Device for mixing, foaming and dispensing liquids from separate compressed-gas containers

Information

  • Patent Grant
  • 6305578
  • Patent Number
    6,305,578
  • Date Filed
    Monday, December 18, 2000
    24 years ago
  • Date Issued
    Tuesday, October 23, 2001
    23 years ago
Abstract
A compressed gas container apparatus having at least two compressed gas containers disposed side by side, each for one foamable liquid product which contains a liquidified propellant gas, wherein both compressed gas containers are each provided with a valve; both valves are actuatable in common by a top fitting, and each valve is provided through the top fitting with a connecting conduit; the connecting conduits discharge into a mixing chamber and an expansion conduit adjoins the mixing chamber and on its end has a foam dispensing opening; wherein the connecting conduits and the mixing chamber have such small cross-sectional areas that when a product is dispensed, the products flowing through the connecting conduits and the mixing chamber remain in a liquid phase.
Description




The invention relates to a compressed gas container apparatus.




From German Patent Disclosure DE 37 29 491 Al which defines this generic type, a compressed gas container apparatus is known, having at least two compressed gas containers, disposed side by side, each for one foamable liquid product which contains a liquidfied propellant gas, wherein both compressed gas containers are each provided with a valve. Both valves are actuatable in common by a top fitting, and each valve is provided through the top fitting with a connecting conduit. The connecting conduits discharge into a mixing chamber, and an expansion conduit adjoins the mixing chamber and on its end has a foam dispensing opening.




This apparatus has the disadvantage that the dispensed foam comprising the two products is not optimally (homogeneously) mixed. This is because the products even as they emerge from the product dispensing valves foam up and are discharged in unmixed foam form into the mixing conduit through the connecting conduits. In the mixing chamber as well, the two foam components flow more or less side by side, and a passive mixing device is therefore adjoined to the mixing chamber in order to achieve further, but still inadequate, mixing of the two foam components.




The object of the invention is to create a compressed gas container apparatus of this same generic type, with which by simple provisions, substantially improved homogeneity of the two products in the dispensed foam is achieved.




This object is attained in accordance with the body of claim


1


. Further advantageous features of the invention are recited in the dependent claims.




Because the connecting conduits and the mixing chamber have such small cross-sectional areas that when a product is dispensed, the products flowing through the connecting conduits and the mixing chamber remain in a liquid phase, optimal mixing (homogeneity) of the two liquid products in the mixing chamber is achieved, and as a result, after the expansion of the mixed liquid, an optimally mixed foam results. Accordingly it is not the foam that is mixed but instead, mixing is done extremely effectively in the still-liquid phase of the products, before foaming occurs.




A further improvement in the mixing of the two liquid products is attained in that connecting conduits discharging into the mixing chamber are oriented at an angle of approximately 180° from one another.




It is advantageous if the connecting conduits have a diameter of approximately 0.6 mm and the mixing chamber has a diameter of from 0.4 to 1.2 mm—preferably approximately 0.6 mm—and as a result the products then still remain in a liquid phase and as a result are optimally mixed. This is important and advantageous in terms of the fact that products that have already foamed up can be made to mix only poorly. Optimal mixing of both products in foam form is especially important for example in foam products for hair treatment, especially a foam dye composed of one peroxide component and one colorant component, since the quality of the dye product depends on the quality of the mixed products.




By means of an impact part disposed oriented toward the mixing chamber disposed in the beginning region of the expansion conduit, an additional mixing of the mixed products is achieved.




Depending on the embodiment of the impact parts (as a disk, concave, and/or with a relatively raw surface), the mixing process of the liquids can be still further optimized.




A dam chamber or an annular chamber, each of which interrupts a connecting conduit, has the function of a retention filter for solid product components (solid particles) that have formed, for instance from crystallization.




Because the mixing chamber with mixing chamber orifices is provided as an insert part into the top fitting, there is the advantage of a simple tool for producing the top fitting and the advantage of an adaptation of the cross section of the mixing chamber orifices and the mixing chamber, so that a targeted adaptation to various product viscosities and various propellant gas pressures can selectively be made.




In a further embodiment of the insert part, it is advantageously provided that the dam chamber (annular chamber) is formed by the insert part, and as a result, in addition, the required dam chamber volume can be predetermined.











The invention will be described in further detail in terms of four exemplary embodiments.




Shown are:





FIG. 1

, in a side view, an upper part of a compressed gas container apparatus in a first exemplary embodiment;





FIG. 2

, in a further side view, the apparatus of

FIG. 1

;





FIG. 3

, in a sectional view along the line III—III (FIG.


4


), a connecting part;





FIG. 4

, in a plan view, the connecting part of

FIG. 3

;





FIG. 5

, in a sectional side view along the line V—V (FIG.


4


), the connecting part;





FIG. 6

, in a sectional side view, a dispenser part;





FIG. 7

, in an enlarged view, the connecting part connected to the dispenser part;





FIGS. 8 and 9

, in an enlarged detail, the connecting part of

FIGS. 3 and 4

;





FIGS. 10 and 11

, in a detail view corresponding to

FIGS. 8 and 9

, a connecting part with dam chambers;





FIGS. 12-15

, a second exemplary embodiment in various views;





FIGS. 16-21

, a third exemplary embodiment in various views; and





FIGS. 22-30

, a fourth exemplary embodiment in various views.












FIGS. 1-11

show a first exemplary embodiment of a compressed gas container apparatus


1


.

FIG. 1

shows a compressed gas container apparatus


1


with two, or selectively more, compressed gas containers


2


,


3


disposed side by side, each for one foamable liquid product


4


,


5


that contains a liquidfied propellant gas. Both compressed gas containers


2


,


3


are provided each with one valve


6


,


7


, and both valves


6


,


7


are actuatable in common by a top fitting


8


. Each valve


6


,


7


is provided through the top fitting


8


with a respective connecting conduit


9


,


10


, and the connecting conduits


9


,


10


discharge into a mixing chamber


11


. The mixing chamber


11


is adjoined by an expansion conduit


12


, which on its end has a foam dispensing opening


13


. The connecting conduits


9


,


10


and the mixing chamber


11


have such small cross-sectional areas that when a product is dispensed, the products


4


,


5


flowing through the connecting conduits


9


,


10


and the mixing chamber


11


remain in a liquid phase. The connecting conduits


9


,


10


discharging into the mixing chamber


11


are oriented approximately at an angle of 180° from one another, and as a result good mixing of both products


4


,


5


takes place in the liquid phase in the mixing chamber


11


. Approximately 0.6 mm has proved to be an optimal diameter for the connecting conduits


9


,


10


, as has a diameter of approximately 0.4 to 1.2 mm, preferably 0.6 mm, for the mixing chamber


11


. For simultaneous actuation of both valves


6


,


7


by way of the top fitting


8


, a pushbutton


14


is provided. A connecting part


15


holds the compressed gas containers


2


,


3


firmly together.




Further details can be seen in FIG.


2


. For actuating the valves


6


,


7


, the pushbutton


16


is provided with a joint


16


, and as a result, for instance by means of two protrusions


17


or rollers


18


, the top fitting


8


can be moved axially downward. A centrally disposed impact part


20


,


20


.


1


that is oriented toward the mixing chamber


11


is disposed in the beginning region


19


of the expansion conduit


12


. As a result, further mixing and incipient foaming of the two liquid products


4


,


5


take place in this beginning region


19


. A further flow of the product mixture through the mixing chamber


11


takes place via radially disposed openings


21


and then flows through the foam dispensing opening


13


to be dispensed. The impact part


20


is advantageously embodied as a disk


22


, advantageously in concave form and/or with a relatively raw surface


23


, resulting in further mixing of the two products


4


,


5


. For adjusting the expansion conduit


12


, this conduit is provided with a bellows region


24


, for example, as a result of which a transport position (indicated by reference numeral


25


) can selectively be provided. Each of the valves


6


,


7


has one axially actuatable valve peg


26


,


27


, which are each received by a respective valve peg receptacle


28


,


29


.




The mixing chamber


11


is provided with mixing chamber orifices


30


,


31


in the form of an insert part


32


in to the top fitting


8


, as is also seen from

FIGS. 3

,


4


,


5


and


7


. As seen especially well from

FIGS. 4

,


5


and


6


, the mixing conduit


11


is provided on its end with a tubular receptacle


33


for receiving a dispensing tube


34


that forms the expansion conduit


12


.




In

FIG. 6

, the dispensing tube


34


is shown as an individual part, which has the impact part


20


or the disk


22


, around which a plurality of radial openings


21


are disposed.





FIG. 7

in an enlargement shows the top fitting


8


communicating with the dispensing tube


34


, and from this drawing the function of the impact part


20


or disk


22


can be seen more clearly, as indicated by the streams shown in dashed lines. The already-mixed main stream


35


from the mixing chamber thus directly, centrally, strikes the impact part


20


(disk


22


), and is then sprayed in a broad scattering pattern


36


from the (raw) surface


23


of the impact part


20


(disk


22


), and as a result the degree of mixing is increased further. Downstream of the scattering


36


, the mixture flows through the radial openings


21


, and then foams up in the expansion conduit


12


.




Further details of the insert part


32


can be seen from

FIGS. 8 and 9

. Depending on the cross-sectional area of the mixing chamber orifices


30


,


31


, a mixture ratio of the liquid products


4


,


5


and an adaptation to various viscosities can be predetermined. For a predetermined axial position of the insert part


32


in the top fitting


8


, a groove guide


37


is provided. Depending on the predetermined angle of the axial position, both mixing chamber orifices


30


,


31


can be changed in their cross section.




A variant of an insert part


32


is shown in

FIGS. 10 and 11

in the form of the insert part


32


.


1


. Here, each of the connecting conduits


9


,


10


are interrupted by a dam chamber


38


,


39


; the dam chambers


38


,


39


are each embodied as an annular chamber


40


,


41


and communicate with the mixing chamber orifices


30


,


31


. As a result of the function of a retention filter, solid product components (solid particles


42


) can accumulate in the dam chambers


38


,


39


, thus preventing a functional hindrance from clogging. The dam chambers


38


,


39


are formed by corresponding recesses in the insert part


32


,


31


. Once again suitable groove guides


37


can be provided.




A first refinement of the first exemplary embodiment of

FIGS. 1-11

is shown as a second exemplary embodiment of a compressed gas container apparatus


1


.


1


in

FIGS. 12-15

. The special feature here is that in addition to the first exemplary embodiment, a further valve


50


upstream of the expansion conduit


12


is provided, which does not open until the two valves


6


,


7


of the compressed gas containers


2


,


3


have already opened. It is in fact not possible to preclude that if the pushbutton


14


is actuated very slowly, only a single product


4


,


5


will flow for a certain time out of the foam dispensing opening


13


, since for a certain period of time only a single valve


6


,


7


is open because of opening travel tolerances of the valves


6


,


7


. The result is that an unmixed foam is improperly dispensed; this is provided by the third valve


50


as an actual product dispensing valve


50


when both valves


6


,


7


are open, because the product dispensing valve


50


does not open until it is certain that the valves


6


,


7


on the pressure containers


2


,


3


have already opened. This is accomplished by providing that, by actuation of the pushbutton


14


.


1


, the two valves


6


,


7


are opened first, and only after that is the product dispensing valve


50


opened. This happened because an additional bolt


51


on the pushbutton


14


.


1


with delayed travel moves a tappet


52


, which presses a spring-loaded (by spring


55


) opening plate


53


open, and as a result the mixture of the liquid products


4


,


5


then flows through the metering bore


54


into the expansion conduit


12


where it foams up as an optimally mixed foam. Once the pushbutton


14


is released, the opening plate


53


first closes, and after that the valves


6


,


7


of the two compressed gas containers


2


,


3


close. The actuating travel paths of the pushbutton


14


, valves


2


,


3


and product dispensing valve


50


are adapted to one another in such a way that at any time, only a foam mixture can be removed from the foam dispensing opening


13


. The bolt


52


is sealed off in fluid-tight fashion from the outside by a sealing disk


56


.




The product dispensing valve


50


shown in

FIG. 14

is constructed more from a functional standpoint; the product dispensing valve


50


.


1


shown in

FIG. 15

is optimized for manufacture and also comprises fewer individual parts. For instance, the sealing disk


55


and the bolt


52


are combined into one part. The same is true for the opening plate


53


and the spring


55


.


1


, which has at least one flow opening


57


.




In

FIG. 16

, a third exemplary embodiment of a compressed gas container apparatus


1


.


2


is shown. Here, a top fitting


8


.


1


, a cap


64


, a product dispensing valve


50


.


2


, and an actuating pushbutton


14


.


1


form an economical structural unit, and the top fitting


8


.


1


and the cap


64


are solidly joined to one another. By manual actuation of the pushbutton


14


.


1


(FIG.


17


), first the two valves


6


,


7


are opened, and after that, by means of a fingerlike protrusion


43


on the connecting part


15


.


1


, a product dispensing valve


50


.


2


is additionally activated. As a result, mixed foam is reliably dispensed.





FIG. 17

, in a side view of

FIG. 16

, shows a swivel connection


44


between the connecting part


15


.


1


and the cap


64


, and as a result, the valves


6


,


7


and the product dispensing valve


50


.


2


can be actuated via the pushbutton


14


.


1


.




Further details can be seen from the plan view in FIG.


18


.





FIGS. 19-21

show the product dispensing valve


50


.


2


of

FIGS. 16-18

in an enlarged detail view. In

FIG. 19

, the product dispensing valve


50


.


2


is shown in the closed state.

FIG. 20

shows the product dispensing valve


50


.


2


in the open state, which is achieved in that the fingerlike protrusion


43


presses a sealing cup


45


axially into the valve


50


.


2


, thereby opening a resilient valve disk


46


. The chamber


47


that is occupied by the valve disk


46


at the same time forms a mixing chamber


11


.




A plan view on the mixing chamber


11


with the two connecting conduits


9


,


10


, but without the valve disk


46


, is shown in FIG.


21


.




A fourth exemplary embodiment of a compressed gas container apparatus


1


.


2


is shown in

FIGS. 22-30

. The two compressed gas containers


2


,


3


are each provided with one valve


6


.


1


,


7


.


1


, which have an opening stroke of approximately 0.2 mm and preferably 0.1 mm. As a result, lopsided, uneven manual actuation of the valves


6


.


1


,


7


.


1


by the pushbutton


14


is practically precluded, which thus also precludes an unmixed foam component comprising only one of the products


4


,


5


from being dispensed. By limiting the actuating stroke of the valves


6


.


1


,


7


.


1


to approximately 0.5 mm, a short actuation travel of the pushbutton


14


.


1


is also achieved. As the mixing chamber


11


, a rotational turbulence mixing chamber


6


.


1


with an impact part


20


.


1


is provided. The rotational turbulence mixing chamber


6


.


1


brings about an extreme mixing of the two liquid products


4


,


5


, and it is dimensioned such that the two liquid products


4


,


5


along with the liquidfied propellant gas component do not change over into a foam phase until they flow into the expansion conduit


12


, and at the end of the expansion conduit


12


, the completely foamed products


4


,


5


can be removed from the foam dispensing opening


13


. A riblike impact part


20


.


1


brings about further mixing of the products


4


,


5


. The top fitting


8


.


1


comprises two mirror-symmetrical halves


62


,


63


, which in the joined-together (welded) state have, all in one piece, the valve peg receptacles


28


,


29


, the connecting conduits


9


,


10


, the mixing chamber


11


or rotational turbulence mixing chamber


61


, the impact part


20


.


1


, and the expansion conduit


12


. By manual pressure on the pushbutton


14


.


1


, which is received by a cap


64


, the top fitting


8


.


1


is pressed downward, and the valves


6


.


1


,


7


.


1


are thus activated. The lower ends of the compressed gas containers


2


,


3


are held together on the lower end of the apparatus


1


.


2


by a bottom part


65


.





FIG. 23

, in an enlarged sectional view, shows one basic example of a valve


6


.


1


,


7


.


1


with a valve plate


66


; this valve has an opening stroke of 0.1 to 0.2 mm and a stroke limitation of approximately 5 mm. The valves


6


.


1


,


7


.


1


have a relatively low tolerance in terms of the opening travel, which assures fairly identical mixing proportions of the components (products


4


,


5


).





FIG. 24

shows a side view of the compressed gas container apparatus


1


.


2


of FIG.


22


.





FIG. 25

, in an enlarged plan view, shows a top fitting


8


.


1


, made of two mirror-symmetrical halves, which in the joined-together state (joined for instance by ultrasonic welding) has the valve peg receptacles


28


,


29


, the connecting conduits


9


,


10


, the mixing chamber


11


, the impact part


20


.


1


, and the expansion conduit


12


.




In

FIG. 26

, for the sake of better illustration, the two halves


62


,


63


of the top fitting


8


.


1


of

FIG. 25

are shown in perspective. The first half


62


is provided with ribs


67


, which are joined together in pressureproof fashion with corresponding grooves


68


of the second half


63


, for instance by an ultrasonic welding process.

FIG. 27

shows this connection of the two halves


62


,


63


in greater detail and in perspective in the form of a one-piece top fitting


8


.


1


.

FIG. 28

, in an enlarged detail, shows a mixing chamber


11


embodied as a turbulence mixing chamber


60


, in which the connecting conduits


9


,


10


are oriented counter to one another. The mixed product


4


,


5


flows from the turbulence mixing chamber


60


into the expansion conduit


12


and is further mixed by the impact part


20


.


1


and then changes over into the form of a foam.





FIG. 29

, in an enlarged detail, shows a mixing chamber


11


embodied as a rotational mixing chamber


61


, in which the connecting conduits


9


,


10


flow in different planes into the rotational mixing chamber


61


, thus achieves still-optimal mixing of the products


4


,


5


, because with this embodiment, additional mixing impact faces


69


,


70


are created.





FIG. 30

shows the complete compressed gas container apparatus


1


.


2


in a perspective view, with various details for the sake of better illustration.















List of Reference Numerals


























 1, 1.1-1.3




Compressed gas container apparatus







 2, 3




Compressed gas container







 4, 5




Liquid product







 6, 7; 6.1, 7.1




Valve







 8, 8.1, 8.2




Top fitting







 9, 10




Connecting conduit







11, 11.1, 11.2




Mixing chamber







12




Expansion conduit







13




Foam dispensing opening







14




Pushbutton







15




connecting part







16




Joint







17




Protrusion







18




Roller







19




Beginning region







20, 20.1




Impact part







21




Radial openings







22




Disk







23




Raw surface







24




Bellows region







25




Transport position







26, 27




Valve peg







28, 29




Valve peg receptacle







30, 31




Mixing conduit orifices







32, 32.1




Insert part







33




Tubular receptacle







34




dispensing tube







35




Main stream







36




Scattering







37




Groove guide







38, 39




Dam chamber







40, 41




Annular chamber







42




Solid particles







43




Protrusion







44




Swivel connection







45




Sealing cup







46




Valve disk







50




product dispensing valve







51




Bolt







52




Tappet







53




Orifice plate







54




Metering bore







55




Spring







56




Sealing disk







57




Flow opening







60




Turbulence mixing chamber







61




Rotational turbulence mixing








chamber







62




First half-part







63




Second half-part







64




Cap







65




Bottom part







66




Valve plate







67




Rib







68




Groove







69




Mixing impact face







70




Mixing impact face














Claims
  • 1. A compressed gas container apparatus (1), havingat least two compressed gas containers (2, 3), disposed side by side, each for one foamable liquid product (4, 5) which contains a liquefied propellant gas, wherein both compressed gas containers (2, 3) are each provided with a valve (6, 7; 6.1, 7.1), both valves (6, 7; 6.1, 7.1) are actuatable in common by a top fitting (8, 8.1), and each valve (6, 7; 6.1, 7.1) is provided through the top fitting (8, 8.1) with a connecting conduit (9, 10), the connecting conduits (9, 10) discharge into a mixing chamber (11), and an expansion conduit (12) adjoins the mixing chamber (11) and on its end has a foam dispensing opening (13), characterized in that the connecting conduits (9, 10) and the mixing chamber (11) have such small cross-sectional areas that when a product is dispensed, the products (4, 5) flowing through the connecting conduits (9, 10) and the mixing chamber (11) remain in a liquid phase.
  • 2. The apparatus of claim 1, characterized in that connecting conduits (9, 10) discharging into the mixing chamber (11) are oriented at an angle of approximately 180° from one another.
  • 3. The apparatus of claim 1, characterized in that the connecting conduits (9, 10) have a diameter of approximately 0.6 mm.
  • 4. The apparatus of claim 1, characterized in that the mixing chamber (11) has a diameter of from 0.4 to 1.2 mm, and preferably approximately 0.6 mm.
  • 5. The apparatus of claim 1, characterized in that a centrally disposed impact part (20, 20.1) that is oriented toward the mixing chamber (11) is disposed in a beginning region (19) of the expansion conduit (12).
  • 6. The apparatus of claim 5, characterized in that the impact part (20) is embodied as a disk (22).
  • 7. The apparatus of claim 6, characterized in that the impact part (20) is embodied in concave form.
  • 8. The apparatus of claim 5, characterized in that the impact part (20) is provided with a relatively raw surface (23).
  • 9. The apparatus of claim 1, characterized in that the connecting conduits (9, 10) are each interrupted by a dam chamber (38, 39).
  • 10. The apparatus of claim 9, characterized in that the dam chamber (38, 39) is embodied as an annular chamber (40, 41).
  • 11. The apparatus of claim 1, characterized in that the mixing conduit (11) with mixing conduit orifices (30, 31) is provided as an insert part (32) into the top fitting (8).
  • 12. The apparatus of claim 11, characterized in that the dam chamber (38, 39) is formed by the insert part (32.1).
  • 13. The apparatus of claim 1, characterized in that a product dispensing valve (50), which opens by actuation of a pushbutton (14) after the opening of the valves (6, 7) is disposed between the mixing conduit (11) and the expansion conduit (12).
  • 14. The apparatus of claim 1, characterized in that the valves (6.1, 7.1) have an opening stroke of approximately 0.2 mm, preferably 0.1 mm.
  • 15. The apparatus of claim 14, characterized in that the valves (6.1, 7.1) have a maximum actuating stroke of approximately 0.5 mm.
  • 16. The apparatus of claim 14, characterized in that the valves (6.1, 7.1) have a relatively low tolerance in the opening travel.
  • 17. The apparatus of claim 1, characterized in that the mixing chamber (11) is embodied as a turbulence mixing chamber (60).
  • 18. The apparatus of claim 1, characterized in that the mixing chamber (11) is embodied as a rotational turbulence mixing chamber (61).
  • 19. The apparatus of claim 1, characterized in that the top fitting (8.1) comprises two mirror-symmetrical halves (62, 63) and in the assembled state has at least two valve peg receptacles (28, 29), the connecting conduits (9, 10), the mixing chamber (11), and the expansion conduit (12).
  • 20. The apparatus of claim 1, characterized in that the products (4, 5) are intended as hair treatment products for dyeing hair.
Priority Claims (1)
Number Date Country Kind
199 08 368 Feb 1999 DE
PCT Information
Filing Document Filing Date Country Kind 102e Date 371c Date
PCT/EP00/01655 WO 00 12/18/2000 12/18/2000
Publishing Document Publishing Date Country Kind
WO00/50163 8/31/2000 WO A
US Referenced Citations (8)
Number Name Date Kind
3236457 Kennedy et al. Feb 1966
3303970 Breslau et al. Feb 1967
3451593 Dillarstone Jun 1969
3825159 Laauwe Jul 1974
5169029 Behar Dec 1992
5270014 Bauer Dec 1993
5330724 Bauman Jul 1994
5874024 Knaus Feb 1999
Foreign Referenced Citations (3)
Number Date Country
37 29 491 A Mar 1988 DE
1 302 577 A Jan 1973 GB
92 14595 A Sep 1992 WO