Patent Publication Number: US-6341732-B1

Title: Method and apparatus for maintaining control of liquid flow in a vibratory atomizing device

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to the atomization of liquids by means of a vibrating perforated member, such as a membrane or an orifice plate. More particularly the invention concerns the control of liquid flow through such orifice plate to ensure a stable and continuous atomizing operation. 
     2. Description of the Related Art 
     Vibratory atomizing devices are well known, as seen for example, in U.S. Pat. No. 5,152,456, U.S. Pat. No. 5,164,740, U.S. Pat. No. 4,632,3171 and U.S. Pat. No. 4,533,082. In general, such devices incorporate a thin plate having at least one small orifice extending therethrough and which is attached to and vibrated by a piezoelectric actuation element. An alternating voltage applied to the piezoelectric actuation element causes it to expand and contract; and this expansion and contraction produces up and down vibratory movement of the orifice plate. A liquid supply, such as a wick, transports liquid to be atomized from a reservoir to the one side of the plate so that the liquid contacts the plate in the region of its perforations. The up and down vibratory movement of the plate pumps the liquid through the orifices and ejects the liquid as aerosolized liquid particles from its upper surface. 
     One particularly efficient piezoelectric atomizing arrangement uses an annularly shaped piezoelectric actuation element having a central opening and an orifice plate that covers the central opening on the piezoelectric element. The plate extends across and somewhat beyond the central opening of the piezoelectric actuation element; and it is fixed to the element where it overlaps the region of the element around its central opening. When an alternating voltage is applied to the upper and lower sides of the piezoelectric actuation element, the element expands and contracts in a radial direction. This radial expansion and contraction increases and decreases the diameter of its central opening, which in turn forces the orifice plate to flex and bend so that its central region, which contains one or more orifices, moves up and down in a vibratory manner. 
     Preferably, the orifices are formed in the central region of the plate and this region is domed slightly. 
     A problem occurs in these piezoelectric vibratory atomizer devices in that not all of the liquid which is pumped through the perforations in the orifice plate becomes ejected from the upper surface of the plate. The liquid which is not ejected or ejected liquid which falls back on the plate remains on the upper surface of the plate and interferes with the atomizing action. Further, in the situation where the orifice plate is attached to the underside of the piezoelectric element, the liquid which is not ejected and accumulates in a well which is formed by the central opening of the piezoelectric actuator element and the underlying plate. Eventually this accumulated liquid builds up to a degree such that it damps the pumping action and decreases the output of atomized liquid particles. 
     The use of drain holes and reflux channels to drain excess ink from nozzle plates is described in U.S. Pat. No. 4,542,389 and U.S. Pat. No. 4,413,268. However, these nozzle plates neither vibrate nor do they convert radial actuator movements to up and down vibratory movements of a perforated orifice plate. Moreover, a wick is not used to transfer liquid to these nozzle plates. 
     SUMMARY OF THE INVENTION 
     In one aspect the present invention involves a novel atomizing device which comprises a generally horizontally extending plate having an elevated region adjacent a lower region and formed with at least one atomizing orifice in the elevated region and at least one drain opening in the lower region. The drain opening is substantially larger than the atomizing orifice and permits liquid to flow freely therethrough. The atomizing device also includes a vibration actuator which is connected to vibrate the plate up and down as well as a liquid conductor which is arranged to conduct liquid from a reservoir to the underside of the elevated region of the plate. The liquid which is not ejected from the atomizing orifices in the elevated region or which falls back on the plate flows down to the lower region and through the drain opening. 
     In another aspect, this invention is based on the discovery that by providing one or more openings in the vibrating plate in a region away from the atomizing orifices, but. over the upper end of the wick or other capillary type liquid conductor means, the liquid which passes down through the openings will tend to saturate the upper end of the liquid conductor means and diminish its drawing power. As a result, the liquid conductor means will stop drawing further liquid from the reservoir and will instead direct the liquid which has passed through the openings back up under the atomizing orifices in the central region of the vibrating orifice plate. This recycled liquid is re-pumped through the atomizing orifices by the continued up and down vibration of the plate and is ejected from the upper surface of the plate. 
     As the recycled liquid is atomized, the upper end of the wick or liquid conductor means becomes less saturated and it is thereby enabled to draw additional liquid up from the reservoir. 
     According to this aspect of the invention, a plate having at least one atomizing orifice is caused to vibrate while a liquid is supplied via a capillary type liquid conductor element, such as a wick, which extends from a liquid reservoir. The capillary action of the liquid conductor element causes liquid to be drawn from the reservoir and supplied to the lower side of the plate in the region of the orifice. The vibration of the plate causes the liquid to be pumped through the orifice and ejected from the other side of the plate in the form of aerosolized liquid particles. 
     The plate is also formed, in a region displaced from the atomizing orifice, with at least one larger opening through which liquid which had not been ejected from the plate or which falls back on the plate can freely flow. This larger opening is located in a position such that it directs the liquid which flows through it to the upper end of the liquid conductor element where it comes into capillary communication with the atomizing orifice on the under side of the plate. This nonejected liquid or liquid which has fallen back on the plate tends to saturate the upper end of the liquid conductor element such that it diminishes the ability of the element to draw additional liquid from the reservoir. As a result, the liquid conductor element draws less or no liquid from the reservoir and instead, by means of capillary action, directs the liquid which has passed through the openings back under the atomizing orifice in the vibrating orifice plate. This recycled liquid is re-pumped through the atomizing orifice by the vibration of the plate and is ejected from the upper surface of the plate in the form of finely divided liquid particles. 
     The returned liquid which is directed by the liquid conductor element tends to increase the saturation of the element and thereby restricts the element&#39;s ability to supply additional liquid from the reservoir, at least until the returned liquid has been re-atomized. This provides an automatic regulation effect on the liquid conductor element, which prevents flooding and waste of the liquid being atomized. 
     According to a further aspect of the invention there is provided a novel method of atomizing a liquid. This novel method comprises the steps of providing an orifice plate having at least one atomizing orifice, vibrating the plate, at least in the region of the atomizing orifice, while delivering a liquid by capillary action through a capillary type liquid conductor element extending from a liquid reservoir to a location adjacent the atomizing orifice on one side of the plate. The liquid is caused to be pumped through the atomizing orifice and ejected from the other side of the plate in the form of aerosolized liquid particles by the vibration of the plate. The liquid which has not been ejected from the plate, or which falls back on the plate, is directed to flow back down through at least one larger opening in the plate at a location displaced from the atomizing orifice. This non-ejected liquid is conveyed by capillary action back to the atomizing orifice on the one side of the plate for further atomization. Also, this non-ejected liquid acts on the liquid conductor element in a manner to restrict its ability to draw additional liquid from the reservoir until the non-ejected liquid is again pumped through the orifice and ejected from the plate. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a plan view showing a vibrator atomizing device according to one embodiment of the invention. 
     FIG. 2 is a section view taken along line  2 — 2  of FIG. 1; and 
     FIG. 3 is an enlarged fragmentary view of the region identified as FIG. 3 in FIG.  2 . 
    
    
     DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT 
     The vibratory atomizing device of FIG. 1 comprises an annularly shaped piezoelectric actuator element  10  having an inner diameter center hole  12  and an orifice plate  14  which extends across the inner diameter hole  12  on the underside of the actuator and slightly overlaps an inner region  15  of the actuator. The orifice plate  14  is fixed to the underside of the actuator  10  in the overlap region  15 . Any suitable cementing means may be used to fix the orifice plate  14  to the piezoelectric actuator element  10 ; however, in cases where the device may be used to atomize liquids which are corrosive, or aggressive in that they tend to soften certain cements, it is preferred that the orifice plate be soldered to the piezoelectric element. Also, the outer diameter of the orifice plate  14  may be as large as the outer diameter of the actuator element  10  so that it extends over the entire surface of one side of the actuator element. It should be understood that this invention also includes a construction wherein the orifice plate  14  is affixed to the upper side of the actuator  10 . 
     The piezoelectric actuator element  10  may be made from any material having piezoelectric properties which cause it to change dimensionally in a direction perpendicular to the direction of an applied electric field. Thus, in the illustrated embodiment, the piezoelectric actuator element  10  should expand and contract in a radial direction when an alternating electrical field is applied across its upper and lower surfaces. The piezoelectric actuator element  10  may, for example, be a ceramic material made from a lead zirconate titanate (PZT) or lead metaniobate (PN). In the embodiment illustrated herein, the piezoelectric actuator element has an outer diameter of about 0.382 inches and a thickness of about 0.025 inches. The size of the center hole inner diameter is about 0.177 inches. These dimensions are not critical and they are given only by way of example. The actuator element  10  is coated with an electrically conductive coating such as silver, nickel or aluminum to permit soldering of the orifice plate and electrical leads and to permit electric fields from the leads to be applied cross the actuator element. 
     The orifice plate  14  in the illustrated embodiment is about 0.250 inches in diameter and has a thickness of about 0.002 inches. The orifice plate  14  is formed with a slightly domed center region  16  and a surrounding flange region  18  which extends between the domed center region  16  and the region where the orifice plate is affixed to the actuator  10 . The domed center region  16  has a diameter of about 0.103 inches and it extends out of the plane of the orifice plate by about 0.0065 inches. The domed center region contains several (for example  85 ) small orifices  20  which have a diameter of about 0.000236 inches and which are spaced from each other by about 0.005 inches. A pair of diametrically opposed larger holes  22  are formed in the flange region  18 . These holes have a diameter of about 0.029 inches and they allow liquid to flow freely therethrough. Again, the dimensions given herein are not critical and only serve to illustrate a particular embodiment. It should also be noted that while an domed orifice plate is described herein, orifice plates of other configurations may be employed, for example, orifice plates with shapes that resemble a convoluted or corrugated diaphragm. 
     It will be noted that the doming of the center region  16 , which contains the orifices  20 , increases its up and down movement of this region so as to improve the pumping and atomizing action of the orifice plate. While the domed center region is spherical in configuration, other configurations in this region may be used. For example, the center region  16  may have a parabolic or arcuate shape. Means other than doming may be used to stiffen the center region  16 . For example, a support with spaced thickened elements, as shown in U.S. Pat. No. 5,152,456 may be used. 
     The orifice plate  14  is preferably made by electroforming with the orifices  20  and the holes  22  being formed in the electroforming process. However, the orifice plate may be made by other processes such as rolling; and the orifices and holes may be formed separately. For ease in manufacture, the center region  16  is domed after the orifices  20  have been formed in the orifice plate. 
     The orifice plate  14  is preferably made of nickel, although other materials may be used, provided that they have sufficient strength and flexibility to maintain the shape of the orifice plate while being subjected to flexing forces. Nickel-cobalt and nickel-palladium alloys may also be used. 
     The piezoelectric actuator element  10  may be supported in any suitable way which will hold it in a given position and yet not interfere with its vibration. Thus, the actuator element may be supported in a grommet type mounting (not shown). 
     The piezoelectric actuator element  10  is coated on its upper and lower surfaces with an electrically conductive coating such as silver, aluminum or nickel. As shown in FIG. 2, electrical leads  26  and  28  are soldered to the electrically conductive coatings on the upper and lower surfaces of the actuator element  10 . these leads extend from a source of alternating voltages (not shown). 
     A liquid reservoir  30 , which contains a liquid  31  to be atomized, is mounted below the actuator element  10  and the orifice plate  14 . A wick  32  extends up from within the reservoir to the underside of the orifice plate  14  so that its upper end (where it is looped over and projects up from the reservoir) lightly touches the orifice plate in the center region  16  at the orifices  20 . The upper end of the wick  32  also extends laterally so that it is directly under and is in direct liquid communication with the larger holes  22 , as shown in FIG.  3 . Actually, the wick could be annular and of a diameter larger than the domed center region  16  so that it contacts only the flange region  18  of the orifice plate. 
     The wick  32  may be made of a porous flexible material which provides good capillary action to the liquid in the reservoir  30  so as to cause the liquid to be pulled up to the underside of the membrane  14 . At the same time the wick should be sufficiently flexible that it does not exert pressure against the orifice plate  14  which would interfere with its vibratory motion. Subject to these conditions, the wick  32  may be made of any of several materials, for example, paper, nylon, cotton, polypropylene, fibreglass, etc. A preferred form of wick  32  is strand of nylon chenille yarn that is looped back on itself where it touches the orifice plate. This causes very thin fibers of the strand to extend up to the plate surface. These very thin fibers are capable of producing capillary action so as to bring liquid up to the orifice plate; however, these thin fibers do not exert any appreciable force on the plate which would interfere with its vibratory movement. 
     The portion of the upper end of the wick  32  which extends under the orifice plate  14  between the larger holes  22  and the orifices  20  places the holes and orifices in capillary communication with each other along the underside of the plate. The effect of this arrangement will be discussed hereinafter. 
     It will be appreciated that liquid conductor means other than a wick may be employed and the use of the word “wick” herein is intended to include such other capillary type liquid conductor means. 
     In operation of the atomizer, the wick  32  or other liquid conductor means, by means of capillary action, draws liquid  31  up from the reservoir  30  and into contact with the orifice plate  14  in the region of the atomizing orifices  20 . 
     At the same time, alternating electrical voltages from an external source are applied through the leads  26  and  28  to the electrically conductive coatings on the upper and lower surfaces of the actuator element  10 . This produces a piezoelectric effect in the material of the actuator element whereby the material expands and contracts in radial directions. As a result, the diameter of the center hole  12  increases and decreases in accordance with these alternating voltages. These changes in diameter are applied as radial forces on the orifice plate  14  and pushes its domed center region  16  up and down. This produces a pumping action on the liquid which was drawn up against the underside plate  14  by the wick  32 . The capillary action of the wick maintains the liquid on the underside of the orifice plate  14 ; and as a result, the liquid  31  is forced upwardly through the orifices  20  by the vibration of the plate and is ejected from the upper surface of the plate as finely divided aerosolized liquid particles into the atmosphere. 
     Not all of the liquid which is pumped through the orifices  20  is ejected; and a small amount of the liquid remains on the upper surface of the orifice plate. This non-ejected liquid flows down the sides of the domed center region  16  and into the region surrounded by the actuator center hole  12 . As a result, liquid tends to build up on the flange region  18  of the orifice plate  14  and interferes with its flexing and pumping action. 
     The present invention overcomes this problem by directing the non-ejected liquid down through the larger holes  22  and onto the upper end of the wick  32 , which as mentioned previously, extends laterally under these larger holes. The wick in turn places this non- ejected liquid into capillary communication, along the under side of the orifice plate  14 , with the atomizing orifices  20 . As a result this liquid is drawn back to the orifices  20  and is pumped back through them by the vibratory movement of the orifice plate  14  for ejection in the form of finely divided liquid particles from the upper side of the plate. 
     The liquid which passes down through the larger holes  22  tends to increase the saturation of the upper end of the wick  32  and restricts the ability of the wick to draw additional liquid up from the reservoir  30 , at least until the liquid from the larger holes has been repumped back up through the atomizing orifices  20 . At this point the upper end of the wick becomes unsaturated so that the wick can then draw additional liquid up from the reservoir. 
     It will be appreciated that the above described arrangement provides a self regulating effect which prevents flooding in the upper region of the reservoir  30 . This is important to preventing leakage and loss of liquid from the atomizer device. Also, in order for the liquid to be effectively drawn up from the reservoir  30 , the reservoir is provided with a vent opening  34  in its upper region. Because the non-ejected liquid is directed along the underside of the orifice plate  14 , it is prevented from coming into contact with, and causing plugging of, the vent opening  34 . 
     Industrial Applicability 
     The atomizer device of this invention permits liquid from a reservoir to be atomized effectively and continuously without a buildup of liquid on the atomizing element. The invention also permits the liquid which has not been ejected from the atomizer to be recycled back through the atomizer device without spilling or waste. The means by which this is accomplished is simple and economical to carry out.