The present invention relates to a dispensing assembly for dispensing a liquid, in particular a foam.
Pump assemblies to be mounted on a container containing a foamable liquid, which upon actuation provide a foam are well known in the art. For instance, U.S. Pat. No. 5,443,569 discloses such dispensing assembly, the contents of which are herein incorporated in its entirety by reference.
This known dispensing assembly comprises a liquid piston pump and an air piston pump concentrically arranged with respect to each other. The cylinders of the liquid and air pump are formed by the inner cylinder and outer cylinder of a double cylinder, respectively. The dispensing assembly further comprises a common actuation button for simultaneous actuation of the liquid pump and the air pump by manual depression of the actuation button. A liquid piston and an air piston are reciprocally movable arranged in the liquid and air cylinder and are operatively connected to the actuation button so that upon actuation of the actuation button the liquid piston and the air piston may reciprocally be moved in the liquid and air cylinder, respectively.
When the above dispensing assembly is mounted on a container containing a foamable liquid, this liquid may be drawn out of the container by actuation of the actuation button. At the same time air will be pumped by the air pump. The pump outlets of the liquid and air pump are connected to a mixing chamber where the liquid and air is mixed to a (pre)foam. The mixture of liquid and air is consequently pumped through a dispensing channel and passes one or more porous elements, for instance sieves, to form a homogeneous foam which is dispensed at a dispensing opening at the end of the dispensing channel.
Although the above pump has been shown to be very successful in the market for a variety of foamable liquids, such as soap, shampoo, dishwashing detergent and sun cream, there may still be some further improvements possible. Furthermore, since the dispensing assembly of the above type is more and more applied as a mass product there is a continuous strive for simplification, while maintaining a good foam quality.
Generally, it is desirable to dispense a desired quantity of foam per stroke of the actuation button. Further, the length of a stroke is limited for handheld foam dispensers since the actuation button is depressed by a finger while the dispensing device is held by the same hand. Due to the required diameter of the double cylinder to dispense a certain quantity of foam and the limited stroke, the neck opening of the container has to be of a certain minimum diameter to receive the double cylinder of appropriate size. In some applications it is desirable to use containers having a neck opening with a smaller diameter, while maintaining the same stroke length and the same quantity of foam dispensed per stroke. The known dispensing assembly design until now cannot fulfil these requirements on dispensing quantity and dimensions.
It is desirable to provide an alternative embodiment of a dispensing assembly being economically attractive while maintaining a good foam quality.
According to an aspect of the invention, there is provided a dispensing assembly mountable on a container for dispensing a foam, comprising:
a liquid piston pump, comprising a liquid cylinder and a liquid piston delimiting a liquid pump chamber, and a liquid inlet and a liquid outlet,
an air piston pump comprising an air cylinder and an air piston delimiting an air pump chamber, and an air inlet and an air outlet,
a common actuation button for actuation of the liquid pump and the air pump,
a dispensing channel for mixing and dispensing liquid and air pumped by the liquid and air pump, respectively, and
a securing collar for attachment of the dispensing assembly to a container.
The dispensing assembly is characterized in that said air cylinder is formed by a cylindrical skirt of said actuation button, and said air piston is at least partially formed by a cylindrical extension of said securing collar and in that a piston seal is arranged between the cylindrical extension and the skirt, said piston seal being displaceable with respect to said cylindrical extension in at least a closed position in which the piston seal provides an air tight seal between environmental air and said air pump chamber, and an open position in which introduction of air into the air pump chamber between the cylindrical extension and the skirt is possible.
The above dispensing assembly is of a relative simple and compact design. It has shown that this design may result in a dispensing assembly which has a relatively low height per dispensed volume of foam. Also, the volume of plastics material and thus the weight of the dispensing assembly per volume of dispensed volume of foam per pump stroke is relatively low.
Furthermore, by providing an air pump outside the neck portion of the container it is possible to use a neck opening of a smaller size without requiring a substantial longer stroke length or obtaining less foam per pump stroke.
As the air cylinder is formed by a cylindrical skirt of the actuation button and the air piston is formed by a cylindrical extension of the securing collar, the actuation button extends about the cylindrical extension of the securing collar. As a result, water which will flow over the actuation button will flow down the outside of the dispensing assembly without entering the dispensing assembly. Thus the dispensing assembly can easily be rinsed off under a tap without the risk of water entering the dispensing assembly. Such dispensing assembly is often referred to as a water resistant foamer. The present invention provides a compact foamer which provides water resistancy and a compact construction.
It is remarked that EP 392 238 discloses a dispensing assembly for the dispensing of foam having a piston air pump having an air cylinder formed by a skirt of the actuation button. However, this dispensing assembly is of relatively complex and voluminous design. Furthermore, in this known dispensing assembly, a piston-cylinder arrangement is provided between the air pump and the liquid pump, which is required for the introduction of air in the container to replace liquid which is pumped out of the container. The cylinder of this piston-cylinder arrangement is part of a double cylinder, the second cylinder forming a part of the liquid piston pump. In view of the above, the dispensing assembly of EP 392 238 does not provide the advantages of the dispensing assembly of the present invention.
In the dispensing assembly of the present invention, a piston seal is arranged between the cylindrical extension and the skirt, the piston seal being displaceable with respect to the cylindrical extension in at least a closed position in which the piston seal provides an air tight seal between the environmental air and the air pump chamber, and an open position in which introduction of air into the air pump chamber between the cylindrical extension and the skirt is possible. Such piston seal which opens and closes due to the actuation of the actuation button is advantageous as there is no threshold underpressure required for opening of the valve.
In an embodiment the air chamber at least partially surrounds the liquid chamber. By providing a liquid pump chamber and air pump chamber at least partially surrounding each other, the design of the foam dispensing assembly can be made more compact.
In an embodiment, the piston seal comprises a cylindrical part concentric with a longitudinal axis of said dispensing assembly. By providing a cylindric part in the piston seal the sealing surface of the piston seal can be brought at a different height than the piston sealing lips. As a result, the sealing surfaces of the air inlet valve can be brought closer to and preferably at the same level as the tilting point of the dispensing assembly, i.e. the point about which the dispensing assembly may tilt when the actuation button is not depressed in the direction of the longitudinal axis of the dispensing assembly.
In other embodiments the part concentric with a longitudinal axis of the foam dispenser may have another shape which is concentric with the longitudinal axis of the dispensing assembly, for instance be frusto-conical.
In an embodiment, the piston seal comprises a lip extending towards the longitudinal axis of said dispensing assembly and having a sealing surface which in said closed position provides a sealing engagement with an other part of said dispensing assembly having a corresponding sealing surface. The other part of said dispensing assembly is preferably a surface on the securing collar or a part fixedly connected to the securing collar. The advantage of a sealing lip extending towards the longitudinal axis of the dispensing assembly has the advantage that the sealing surface diameter is smaller than the diameter of a piston sealing part which provides a sealing connection between the piston seal and the skirt. As a result the sealing between the sealing surface of the lip and the corresponding sealing surface may be improved.
In an embodiment the lip is a flexible lip. By providing a flexible lip the sealing between the lip and the cooperating other part of the may further be improved.
Hereinafter further possible features of the compact design of the dispensing assembly of the invention will be discussed. Such features may also be applied in a foam dispensing assembly not having the displaceable piston seal. Such alternative dispensing assembly may have any suitable air inlet valve, for instance the flexible ring of the air inlet valve of EP 392 238.
In an embodiment a bottom end of the liquid cylinder does not project beyond the bottom side of the securing collar. In the case of a transparent container, the liquid cylinder in the known dispensing device is at least partially visible. The liquid cylinder of this embodiment does not have this disadvantage, while at the same time, due to the arrangement of liquid pump and air pump according to the invention, a desired quantity of foam can be dispensed per stroke while having a more compact design of the dispensing assembly which is easy to handle.
In an embodiment, a height of a part of the dispensing assembly projecting after mounting downwardly from the top end of a container is smaller than 1.5 times the maximal stroke length of the actuation button, preferably 1 times the maximal stroke length of the actuation button, or a total height of the dispensing assembly is smaller than 4.5 times the maximal stroke length of the actuation button. Such dimensions of the dispensing assembly provide a good ratio between quantity of foam dispensed per pump stroke, the stroke length and the distance from the container to the top of the actuation button. The latter distance is of importance since the actuation button is designed to be actuated by a finger of the hand holding the dispensing device. It will be clear that the reach of such finger is limited and that this should be taken into account in the design of the dispensing device. The stroke length of a hand-held dispenser having a finger-actuated actuation button lies typically between 5 and 25 mm, more typically between 10 and 20 mm. In preferred embodiments the stroke length is about 11 mm or about 15.5 mm.
It is remarked that the bottom of the liquid inlet valve is regarded to be the bottom side of the dispensing assembly, and the top side of the actuation button is regarded to be the top side of the dispensing assembly. Thus, the dip tube and a part of the connection piece for the dip tube extending downwardly from the liquid inlet valve are not taken into account in the determination of a height of the dispensing assembly.
In an embodiment, the skirt is an integral part of the actuation button and/or the cylindrical extension is an integral part of the securing collar. By making the skirt and/or cylindrical extension integral part of the actuation button, less parts are to be assembled during the manufacturing process of the dispensing assembly.
In an embodiment, the liquid cylinder is at least partially formed by a cylindrical extension of the securing collar. Such embodiment further simplifies the foamer design, wherein both the air piston an the liquid cylinder are supported and preferably are part of the securing collar.
In another embodiment, the liquid cylinder is formed by a cylindric element placed in a recess of the securing collar. Such embodiment provides also a simple design which can be made cost effectively. Such design has the further advantage that it is possible to make the cylindrical element exchangeable for another cylindrical element having the same or a different internal diameter. By exchanging the cylindrical element for an element having a different internal diameter, the quantity of liquid dispensed per pump stroke may be changed, and therewith the ratio between the quantity of liquid and quantity of air which is dispensed per pump stroke.
In an embodiment, the air outlet comprises a part which runs in the upright position of the dispensing device at least partially vertical, an upper end of the at least partially vertically running air outlet being in communication with the air pump chamber, a lower end being in communication with the dispensing channel.
By providing such vertical part in the air outlet foam or liquid present in the mixing chamber cannot flow in the air pump. This is desirable as the presence of foam and/or liquid in the air chamber may result in misfunctioning of the pump. For instance, the seal between the air piston and the air cylinder, may stick together due to solidified liquid on the seal.
In an embodiment, the dispensing assembly comprises a liquid outlet valve in said liquid outlet, wherein said liquid outlet valve comprises a valve seat and a valve member, said valve member being displaceable between a closed valve position, in which the valve member sealingly engages with said valve seat, and an open valve position, in which a gap is formed between the valve member and the valve seat, and wherein said liquid outlet valve further comprises a biasing means to bias said valve member in said closed valve position. By providing biasing means which bias the valve member in the biased position, the closure of the liquid outlet valve can be controlled more accurately. Furthermore, leakage in the up-side-down position of the dispensing assembly, for instance in a wall dispenser, may be avoided by the presence of the biasing means.
In an embodiment, the biasing means comprises one or more spring like elements arranged between the valve member and an inner wall of the dispensing channel and/or a porous element being arranged in said dispensing channel, and the spring like elements are preferably formed by one or more flexible arms fixed to said valve member.
In an embodiment the valve member is a part of an inner rod configured to limit the maximum height of the common actuation button. A known foam dispenser as for instance disclosed in U.S. Pat. No. 5,443,569 comprises a so-called inner rod. The inner rod forms a valve member for the liquid outlet valve as well as a stop member which cooperates with an annular rim which is provided on a tubular element which is arranged in the liquid chamber. The tubular element is typically fixed to the securing collar, while the valve seat is fixed to the common actuation button. As a result the inner rod comprising the valve member limits the maximum height of the common actuation button with respect to the securing collar. Such inner rod improves the sealing of the valve. In the present embodiment this sealing is further improved by the provision of biasing means on the inner rod. Such biasing means further has the advantage that the liquid outlet valve is directly and firmly closed in any position of the actuation button, when there is no longer an over pressure in the liquid pump chamber.
According to a second aspect of the invention there is provided a dispensing assembly The dispensing assembly mountable on a container for dispensing a foam, comprising:
a liquid pump,
an air pump
a common actuation button for actuation of the liquid pump and the air pump,
a dispensing channel for mixing and dispensing liquid and air pumped by the liquid and air pump, respectively, and
a securing collar for attachment of the dispensing assembly to a container, characterized in that,
the dispensing assembly comprises a sealing gasket, wherein the sealing gasket comprises a sealing part to be placed between the securing collar and the container, and a radially inwardly extending flexible part to be placed sealingly against an inner rim of the dispensing assembly, the flexible part forming an inlet valve element for aeration of the container.
By combination of the sealing gasket and the aeration inlet valve in a single element an attractive aeration valve is obtained. Furthermore, since the airflow path for the aeration may run through the space between the securing collar and the neck portion of the container, the design of the liquid pump and air pump is not importantly influenced by the requirement of an aeration air flow path. This is in contrast to many prior art dispensing assemblies in which the aeration air flow path has a large influence on the design of the liquid and/or air pump.
The embodiment of the present invention has the further advantage that since the flexible lip extends radially inwardly, i.e. substantially perpendicular to the longitudinal axis of the dispensing assembly, fluid will come to rest on the flexible lip when the container is turned upside down, therewith improving the sealing between the flexible lip and the rim of the dispensing assembly. Thus the chance on leaking of the aeration valve is therewith substantially reduced.
In an embodiment, the sealing gasket defines at least one substantially radially extending air channel, one end of the air channel being in communication with the environment, the other end being in communication with the space at the side of the radially inwardly extending flexible lip which is opposite to the interior of the container.
The air channel may for instance be formed by a hole in the sealing gasket or by grooves arranged in one or both of the abutting surfaces of the sealing gasket or the securing collar.
Further details and characteristics will now be discussed at the hand of a preferred embodiment of a dispensing assembly of the invention, whereby reference will be made to the appended drawing in which:
a and 3b show the embodiment of the sealing gasket of
a-4d show alternative embodiments of the sealing surface of the gasket of the invention.
The dispensing assembly 2 comprises a piston-type liquid pump 4, a piston-type air pump 5 and a common actuation button 6. A securing collar 7 is provided to mount the dispensing assembly 2 on the container 3. For this purpose the securing collar 7 comprises an internal screw thread which is configured to cooperate with a screw thread provided about the neck of the container. Any other type connection between dispensing assembly 2 and the container, such as a snap connection, or bayonet catch may also be used.
A sealing gasket 31 is provided between the securing collar 7 and the container 3 to provide a sealing engagement. The sealing gasket 31 comprises a flexible lip 32 extending radially inwardly. A free end of the flexible lip 32 lies sealingly against a rim 33 formed at the bottom side of the securing collar 7. An air channel 34 is provided in the sealing gasket to provide communication between the environment and the space at the side of the flexible lip 32 opposite of the interior of the container 3. When the pressure in the container 3 decreases due to liquid being pumped out of the container, air may enter the container via the air channel 34 and the flexible lip 32 which will come free from the rim 33 due to the underpressure in the container 3 to avoid that the pressure in the container will become too low which may result in deformation of the container and malfunctioning of the liquid pump 4.
The substantially horizontally extending lip 32 has the advantage that when the dispensing device 1 is turned upside down, the liquid in the container will come to rest on the flexible lip 32 and will therefore press the flexible lip 32 against the rim 33. In this way the sealing of the container is improved and leakage through the aeration channel 34 is substantially avoided. The air channel 34 is formed by a groove in the sealing gasket. The air channel 34 may also be formed by a groove in the securing collar 7 or a through-going hole in the sealing gasket 31 or the securing collar 7.
The liquid pump 4 comprises a liquid cylinder 8, and a liquid piston 9 reciprocally movable in said liquid cylinder 8. The liquid cylinder 8 and liquid piston 9 delimit a liquid pump chamber 10. The liquid pump 4 further comprises a liquid inlet 11 and a liquid pump outlet 12. The liquid inlet 11 is connected with a dip tube 30 which runs to the bottom of the interior of the container 3.
A liquid inlet valve 13 is provided in the liquid inlet 11, and a liquid outlet valve 14 is provided in the liquid outlet 12 to control the entering and departure of liquid from the liquid pump chamber 10. The liquid inlet valve 13 is a ball valve which is opened by creation of an underpressure in the liquid pump chamber 10 with respect to the pressure in the interior of the container 3 and closed by an overpressure in the liquid pump chamber 10 with respect to the pressure in the interior of the container 3. The opening and closing of the liquid outlet valve 14 is controlled by the depression and release of the actuation button 6. Such valve is known in the art and for instance described in U.S. Pat. No. 5,443,569. Any other suitable type of liquid outlet valve may also be applied.
The air pump 5 comprises an air cylinder 15 and an air piston 16 reciprocally movable in said air cylinder 15. The air cylinder 15 and air piston 16 delimit an air pump chamber 17. The air cylinder is formed by an integral cylindrical skirt of the actuation button 6. The air piston 16 is formed by an integral cylindrical extension of the securing collar 7. Such construction is advantageous since the air cylinder and piston are formed by the actuation button 6 and the securing collar 7 and thus no separate parts have to be provided.
The air pump 5 further comprises an air inlet 18 and an air outlet 19. A piston seal 20 is mounted on the air piston 16. The piston seal 20 sealingly engages the air cylinder 15 and the air piston 16, and is movable between two positions with respect to the air piston 16. In a first position as shown in
The liquid outlet 12 and air outlet 19 both end in a mixing chamber 22 which is a part of the dispensing channel 23 running from the mixing chamber 22 to a dispensing opening 24 at the other end of the dispensing channel 23.
In the shown embodiment, the dispensing channel 23 runs through the actuation button 6. In the dispensing channel 23 a foam-forming element 25 is arranged which comprises two sieves 26 and a constriction 27 between the two sieves 26. This foam-forming element 25 is provided to form or improve a foam from a liquid air mixture/foam passing the foam-forming element 25. The sieves 26 are provided to obtain a fine and homogeneous foam.
Due to the constriction 27, the foam will be accelerated in the dispensing channel 23 before passing the sieve 26 which is the closest to the dispensing opening 24. It has shown that the provision of a constriction 27 between the two sieves 26, and the resulting acceleration of the foam improves substantially the quality of the foam dispensed by the dispensing device. In alternative embodiments the constriction 27 may also be provided at another location in the dispensing channel 23 with respect to the sieves 26, but is preferably located in the dispensing channel 23 downstream of at least one porous element, for instance a sieve 26.
Starting from the position shown in
By further depression of the actuation button the air cylinder 15 will further move downwards, therewith decreasing the volume of the air chamber 17. As a result, air present in the air chamber 17 will be pumped out of the air chamber 17 via the air outlet.
When at the end of the downwardstroke the actuation button 6 is released, the pump actuation button 6 is pressed upwards by the springs 28 and 29. The air cylinder 15 which is an integral part of the actuation button 6, will also move upwards and take the piston seal 20 along due to the friction between the air cylinder 15 and the piston seal 20. As a result, the piston seal 20 will move from the closed position to the open position with respect to the air piston 16. When the piston seal 20 is fully in the open position a rim 20A on the piston seal 20 will cling behind a corresponding rim 16a on the air piston 16. As a consequence, the sealing rim 20 will no longer move upwards with the air cylinder 15, but stick to the air piston 16. By this movement of the piston seal 20 with respect to the air cylinder 16 the air inlet valve is opened.
It is remarked that in the embodiment shown in
When the air cylinder 16 further move upwards the volume of air chamber 17 will increase and as a consequence air will be sucked into the air chamber 17 via the air inlet 18.
At the same time, the volume of the liquid chamber 10 increases which results in an underpressure in the liquid chamber 10. This underpressure opens the liquid inlet valve 13 and liquid is sucked out of the container 3 through the dip tube 30 and the liquid inlet 11.
When the actuation button 6 is again in its top position as shown in
By further reciprocating movements of the actuation button 6 more foam can be dispensed from the foam dispensing device. It is remarked that although it is described that the foam dispensing device will dispense a foam after one so-called prime stroke, more prime strokes may be required before a desired quantity of foam per pump stroke is dispensed.
After foam has been dispensed, foam will remain in the dispensing channel 23. When the dispensing device is held in the upright position, this foam will run back into the dispensing channel 23 towards the mixing chamber 22. Here it will not flow further in the dispensing device 1 as the liquid outlet 12 is closed by the liquid outlet valve 14 and the air outlet 19 has a vertical part which runs upwards from the mixing chamber 22. As a result, the foam which may turn back to liquid will stay in the mixing chamber 22 and may partially fill the vertical part of the air outlet 19.
The foam and/or liquid in the vertical part of the air outlet 19 can advantageously function as an air outlet valve during the upward movement of the actuation button 6 when air is drawn into the air chamber 17 via the air inlet 18. Due to the presence of the foam/liquid in the air outlet 19, the flow resistance for air coming from the environment is considerably higher in the air outlet 19, than in the air inlet 18. In this way it is avoided that foam/liquid is sucked back into the air chamber 17 without the need for the provision of a mechanical air outlet valve in the air outlet 19. This is desirable as the presence of foam/liquid may have a negative effect on the functioning of the air pump 5. In particular, the foam/liquid may have a negative effect on the sliding sealingly engagement between the air cylinder 15, the air piston 16 and the piston seal 20.
The above described pump dispensing assembly provides is relatively compact. It has shown that this design may result in a dispensing assembly which has a relatively low height per dispensed volume of foam. Also, the volume of plastics material and the weight of the dispensing assembly per volume of dispensed volume of foam per pump stroke is relatively low.
The dispensing assembly further has the advantage that it is resistant to water, i.e. it can easily be rinsed with water from the top side of the dispensing assembly without water entering into the dispensing assembly. This water resistancy is in particular obtained by the skirt of the actuation button extending circumferentially about the cylindrical extension extending upwardly from the securing collar, and the aeration valve formed by the sealing gasket which is arranged under the securing collar. It is remarked that in particular for so-called water resistant foamers the dispensing assembly according to the invention provides a relative compact design.
In an embodiment, a height of a part of the dispensing assembly projecting after mounting downwardly from the top end of a container, i.e. the distance with which the dispensing assembly projects into the neck of the container, is smaller than 1.5 times the maximal stroke length of the actuation button, preferably 1 times the maximal stroke length of the actuation button, or a total height of the dispensing assembly is smaller than 4.5 times the maximal stroke length of the actuation button. The part of the dispensing assembly projecting upwardly from the container on which the dispensing assembly is mounted is preferably maximally 3.5 times the maximal stroke length of the dispensing assembly.
It is remarked that the bottom of the liquid inlet valve is regarded to be the bottom side of the dispensing assembly, and the top side of the actuation button is regarded to be the top side of the dispensing assembly. Thus, the dip tube and the connection piece for the dip tube are not taken into account in the determination of a height of the dispensing assembly.
The above dimensions of the dispensing assembly provide a good ratio between quantity of foam dispensed per pump stroke, the stroke length and the distance from the container to the top of the actuation button. The latter distance is of importance since the actuation button is designed to be actuated by a finger of the hand holding the dispensing device. It will be clear that the reach of such finger is limited and that this should be taken into account in the design of the dispensing device. The stroke length of a hand-held dispenser having a finger-actuated actuation button lies typically between 5 and 25 mm, more typically between 10 and 20 mm. In preferred embodiments the stroke length is about 11 mm or about 15.5 mm.
With these stroke lengths the height of the dispensing assembly (from bottom of liquid inlet valve to top of actuation button in rest position) is typically 40-60 mm, and the dispensing assembly projects after mounting on a container maximally 15 mm, preferably maximally 10 mm into the neck of the container. Due to the compact design of the dispensing assembly, the weight of the pump per dispensed ml liquid per pump stroke may in an embodiment be smaller than 15 gr/ml.
a and 3b show the sealing gasket 31 according to the invention in more detail.
a-4d show top views of alternative embodiments of sealing gaskets according to the invention each having a different sealing surface between the sealing gasket and the securing collar.
a shows a sealing surface 36 also extending circumferentially about the longitudinal axis of the dispensing assembly. However, the sealing surface is about the whole circumference broader which may improve the sealing between the sealing gasket and the securing collar depending on the materials used.
b shows a sealing surface 36 extending about the longitudinal axis of the dispensing assembly, but over a part 36a of the circumference the sealing surface 36 is smaller than over the rest of the circumference. In some applications such smaller part 36a may provide a more controlled opening and closing of the sealing opening between the sealing gasket and the securing collar.
c shows a further embodiment of a sealing gasket of the invention. In this embodiment the sealing gasket is provided with a sealing surface 36 substantially corresponding to the sealing surface of
d shows a sealing gasket having a hole 37 corresponding to the hole provided in the sealing gasket of
All embodiments of the sealing gaskets of
The piston seal 20 of the embodiment of
The cylindrical portion 120 is provided so that the sealing lip 121 is at another height level than the sealing surface of the two piston sealing lips 122. in particular the height of the sealing surface 121 is chosen such that it is close to, and preferably at the same level as the tilting point of the dispensing assembly 2, i.e. the point of the dispensing assembly 2 about which the dispensing assembly 2 may tilt when the actuation button 6 is not pushed in, in a direction parallel to the longitudinal axis of the dispensing assembly 2. As a result, the sealing between the sealing surfaces 123 and 124 will less be influenced by tilting of the dispensing assembly 2 when the pump actuation button 6 is not depressed correctly.
The annular sealing lip 121 has the advantage that as the sealing lip 121 extends inwardly to the longitudinal axis of the dispensing assembly 2, the sealing surface 123 has a substantial smaller diameter than the air cylinder 15, i.e. where the piston seal 20 abuts the inner surface of the air cylinder 15. Therewith the sealing is substantially improved. This sealing is further improved by the flexibility of the sealing lip 121.
In the dispensing assemblies shown in
To further improve the sealing between the valve member and the valve seat of the liquid outlet valve, the inner rod of the embodiment of
In an alternative embodiment, the inner rod 131 may be provided with any biasing means for pushing the valve member in the valve seat as soon as there is no over pressure in the liquid pump chamber. Preferably the biasing means are integral with the inner rod 131, and flexible arms 133 have proven to be very suitable as they can be integrally moulded with the inner rod and require not much space.
Furthermore, the biasing means may be placed against an inner rim of the mixing chamber or any suitable other location instead of the foam-forming element 25.
Number | Date | Country | Kind |
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PCT/NL2007/000228 | Sep 2007 | NL | national |
This application is the National Stage of International Application No. PCT/NL2008/000200, filed Sep. 10, 2008, which claims the benefit of National Stage of International Application No. PCT/NL2007/000228, filed Sep. 17, 2007, the contents of which is incorporated by reference herein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/NL08/00200 | 9/10/2008 | WO | 00 | 3/8/2010 |