NO315182B1 - Valve device, protective device and method for regulating flow from a beverage container - Google Patents

Abstract

A method and device for regulating liquid flow from beverage containers wherein a diaphragm (12) is connected to a valve head (15) via a valve stem (14) to form a vacuum controlled valve for beverage, and wherein the force from the diaphragm (12) is sufficient to open the valve head (15) even at full pressure against the valve seat (21) caused by, for example, carbonated soft drinks.

Description

VALVE DEVICE, PROTECTION DEVICE AND METHOD FOR REGULATING FLOW FROM A BEVERAGE CONTAINER

This invention relates to a device at a valve for a drinking container, e.g. a baby bottle or similar container. The invention also includes a method for using the valve device as well as a protective device for a drinking spout for the drinking container.

According to known technology, and in addition to ordinary capsules, there are several types of closure devices that prevent a fluid from flowing freely from a beverage container.

US 5,975,369 and US 5,465,876 show examples of such closing devices. In order to open or close such a device, however, the user must perform a mechanical movement of a closing mechanism assigned to the device. Such a device, on the other hand, provides a poor gas seal for a pressurized fluid in the beverage container, for example a carbonated liquid.

NO 137258 deals with a valve device which will be able to prevent pressurized liquid from leaking out of a beverage container. The device, on the other hand, is arranged in such a way that it reinforces a valve-closing force from any liquid overpressure in the beverage container. The valve device is therefore not suitable for containers containing pressurized liquid.

GB 1,453,968 deals with a flow-activated valve device for a baby bottle, the invention i.a. aims to minimize the negative pressure that a small child must use to suck liquid out of through an outlet spout in the baby bottle. The valve device comprises a plate between the outlet spout and the feeding bottle. The plate is assigned an air opening for continuous pressure equalization between the internal cavity of the bottle and the ambient pressure. The plate is also provided with an outlet opening and an external flap which resiliently covers the plate's outlet opening. The flap is held open by liquid flowing out of the feeding bottle, after which the flap due to its suspension closes when the liquid outflow ceases. Such a flap valve will therefore open for liquid outflow if the pressure in the outlet spout falls below the pressure inside the feeding bottle, for example if the bottle is held upside down containing sufficient liquid to open the flap valve. The valve is thereby pressure-balanced against the pressure inside the bottle. Because of. said air opening for continuous pressure equalization, the valve device cannot be used to keep a pressurized liquid in the bottle tight.

US 5,607,073 also relates to a valve device for a baby bottle. The valve device consists of, among other things of a vacuum-activated and external seat element which is springy and movably suspended between two supports in an outlet spout for the bottle. The seat element is provided with a valve seat that covers an outlet opening in a plate between the baby bottle and the outlet spout. When the pressure in the outlet spout falls below the pressure inside the feeding bottle, the valve seat opens for liquid outflow. The valve is thereby pressure-balanced against the pressure inside the bottle. Like the device according to GB 1,453,968, the valve device according to US 5,607,073 will also not keep tight against pressurized liquids in the bottle. Moreover, the latter device does not have an air opening through which the bottle pressure can be equalized against the ambient pressure. When liquid is sucked out of the bottle, a gradually increasing negative pressure will therefore be created in the bottle, which causes the valve seat to be pressed progressively harder against said outlet opening, thereby making drinking from the bottle difficult.

The purpose of the invention is to remedy the above-mentioned disadvantages of the known technique.

The present valve device and method shall prevent spillage of fluid when a user sucks the fluid out of a drinking container. With the help of the valve device, the drink container is automatically sealed when the suction force from the user ceases. With the help of the present protection device, a drinking opening in a drinking spout for the container is also protected.

The purpose is achieved by features as stated in the following description and in subsequent patent claims.

In the position of use, the present valve device is connected to an opening in a separating wall part of the beverage container. This wall part is either a part of the beverage container or, alternatively, a part of a capsule which is pressure-tightly assigned to the beverage container. The wall part functions as a dividing wall between the drink container's inner space and the outer surroundings. Via a downstream drinking opening, the valve is designed to be able to open and close fluid outflow from the drinking container. The valve comprises a movable activation element which is assigned to a sealing element, where the activation element is pressure-sensitive and arranged to move the sealing element into the open position for fluid outflow. The peculiarity of the valve arrangement is that the activation element is pressure-balanced against the beverage container's ambient pressure Pl, and that the activation element is designed to open for fluid outflow when the pressure P2 in said beverage opening falls below the ambient pressure Pl by a predetermined value. The resulting differential pressure (P1-P2) thereby moves the actuating element with a valve-opening force Fl. None of the above-mentioned, known valve devices are pressure-balanced against a beverage container's ambient pressure Pl, which is significantly different from the present valve device.

In a preferred embodiment of the valve device, said activation element comprises a movable membrane which is formed around an axis on said wall section. The membrane is arranged with a peripheral edge which, in the position of use, is pressure-tightly assigned to the outside of said wall section, and which encloses the opening in the wall section. A suction chamber is thereby provided between the membrane and the wall section. Via an axially oriented and stiffening strut, the membrane is connected to a valve head which is assigned to the wall opening to open and close for fluid outflow. The valve head is attached to the rod and tightened against the wall section with a specific force, e.g. can be effected by a springy unit attached to the strut, or which is effected through the design of the membrane. In order to center the valve stem in the opening of the wall section, the opening can, for example, be provided with guides that protrude from it, or self-centering valve surfaces are used. In its position of use, the downstream side of the suction chamber is pressure-tightly connected to said drinking opening for negative pressure activation of the membrane. With such activation, the rod transfers an axially directed and valve-opening force Fl from the diaphragm to the valve head. In order to get enough strength in the membrane to convey the pressure forces into the valve stem, the membrane can be equipped with reinforcing ribs, preferably on the upper side of the membrane.

The valve head can be made of a soft material or provided with a separately adapted seal for sealing against said wall opening. The valve head is optionally attached to a separate strut via a ball joint. Thereby, the head can move in relation to the valve stem and compensate for any unevenness in said wall opening.

In the position of use, the valve device can be assigned to a cover which encloses it, and which is preferably pressure equalizing assigned to the outside of said wall section. The lid can be designed as, or be provided with, a drinking spout or a teat that defines at least one drinking channel through which a user can activate the valve device and drink the fluid in the container. A breakable seal or enclosure can also cover the drinking spout or pacifier. The lid and any components therein are preferably designed to be detachable/removable, whereby cleaning or replacement of the lid and/or its components can be easily carried out. The membrane and the lid are preferably connected by means of a flexible and tight sealing connection which does not hinder the membrane's movements.

If the lid is pressure-tight connected to the drinking container, the lid must be equipped with venting options up to the outside of the membrane, for example in the form of at least one vent hole in the lid. You can optionally achieve a controlled delay in the valve device's reaction time by adjusting the size and/or number of at least one air hole. Such an adaptation can also dampen any membrane oscillations that may occur during use.

The invention also relates to a method for preventing the accidental outflow of a fluid from a beverage container, where the method comprises the use of a valve device of the present type. The peculiarity of the method is that the activation element is pressure-balanced against the beverage container's ambient ice pressure Pl, and that the activation element is arranged to open for fluid outflow when the pressure P2 in said beverage opening falls below the ambient pressure Pl by a predetermined value, whereby the activation element is moved with a valve-opening force Fl.

In the following, non-limiting examples of the present invention are described, as these are illustrated in the accompanying drawings, where: Fig. 1 shows a capsule for a beverage container, where the capsule is provided with a valve device according to the invention, and where the valve device is connected to a lid with a drinking spout and a removable protective cover; Fig. lb-lc shows a section of peripheral details of the lid and the protective cover according to Fig. 1, with Fig. lb showing the cover connected to the lid, while Fig. lc shows the cover disconnected from the lid; Fig. 2 shows a section of central details of the valve arrangement according to Fig. 1; Fig. 3a-3b show the capsule according to Fig. 1 placed on a bottle, each capsule being provided with a lid and a removable protective cover, but where the figures show two different variants of a drinking spout for the capsule; and Figs. 4a-4b show a capsule for a beverage container, where the capsule is provided with a valve device according to the invention, and where the figures show the principle operation of the valve device, with Fig. 4a showing the device in a closed position, while

Fig. 4b shows the device in the open position.

The drawing figures are otherwise schematic and may be somewhat exaggerated regarding design and relative dimensions. In what follows, similar details in the figures will mainly be indicated by the same reference number.

As Fig. 4a-4b show the principle operation of a device for a valve 30 according to the invention, these figures will be discussed first. The figures show a beverage container in the form of a bottle 23 which, when opened, is provided with a capsule 1. The bottle 23 has an internal pressure P3 which can be greater than the bottle 23's ambient pressure Pl, for example when the bottle 23 contains a carbonated liquid. Inside, the capsule 1 is provided with a separating wall section in the form of a concentric and flat partition lb which is provided with a central wall opening lc. The partition wall lb is formed around the capsule 1's longitudinal axis. A concentric membrane 12 is placed between the partition wall 1b and the capsule 1's end wall. Along its peripheral edge 8, the membrane 12 is pressure-tightly connected to the side wall of the capsule 1, the membrane 12 also being provided with a flexible zone in the form of at least one concentric ring-shaped corrugation 12c which is placed between said axis and the peripheral edge 8. The membrane corrugation(s) 12c acts springy when the membrane 12 moves. A strut 14 is connected to the inside 22 of the membrane 12 and at its midpoint. The strut 14 projects along the longitudinal axis and through said opening lc in the partition lb, the cross section of the strut 14 being smaller than the diameter of the wall opening lc. At its free end, the rod 14 is provided with a flat valve head 15 which is designed to close pressure-tight against the inside ld of the partition wall lb. In the capsule 1, between the partition wall 1b and the membrane 12, there is thereby a suction chamber P2' which is connected to a drinking opening in the capsule 1's side wall, the drinking opening being delimited by a drinking channel in the form of a pipe nozzle 5. Between the membrane 12's outside 13 and the capsule 1's end wall, there is an outer chamber which is connected to an air hole 20 in the capsule 1, whereby the outer chamber is pressure-balanced against the ambient pressure Pl. The outer chamber thereby functions as a protective cover for the membrane 12.

The valve device is activated by suction through the drinking opening, whereby a negative pressure P2 is created in the suction chamber P2'. A resulting differential pressure (P1-P2) will thereby act on the membrane 12 with a compressive force Fl which is transferred to the valve head 15 via the rod 14. If the compressive force Fl exceeds an oppositely directed compressive force F2 caused by an overpressure P3 in the bottle 23 and a possible biasing force, the membrane 12 is moved towards the wall opening lc, the pressure P3 acting on the inner surface of the valve head 15. Thereby, the rod 14 and the valve head 15 will be moved to the open position, cf. Fig. 4b. When the negative pressure P2 and the force Fl cease, the membrane 12 will due to its flexible zone 12c return to its inactive position and close for outflow, cf. Fig. 4a.

In order to be able to activate the valve 30 at overpressure P3 in the bottle 23, the surface area of the membrane 12's underpressure-affected inside 22 must be substantially larger than the surface of the valve head 15 affected by overpressure. By appropriate matching between the area of said two surfaces, a user can, even with a relatively high overpressure P3 in the bottle 23, open the valve 30 by sucking a moderate negative pressure P2 in the suction chamber P2'. Fig. 1 and Fig. 2 show a preferred embodiment of the device for a valve 30 according to the invention, the device being releasably placed in an external housing of a capsule 1. Fig. 2 shows enlarged sectional details of the valve device. These figures also show the capsule 1 provided with a wall section in the form of a concentric and flat dividing wall lb with a central wall opening lc. The capsule 1 is thereby arranged with an outer and an inner part. The outer housing is concentrically designed around the longitudinal axis of the capsule 1, and the axis is centered in said wall opening lc. The housing appears between said partition 1b and an outer extension 25 of the capsule 1's side wall. A concentric and planar designed membrane 12 is placed in the housing and perpendicular to the axis. The membrane 12 is attached to a peripheral attachment ring 8 which is attached pressure-sealingly and releasably in the housing. For this pressure sealing, each side of the fastening ring 8 is provided with a sealing ring 9a, 9b. This membrane 12 is also provided with at least one circumferential corrugation 12c.

The membrane 12 is also provided with a central drinking opening in the form of an outflow hole 12b. A strut 14 is placed in this outflow hole 12b and projects axially from it and through the wall opening lc in the partition lb. The rod 14 is attached to the membrane wall around the hole 12b by means of radial bars, whereby unrestricted fluid flow through the hole 12b is thereby possible when the valve 30 is open. At its free end, the rod 14 is rotatably connected via a ball joint 16 to a conically designed valve head 15. At its circumference, the valve head 15 is designed as a flexible and pointed sealing ring which can close pressure-sealingly against a valve seat 21 on the inside ld of the partition wall lb and around its wall opening lc.

On its outside 13 and around the outflow hole 12b, the membrane 12 is provided with a flexible and ring-shaped seal 17. The seal 17 is also provided with an inner connection collar. The collar is arranged to fit pressure-tight and releasably together with an annular groove around a first end part of a concentric drinking channel 5 in a separate lid 4. In a second end part of the drinking channel 5, the lid 4 is designed as a drinking spout 7. An external part of a lid jacket and an internal part of the capsule extension 25 is also provided with complementary connection grooves 2a, 2b. Thereby, the lid 4 can be releasably fixed in the capsule housing and outside the membrane 12. To ensure that the membrane 12 is pressure-tightly assigned to the partition wall 1b, the lid jacket is pressed against the membrane 12's fastening ring 8 and its sealing rings 9a, 9b. Thereby, said drinking channel 5 is also pressure-tightly and releasably connected to the outflow hole 12b in the membrane 12. The lid 4 is also provided with an air hole 20 into an outer chamber situated between the membrane 12 and the lid 4. The outer chamber is thereby pressure-balanced against the ambient pressure Pl. The membrane 12 is also placed at a certain distance from the partition wall lb, so that there is a suction chamber P2' between the membrane 12 and the partition wall lb. When a negative pressure P2 is supplied to the suction chamber P2' via the drinking spout 7, the membrane 12 is moved towards the partition wall 1b, thereby displacing the rod 14 and the valve head 15 and opening the valve 30 for fluid outflow.

The capsule 1 in Fig. 1 is also provided with internal threads 11 and an anti-screw stop ring 19 with stop flaps 18. This is known technology. The flaps 18 are designed to engage in not shown barbs on a beverage container 23 to thereby prevent the capsule 1 from being accidentally unscrewed. The stop ring 19 functions as a seal between a beverage container 23 and the capsule 1. To break the seal, the capsule 1 must be subjected to a considerable twisting force along its circumference. A broken seal therefore indicates prior opening of the beverage container 23.

Such an opening indication is, on the other hand, insufficient if the beverage container 23 is provided with a capsule 1 with a beverage spout 7 through which a fluid in the container 23 can flow. Therefore, the cap 4 of the capsule 1 and its drinking spout 7 can be provided with a protective device according to the invention. The protective device has the form of a protective cover 6 which can cover the lid 4. The protective device is shown in Fig. 1, while Fig. lb and Fig. lc show details of the cover 6 and the lid 4. The distinctive feature of the protective device is that the lid 4 and the cover 6 is releasably connected in a primary connection part at the drinking spout 7, and in a secondary connection part located circumferentially at the cover 6's circumference. In the primary connection part, the lid 4 and the cover 6 are connected by means of complementary connection parts in a flange connection 3c. In the secondary connection part, the lid 4 and the cover 6 are connected together by means of a complementary groove 3a and spring 3b which are essentially radially aligned. The lid 4 and the cover 6 are connected together in the secondary connection part before the groove 3a and the spring 3b are torn apart when the cover 6 is removed for the first time, cf. Fig. lb. The connection of the primary connection part is then effected, cf. Fig. 1c, which indicates prior opening of the beverage container 23.

Claims (10)

1. Device with a valve (30) for a drink container (23), where the valve (30) in the use position is connected to an opening (lc) in a separating wall part (lb) of the drink container (23), the wall part (lb) being either a part of the beverage container (23) or, alternatively, is a part of a capsule (1) which is pressure-tightly assigned to the beverage container (23), and where the valve (30) is arranged to be able to open and close for the outflow of a fluid from the beverage container (23) via a downstream drinking opening, the valve (30) comprising a movable activation element (12, 14) which is assigned to a sealing element (15), and where the activation element (12, 14) is pressure-sensitive and arranged to displace the sealing element (15) in the open position for outflow of the fluid, characterized in that the activation element (12, 14) is pressure-balanced against the ambient pressure (Pl) of the beverage container (23), and that the activation element (12, 14) is arranged to open for fluid outflow when said beverage opening its pressure (P2 ) falls below the ambient pressure (Pl) by a predetermined value, whereby a resulting differential pressure (P1-P2) moves the actuating element (12, 14) with a valve-opening force (Fl). 2. Device according to claim 1, characterized in that said activation element comprises a movable membrane (12) which is formed around an axis on said wall part (lb), and that the membrane (12) is aligned with a peripheral edge (8) as in the use position is pressure-tightly assigned to the outside of said wall part (lb) and encloses said opening (lc) in the wall part (lb), whereby a suction chamber (P2') exists between the membrane (12) and the wall part (lb), and that the membrane (12) via a axially directed and stiffening strut (14) is connected to a valve head (15) which is assigned to said wall opening (lc) to open and close for fluid outflow, whereby the strut (14) can transmit an axially directed and valve-opening force (Fl) from the membrane ( 12) to the valve head (15), and that downstream side of the suction chamber (P2') in the use position is pressure-tightly connected to said drinking opening for negative pressure activation of the membrane (12). 3. Device according to claim 2, characterized in that the membrane (12) is substantially planar in design, and that the membrane (12) is placed perpendicular to said axis. 4. Device according to claim 2 or 3, characterized in that the membrane (12) is provided with at least one flexible and concentric ring-shaped membrane corrugation (12c) which acts as a spring upon movement of the membrane (12), and which is placed between said axis and the peripheral edge (8) of the diaphragm (12). 5. Device according to claim 2, 3 or 4, characterized in that the membrane (12) is provided with reinforcing ribs. 6. Device according to one of claims 2-5, characterized in that the rod (14) is placed in and protrudes axially from an outflow opening (12b) in the membrane (12), and that the rod (14) is attached to the membrane (12) in a flow-through manner ) its wall around the outflow opening (12b), as the fluid can thereby flow unhindered through the outflow opening (12b) when the valve (30) is open. 7. Device according to claim 6, characterized in that the membrane (12) on its outside (13) and around the outflow opening (12b) is provided with a flexible and ring-shaped seal (17) which, in the use position, encloses a separate drinking channel (5) in a pressure-tight manner , whereby the membrane (12) is designed for releasable connection with the drinking channel (5). 8. Device according to claim 7, characterized in that the drinking channel (5) is formed in a lid (4) which is pressure equalizing assigned to the outside of said wall part (lb) and encloses the valve device, and that a first end part of the drinking channel (5) is arranged to to fit into said seal (17), while a second end part of the drinking channel (5) is designed as a drinking spout (7). 9. Protective device for a drinking spout (7) in an external lid (4) of a capsule (1) of a drinking container (23), where the device comprises a protective cover (6) as well as complementary connection parts (3a, 3b, 3c) to connect the cover (6) detachable to the lid (4), the cover (6) being arranged to cover the lid (4), characterized in that the lid (4) and the cover (6) are releasably connected in a primary and central connection part at the lid ( 4) its drinking spout (7), and in a secondary and peripheral connection part at the cover (6) its outer circumference, and that the lid (4) and the cover (6) in the primary connection part are connected by means of complementary connection parts in a flange connection ( 3c), while the lid (4) and the cover (6) in the secondary connection part are connected by means of a complementary groove (3a) and spring (3b) which are essentially radially aligned, the lid (4) and the cover ( 6) is connected in the secondary connection section before the cover (6) is removed for the first time g, after which connection is effected by the primary connection part and indicates prior opening of the beverage container (23). 10. Method for preventing the accidental outflow of a fluid from a drink container (23), where the method comprises the use of a valve (30) which is connected to an opening (lc) in a wall part (lb) of the drink container (23), the wall part ( lb) is either part of the beverage container (23) or, alternatively, is a part of a capsule (1) which is pressure-tightly assigned to the beverage container (23), and where the valve (30) is arranged to regulate the fluid outflow via a downstream drinking opening, in that the valve (30) comprises a movable activation element (12, 14) which is assigned to a sealing element (15), and where the activation element (12, 14) is pressure-sensitive and arranged to move the sealing element (15) into an open position for out- flow of the fluid, characterized in that the activation element (12, 14) is pressure-balanced against the beverage container's (23) ambient pressure (Pl), and that the activation element (12, 14) is arranged to open for fluid outflow when said beverage opening's pressure (P2) u exceeds the ambient pressure (Pl) by a predetermined value, whereby a resulting differential pressure (P1-P2) moves the actuating element (12, 14) with a valve-opening force (Fl).