CA2077436A1 - Squeeze bottle foam dispenser with threshold pressure valve - Google Patents

Abstract

The invention relates to foamable liquid dispensers of the type where foamable liquid and air are mixed. The problem associated with foam dispensers is the inconsistency in the foams characteristics when dispensed throughout a range of manual squeeze conditions. The foamer includes a squeeze bottle (10) and a device (20, 30) for simultaneously restricting flow of the compressible fluid (130) and incompressible fluid (140) until a predetermined threshold pressure is developed within the bottle by manual deformation thereof. Thus, foam (170) is not dispensed from the bottle until a pressure is developed within the bottle sufficient to produce a desirable foam.

Description

WO glJl4648 P~/VS91/al14~8

2 ~ 7 7 ~
SQUEEZE BOTTLE FOAM DISPENSER WXTH THRESHOLD PRESSURE VALVE

E~L~g~ .
- The present invention rèlates t o l~quid dispensers, and more particularly.~o foamable liqu1d d)spensers, wherein air and a -- foa~able l iquid from within the dispenser are mixed to generate a - 5foam. Even more partkularly, ~the presènt lnvention relates to such d~spensers which àre of the hand held squeeze bottle type.

Foa~ may be techn kally defined as a physical mixture of a compressible fluid and an incompressible flutd in such a manner that bubbles are formed. The degree of m~x~ng and work put into the : system determines the size and dispersion of bubbles.; A lather is a - specif1c form of foam w~th uniformly -small bubbles that is recognized for -its penetrat~on and cleaning abil~ty on soiled surfaces.-:-Lathering ~:generally- requir~s considerable mechanical work~ng of;a foamable mater~al. For example, a bar of soap or liquid soap can be mixed with water in the hands and worked for 10 seconds or so`to pro~uce an effective lath@r.
`:~ Alt~rnat~ves to ~anùilly ~worklng bar and liquid soaps may : ' - ;`becbme~'populàr;~`beeausè-`o~ the -eonveliience offerèdi~in reducing the 20 ~~t~me'land :energy ~required to ~gëneràte i làther: ~Aerosol foam generators, fcr exa~ple, m~x a propeillant wlth a foimable l~quid to produce a`rich'~oam.` -Hwéve`r, àerosols are increa ingly unpopular beéause''of`thétr eost and nëgative environmentàl impact.
Another, morè cost effëct~vé, alternativè t~ ~enerating and 25 -- dispens~ng a~oà~~3isit'o1!use'3~hand~hèid^~squéèzet~`b~o`ttl`e dl 7 ' Inexpèns'ivë` sqa2eze-bottle;foam ~isp`ènsèrs have been deveioped by a ..r;~ ' nu`m~èi~ nd1v~dlJals. `~ Squeeze-bottie 'fo2~ers; such as those described in U.S. Patent No. 3,422,993 to Boeh0 ét~al., U.S. Patent No.i 3,-93i,i6i~to7tlright, U.S;i`-Patent 3no.~ 4,018,364 to ~right, and : ...;..~.30.v U.S.~ Pi~ent No. !4,531`7659 to Wright;~ use hànd~squeez~ng foree an~ a ~ 3 ; -b~ ;1`;nJ aef~ablë~5~s~quee~e3sbot~lè~ r~x a~r w~j~th-~,a~ fOa~a~fè~ qù d id ' Jf ` ~ ~ 1 t~ ~d ` h "!JJ f ^~ r~` thi~ ~ ' `'; t i ~C~ ~th '~ ugh~ 'à !`poro`us ` homogeni2er to generate smal l bubbl es .

WO 91/14648 PCI/US91/0148~
207743~ ^2- t, Unfortunately9 currently existing squeeze bottle foam dispensers have several drawbacks. The mDst troubling drawback involves in~onsistency in the foam's characteristics. One reason for foam inconsistency is that some individuals squeeze the foam dispensers with a great deal of force which results in a high squeeze rate and high bottle pressure while others squeeze more gingerly resulting in a relatively low squeeze rate and bottle pressure. This variation in the squeeze rate and the pressure developed within the bottle results in variation in the consistency and overall quality of the foam dispensed. As a result a poor runny foam is frequently produced rather than the desired lather.
Additionally, there ar~ several drawbacks which are a direct result of the storage and operation of current squeeze bottle fo2m dispensers in an upright orientation. The upright orientation necessitates spouts which extend horizontally or downwardly beeause foam is normally dispensed into an upward-facing palm. These spouts have a eertain length. Often a eonsiderable amount of foam remains throughout the length of the spout after dispensing and condenses in time. This condensate either drips out of the spout as a liquid or forms a residue which gradually plugs up the spout. Other pnoblems which result from the upright operating and storage orientation include the inability to dispense a foam if the bnttle is tilted ; ~ . such that ~he diptube,is no longeris!~bmerged9 and the difficulty in dispensing any foamable liquid loc~ted below the diptube as the bottle becomes empty. , , ~ Q~EÇ~_9~ INYENTION
It is a princ~ple object of the present invention, therefore, ~to provid~ a hand held squeeze bottle foamer.with improved foam ; sonsistency throughout the range of manual squeeze;conditions.
. ~ is a further object of-th2~ presQnt invention is to produee a foam which is as :close to the.wetness and richness of lather as . possible~
.. .. .. ~ .It.ls likewise~ an objeet of..the present invention~ ~o provide a -? dispenser that~is both st,ored and used in an~lnverted orientatinn;
~i 35 thereby;,~avoiding the r,eauirement~ pf a;,,spout wh,ich,minimizes the - ~ 2~ . messiness .associated with ;foam-being !eft in,Jthe, spcut after dispensing. ,-~

~, WO 91/14648 PC~/US91/01488 :, ~3~ 2~37l~3~
It is an add;tional object of the present invention to provide a dispenser that is used in the inverted ori~ntation; thereby minimizing the amount of liquid in the bottle that can not be removed as a high quality foam.
5It is also an object of the present invention to accomplish the aforementi oned objecti ves at nli nimal cost .
SUMMARY OF THE INVENTION
In accordance with one aspect of the present invention there is provided a squeeze bottle foam dispenser. This dispenser includes a manually d~formable bottle which is adapted to contain a compressible fluid in a head space and an incompressiblP foamable fluid. The bottle has an vpening located therein. Inserted into the opening in the bottle is a housing which has an incompressible fluid passage, a compressible fluid passage and a dispensing passage. A m@ans is int~rposed between the dispensing passage and the incompressible and compressible fluid passages which simultaneously restricts flow from the incompressible fluid passage and the compressible fluid passage to the dispensing passage until a predetermined threshold pressure is developed within the bottle by the manual deformation thereof. The dispenser also has a means for ~ converting the mixture of fluids in the dispensing passage to a foam . prior to exiting the dispensing passage of the hw s~ng.
lh55~ 55LQF THF D MWINGS`
: Figure 1 .133s ~an exploded eleval;ion~`view of a squeeze bottle 25... foamer of the present invention; ` ~ ?~' .. Figure 2 is an exploded eleYation view of the housing and its - - relat~d components used in the squeeze bottle foamer of Figure l;
Figure 3 is :an enlarged end !view of~the :housing of Fiyure 2 showing the~inner end-of~the housin~, '; ; '~ t~ ' - , 30 ;3 '`- Figure 4 is bottom plan vi~w of th~'sqùeezeibottle foamer of :~ ~...Figure 1; .1.-.;3 ~ r ~ r tl ~.Figure-l5sis ~ oross-sectional ~levation vièw~of the squeeze : - : bottle foamer of Figure-I, taken through line;5-5 of Figure 4; and F19ure 6 ;is a .lcross-sectional elevation view similar to Figure 35 5: with the closlJre removed rand the squeéze bottiê ~!foamer~ in the t operating"condition. ~, r,~ t-:~ ;t ~

In a particularly preferred embodiment shown in Figure l, the , ~. .,... ~ -;; . ,,. . :.
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, ,, , . , , ,. . :, WO 91/14li48 PCI'/US91/0148 207743~ present invention is a hand held squeez~ bottle foamer, indicated generally as 15, fur housing a compressible fluid and an incompressible fluid, and dispensing a mixture of these fluids as a foam. The foamer 15 of the preferred embodiment consists essen~ially of a squeeze bottle 10, a housing 20 and a closure 14.
The squeeze bottle 10 is a preferably oval bottle 10 with a rounded bottDm and manually deformable side walls. Centered on the bottle 10 is an Pxternally threaded finish with a cylindrical inside surface 12. The inside surface 12 of the finish of the bottle 10 is adapted for receiving the flanged foam generator housing 20, preferably by means ' of a fluid-tight interference fit.
Alternatively, attachment of the housing 20 to the surface 12 of the bottle 10 may be achieved by a threading means in order that the housing 20 might be removable from the bottle 10 for liquid refill purposes. In any event, when the flexible side walls of the bottle 10 are squeezed to pressurize the inside of bottle 10, the foam generator .housing 20 remains affixed to the bottle 10 in a leak-tight manner. ; :
In the preferred e~bodiment sf the present invent;on, the bottle 10 is fitted with the threaded closure 14. The threaded closure 14 preferably has a flange 16 at its outen end. This flange 16 is preferably circular in shape with a flat face perpendicular to the axis of,then,finish.of~the,bottle 10. The rounded bottom of the bottle 10,..encourages.:storage of the .foam2r ,15 in its intended inverted orientation on the flange 16 of the closure 14 when not in ., ~ .. use.-~Alternativelyj;a larger..diameter finish-on the bottle 10 mayserve as the.inverted orientation support so,;.that-the-closure 14 is needed.only for sealing t,he,bot~le 10 during transport, for example.
.- . . ~
Figure 2 illustrates~,the assembly of,the-foam generator housing 30` ~20 of,-the~cprefer,red .embodiment.:J..-The housing' 20 has..:several components attached thereto including foam : homogenizer 50j a diaphragm 609-a piston~-70,~la--spring.BO,Ia plug,90, a diptube 100, ,. ,~. ~,.and a checkball.~110.~ .These components are preferably received .
. witbin-.several,,bnres.located within the housing 20. Fxtending from 35~3.~ the,f,langed-en,d~of the housing 20:is a relatively ,large`stepped bore 22 offset from the central aXiC of..the;~housing~ 20. At the non-flanged~ end of ~the .housing 20 is a bore 28 which has a : . .. .. . : , . . .: . - ; .
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W O 91/1464~ PCT/US91tO1488 :: -5-preferably flat bottom surfacQ 30, substantially perpendicu7ar to the center 1ine of the bore 28. The flat bottom bore 28 communicates with the stepped bore 22 through a relatively small concentric bore 40, The st~pped bore 22 and the relatively small bore 40 in combination form a dispensing passage.
A means for forming foam ts received within the stepped bore 22 and is supported by the shoulder 26 of the bore ~2. The means of the preferred embodiment is a homogenizer 50~ which includes 3 porous screens 52 spaced apart by two spacer rings 54 and a final 0 ring 56. Each spacer 54 is an annular ring which is adaptPd to hold the edges of the screens 52. The internal diameter of the final ring 56 is preferably smaller than the internal diameter of the spacers 54. The spacers 54 and the screens 52 are secured in place against the shoulder 26 by the final ring 56, which is connected to the stepped bore 22 preferably by an interference fit. Thus, the homogenizer 50 is held between the shoulder 26 an~ the final ring - 56 . Al ternati vely, the homogenizer 50 can have as many screens 52 as desired or as few as une. These screens 52 may also be placed in face-to-face relationship without the spacers therebetween. Even some eombination of spaced and adjacent screens of varying sizes would be acceptable.
The flat bottom bore 28 receives the diaphragm 60, the piston 70, the spring 80, and the plug 90. : The diaphragm -60 is a thin flexible circular diaphragm 60. The diaphragm 60 is assembled into the foam generator housing 20 against the flat bottom surface 30 : (seen best in Figure 3) of the bore 28. ; A eylindrical piston 70, is - - inskalled behind the-flexible diaphragm 60 with a flat surface 72 against the diaphragm 60. This piston-70 has an annular wall 74 . - ~ depending from the circular horizontal wall with i` flit surface 72.
A helical compression spring 80 fits~loosely within the annular wall . 74 of th~ piston 70.-~ Y'''''~
The cylindrical plug 90 s~pports the other end of the helical - . - compression spring 80 such that it is pre-loaded to press the piston ~ ~ 70 and consequently,~-!the'diaphragm 60,~against the flat surface 30 .35:. of the flat bottum bore-28 creatingia valve. The plug 93 has a - shape similar to that-of:the~piston-70, ilthough thë inner diameter . of its annular-wall 92 is slightly greater than the outer diameter ... . .... . . ..

. . , -, . , --, , WO 91/146q8 PCr/ll59~/01~8.P7--6- f`;
7 a~3 6 of the annular wall 74 of the piston 70. Consequently, the piston 2~7 70 slides freely wi$hin the annular wall 92 of the plug 90. When assembled, the annular surfaoe 94 of the plug 90 presses against the peripheral edge of the diaphragm 60 to secure it to the flat surface 30. The plug 90 is connected to the flat bottom bore 28 preferably by a fluid-tight interference fit. In addition to holding the diaphragm 6n in plaoe this configuration seals pistsn 70 from the contents of the foamer lSo Alternatives to the spring 80 arrangement include: the peripheral clamping of the diaphragm 60 below the flat surface 30 so that the diaphr~gm 60 is stretched over the flat surface 30; doming the surface 30 so that again the diaphragm 60 is stretched over it; or simply using a thick diaphragm 60 that s~als the sur~ace 30 by virtue of its rigidity.
Next to the flat.bottom bore 28 is a substantially parallel 45-countersink bore 42. The countersink bore 42 receives a checkball 110 and a diptube 100. The diptube I00 is secured to the coun~ersink bore 42 preferably by a fluid tight interferenoe fit.
The 45~-taper of the countersink bore 42 serves as the seat for the checkball 110 such that a one way valve is created. ~The spherical checkball 110 is placed in the countersink bore 42 prior to the insertion of the diptube 100 into the foam yenerating housing 20.
The diptube 100 has a passage 102 extending through its entire length. The.tip of the diptube lOO..which is inserted into the ..... ...countersink bore 42 has a.notch 104. Thè notch 104 permits air to -25 pass from a ~vent passage 24~through l;he passage 102 in the diptube . 100 when the checkball llO.rests against -the diptube 100. A hole . 106 extends through one wall of the d~ptubei 100 near the notched end - of; the ;diptube 100. When. diptube -:100 is inserted into the :- j; jcountersink ,bore-42 to the--intended -d pth and with .the intended r ;30~ - or~entation, the;hole-106 lines up with compressible fluid passage 32. The outer portion of the compressible -fluid passage 32 is ~t `~ -bl~ked~by~the~diptube -100.~
` `,.; f-~. Concentric-with the countersink bore 42 is an air vent passage - i- ;24 which extends from the tapered end of the countersink bore 42 and ;I ~35,.~jjexits out~.the side of the~flange--of the.housing 20. The exit of the . ....;,~,; ..~r,vent passage.24 is-pre~er?bly located well away from the exit of the .; ., ~.foam dispensing passage. -In order to vent airito.the`bottle 10 when .. , , . , . , .. ... , .,, , . . , . . ~

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W ~ 9Itl~6~8 PCT/~S91/Olq88 ,~. . ~7~ 2~77~36 the closure 14 is installed, a grooYe 18 in the closure 14, shown in Figure 1, connects hole 24 to the ambient air outside of the foamer 15.
Figures 2 and 3 together illustrate additional features of the foam generator-housing 20. The flat bottom surface 30 of bore 28 has a 240~ radial annular grQove 34 which is the vertic~l section of the bore 32 which is also the terminal end of the bore 32 which serves as a compressible fluid passage. When the foamer 15 is in the dispensing orientation and mode, this.compressibl~ fluid passage o 32 communicates the compress1ble fluid region within the foamer 1~
with ~he flat bottom bore 28. An additional bore 38 serves as an incompressible fluid passage and when the foamer 15 is in the dispensing orientation and mode, this incompressible fluid passage 38 communicates the incompressible fluid region within the foamer 15 with ~he flat bottom bore 28. The radial annular groove 34 at the terminal end of the comprcssible fluid passag2 38 in surface 30, shown in Figure 39 and the terminal end of the incompressible fluid passage 33 are located inwardly of the annular clamping area of surface 94 so that fluid pressure through the passages 32 and 38 20 will lift the diaphragm 60. Additionally, the originating end of the fluid passages 32 and:38 exit the housing 20 an a~ial distance from the flange such that they are inside the bottle 10 beyond the ; " ~ . finish,sur~aoe 12~when the $oamed generator.housing 20 is installed.
. This configuration allows these passages.32 and 38 to pass their respective fluids out of the foamer 15 through. the dispensing passage.; ~.,: ... ~.. -.. ~- :. ~ ` ` :` :-- - Referring now ,to Figures 4 and 5, the foamer lS contains an incompressible fluid 140 which is preferably a foamable liquid and a compressible fluid~;l30~which~istpreferably-air,-i~rapped in the head 0 ,j space~of^,the~bottle 10. -The`foamer.:15.:;is;shown ~in the.preferred storage posit~on,~in~erted and.resting on the:.flat surface 16 of the ~ . closure{l4. ~The.compress~ble fluid 130(:and the incompressible fluid .î .. . ..~.140 are both,prevented.from discharging:from .~henfoamer 1~ by the -.;.,J~ spring ~80 ~which presses:e`the rpiston :'!70, i;and~ conse~uently, the 5-~ diaphragm 60 against~thecs~rface~.~O.~. PriJr.to.~op~iration, the fluids 130 and 140 .aremin;;.communication;with the~tdiaphragm 60~ The . ,..incumpressible:fluid-140i..~si,in communication.via the incompressible .~.. . .. .
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WO 91/14648 PCr/US91/0148 7 ~3 ~ fluid passage 38 and the compressible fluid is in commun;cation via ~7 the diptube 100, diptube hole 106 and the compressible fluid passage 32.
Referring to Figure 67 the foamer is operàted by removing the closure 14 and manually compressing the side walls of the bottle lO.
The compression causes an increase in pressure within the bottle 10.
Since the cheekball 110 ~s he'ld by gravity against its 45 tapered seat of the countersink bore 42 creating a seal, the pressure ,. increases within the bottle 10 until a threshold pressure is reached lo within the foamer 15. :Neither the compressible fluid 130 nor the incompressible fluid 140 can pass to the bore 40 until enough pressure is ~enerated in the squeeze bottle 10 to cause the diaphragm 60 to be l;fted off the surface 30. Once the threshold pressure is reached the diaphragm 60 is forced away from the surface 30 which allows the fluids 130 and 140 to simultaneously exit the foamer 15 through the dispensing passage.
The squeeze bottle foamer 15 with the closure 14 removed is shown in its squeezed condition in Figure 6, whereby foam is being . . discharged. The pressure developed inside the bottle 10 is sreater 20 than the threshold pressure. Therefore, the compressible fluid 130 in radial annu~ar groove 34 and the incompressible fluid 140 in the ; ,., incompressible fluid ;passage 38 generate sufficient force to overcome~the pre-load of the spring 80,~ thereby lifting diaphragm 60 ~away from the ~surface 30.~The cross-sectional ~'area of the incompressible fluid!passage 38 and the radial annular groove 34 combined, times the pressure developed ~nside bottle'10 equals the lifting.foroe. :-In ~the preferred ~embodiment, the cross-sectional area~ofithe compressible fluid 130 pressing un thc diaphragm 60 via he radial annular~groove'34.is,làrger-'thàn thè~cross-sectional area o 30-,of-ithe ,incompressible,i-flu'id 140 pressing':on the~ diaphragm 60.
Consequently,~ the,~compressible fluid 130 presses 'upon'the diaphragm ~;;J'ia o.r~JQ60,iwith more- force' than''~theiiincompressible -fluid;140. This helps t :~.insure.theliproper:ratio of~compressible`fluid ~130~:to'~incompressible ~ ,;c;i~luid 140.in.the resultingi*oam. ~The ratio of-~.these-cross-sect~onal ..~b~s~ L~l~35 tareas~can~be changed~to accommodate :various:incompressible fluids:or

3.create;foams with various~charac~erist~cs. ~ ~ ? !.. s ~ ~nA~ I
In~i"';~ ";~"'1;7 ;.'The preferred~,~otal pre-lo'ad.force-pressing 'upon ;the diaphragm - .. . . .. . ~. . ,-., ~ ,.

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W ~ 91/14i6~ Pi~T/~91/01488 c -9- - 2~77~3~
60 by the spring 80 ranges from .01 to .10 pounds, and even morei preferably from .04 to .06 pciunds. This force requires a threshold pressur? of preferably from about .26 PSI to aL~iout 2.6 PSI and even more preferably from about 1.04 PSI to abcut 1.56 PSI to be developed within the bottle 10 before any fluid will be dispensed.
. It is this threshold condition which producEs the important benefit of a substantlally constant density foam through the squeeze stroke.
Without thei threshold pressure, compressible fluid 130 and incompressible fluid 140 could dribble through the foam homogenizer o 50i with low initial squeeze pressure produciing a heavy, wet, runny foam, while .near the end of the stroke under a higher squeeze pressure9 a light, dry preferred density foam would be produced.
Thii ~hreshold pressure reduces the variation.in pressure at which foam will :be produced, and therefore, it reduces:the variation in the foam quality.
When the foamer 15 is no longer squee~ed, the spring 80 forc2s the diaphragm 60 to return against the flat surface 30 of bore 28 and foam generation is discontinued. When the flexible sidewalls of the bottle 10 are released,-their molded-in memory provides a force ~o return them to their original non-squeezed positioin. In order to return, the fluid~ diseharged as foam must be replaced. Both compressible 130 and incompressible 140 fluids were discharged, but air;is ithei.pref@rred replacement: fluid becausiE..of-:its presumed . immediate availabil.ity. Therefore, the fo`amer 15~is~vented to the ' 25 atmosphere through the one,way valve created by the checkball 110 - .; . and.the 45-.taper .of countersink bore:. 42.- .The::suction crea$ed inside the bottle ~10 by -the force of the flexible. sidewalls lifts ..... checkball .llO from its seat and permits air to enter the foamEr 15 ~.via vent passage 24-:.and compressible borer42~The.notch 104 in the .. - 30 diptubei 110-prevents:the checkball 110:from blocking.the passage 102 .-. -through:the diptube,110u. Thus, air passes checkball-~110 and passas ~,7. through the diptube:-passage 102,to ~the: headtspace ;130, thereby 3ril~placing the~discha~9ed-lflu~lds~ r~
;r~o~ After:use~of the preferrèd embodiment of.the current invention, ~ 35 .iany.foam that!~.had ioccupied.i.theidispensing-passage would gradually .'`J''''~ i.^ }icondense ~to? fnrmi~liquid~ii The -closure- 14 seals ;ithe` dispensing ' passage so .that-;such liquid;~cinnot-~drip out ;betweên~ dispensing ' .. 1, .. . .
:
, , , . - , , i .
. i, ..~.. .

Wl~) 91/146~i8 P~r/~9l/0148 6opera~ions. Meanwhile, air may enter the foamer 15 to replenish the a 7 7 4 3 head space by passing throu~h the groov~ 18 in the closure 14, through the vent passage 24 in the housing 20, past the checkball 1109 through the diptube 100 and in~o the head space.
5 Alternatively, the bottle 10 sidewalls would have enou~h molded-in memory to create a force sufficient to replenish the head space before the closure 14 can be replaced, thereby eliminating the need for the groove 18 in the closure 14.
If the foamer lS wer~ inadvertently tilted or turned upright lo prior to the . in~erted ~dispensing of foam such that the incompressible fluid 140 could enter the d;ptube lD0, foam would not be immediately dispensed. When first squeezed, incompressible fluid would flow through both the incompressible fluid passage 38 and the compressible fluid passage 32. As a result, substantially no foam 15 would be produced. However, after all the incompressible fluid 140 from the diptube 100 was discharged, and compressible fluid 130 was again available in groove 34, further squeezing would result in foam being dispensed. This problem eould be solved by simply adding a .
one way check valve at the distal.encl of the diptube 100, thereby preventing the escape of compressible fluid 30 from the passage 102 when the foamer lS is tilted or kurned upright.
If the foamer 15 were ;squeezed in the upright orientation, .incompressible flu~d 140 would be .lifted ~hrough diptube 100 while compressible fluid:130 would ~flow through.-the incompressible fluid :25 passage 38.~ If ths~threshold pressure~were overeome, allowing the fluids-130 and 140 to pass to the dispensing passage, foam would be produoed. .~.HoweYer, the`: foam ~ight.; not have ; the preferred . charaeteristics. .Jhe foamiwould:likely.be wetter than that produced ' 'nJL by-the bottle~10 in an inverted~orientation because~th~ passages are : : -30 , sized i.~or, co~pressible: fluid passing~ithrough :diptube 100 and incompressible~.fluid ipassing through:::passage;-.38. ~ It is to be t~ .~ understood~that9i;as~withimany,.commercially available:-deviees, the passages could be sized in`the`'reverse mannerJtherebyiproviding the preferred operation of the.. foamer-in the upright orientation. ~ -~ 35 ~ In;the pre~erred..embodiment1of~the.presentiinvent~on, the foam -: .n~o~;: homogenizer S0 is,preferably an~assembly;of three-.375.inch diameter. Fluortex #90-70/22~879,fine ,mesh screens,;52, -made.by Tetko, Inc..

.- . . .. ;

- . ~ ,.. .

WO 9 I / 1 46418 PCI`/ US 9 1 /0 1 488 X~77~36 These screens 52 are stacked face-to-face, perpendicular to their`:, common axis and spaced .06 inches apart by the spacer rings 54. The spacer rings 54 have a .25 inch internal diameter. The final ring 56 is rigid and has a .376 inch external diameter and a .lZ5 inch internal diameter. The final ring 56 secures the screens 52 and the resilient spacer assembly into the stepped bore 22 of housing 20 by means of an interference fit. Alternatively, foam homogenizer 50 is a .376 inch diameter by .50 inch long porous polymer cylinder which is assembled into the stepped bore 22 of housing 20 and held in lo place by means`of an interference fit. '~
In either homog@nizer 50 design, compressible fluid 130 and incompressible fluid 140, preferably iir 130 and a foamable liquid 140, are mixed ahead of the homogenizer in the passage 40 and the chamber 36 immediately before the homogenizer 50. By passing this 1S mixture through the small holes of the homogenizer 50, many small air bubbles are formed from the incompressible fluid 140. It is the mixture of very small bubbles, substantially uniformly distributed in the liquid, that defines the foam.
Many factors affect bubble size and foam densit~. The liquid properties of the incompressible fluid 140, including surface tension and viscosity, are among these factors. Also a factor is - ' the volumetric ratio of' compressible 13~ to 'incompressible 140 - fluids. ' Additionally, ithe'rate of flow through the homogenizer 50 : can af~ect; bubble size ~iand'ifoam density. ;':In :the preferred : -25 embodiment 'thei'form`ula~ion of the incompres~ible'' fluid 140 in . ' ` solution-percent'is: 5%`myristoyl glutamate, 5~0`1auramide DEA, 2.5%
.. icocamido`pr'opyl betaine '(30%), 2.5Y. `sod~u'm' n-ia`uroyl sarcosinate ' (30Yo~'0.2X quatemium-15,'0.05% delaire', and 84i~75% wi`ter.
Th'e bottle`'10'~s' preferàbly''a 6'~oz.`oval containèr filled such '3~0'"'''th`at'initiail~at'least 15~'of`its'volumë`is;'hPid spàce for~air (the '' "compressible flui~l130).`~`'The`housing'20 ~s'p'refe'rably an injection molded~high density polyethylene--cylinder having a body diameter of ''' 'at le~a'st `.6`jinches:~and-'siz'ed~to~in~'er'ference -fit~thè finish of the ~/r ~ bottle 10 .t;~he hôusi ng~'2b~b'ody lèngth is'preièrably ~àt least 1.75 :` r~i` 355-~-inches for~a 1 inch iong`~bottle 'fi`h'ish.~'Thè';finish'is preferably `"'':' .125''inches''thick and~has~'a''iir~iamet'er' .'06-inch'es~les's/than the root d~ameter of'`the`'`fin`ish'treads'.' Thé closùre'~14 has an internal axial . ' , ;.';' , , .

WO 91/14648 -12- P~/US91/D148~ ~

207743~ groove 18 which is preferably .1 inches wide with a depth 003 inches deeper than the thread root depth.
The preferred dimensions of the bores in the flanged housing 20 are as follows:
Stepped bore 22: .37S inches diameter x .5 inches deep (outer section3 and .25 inches diameter x .25 inches deep (inner section);
Bore 40: .09 inches diameter x .5 inches long;
o Flat bott3m bore 28~ .375 inches diameter x .5 inches deep;
Compressible fluid passage 32: -.09 inches diameter;
Incompressible fluid . passa~e 38: .06 inches diameter (horizontal section).and .09 inches diameter x .188 inches long (vertical section);
air vent passage 24: .09 inches diameter;
Countersink bore 42: .156 inches diamet~r x .875 inches deep;
.... ........... .....and.
Radial annular groove 34: .06 inches wide x .188 inches deep.
. .
The diaphragm 69 is preferably a .005 inch thick x .375 inch diameter circle of latex rubber. The piston 70 .is preferably an injection molded low density polyethylene cylinder, .25 inches long ~,~.. ; ;,~... x!.27~inchesloutside:diameter,~with a;;.03 inch thick by .188 inch long annular wal~ 74. The spring 80 is preferably a Century Spring Corporation.model no. S-900 ;hel~ical.compression ;spring wound from : ~ stainless steel wire, with a free length of .59 inches and a spring } rate of.. 13 pounds per inch. The plug~90 is preferably an injection .~molded~high density;polye~thylene cylinderj~.438.inches long x .376 .7; ' ` inches,~,outside diameter,lwith~an annular~;wall .0475 inches thick x , 30 ~ .37~5t.inches~!ong..~.The,diptube 100 ~is~;preferably aniextr.uded low ~ density ~polyethylene -`tube~w~th ;a .156~inch~,outside,diameter x a -- `, .. 3",~,".. ,.~.3 ~1 ength ,putti,ng.j.-i,t~ 25,~.ii nches ,~from `t the-, bottle ~10 ~bottom when : .~. ^., ,;",assembled.. ~.~The~holes~102 and~the passagei,102 in~the diptube 100 ~re .", ~ .preferablx~ .09. ,i,~nches ~d7 ameter.~ .~Tbe ~diptube 100j,notch 104 is preferablyi~-.o9 ,inches .Awide~,x~.09 ,~'nches .~deep. ?.Checkball 110 is preferably~Ja~.125 inch;-,diameter.;,$phe~e made of!.stainless steel.
. ; ,.... . ,.~ It~jis;thought,that the~.inverted;jsqueeze~bottle foam dispenser ~:

' . . .. ~ :, .. ,.,. , , .: ` :

91/14~48 -13- P ~ /7S7 ~/0~ 4~8 15 of the present invention, and many of its attendant advantages, will be understood from the foregoing description; and it will be apparent that various changes may be made in form, construction, and arrangement without departing from the spirit and scope of the invention or sacriFicing all of its material advantages, the forms hereinbefore described being merely preferred or exemplary embodiments thereof. Accordingly the present invention comprises tll embodiments within the scope of the appended c7aims.
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Claims (20)

WHAT IS CLAIMED IS:

1. A foam dispenser comprising:
(a) a manually deformable bottle being adapted to contain a compressible fluid in a head space and an incompressible foamable fluid, said bottle having an opening therein;
(b) a housing inserted into said opening in said bottle, said housing having an- incompressible fluid passage, a compressible fluid passage and a dispensing passage;
(c) means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof; and (d) means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing.

2. A foam dispenser according to Claim 1 wherein said means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof comprises a diaphragm biased against a surface having the terminal end of each of said incompressible fluid passage and said compressible fluid passages located therein, and the originating end of said dispensing passage located therein; said diaphragm operating as a valve selectively allowing flow from the incompressible and compressible fluid passages to the dispensing passage only after a threshold pressure is developed within said bottle.

3. A foam dispenser according to Claim 2 wherein said means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof further comprises a piston biased against said diaphragm by a spring.

4. A foam producing dispenser according to Claim l wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

5. A foam producing dispenser according to Claim 2 wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

6. A foam producing dispenser according to Claim 3 wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

7. A foam producing dispenser according to Claim 2 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

8. A foam producing dispenser according to Claim 3 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

9. A foam producing dispenser according to Claim 4 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

10. A foam producing dispenser according to Claim 4 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens spaced apart by spacer rings.

11. A foam dispenser for operation in the inverted orientating comprising:
(a) a manually deformable bottle being adapted to contain a compressible fluid in a head space and an incompressible foamable fluid, said bottle having an opening therein;
(b) a housing inserted into said opening in said bottle, said housing having an incompressible fluid passage, a compressible fluid passage and a dispensing passage; said compressible fluid passage extending into said bottle and terminating in said head space when said bottle is in the inverted orientation;
(c) means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof; and (d) means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing.

12. A foam dispenser according to Claim 11 wherein said means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof comprises a diaphragm biased against a surface having the terminal end of each of said incompressible fluid passage and said compressible fluid passages located therein, and the originating end of said dispensing passage located therein; said diaphragm operating as a valve selectively allowing flow from the incompressible and compressible fluid passages to the dispensing passage only after a threshold pressure is developed within said bottle.

13. A foam dispenser according to Claim 12 wherein said means interposed between said dispensing passage and said incompressible and compressible fluid passages for simultaneously restricting flow from said incompressible fluid passage and said compressible fluid passage to said dispensing passage until a predetermined threshold pressure is developed within said bottle by manual deformation thereof further comprises a piston biased against said diaphragm by a spring.

14. A foam producing dispenser according to Claim 11 wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

15. A foam producing dispenser according to Claim 12 wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

16. A foam producing dispenser according to Claim 13 wherein the terminal end of the incompressible fluid passage has a smaller cross sectional area than the terminal end of the compressible fluid passage.

17. A foam producing dispenser according to Claim 12 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

18. A foam producing dispenser according to Claim 13 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

19. A foam producing dispenser according to Claim 14 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens.

20. A foam producing dispenser according to Claim 14 wherein said means for converting the mixture of fluids in said dispensing passage to a foam prior to exiting said dispensing passage of said housing comprises a multiplicity of screens spaced apart by spacer rings.