United States Patent 1191 Riccio 1 Dec.2, 1975 1 NON-SPITTING LIQUID DISPENSING DEVICE WITH PRESSURIZED PRODUCT SUPPLY [75] Inventor: Pasquale R. Riccio, Salem, NH.
[73] Assignee: Ciba-Geigy Corporation, Ardsley,
[22] Filed: Nov. 29, 1973 [21] Appl. No.: 419,967
[52] US. Cl 222/145; 222/193 [51] Int. Cl. B67D 5/54 [58] Field of Search 222/129, 145, 193, 398,
[56] References Cited UNITED STATES PATENTS 2,029,408 2/1936 Bramsen et al. 222/193 3,415,425 12/1968 Knight et al. 222/387 X 3,666,150 5/1972 Liljeholm... 222/453 3,741,443 6/1973 Marand 222/145 3,788,556 1/1974 Riccio 239/357 X 'IIIIAUI').
Primary Examiner-Robert B. Reeves Assistant Examiner-Joseph J. Rolla Attorney, Agent, or Firm-Wenderoth, Lind & Ponack 57 ABSTRACT A device for dispensing a spray of fine droplets of liquid in gas. The device has a dispenser body. with a nozzle opening out of the body and having a central outlet passage and lateral passages opening into the central outlet passage. The dispenser body also has a supply chamber therein to which the lateral passages are connected. A source of pressurized liquid to be 6 Claims, 3 Drawing Figures 3 1 8 "3 34 a 30 I A n 34 I): Q w ill ((3! 11 i T US. atent Dec. 2, 1975 NON-SPETTHN'G LllQUllD DlSPENSlNG DEVICE Wi'lili PRESSUREZED FRODUCT SUPPLY BACKGROUND AND PRIOR ART For many years, most of the aerosol dispensers have been the type in which a propellant is compressed in a valved container along with the product to be dispensed, so that when the valve is opened, the pressure of the propellant forces the product, mixed with the propellant, through the valve and out through a nozzle means, and because of the high pressure of the propellant, the mixed product and propellant emerge from the nozzle in spray form. Because of the high pressure,
the start of flow of the mixed propellant and product is almost instantaneous and little or no trouble is experienced because of larger drops of liquid first being ejected, followed by a fine spray. Such a difficulty will hereinafter be referred to as spitting.
In the last few years, there has been developed a type of aerosol dispenser in which the propellant is stored in the dispensing apparatus separately from the product to be dispensed, the propellant and product being mixed only upon being actually dispensed. This has enabled the dispensing by means of aerosol dispensers of products which are normally incompatible with the propellants being used when the two are stored together for any length of time. However, this type of dispenser still utilizes a propellant as the means for dispensing and atomizing the product. Occasionally, the type of device is subject to spitting.
There has recently been much discussion about the possible damaging effects of the propellants commonly used in such aerosol dispensers, such as freon gas. Where the products are not used on the human body, such as with paint or insecticide, precautions can be taken by the user so that he does not inhale the dispensed mixture of product and propellant. However, where the product is to be used on the human body or to be ingested into the human body, such as in the case of deodorant which is used directly on the body, or a breath freshner which is sprayed directly into the mouth, there is no way to avoid exposing the user to the damaging effects of the propellant.
drawback in the aerosol dispensers has led to the recent development of dispensers which use a charge of compressed air to aspirate a product from a separate product container each time the dispenser is actuated. Examples of such dispensers are found in the U.S. Pat. Nos. 3,672,545 and 3,733,010. In these dispensers, since there is no propellant used, but only compressed air, there is no danger to the user from the propellant. These devices therefore have a great potential for use in dispensing such products as medicaments, cosmetic and personal hygiene products, and the like where it is desirable that the user not be exposed to the dangers of conventional propellants. However, these devices are subject to the problem of spitting.
In addition, in U.S. application Ser. No. 496,282, filed Aug. 4, i974, which is a continuation of Ser. No. 41 1,267, filed Oct. 3 l i973, now abandon, there is dis closed a dispenser device in which at the same time as the compressed air is produced by a piston-cylinder means, pressure is also exerted on the liquid product to be dispensed, so that at the time the compressed air is released, the liquid product is supplied under pressure. A similar device is disclosed in U.S. application Ser. No. 411,265, filed Oct. 3i, 1973 now U.S. Pat. No.
2 3,878,973. These devices have made it possible to provide a spray of very fine droplets and can provide a spray with a droplet size which makes it possible to use these devices for medicaments which are to be inhaled by the user. However, the devices disclosed in both applications are also subject to the problem of spitting.
In U.S. application Ser. No. 419,966, filed Nov. 59, 1973, there is disclosed a dispenser for overcoming the problem of spitting in this type of dispenser. The structure of that dispenser, however, is somewhat complex, and requires a branched compressed air flow path and a Venturi type nozzle.
OBJECTS AND BRIEF DESCRIPTIONS OF THE INVENTION It is an object of the present invention to provide a device for dispensing a spray of liquid in compressed gas in which the problem of spitting is avoided, and the device upon actuation immediately starts to dispense a sprayof fine droplets without first ejecting larger droplets of the liquid to be dispensed, and which device has a somewhat simpler construction than prior art devices.
This object is achieved by providing a dispq sing device having a source of gas under pressure and a source of liquid to be dispensed which is also under pressure and a dispensing nozzle which has a central outlet passage and lateral passages opening into the central outlet passage from an annular mixing chamber around the nozzle. The device has a product flow path from the source of liquid under pressure which opens into the mixing chamber, and a compressed gas flow path from the source of compressed gas into the mixing chamber. By this arrangement, the liquid to be dispensed is mixed with compressed gas to a certain extent prior to its being fed into the central outlet passage of the nozzle through the lateral passage, and the ejection of large droplets at the start of the flow of compressed gas and liquid under pressure is avoided.
BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in greater detail in the following specification taken in connection with the accompanying drawings, in which:
FIG. 1 is a sectional elevation view of a dispenser according to the present invention with the parts in the rest or non-dispensing positions;
FIG. 2 is a sectional elevation view similar to FIG. 1 with the parts in the dispensing positions; and
FIG. 3 is an elevation view, on a reduced scale, of the device of FIGS. 1 and 2.
DETAILED DESCRIPTION OF THE INVENTION Referring to the figures, in adispenser body 10 is an upwardly open recess 1 1 having a cross-sectional shape complementary to the cross-sectional shape of apiston 31 of a measured dose dispenser which is a source of pressurized liquid to be dispensed and which will be described below. Thepiston 31 fits intorecess 11 in slidable relationship. Afurther recess 12 is provided in the bottom of the recess 1 l which has a cross-sectional shape complementary to the cross-sectional shape of thehollow stem portion 37 of the measured dose dispenser and which receives thehollow stem portion 37 in a substantially fluid tight fit with the end of thestem portion 37 in the bottom of therecess 12, and with the parts in the rest or non-dispensing positions, as seen in FIG. 1, with the lower end of thepiston 31 spaced above the bottom of therecess 11.
Nozzle means 13 in the form of anozzle insert 14 opens out of the side of thedispenser body 10. The nozzle insert 14- is positioned in a laterallyopening recess 16 in the dispenser body which is shaped to leave anannular mixing 17 around the nozzle insert. The nozzle insert has acentral outlet passage 14a into whichlateral passages 14b extend from themixing chamber 17. As one practical embodiment of a nozzle insert, it is possible to use the Venturi nozzle insert disclosed in US. application Ser. No. 419,966, since this is a commercially available element. However, it will be understood that the central through passage thereof performs no function in the present invention. In the specific form of the structure as shown, therecess 16 has a smaller diameter portion at the inner end and a larger diameter portion at the outer end and thenozzle insert 14 has a smaller diameter portion which fits into the smaller diameter portion of the recess but is longer than this portion is deep. The larger diameter portion of the nozzle insert is thus spaced outwardly of the bottom of the larger portion ofrecess 16 to leave themixing chamber 17. The dispenser body has a liquid product flow path therethrough in the form of a passage from therecess 12 to the mixingchamber 17 around thenozzle insert 14.
A source of gas under pressure in the form of an air compressing piston cylinder means is provided on the opposite end of thebody 10 from the measured dose dispenser, and in the embodiment disclosed comprises acylinder 18 which extends downwardly from thebody 10 and within which apiston 19 is slidably positioned.Gasket 19a seals the piston in its movement into thecylinder 18. Areturn spring 20 within thecylinder 18 urges thepiston 19 out of thecylinder 18. Opening out of the inner end of thecylinder 18 and into thebody 10 is arecess 21, and from the recess 21 a compressed air path is provided which has a vertically extendingportion 22 and a horizontal portion 24 extending to the mixingchamber 17.
Therecess 21 and theair path portions 22 and 24 comprise a compressed air flow path through thebody 10. Within therecess 21 is apoppet valve member 25 which seats on aseat 26 retained in therecess 21 by aretainer 27 which is positioned in the inner end of thecylinder 18. Avalve return spring 28 in therecess 21 holds the poppet valve on theseat 26. Anactuating pin 29 extends upwardly from thepiston 19. At the inner end of the stroke of thepiston 19 it is engaged with thepoppet valve member 25 to lift thepoppet valve member 25 from theseat 26 sufficiently far to pass compressed air into therecess 21.
The measured dose dispenser which serves in this embodiment as the source of pressurized liquid comprises a piston-cylinder means generally indicated at 30 which, in this embodiment, has apiston 31 over which acylinder 32 is slidable. Agasket 32a in the end of thepiston 31 seals against the inside surface of thecylinder 32 as the cylinder slides along the piston. Thepiston 31 is made up of anouter shell 33 within which is positioned aninner body 34. The end of theshell 33 has anaperture 33a therein, and on the inside of the shell, between the bottom thereof and the end of theinner body 34, is a firstannular sealing gasket 35. Theinner body 34 has alarger diameter recess 34a in the end toward the bottom of the shell, and has a smaller diameter bore 34b extending from the inner end of therecess 34a to the end of the piston which is within thecylinder 32.
Movably mounted within therecess 34a and bore 34b is a metering valve stem generally indicated at 36 which has a solid stem portion within therecess 34a and a hollowstern portion 37 extending from the solid stern portion out through the firstannular sealing gasket 35 and theaperture 33a in the bottom of theshell 33, the outside surface of thehollow stem portion 37 being in sea]- ing relationship with the firstannular sealing gasket 35. At the joint between thehollow stem portion 37 and the solid stern portion is aflange 38, which in the rest position of the stem, as shown in FIG. 1, rests on the firstannular gasket 35. The cross-sectional shape of the solid stem portion is such that it will move freely into thebore 34b. Around the end of the bore 3412, where it opens into thelarger diameter recess 34a, is a secondannular sealing gasket 40 through which the solid portion of the stern can move in sealing relationship therewith when thestem 36 is raised. Aspring 39 is positioned between the second annular-sealinggasket 40 and theflange 38, and urges the flange toward the firstannular sealing gasket 35.
In thehollow stem portion 37 is an aperture 37b which, in the rest position of the device as shown in FIG. 1, is below or outside the bottom of thepiston 31. In the dispensing position, this aperture is within the larger diameter recess 340.
It will be seen that thevalve stem 36 and theinner body 34 with itslarger diameter recess 34a, theannular sealing gaskets 35 and 40, and thespring 39 form a simple metering stem which is known from the aerosol dispensing art and is shown in US. Pat. No. 2,721,010.
In operation with the parts in the positions a shown in FIG. 1 and with the cylinder filled with liquid L, pressure is exerted against the top of thecylinder 32 to urge the cylinder along thepiston 31 to thereby exert pressure on the liquid L within the cylinder and within the smaller diameter bore 34b andlarger diameter recess 34a. Since thestem 36 is fixed in position inrecess 12, the pressure will move thepiston 31 down around thestem 36 against the action of thespring 39, first causing the secondannular sealing gasket 40 to move around the upper end of the solid portion of thestem 36 and seal off therecess 34a from the smaller diameter bore 34b and the interior of thecylinder 32, thus trapping a metered quantity of liquid inrecess 34a. Thereafter, further movement of thepiston 31 andcylinder 32 downwardly along thestem 36 causes the firstannular sealing gasket 35 to move past the aperture 37b so that therecess 34a is in communication with the interior of thehollow stem portion 37.
It has been found that with this construction, when the aperture 37b is placed in communication with therecess 34a, the liquid which has been trapped in therecess 34a is ejected from the hollowstern portion 37 in a squirt which has considerable force.
In the operation of the overall device, when pressure is exerted by the fingers of the user on thecylinder 32 of the measured dose dispenser and thepiston 19 of the air compressing piston cylinder means, the measured does dispenser is caused to operate to dispense a squirt of liquid through thehollow stem portion 37 into theproduct flow path 15 and into the mixingchamber 17. At the same time, air is compressed in thecylinder 18 ahead of thepiston 19. However, until thepiston 19 reaches the end of its stroke, thepoppet valve 25 remains closed. When theactuating pin 29 hits thepoppet valve 25, the poppet valve is lifted from theseat 26, as shown in FIG. 2, and the air compressed in thecylinder 18 is suddenly released to flow through the compressed air path to the mixingchamber 17 around thenozzle insert 14. The compressed air flowing into the mixingchamber 17 mixes and shears the liquid under pressure from the metered dose dispenser and this mixture flows through thelateral passages 14b and then out throughcentral outlet passage 14a of the nozzle insert. Due to this mechanical break action the liquid is immediately dispensed from the nozzle insert as a fine spray of droplets of the liquid in compressed air without there first being ejected relatively large droplets of liquid.
The particular advantage of such a source of pressurized liquid as described above is that it can simply be replaced by a filled measured does dispensing device.
In addition to dispensing only a measured dose the valve means of the measured dose dispenser acts to control the flow of the liquid productfrom the liquid supply in a simple and effective manner and independently of the air valve controlling the flow of the compressed air from the air compressing piston cylinder means.
While the metered dose dispensing device has been shown as one specific source of pressurized liquid, other sources can also be provided, such as are disclosed in US. application Ser. No. 496,282. Moreover, while the piston cylinder air pressurizing means have been described as a specific source of gas under pressure, other sources could be provided, for example, a valved conventional aerosol can containing a conventional propellant under pressure.
It will thus be seen that by a very simple change in the structure such that the gas under pressure and the liquid to be dispensed are supplied together to the supply chamber around the nozzle, the liquid is initially dispensed in the form of fine droplets, and the problems of spitting are overcome.
It is thought that the invention and its advantages will be understood from the foregoing description, and it is apparent that various changes may be made in the form, construction and arrangement of the parts without departing from the spirit and scope of the invention or sacrificing its material advantages, the form hereinbefore described and illustrated in the drawings being merely a preferred embodiment thereof.
What is claimed is:
1. A device for dispensing a spray of fine droplets of liquid in gas comprising a dispenser body, said dispenser body having a nozzle means opening out of said body and having a central outlet passage closed on the end remote from the end opening out of the nozzle means and lateral passages opening into said central outlet passage, said dispenser body having an annular mixing chamber around said central outlet passage to which said lateral passages are connected, a source of liquid to be dispensed having means for mechanically pressuring said liquid and operatively associated with said dispenser body, said dispenser body having a product flow conduit therethrough from said source of pressurized liquid to said annular mixing chamber, and a source of gas under pressure operatively associated with said body and said body having a compressed gas flow conduit therethrough separate from said product flow conduit and extending from said source of gas under pressure and opening into said annular mixing chamber at a point spaced from the point at which said produce flow conduit opens into said annular mixing chamber.
2. A device as claimed in claim 1 in which said source of liquid comprises a measured dose dispenser having a piston-cylinder means containing the liquid to be dispensed and valve means for dispensing a measured dose of the liquid when the piston-cylinder means is actuated.
3. A device as claimed in claim 1 in which said source of compressed gas comprises an air compressing piston-cylinder means having a fixed member and a movable member movable through a compressing stroke relative to the fixed member and a valve member in said compressed air flow path mormally closing said path, actuating pin means operatively associated with air compressing piston-cylinder means and said valve member for actuating said valve member to open it near the end of the compression stroke.
4. A device as claimed in claim 3 in which said source of pressurized liquid comprises a dispenser having a liquid pressurizing piston-cylinder means containing the liquid to be dispensed and valve means for dispensing an amount of the liquid when the liquid pressurizing piston-cylinder means is actuated, said air compressing piston-cylinder means being on one end of said dispenser body and the liquid pressurizing piston-cylinder means being on the other end of said dispenser body, and said nozzle opening laterally of said dispenser body, whereby pressure on the opposite ends of said device actuates both piston-cylinder means.
5. A device as claimed in claim 1 in which said annular mixing chamber is coaxial with the axis of said central outlet passage.
6. A device as claimed in claim 1 in which said product flow path and said compressed gas flow path open into said supply chamber in a direction parallel to the axis of said central outlet passage.