relief chamber 265 and the first outlet chamber 266. At this time, the downward gas pressure causes the flexible valve piece 27 to be bent downward, thereby making the first pressure relief chamber The volume of the chamber 265 is increased, and corresponds to the end of the first through hole 263 and abuts against the end of the third through hole 281, so that the third through hole 281 of the outlet plate 28 can be closed. The gas in the pressure chamber 283 does not flow out from the third through hole 281. Of course, in this embodiment, the protrusion structure 281a added at the end of the third through hole 281 can be used to strengthen the valve piece 27 to quickly close the third through hole 281, and achieve a full force of the pre-impacting effect. On the other hand, since the gas system flows downward from the second through hole 264 into the first outlet chamber 266, and the valve piece 27 corresponding to the first outlet chamber 266 is also bent downward, the corresponding The valve hole 270 is opened downward, and the gas can flow from the first outlet chamber 266 through the valve hole 270 into the second outlet chamber 284, and from the fourth through hole 282 to the outlet 29 and to the outlet 29. In the device (not shown), the device is operated by collecting pressure.

請續參閱第6B圖,當微型閥門裝置2B進行卸壓時,其係可藉由調控微型氣體傳輸裝置2A之氣體傳輸量,使氣體不再輸入集氣腔室262中,或是當與出口29連接之裝置(未圖示)內部壓力大於外界的大氣壓力時, 則可使微型閥門裝置2B進行卸壓。此時,氣體將自與出口29連接的第四貫穿孔282輸入至第二出口腔室284內,使得第二出口腔室284之體積膨脹,進而促使可撓性之閥門片27向上彎曲形變,並向上平貼、抵頂於集氣板26上,故閥門片27之閥孔270會因抵頂於集氣板26而關閉。當然,在本實施例,可利用第一出口腔室266增設凸部結構269,讓可撓性之閥門片27向上彎曲形變更快速抵觸,使閥孔270更有利達到一預力抵觸作用完全貼附密封之關閉狀態,故閥門片27之閥孔270會因抵頂於該凸部結構269而關閉,則該第二出口腔室284內的氣體將不會逆流至第一出口腔室266中。以及,第二出口腔室284中的氣體係可經由連通流道285而流至第二卸壓腔室283中,進而使第二卸壓腔室283的體積擴張,並使對應於第二卸壓腔室283的閥門片27同樣向上彎曲形變,此時由於閥門片27未抵頂封閉於第三貫穿孔281端部,,故該第三貫穿孔281即處於開啟狀態,即第二卸壓腔室283內的氣體可由第三貫穿孔281向外流至卸壓孔288處以進行卸壓作業。當然,本實施例,可利用第三貫穿孔281端部增設之凸部結構281a,讓可撓性之閥門片27向上彎曲形變更快速,更有利脫離關閉第三貫穿孔281之狀態。如此,則可藉由此單向之卸壓作業將與出口29連接的裝置(未圖示)內的氣體排出而降壓,或是完全排出而完成卸壓作業。Referring to FIG. 6B, when the microvalve device 2B is depressurized, it can control the gas transmission amount of the micro gas transmission device 2A so that the gas is no longer input into the gas collection chamber 262, or when it is connected to the outlet. When the internal pressure of the connected device (not shown) is greater than the atmospheric pressure of the outside world, The microvalve device 2B can be depressurized. At this time, the gas is input into the second outlet chamber 284 from the fourth through hole 282 connected to the outlet 29, so that the volume of the second outlet chamber 284 is expanded, thereby causing the flexible valve piece 27 to be bent upward. The valve hole 270 of the valve piece 27 is closed by the top of the gas collecting plate 26 by flattening against the top of the gas collecting plate 26. Of course, in the embodiment, the first outlet chamber 266 can be used to add the protrusion structure 269, so that the flexible valve piece 27 can be bent upwardly to change the rapid resistance, so that the valve hole 270 is more favorable to achieve a pre-stressing effect. With the closed state of the seal, the valve hole 270 of the valve piece 27 is closed by the protrusion of the protrusion structure 269, and the gas in the second outlet chamber 284 will not flow back into the first outlet chamber 266. . And the gas system in the second outlet chamber 284 can flow into the second pressure relief chamber 283 via the communication passage 285, thereby expanding the volume of the second pressure relief chamber 283 and corresponding to the second discharge The valve piece 27 of the pressure chamber 283 is also bent upwardly. At this time, since the valve piece 27 is not closed to the end of the third through hole 281, the third through hole 281 is in an open state, that is, the second pressure relief. The gas in the chamber 283 may flow outward from the third through hole 281 to the pressure relief hole 288 for pressure relief operation. Of course, in the present embodiment, the convex portion structure 281a added to the end portion of the third through hole 281 can be used to change the flexible valve piece 27 upwardly, and it is more advantageous to be separated from the third through hole 281. In this way, the gas in the device (not shown) connected to the outlet 29 can be discharged by the one-way pressure relief operation, and the pressure can be reduced or completely discharged to complete the pressure relief operation.

請同時參閱第2A圖、第2B圖及第7A圖至第7E圖,其中第7A圖至第7E圖係為第2A圖所示之微型氣壓動力裝置之集壓作動示意圖。如第7A圖所示,微型氣壓動力裝置2即由微型氣體傳輸裝置2A以及微型閥門裝置2B所組合而成,其中微型氣體傳輸裝置2A係如前述,依序由進氣板20、流道板21、共振片22、壓電致動器23、絕緣片24、導電片25等結構堆疊組 裝定位而成,且於共振片22與壓電致動器23之間係具有一間隙g0,且於共振片22與壓電致動器23之間具有第一腔室222,以及,微型閥門裝置2B則同樣由集氣板26、閥門片27以及出口板28等依序堆疊組裝定位而成,且於微型閥門裝置2B之集氣板26與微型氣體傳輸裝置2A之壓電致動器23之間係具有集氣腔室262、於集氣板26之第二表面261更具有第一卸壓腔室265以及第一出口腔室266,以及於出口板28之第一表面280更具有第二卸壓腔室283及第二出口腔室284,藉由該等多個不同的壓力腔室搭配壓電致動器23之驅動及共振片22、閥門片27之振動,以使氣體向下集壓傳輸。Please refer to FIG. 2A, FIG. 2B and FIGS. 7A to 7E simultaneously, wherein FIGS. 7A to 7E are schematic diagrams of the collective pressure operation of the micro pneumatic power device shown in FIG. 2A. As shown in FIG. 7A, the micro pneumatic power device 2 is composed of a micro gas transmission device 2A and a micro valve device 2B, wherein the micro gas transmission device 2A is sequentially connected to the air intake plate 20 and the flow channel plate as described above. 21. Resonant sheet 22, piezoelectric actuator 23, insulating sheet 24, conductive sheet 25, and the like Positioned with a gap g0 between the resonator piece 22 and the piezoelectric actuator 23, and a first chamber 222 between the resonator piece 22 and the piezoelectric actuator 23, and a microvalve The device 2B is also sequentially assembled and assembled by the gas collecting plate 26, the valve piece 27 and the outlet plate 28, and the gas collecting plate 26 of the micro valve device 2B and the piezoelectric actuator 23 of the micro gas conveying device 2A. There is a gas collection chamber 262, a second pressure relief chamber 265 and a first outlet chamber 266 on the second surface 261 of the gas collection plate 26, and a first surface 280 on the outlet plate 28. The second pressure relief chamber 283 and the second outlet chamber 284 are coupled to the piezoelectric actuator 23 and the vibration of the resonator piece 22 and the valve piece 27 by the plurality of different pressure chambers to make the gas downward. Collective transmission.

如第7B圖所示,當微型氣體傳輸裝置2A之壓電致動器23受電壓致動而向下振動時,則氣體會由進氣板20上的進氣孔200進入微型氣體傳輸裝置2A中,並經由流道板21上的至少一匯流排孔211以匯集到其中心孔洞210處,再經由共振片22上的中空孔洞220向下流入至第一腔室222中。其後,則如第7C圖所示,由於受壓電致動器23振動之共振作用,共振片22亦會隨之進行往復式振動,即其向下振動,並吸附於壓電致動器23之懸浮板230之凸部230c上,藉由此共振片22之形變,使得流道板21之中央孔洞210處之腔室之體積增大,並同時壓縮第一腔室222之體積,進而促使第一腔室222內的氣體推擠向兩側流動,進而經過壓電致動器23之支架232之間的空隙235而向下穿越流通,以流至微型氣體傳輸裝置2A與微型閥門裝置2B之間的集氣腔室262內,並再由與集氣腔室262相連通之第一貫穿孔263及第二貫穿孔264向下對應流至第一卸壓腔室265及第一出口腔室266中。接著,則如第7D圖所示,由於微型氣體傳輸裝置2A之共振片22回復至初始位置,而壓電致動器23受電壓驅動以向上振動,如此同樣擠壓第一腔室222之體積,使 得第一腔室222內的氣體朝兩側流動,並由壓電致動器23之支架232之間的空隙235持續地輸入至微型閥門裝置2B之集氣腔室262、第一卸壓腔室265以及第一出口腔室266中,如此更使得第一卸壓腔室265及第一出口腔室266內的氣壓越大,進而推動可撓性的閥門片27向下產生彎曲形變,則於第二卸壓腔室283中,閥門片27則向下平貼並抵頂於第三貫穿孔281端部之凸部結構281a,進而使第三貫穿孔281封閉,而於第二出口腔室284中,閥門片27上對應於第四貫穿孔282之閥孔270係向下打開,使第二出口腔室284內之氣體可由第四貫穿孔282向下傳遞至出口29及與出口29連接的任何裝置(未圖示),進而以達到集壓作業之目的。最後,則如第7E圖所示,當微型氣體傳輸裝置2A之共振片22共振向上位移,進而使流道板21的中心孔洞210內的氣體可由共振片22的中空孔洞220而流入第一腔室222內,再經由壓電致動器23之支架232之間的空隙235而向下持續地傳輸至微型閥門裝置2B中,則由於其氣體壓係持續向下增加,故氣體仍會持續地經由微型閥門裝置2B之集氣腔室262、第二貫穿孔264、第一出口腔室266、第二出口腔室284及第四貫穿孔282而流至出口29及與出口29連接的任何裝置中,此集壓作業係可經由外界之大氣壓力與裝置內的壓力差以驅動之,但不以此為限。As shown in Fig. 7B, when the piezoelectric actuator 23 of the micro gas transmission device 2A is vibrated downward by the voltage, the gas enters the micro gas transmission device 2A from the air inlet hole 200 in the air intake plate 20. And passing through at least one bus bar hole 211 on the flow channel plate 21 to be collected to the center hole 210 thereof, and then flowing down into the first chamber 222 through the hollow hole 220 on the resonance piece 22 . Thereafter, as shown in Fig. 7C, the resonance piece 22 is also reciprocally vibrated by the resonance of the vibration of the piezoelectric actuator 23, that is, it vibrates downward and is adsorbed to the piezoelectric actuator. On the convex portion 230c of the suspension plate 230 of 23, by the deformation of the resonance piece 22, the volume of the chamber at the central hole 210 of the flow path plate 21 is increased, and at the same time, the volume of the first chamber 222 is compressed, thereby further The gas in the first chamber 222 is caused to flow toward both sides, and then flows downward through the gap 235 between the brackets 232 of the piezoelectric actuator 23 to flow to the micro gas transmission device 2A and the micro valve device. The first through hole 263 and the second through hole 264 communicating with the gas collecting chamber 262 are correspondingly flowed into the first pressure relief chamber 265 and the first out of the gas collecting chamber 262. In the oral chamber 266. Next, as shown in Fig. 7D, since the resonator piece 22 of the micro gas transmission device 2A is returned to the initial position, and the piezoelectric actuator 23 is driven by the voltage to vibrate upward, the volume of the first chamber 222 is also pressed. ,Make The gas in the first chamber 222 flows toward both sides, and is continuously input into the gas collection chamber 262 of the microvalve device 2B and the first pressure relief chamber by the gap 235 between the brackets 232 of the piezoelectric actuator 23. In the chamber 265 and the first outlet chamber 266, the air pressure in the first pressure relief chamber 265 and the first outlet chamber 266 is further increased, thereby pushing the flexible valve piece 27 to bend downward. In the second pressure relief chamber 283, the valve piece 27 is flattened and abuts against the convex portion structure 281a at the end of the third through hole 281, thereby closing the third through hole 281 and the second outlet chamber. In 284, the valve hole 270 corresponding to the fourth through hole 282 of the valve piece 27 is opened downward, so that the gas in the second outlet chamber 284 can be transmitted downward from the fourth through hole 282 to the outlet 29 and connected to the outlet 29. Any device (not shown), in order to achieve the purpose of the collection operation. Finally, as shown in FIG. 7E, when the resonator piece 22 of the micro gas transmission device 2A is resonantly displaced upward, the gas in the central hole 210 of the flow channel plate 21 can flow into the first cavity from the hollow hole 220 of the resonator piece 22. The chamber 222 is continuously transmitted downward into the microvalve device 2B via the gap 235 between the brackets 232 of the piezoelectric actuator 23, and since the gas pressure system continues to increase downward, the gas continues to be continuously Flowing through the gas collection chamber 262, the second through hole 264, the first outlet chamber 266, the second outlet chamber 284, and the fourth through hole 282 of the microvalve device 2B to the outlet 29 and any device connected to the outlet 29 In this case, the pressure collecting operation can be driven by the atmospheric pressure of the outside and the pressure difference in the device, but not limited thereto.

當與出口29連接的裝置(未圖示)內部的壓力大於外界的壓力時,則微型氣壓動力裝置2係可如第8圖所示進行降壓或是卸壓之作業,其降壓或是卸壓之作動方式主要係如前所述,可藉由調控微型氣體傳輸裝置2A之氣體傳輸量,使氣體不再輸入集氣腔室262中,此時,氣體將自與出口29連接的第四貫穿孔282輸入至第二出口腔室284內,使得第二出口腔室284之體積膨脹,進而促使可撓性之閥門片27向上彎曲形變,並向上平貼、 抵頂於第一出口腔室266之凸部結構269上,而使閥門片27之閥孔270關閉,即第二出口腔室284內的氣體不會逆流至第一出口腔室266中;以及,第二出口腔室284中的氣體係可經由連通流道285而流至第二卸壓腔室283中,再由第三貫穿孔281向外流至卸壓孔288處以進行卸壓作業;如此可藉由此微型閥門結構2B之單向氣體傳輸作業將與出口29連接的裝置內的氣體排出而降壓,或是完全排出而完成卸壓作業。When the pressure inside the device (not shown) connected to the outlet 29 is greater than the external pressure, the micro-pneumatic power device 2 can perform the step-down or pressure-reduction operation as shown in FIG. The pressure relief operation mode is mainly as described above, and the gas can be no longer input into the air collection chamber 262 by regulating the gas transmission amount of the micro gas transmission device 2A. At this time, the gas will be connected to the outlet 29 The four through holes 282 are input into the second outlet chamber 284, so that the volume of the second outlet chamber 284 is expanded, thereby causing the flexible valve piece 27 to be bent upward and flattened, Adjacent to the convex structure 269 of the first outlet chamber 266, the valve hole 270 of the valve piece 27 is closed, that is, the gas in the second outlet chamber 284 does not flow back into the first outlet chamber 266; The gas system in the second outlet chamber 284 can flow into the second pressure relief chamber 283 via the communication passage 285, and then flow outward from the third through hole 281 to the pressure relief hole 288 for pressure relief operation; The gas in the apparatus connected to the outlet 29 can be discharged by the one-way gas transfer operation of the microvalve structure 2B, and the pressure can be reduced or completely discharged to complete the pressure relief operation.

綜上所述,本創作所提供之微型氣體傳輸裝置係包含進氣板、流道板、共振片、壓電致動器、絕緣片以及導電片等結構,使氣體自進氣板之進氣孔進入,並利用壓電致動器之作動,使氣體於流經流道板中設計過之匯流排孔及中心孔洞進行流動,並沿共振片之中空孔洞向下流動,以於共振片及壓電致動器之間形成的第一腔室內產生壓力梯度,進而使氣體高速流動,並可繼續向下傳遞,進而以達到可使氣體迅速地傳輸,且同時可達到靜音之功效,更可使微型氣體傳輸裝置之整體體積減小及薄型化,進而使其所適用之微型氣體動力裝置達成輕便舒適之可攜式目的,並可廣泛地應用於醫療器材及相關設備之中。因此,本案之極具產業利用價值,爰依法提出申請。In summary, the micro gas transmission device provided by the present invention comprises an air inlet plate, a flow channel plate, a resonance plate, a piezoelectric actuator, an insulating sheet and a conductive sheet to make the gas from the air inlet plate. The hole enters and uses the action of the piezoelectric actuator to flow the gas through the bus hole and the central hole designed through the flow channel plate, and flows downward along the hollow hole of the resonator to the resonance piece and A pressure gradient is generated in the first chamber formed between the piezoelectric actuators, so that the gas flows at a high speed, and can continue to be transmitted downward, so as to achieve rapid gas transfer and at the same time achieve mute effect, and The overall volume of the micro gas transmission device is reduced and thinned, so that the micro gas power device to which it is applied achieves the purpose of being portable and portable, and can be widely used in medical equipment and related equipment. Therefore, the case is of great industrial use value and is submitted in accordance with the law.

縱使本創作已由上述實施例詳細敘述而可由熟悉本技藝人士任施匠思而為諸般修飾,然皆不脫如附申請專利範圍所欲保護者。Even though the present invention has been described in detail by the above-described embodiments, it can be modified by those skilled in the art, and is not intended to be protected as claimed.

2A‧‧‧微型氣體傳輸裝置2A‧‧‧Micro Gas Transmission

20‧‧‧進氣板20‧‧‧Air intake plate

200‧‧‧進氣孔200‧‧‧Air intake

21‧‧‧流道板21‧‧‧Channel board

210‧‧‧中心孔洞210‧‧‧ center hole

22‧‧‧共振片22‧‧‧Resonance film

220‧‧‧中空孔洞220‧‧‧ hollow holes

23‧‧‧壓電致動器23‧‧‧ Piezoelectric Actuator

230c‧‧‧凸部230c‧‧‧ convex

231‧‧‧外框231‧‧‧Front frame

24‧‧‧絕緣片24‧‧‧Insulation sheet

25‧‧‧導電片25‧‧‧Conductor

g0‧‧‧間隙G0‧‧‧ gap

Claims (9)

一種微型氣體傳輸裝置,適用於一微型氣壓動力裝置,至少包括:一進氣板,具有至少一進氣孔,供導入氣體;一流道板,具有至少一匯流排孔及一中心孔洞,該匯流排孔對應該進氣板之進氣孔,且引導該進氣孔之氣體匯流至該中心孔洞;一共振片,具有一中空孔洞,對應該流道板之中心孔洞;以及一壓電致動器,具有一懸浮板及一外框,該懸浮板及該外框之間以至少一支架連接,且於該懸浮板之一表面貼附一壓電陶瓷板;其中,上述之進氣板、流道板、共振片及壓電致動器依序對應堆疊設置定位,且該共振片與該壓電致動器之間具有一間隙形成一第一腔室,以使該壓電致動器受驅動時,氣體由該進氣板之該至少一進氣孔導入,經該流道板之該至少一匯流排孔匯集至該中心孔洞,再流經該共振片之該中空孔洞,以進入該第一腔室內,再由該壓電致動器之該至少一支架之間之一空隙向下傳輸,以持續推出氣體。A micro gas transmission device suitable for a micro pneumatic power device, comprising at least: an air inlet plate having at least one air inlet for introducing a gas; a first channel plate having at least one bus bar hole and a center hole, the confluence The exhaust hole corresponds to the air inlet hole of the air inlet plate, and the gas guiding the air inlet hole is merged to the center hole; a resonance piece having a hollow hole corresponding to the center hole of the flow path plate; and a piezoelectric actuation The device has a suspension plate and an outer frame, and the suspension plate and the outer frame are connected by at least one bracket, and a piezoelectric ceramic plate is attached to one surface of the suspension plate; wherein the air inlet plate, The flow channel plate, the resonant plate and the piezoelectric actuator are sequentially positioned corresponding to the stack, and a gap is formed between the resonant plate and the piezoelectric actuator to form a first chamber, so that the piezoelectric actuator When being driven, the gas is introduced from the at least one air inlet hole of the air intake plate, and the at least one bus bar hole of the flow channel plate is collected to the central hole, and then flows through the hollow hole of the resonance piece to enter In the first chamber, the piezoelectric The device of at least one bracket between a downward transmission gap, to continuously introduced gas. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該微型氣體傳輸裝置更包括一絕緣片及一導電片,且該絕緣片及該導電片依序設置於該壓電致動器之下。The micro gas transmission device of claim 1, wherein the micro gas transmission device further comprises an insulating sheet and a conductive sheet, and the insulating sheet and the conductive sheet are sequentially disposed on the piezoelectric actuator. under. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該進氣板及該流道板可為一體成型之結構。The micro gas transmission device of claim 1, wherein the air inlet plate and the flow channel plate are integrally formed. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該共振片由一可撓性之材質所構成,並可與該壓電致動器產生共振。The micro gas transmission device according to claim 1, wherein the resonance piece is made of a flexible material and is resonate with the piezoelectric actuator. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該壓電致動器之該 懸浮板之一上表面為一階梯面之結構,即該上表面具有一凸部,且該凸部與該外框之一上表面共平面,該凸部及該外框之該上表面與該懸浮板之該上表面及該支架之一上表面之間具有一特定深度。The micro gas transmission device of claim 1, wherein the piezoelectric actuator One of the upper surfaces of the suspension plate is a stepped surface, that is, the upper surface has a convex portion, and the convex portion is coplanar with an upper surface of the outer frame, and the convex portion and the upper surface of the outer frame are There is a specific depth between the upper surface of the suspension plate and the upper surface of one of the brackets. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該壓電致動器之該壓電陶瓷板貼附於該懸浮板之一下表面,且該懸浮板之該下表面與該外框及該支架之一下表面共平面。The micro gas transmission device of claim 1, wherein the piezoelectric ceramic plate of the piezoelectric actuator is attached to a lower surface of the suspension plate, and the lower surface of the suspension plate and the outer frame And the lower surface of one of the brackets is coplanar. 如申請專利範圍第1項所述之微型氣體傳輸裝置,其中該壓電致動器之該懸浮板、該外框、該支架為一體成型之結構,且該懸浮板、該外框、該支架可由一金屬材質所構成。The micro gas transmission device of claim 1, wherein the suspension plate, the outer frame and the bracket of the piezoelectric actuator are integrally formed, and the suspension plate, the outer frame and the bracket are It can be made of a metal material. 一種微型氣體傳輸裝置,適用於一微型氣壓動力裝置,至少包括:一進氣板,具有至少一進氣孔,供導入氣體;一流道板,具有至少一匯流排孔及一中心孔洞,該匯流排孔對應該進氣板之進氣孔,且引導該進氣孔之氣體匯流至該中心孔洞;一共振片,具有一中空孔洞,對應該流道板之中心孔洞;以及一壓電致動器,具有一懸浮板及一外框,該懸浮板及該外框之間以至少一支架連接,且於該懸浮板之一表面貼附一壓電陶瓷板;其中,上述之進氣板、流道板、共振片及壓電致動器依序對應堆疊設置定位,以使該壓電致動器受驅動時,氣體由該進氣板之該至少一進氣孔進入,並由該流道板之該至少一匯流排孔匯集至該中心孔洞,再流經該共振片之該中空孔洞以進入該共振片及該壓電致動器之間,再由該壓電致動器之該至少一支架之間之一空隙向下傳輸,以持續推出氣體。A micro gas transmission device suitable for a micro pneumatic power device, comprising at least: an air inlet plate having at least one air inlet for introducing a gas; a first channel plate having at least one bus bar hole and a center hole, the confluence The exhaust hole corresponds to the air inlet hole of the air inlet plate, and the gas guiding the air inlet hole is merged to the center hole; a resonance piece having a hollow hole corresponding to the center hole of the flow path plate; and a piezoelectric actuation The device has a suspension plate and an outer frame, and the suspension plate and the outer frame are connected by at least one bracket, and a piezoelectric ceramic plate is attached to one surface of the suspension plate; wherein the air inlet plate, The flow channel plate, the resonance plate and the piezoelectric actuator are sequentially positioned corresponding to the stack, so that when the piezoelectric actuator is driven, the gas enters through the at least one air inlet hole of the air inlet plate, and the flow is The at least one bus bar hole of the land plate is collected into the center hole, and then flows through the hollow hole of the resonance plate to enter between the resonance piece and the piezoelectric actuator, and the piezoelectric actuator a gap between at least one of the brackets is transmitted downward, Continued introduction of gas. 一種微型氣體傳輸裝置,適用於一微型氣壓動力裝置,至少包括依序堆疊 設置之一進氣板、一流道板、一共振片以及一壓電致動器,其中該共振片與該壓電致動器之間具有一間隙形成一第一腔室,該壓電致動器受驅動時,氣體由該進氣板進入,流經該流道板及該共振片,以進入該第一腔室內再傳輸,以持續推出氣體。A micro gas transmission device suitable for a micro pneumatic power device, at least comprising sequentially stacking Providing an air inlet plate, a first channel plate, a resonance plate, and a piezoelectric actuator, wherein the resonator plate has a gap with the piezoelectric actuator to form a first chamber, the piezoelectric actuator When the device is driven, gas enters through the air inlet plate, flows through the flow channel plate and the resonant plate to enter the first cavity and is retransmitted to continuously push out the gas.
TW102211827U 2013-06-24 2013-06-24 Micro-gas transmission apparatus TWM465471U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
TW102211827U TWM465471U (en) 2013-06-24 2013-06-24 Micro-gas transmission apparatus

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
TW102211827U TWM465471U (en) 2013-06-24 2013-06-24 Micro-gas transmission apparatus

Publications (1)

Publication Number Publication Date
TWM465471U true TWM465471U (en) 2013-11-11

Family

ID=49992337

Family Applications (1)

Application Number Title Priority Date Filing Date
TW102211827U TWM465471U (en) 2013-06-24 2013-06-24 Micro-gas transmission apparatus

Country Status (1)

Country Link
TW (1) TWM465471U (en)

Cited By (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9976673B2 (en) 2016-01-29 2018-05-22 Microjet Technology Co., Ltd. Miniature fluid control device
CN108302019A (en) * 2017-01-13 2018-07-20 研能科技股份有限公司 Air motor
TWI633239B (en) * 2016-01-29 2018-08-21 研能科技股份有限公司 Micro-gas pressure driving apparatus
US10371136B2 (en) 2016-01-29 2019-08-06 Microjet Technology Co., Ltd. Miniature pneumatic device
US10378529B2 (en) 2016-01-29 2019-08-13 Microjet Technology Co., Ltd. Miniature pneumatic device
US10388850B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Piezoelectric actuator
US10388849B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Piezoelectric actuator
US10385838B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Miniature fluid control device
US10451051B2 (en) 2016-01-29 2019-10-22 Microjet Technology Co., Ltd. Miniature pneumatic device
US10487820B2 (en) 2016-01-29 2019-11-26 Microjet Technology Co., Ltd. Miniature pneumatic device
US10487821B2 (en) 2016-01-29 2019-11-26 Microjet Technology Co., Ltd. Miniature fluid control device
US10529911B2 (en) 2016-01-29 2020-01-07 Microjet Technology Co., Ltd. Piezoelectric actuator
US10584695B2 (en) 2016-01-29 2020-03-10 Microjet Technology Co., Ltd. Miniature fluid control device
US10615329B2 (en) 2016-01-29 2020-04-07 Microjet Technology Co., Ltd. Piezoelectric actuator
US10655620B2 (en) 2016-11-10 2020-05-19 Microjet Technology Co., Ltd. Miniature fluid control device
US10683861B2 (en) 2016-11-10 2020-06-16 Microjet Technology Co., Ltd. Miniature pneumatic device
US10746169B2 (en) 2016-11-10 2020-08-18 Microjet Technology Co., Ltd. Miniature pneumatic device
US11530696B2 (en) 2017-01-13 2022-12-20 Microjet Technology Co., Ltd. Piezoelectric motor having a main body structured as a polygonal prism

Cited By (23)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10487821B2 (en) 2016-01-29 2019-11-26 Microjet Technology Co., Ltd. Miniature fluid control device
TWI690656B (en) * 2016-01-29 2020-04-11 研能科技股份有限公司 Actuator
US9976673B2 (en) 2016-01-29 2018-05-22 Microjet Technology Co., Ltd. Miniature fluid control device
US10371136B2 (en) 2016-01-29 2019-08-06 Microjet Technology Co., Ltd. Miniature pneumatic device
US10378529B2 (en) 2016-01-29 2019-08-13 Microjet Technology Co., Ltd. Miniature pneumatic device
US10388850B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Piezoelectric actuator
US10388849B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Piezoelectric actuator
US10385838B2 (en) 2016-01-29 2019-08-20 Microjet Technology Co., Ltd. Miniature fluid control device
US10451051B2 (en) 2016-01-29 2019-10-22 Microjet Technology Co., Ltd. Miniature pneumatic device
US10529911B2 (en) 2016-01-29 2020-01-07 Microjet Technology Co., Ltd. Piezoelectric actuator
TWI633239B (en) * 2016-01-29 2018-08-21 研能科技股份有限公司 Micro-gas pressure driving apparatus
TWI679346B (en) * 2016-01-29 2019-12-11 研能科技股份有限公司 Micro-gas pressure driving apparatus
US10487820B2 (en) 2016-01-29 2019-11-26 Microjet Technology Co., Ltd. Miniature pneumatic device
US10584695B2 (en) 2016-01-29 2020-03-10 Microjet Technology Co., Ltd. Miniature fluid control device
TWI689663B (en) * 2016-01-29 2020-04-01 研能科技股份有限公司 Micro-fluid control device
US10615329B2 (en) 2016-01-29 2020-04-07 Microjet Technology Co., Ltd. Piezoelectric actuator
TWI722012B (en) * 2016-01-29 2021-03-21 研能科技股份有限公司 Actuator
TWI696757B (en) * 2016-01-29 2020-06-21 研能科技股份有限公司 Micro-fluid control device
US10683861B2 (en) 2016-11-10 2020-06-16 Microjet Technology Co., Ltd. Miniature pneumatic device
US10655620B2 (en) 2016-11-10 2020-05-19 Microjet Technology Co., Ltd. Miniature fluid control device
US10746169B2 (en) 2016-11-10 2020-08-18 Microjet Technology Co., Ltd. Miniature pneumatic device
CN108302019A (en) * 2017-01-13 2018-07-20 研能科技股份有限公司 Air motor
US11530696B2 (en) 2017-01-13 2022-12-20 Microjet Technology Co., Ltd. Piezoelectric motor having a main body structured as a polygonal prism

Similar Documents

Publication Publication Date Title
TWI552838B (en) Micro-gas pressure driving apparatus
TWM465471U (en) Micro-gas transmission apparatus
TWM467740U (en) Micro-gas pressure driving apparatus
TWI553230B (en) Micro-gas pressure driving apparatus
TWI539105B (en) Micro-valve device
TWM529794U (en) Micro pneumatic driving apparatus
TWM481312U (en) Micro-gas pressure driving apparatus
TWI602996B (en) Actuator
TWI681120B (en) Micro gas driving apparatus
TWM528306U (en) Micro-valve device
TWM530883U (en) Piezoelectric actuator
TWI625462B (en) Micro-gas pressure driving apparatus
TWI626374B (en) Micro-fluid control device
TWI636189B (en) Micro-air control device
TWM565241U (en) Micro gas driving apparatus
TW201500668A (en) Micro-gas transmission apparatus
TWM529698U (en) Micro-gas transmission apparatus
TWM465472U (en) Micro-valve device
TWM540931U (en) Micro-gas pressure driving apparatus
TWM540933U (en) Micro-gas pressure driving apparatus
TWI681121B (en) Micro gas driving apparatus
TWI620887B (en) Micro-valve device
TWM565240U (en) Micro gas driving apparatus
TWM532530U (en) Miniature fluid control device
CN211500944U (en) Miniature pneumatic power device

Legal Events

Date Code Title Description
MM4K Annulment or lapse of a utility model due to non-payment of fees