RU2379222C2 - Method and device for air intake into drinking vessel - Google Patents

Abstract

FIELD: packing industry.

SUBSTANCE: device for air intake into drinking vessel has dispenser device and connector ring, which joins dispensing device to vessel, and also includes disk part and main part. Disk part has multiple holes for liquid, which represent descending elements. Main part is made of flexible material and contains multiple channels for air passage that pass between periphery of specified main part and single passage valve arranged as a whole, which in open position makes it possible for air to enter drinking vessel, and in close position it prevents liquid outflow from vessel and also comprises multiple holes for liquid in the main part. Holes for liquid in the main part correspond to descending elements of disk part and are joined to them through seal. Disk part and main part together produce channels for passage of air between lower surface of disk part and channels for air passage in the main part, besides channels for air supply make it possible for air to enter vessel through valve. Method is provided for manufacturing of device for air intake into drinking vessel as well as drinking vessel itself.

EFFECT: development of new device design, using which substantially does not pull vacuum in drinking vessel, and as vessel is filled with liquid and exposed to vigorous shaking, it prevents leakage of liquid.

10 cl, 23 dwg

Description

FIELD OF THE INVENTION

The present invention relates to drinking vessels, drinking devices, methods for allowing flow through such vessels, and devices intended for use with sealed and substantially non-vacuum drinking mugs for young children and bottles for babies.

State of the art

Special bottles for babies are made with design features aimed at reducing the symptoms of colic (spastic pain) in infants under four months of age. In particular, in patents US 5570796 and US 5779071 claims that the proposed device exclude mixing of air into the infant formula, since such mixing increases the risk of colic symptoms.

The devices described in patents US 5570796 and US 5779071, contain a vessel (bottle), equipped with an inserted tube in combination with a liquid trap. The removable tip used with the bottle allows air to pass from the environment to the inside of the bottle. When the bottle characterized by the features of the inventions of the aforementioned U.S. patents is completely overturned, the liquid trap receives liquid from the internal volume of the tube inserted into the bottle and prevents the liquid from entering the opening of the removable tip because the opening of the removable tip is located above the level of the liquid contained in the liquid collector. It is important to note that the volume of the liquid trap is greater than the volume of the vessel tube, and therefore the volume of liquid can completely fit in the liquid trap in a narrow range of operating conditions.

Unfortunately, the device described in patents US 5570796 and US 5779071, when overflowing the bottle allows leakage, because in this case the bottle tube and the liquid trap inherent in the known device are filled with liquid in excess of the volume of the liquid trap, as a result of which the liquid enters the removable tip and, after all, beyond the bottle. In addition, leaks occur in the device described in these patents when the bottle is squeezed or the nipple attached to it is squeezed. In addition, leaks will occur from the bottle described in these patents when it is shaken to stir the milk mixture if the liquid is heated above 45 ° C or if the bottle is exposed to variable atmospheric pressure.

It is important to note that colic symptoms are usually present in newborns, such as children under four months of age. It should be noted that the age ranges indicated here are approximate and are not intended to set certain limits regarding the use of certain baby bottles or certain non-spillable drinking mugs for young children.

It should also be noted that the use of a bottle that requires for a child older than four months to apply too much effort to “suck” the bottle's nipples can lead to an increased likelihood of the child developing an ear infection.

SUMMARY OF THE INVENTION

The present invention relates to drinking vessels, devices for drinking and methods for creating a fluid flow through vessels and devices for use with drinking mugs for babies starting to walk, and bottles for babies that are airtight and without vacuum (vacuum). .

As used herein, the term “substantially free of vacuum” means that fluid flows out of the vessel through the nipple or nozzle when the vessel is tipped over or placed at an angle. The closure allows air to enter from the atmosphere surrounding the vessel and the drinking process, essentially without creating a vacuum in the vessel. The functioning of the closure, "essentially without the formation of a (low) vacuum in the vessel" or "almost without the formation of vacuum" makes it possible to obtain a vessel that does not require additional suction effort, which the user must apply to consume liquid from the vessel. In addition, due to the inlet of air into the vessel during its use, no tangible holding force of the vacuum is created. One skilled in the art will recognize that the liquid in the vessel will create a minimum vacuum force. This minimum vacuum force arising from the consumption of the contents of the vessel of the present invention draws air into the vessel from the surrounding atmosphere until an equilibrium occurs between atmospheric pressure and the pressure inside the vessel. The above definitions of the terms “essentially without vacuum in the vessel” or “almost without vacuum” suggest that as the liquid flows out of the vessel, a minimum vacuum force will be created to draw air into the vessel. All examples of embodiments of the present invention are implemented under conditions of a substantially lack of vacuum in the vessel.

As used herein, the term “sealed” means that the vessel does not have leaks through the closure element. Since the closure element provides air inlet, a valve is needed to prevent leakage through the closure element. All examples of embodiments of the present invention are carried out under sealed conditions. As used herein, the term “non-shedding” refers to shedding (liquid) possible through a nipple or nose of a vessel. Certain embodiments of the invention are implemented without spilling.

A first embodiment of the present invention relates to a drinking device comprising a valve that is hermetically and removably connected to a closure member for a drinking vessel. This valve is easy to clean and can be replaced if the user does not want to clean the valve, which is economically feasible. For the purposes of the present invention, the closure element is an element configured to be placed on the open upper end of the drinking vessel or in the open end, an element through which external air penetrates into the inner volume of the vessel and which is not a nipple or nozzle, or other type of release means liquids. In accordance with some exemplary embodiments, there are fluid passages in the closure member to allow fluid to flow from the interior of the vessel to the outlet member. According to other exemplary embodiments, the liquid flows from the inner volume of the vessel around the circumference of the closure element to the outlet. One example of a closure member is a removable tip used in the aforementioned US Pat. No. 5,570,796.

The valve and closure element are used together in various non-spillable, sealed and / or substantially non-vacuum drinking vessels, examples of which are drinking mugs for toddlers starting to walk, baby bottles and other drinking vessels. The closure element allows a baby drinking from a vessel of the invention to drink easily from a nipple or nozzle attached to the vessel, while there is no appreciable increase in the effect of the force of vacuum inside the vessel. However, it is important to note that a valve connected to the closure element prevents leakage of liquid from the vessel through the closure element when the vessel is in an inverted position or in a side position, since this valve prevents fluid from flowing into the closure element. The valve is designed so that it is not necessary for the user to strain to create a large suction force, such that the liquid flows out of the vessel, and thus, the user is less likely to develop an ear infection as a result of applying an excessive suction force.

A second embodiment of the present invention relates to an air inlet device including a valve that is hermetically and removably connected to the closure member according to the first embodiment, and further an anti-bubble tube. An air inlet device is attached or attached to an opening or a neck of the drinking vessel and provides passage for air outside the drinking vessel to the internal volume of the drinking vessel. The valve and the anti-bubble tube act as a “diving bell" and, in general, prevent liquid from entering the anti-bubble tube when the drinking vessel is in a substantially vertical position, since air is entrained in the anti-bubble tube and does not leave it while the valve is open, those. trapped air acts as an obstruction to prevent the passage of fluid into the anti-bubble tube. The diving bell effect is created by the user of the vessel when the user installs a closure element (together with a valve and an anti-bubble tube attached to it) on the vessel. When the vessel is turned upside down and the liquid flows out of the vessel, a vacuum force is immediately created inside the vessel, the valve opens, and air enters the vessel. When it is sucked into the air vessel, the valve enters the “new” air into the anti-bubble tube and into the volume of previously trapped air. This "new" air can replace a certain amount of trapped air by pushing it through the anti-bubble tube. In this case, the effect of the "diving bell" in the anti-bubble tube is not saved. The anti-bubble tube is always profiled and attached to the capping element so that only a small amount of liquid can enter the anti-bubble tube. Therefore, despite the absence of the diving bell effect, the fluid does not cover the valve. However, the vessel is and is being operated in a sealed state.

As in the first embodiment, the valve is attached or attached to the closure element, as is the anti-bubble tube. The valve allows air to enter the vessel, but does not allow fluid to flow out of the vessel through the air intake system. The anti-bubble tube allows air entering the inverted vessel to an air pocket formed in the bottom of the vessel, which during use of the vessel rises above the nipple or nose of the vessel. The air pocket is formed by the air entering the vessel through the valve as a result of the emptying of the vessel produced by the user through the nipple or nose of the vessel. Due to the passage of air directly to the air pocket, the air is not able to mix with the liquid in the vessel and create air bubbles in the liquid. An anti-bubble tube is an important structural element when the vessel is used by newborns, as they are more prone to colic than older children. However, when the baby grows up and goes through the colic stage, the present invention allows the user to remove the anti-bubble tube (leaving the valve and closure in place) and, nevertheless, keep the bottle or mug for older children in working condition.

According to an alternative embodiment, the present invention further relates to a drinking device, which is an air intake device comprising a closure member formed from several parts and comprising a disk part (a disk-shaped part) and a main part (base) . The main part is connected to a non-return valve or is made integral with a non-return valve. Such a closure element functions essentially in the same way as the closure element according to the first embodiment. Various embodiments of the closure member are disclosed herein, including a preferred embodiment using a valve made with a flat end having an end gap (like a duck nose). If necessary, according to such an embodiment, an anti-bubble tube can be used together with the air intake system.

Like other exemplary embodiments, the air inlet device with the disk portion and the main portion is attached to certain vessels readily available to customers by the industry related to the manufacture of bottles for young children. In addition, the air intake device with the disk part and the main part is especially easy to carry out cleaning, since all surfaces of the main part and the disk part are easily accessible, and therefore no special equipment is required for cleaning. Thus, the air inlet device according to these embodiments provides full access to the various elements for cleaning them. In addition, various elements of the air intake device can be observed visually for lack of contamination.

In other embodiments of the present invention, the valve and closure element together with a “mug for sipping liquid (drinking in small sips)” and a spout can be used by babies starting to walk. Such circles, in addition, may contain a flexible nose.

In addition to baby bottles and “sips” mugs, the device of the present invention can be used with non-spill vessels for use by consumers of all ages.

For example, cyclists and other athletes participating in sporting events can benefit from the use of a non-shedding vessel in which essentially no vacuum is generated.

One aspect of the present invention is to provide a sealed drinking vessel in which substantially no vacuum is generated and which can be used when positioned at almost any angle in the absence of fluid leakage from the vessel.

Another aspect of the present invention is the provision of a drinking vessel in which essentially no vacuum is formed having fewer structural elements and is characterized by greater ease of action compared to the analogue.

A further aspect of the present invention is to provide a bottle for babies that is sealed and substantially free from vacuum, which may be filled with hot or boiling water.

Another aspect of the present invention is to provide a sealed and substantially non-vacuum vessel that can be filled with liquid and shaken vigorously without leakage.

These and other aspects are achieved according to the present invention.

Brief Description of the Drawings

1 is a perspective view of a valve for use in an air intake device according to one embodiment of the present invention.

Figure 2 is a side view of a closure member in accordance with one embodiment of the invention.

Figure 3 - capping element shown in figure 2, a top view.

FIG. 4 is a perspective view of an air inlet device according to one embodiment of the present invention with the closure member shown in FIG. 2 and a valve connected to it as shown in FIG. 1.

5 is a bottle, a capping element, a connecting ring, a nipple and a valve, shown together.

FIG. 6 is a partial cross-sectional view of an alternative embodiment of an air intake bottle of the present invention provided with an anti-bubble tube. FIG.

Fig. 7 is a side view of a closure member in accordance with an alternative embodiment of the invention for use with an anti-bubble tube.

Fig. 8 is a partial sectional view of an anti-bubble tube schematically illustrating its internal volume.

9 (A) to (D) are various views of one embodiment of a valve for use with a mug.

10 (A) to (D) are various views of one embodiment of a closure member for use with a mug.

11 is a valve according to figv and capping element according to fig.100, a perspective view from below.

12 is an illustration of an air inlet device in accordance with another embodiment, comprising a closure member including a disk portion and a main portion, a sectional view.

Fig. 13 (A) is an air intake device shown in Fig. 12, an exploded view of an image.

Fig. 13 (B) is an air intake device according to Fig. 12, shown together with an anti-bubble tube, complete assembly.

Fig. 14 (A) is a closure member in accordance with another embodiment, comprising a disk portion, a main portion and an anti-bubble tube, an exploded view of an image.

Fig. 14 (B) is a disk and main part and an anti-bubble tube for an example embodiment of the closure member shown in Fig. 14 (A), assembly view.

Fig - the main part of the example embodiment shown in Fig.14 (A) - (B), a perspective view from below.

Detailed Description of Preferred Embodiments

The present invention will now be described with respect to a first embodiment aimed at providing an air intake device for use with a drinking vessel. The specified device for air intake contains a check valve, hermetically and removably attached to the capping element, which serves to close the drinking vessel. Then, a second embodiment of the present invention will be disclosed, which provides for the use of an air intake device according to the first embodiment, together with an anti-bubble tube. The first and second examples of implementation are characterized by various structural execution, corresponding to the scope of the present invention.

According to a first embodiment, the present invention is directed to an air discharge device that provides non-spillable, sealed and / or substantially non-vacuum drinking vessels, such as baby bottles, small sips and other non-spillable drinking vessels vessels used by young and old people. The air intake device is equipped with a check valve, made with the possibility of tight connection with the capping element, and is intended for use with a drinking vessel. The valve has an opening that allows air to flow from the atmosphere surrounding the drinking vessel into the internal volume of the drinking vessel, but preventing liquid from flowing out of the internal volume of the drinking vessel through the air inlet device.

It should be borne in mind that certain closures available to the consumer that are used with baby bottles can be converted into an air outlet device according to the present invention by supplementing them with a suitable non-return valve. In general, the closure is held in or on the drinking vessel by means of a connecting ring. The closure element contains a tube or channel for air inlet, which is connected to the valve and allows air to enter the vessel from the atmosphere surrounding the drinking vessel through the gap between the vessel and the connecting ring. As a result, the closure element allows the liquid to be sucked out of the vessel substantially without creating a vacuum in it.

A first embodiment of the present invention will now be described with reference to FIG. 1, which shows a check valve 10 for use in an air intake device. The valve 10 is adapted and configured to detach to a closure member (not shown). In the embodiment of FIG. 1, the valve 10 comprises a connecting portion 20 for tightly sealing the valve with the closure member. The connecting part 20 has a circular hole 25. The circular hole 25 is adapted and configured to insert a connecting element 150 included in the design of the closure element 90 and which in this case is a downwardly extending tube (shown in FIG. 2). The wall 45 of the connecting part 20 is adapted and configured to tightly enclose the connecting element 150 so as to prevent the valve from accidentally falling into the vessel when it is shaken and during consumption of the beverage. The connecting element 150 is inserted into the circular hole 25, and the wall 45 is first slightly stretched and then compressed, which allows you to insert the connecting element 150 into the hole 25 and hold it. The wall 45 should be of sufficient thickness so that it snugly and securely surrounds the connecting element 150. For example, the wall 45 may have a thickness of approximately two (2) to three (3) millimeters. If necessary, means can be used that improve adhesion between the valve and the connecting element during drinking, for example, sections with protrusions on one of them (on the valve or on the connecting element), which correspond to sections with depressions on the other, or ridges and mating grooves, or reinforced connecting ring. However, it should be understood that the valve should be easily removable from the closure element to clean it.

In addition, the valve 10 includes a lower part 30 in which there is an opening or slot 35. The opening 35 is configured to allow relatively easy passage of air from the internal volume of the valve into the vessel, while substantially preventing the passage of liquid from the vessel into the internal volume valve.

Between the lower part 30 and the connecting part 20 of the valve there is an element for hand grip, shown in figure 1 in the form of a rim 40. The rim 40 creates a section that is easily grasped by the user of the valve 10 so that the valve 10 can be pulled from the capping element cleaning when valve surfaces are wet. The rim 40 may be of any shape, for example in the form of a square, octagon or circle, i.e. in a form that provides the user with friction.

The valve 10 may be made of various plastic / rubber materials, such as silicone and thermoplastic rubber. A particularly preferred material for valve 10 is silicone. Valve 10 must be made of non-toxic material.

The present invention will be described below with reference to FIG. 2 and FIG. 3, in which a closure member 90 according to one embodiment of the invention, which can be used in conjunction with a check valve, such as valve 10 shown in FIG. 1, is shown. The closure element 90 is configured to attach to the top opening of a bottle or mug for drinking in small sips, although one of ordinary skill in the art can resize the closure element 90 so that it can be used with a large sip of a drinking mug having large dimensions, or even for a larger drinking vessel for adults.

The closure element 90 comprises an outer ring 100 and an inner ring 110. The inner ring 110 fits snugly against the inner surface of the baby bottle or mug for drinking, while the outer ring 100 rests on the upper edge 95 (shown in FIG. 5) of the baby bottle or sips for drinking. The closure element 90 also includes a central portion 120 and one or more air inlet tubes 130 having one or more inlets 135 and 140 located on the outer peripheral surface of the closure element. Air enters the vessel through the opening or openings 135 and 140 of the air inlet tube and through the air inlet tube 130 itself. The downwardly extending tube 150 further has an opening 180 in communication with the internal volume of the valve 10. The air inlet tube 130 is connected to the downwardly flowing tube 150 so that air can pass from the outside of the vessel through the openings 135 and 140 of the air inlet tube through the air inlet tube 130, through the downwardly directed tube 150, through the valve 10 and through the openings or slots 35 of the valve 10. Air from the outside can pass between the threads of the connecting ring and the threads of the thread made on the outer surface of the child bottles or mugs to drink in small sips, to the holes 135 and 140 of the inlet tube. The closure member 90 further comprises support members 160 that support the air discharge tube 130 and form the boundaries of the openings 170. These openings 170 allow liquids, such as milk mixture, juice, milk, and the like, to leak during drinking. from a bottle or mug for drinking in small sips to the existing nipple or spout. The support members 160 may be of any shape that gives rigidity to the closure member 90 and allows fluid to flow through openings 170.

An air intake device according to this embodiment will now be described with reference to FIG. As you can see, the wall 45 of the valve 10 covers the outside of the connecting element, which here is the downwardly extending tube 150 and the hole 180 of the tube 150. When the downward flowing tube 150 is inserted into the connecting part 20, the wall 45 is deformed so that when using the device for air inlet, it compresses the tube 150 with a force sufficient to tightly tightly hold the valve on the downstream tube 150.

5 shows a baby bottle with a locally mounted air intake device in accordance with the present invention. In this embodiment, the connecting ring 200 is screwed onto the neck of the bottle 210, covering the closure 90 from the outside. The connecting ring 200 holds the nipple 425 in place. In an alternative embodiment, instead of a nipple 425, a cap with a flexible nose or some other known liquid release member used in a drinking vessel may be used.

Air passes between the threaded portion of the neck of the bottle 230 and the threaded portion 240 of the connecting ring and enters the openings 135 and 140 of the air inlet tube. This can be achieved by performing each of the threaded parts with the formation of sufficient space for air to escape, or, alternatively, by making recesses or gaps in the threaded part for air to flow through them. From the inlet openings 135 and 140, air passes through the air inlet pipe 130 through the opening 180 of the downstream pipe and then through the opening 35 in the valve enters the internal volume of the bottle 210.

The valve and closure element of the present invention can be used in relation to many commercially available baby bottles. In this case, it is possible that the dimensions of the connecting ring, closure and teats will need to be changed in order to maintain proper sealing of the various bottles.

In other embodiments of the present invention, the valve and closure member are molded (molded) as a single piece. A single-component embodiment works in essentially the same way as other embodiments of the present invention.

A second embodiment of the present invention relates to a drinking vessel comprising an air inlet device that is removably connected to a drinking vessel, for example a bottle. An air intake device in accordance with a second embodiment of the invention includes a closure member, a valve that is tightly detachably attached to the closure member, and an anti-bubble tube that is removably attached to the closure member. The air inlet device attaches or attaches to the opening or neck of the drinking vessel and allows air to pass from the environment into the internal volume of the drinking vessel, which allows the liquid to flow freely from the drinking vessel without the consumer applying a force to suck in the liquid, essentially as noted above. The anti-bubble tube allows the air entering the overturned vessel to reach the air pocket formed in the bottom of the vessel, as noted above.

An anti-bubble tube reduces the likelihood that air entering the vessel will mix with the liquid in the vessel. An anti-bubble tube connects the closure element and creates a passage channel from the valve to the bottom of the vessel. The anti-bubble tube allows the air entering the vessel to pass to the bottom of the vessel and to the air pocket, which will form when the vessel capsizes during its use. The anti-bubble tube mainly covers the valve from the outside, except for covering the opening of the anti-bubble tube located near the bottom of the drinking vessel.

A second embodiment of the present invention will now be described with reference to FIG. 6 and FIG. 7, showing an air intake device according to the present invention mounted on a vessel 211. Said air intake device comprises a closure member 91 in accordance with an alternative embodiment of the invention, the anti-bubble tube 400 and the valve, which may be the valve 10 discussed above. The closure element 91 operates similarly to the closure element 90, except that the closures The th element 91 according to this example is characterized by the execution features noted below, providing a detachable connection between the closure element 91 and the anti-bubble tube 400.

The air inlet device allows air to enter the vessel 211, compensating for the fluid intake from the vessel 211 and thereby preventing the formation of a vacuum inside the vessel 211. In addition, the air inlet device produces a “diving bell” effect, which typically prevents the flow of liquid into the anti-bubble tube 400 until the “diving bell” effect remains in effect. The “diving bell” effect allows the consumer to carefully shake the vessel 211 and fill it with boiling water in the absence of leaks in the contents of the vessel. In addition, the vessel 211 may be completely, i.e. without limitation, filled with liquid. The “diving bell” effect is created by the air trapped in the anti-bubble tube 400 by means of the valve 10. In the closed position, the valve 10 does not allow the air in the anti-bubble tube to escape from the vessel 211. Thus, the trapped air acts as a barrier preventing the entry of liquid into the anti-bubble handset 400.

In the embodiment of FIG. 6, an anti-bubble tube 400 is shown comprising an upper portion 405 and a lower portion 410. The upper portion 405 of the anti-bubble tube extends externally to valve 10, and the lower portion 410 extends over almost the entire height of vessel 211. The volume of the lower portion 410 is larger than the volume of the upper part 405. The volume ratio of the upper part 405 and the lower part 410 is schematically illustrated in FIG. As can be seen in FIG. 8, the volume In the lower part 410 is larger than the volume A of the upper part 405. The anti-bubble tube 400 is connected to the closure member 91. FIG. 7 is a side view of the closure member according to an alternative embodiment of the present invention, using capping element together with anti-bubble tube. The closure element 91 includes a sealing ring 111 for sealing the connection with the inner surface of the neck of the drinking vessel. The circular hole 470 of the upper part 405 of the anti-bubble tube delimits the central part 122 of the closure element 91 from the outside.

In the process of drinking, the valve 10 allows air to enter the vessel in response to the generation of vacuum due to leakage of liquid from the vessel. This initial vacuum causes air to be sucked into the vessel, the influx of which minimizes the effect of the vacuum emerging in the vessel and maintains a substantially lack of vacuum in the vessel. At the same time, said valve does not allow fluid to exit the bottle through the air intake system and thereby create problems. When air enters the vessel 211 through the valve 10 and the anti-bubble tube 400, this “new” air can replace some of the previously trapped air, thereby forcing the trapped air from the anti-bubble tube 400 into an air pocket above the liquid level in the vessel 211. A new portion of air entering the anti-bubble tube supports the “diving bell” effect.

In this embodiment, a connecting ring, such as, for example, the connecting ring 200 described above, is screwed over the closure member 91 and around the neck of the vessel 211. The connecting ring holds the teat in place, for example the teat 425 described above. Air passes between the threaded portion of the neck of the vessel 211 and the threaded part of the connecting ring and enters the holes 136 of the air intake pipe. From the openings 136 of the air inlet tube, air passes through the air inlet tube, valve 10 and the anti-bubble tube 400, and then enters the internal volume of the vessel 211.

An anti-bubble tube 400 has an opening 430 that allows air from the valve 10 to enter the inner volume of the vessel 211. The anti-bubble tube 400 is connected to the closure member 91 and extends almost to the bottom of the vessel 211. Preferably, the anti-bubble tube 400 allows air to enter the overturned vessel 211 s achieving an air pocket formed in the bottom of the vessel 211. As air is sucked into the vessel 211 by removing liquid from it through the openings 170, the anti-bubble tube 400 acts as channel for air exiting the valve 10 through which it reaches the air pocket in the bottom portion of the container (bottle) without mixing with the liquid or the formation of bubbles in the liquid.

9, 10 and 11, a valve 1000 and a closure element 900 are shown in accordance with an alternative embodiment of the invention. This embodiment is particularly suitable for use with a drinking mug. In particular, valve 1000 is described with reference to FIGS. 9A-D. By its function, the valve 1000 is similar to other valves corresponding to the present invention containing a connecting part 1005 and a slot 1010. However, this valve 1000 contains an element for hand grip, shown in the drawings as side sections 1020 with a curved profile, and a base 1060. On Fig. 9B shows the bottom surface 1070 of valve 1000, in which a passage 806 for air passage through the valve is visible.

The lateral sections 1020 with a curved profile allow the user of the valve 1000 to hold and remove the valve 1000 from the closure element, such as the closure element 900, using an additional gripping surface. This design feature is especially useful when trying to remove a wet and slippery valve 1000 that may be covered liquid in the cup or soapy water used in the cleaning process. Although two side portions 1020 with a curved profile of valve 1000 are shown in the drawings, other embodiments may include additional gripping surfaces. The lateral sections 1020 with a curved profile and the base 1060, in addition, provide an additional surface area in the valve 1000, which increases the overall size of the valve 1000. By increasing the overall size of the valve 1000, certain size standards can be met that must be met by children's accessories. The lateral sections 1020 with a curved profile, in addition, provide the user with a large gripping surface around the perimeter of the valve 1000, necessary for rotation when manipulating the valve 1000. The lateral sections 1020 with a curved profile are connected to the base 1060, providing strength and structural integrity of the valve 1000.

In this embodiment, the base 1060 also functions as a connecting part 1005 for attaching the valve 1000 to the closure 900. For example, the closure 900 may be provided with a portion 902 with a recess corresponding in shape to the base 1060 to fit the valve on the closure element using a snap-fit connection. Alternatively, the valve 1000 may be made with a straight tube (not shown) protruding from the channel 806 for the passage of air outside, providing a tight entry into the air channel 940 of the closure element 900.

10A-D illustrate a specific embodiment of the closure element 900. The closure element 900 functions essentially the same as the previously described closure element 90 and closure element 91. However, the illustrated closure element 900 instead of a downwardly extending tube contains a flat disk 910 . The closure element 900 includes air inlet openings 930 that communicate with the air passage 940. In addition, the closure element 900 includes liquid openings 950 that allow fluid to flow from a vessel attached to the closure element 900, to a nozzle or teat mounted on the closure. element 900. The outer edge 102 of the closure element rests on the upper edge of the vessel, while the inner ring 112 fits snugly against the inner wall of the vessel.

The air channel 940 of the closure element 900 is adapted to be connected to the opening 806 of the connecting part 1005 of the valve 1000 during operation. The valve 1000 is provided with an opening or slot 1010, which allows air entering the air channel 940 to enter the mug. The disk 910 of the closure member 900 is easy to clean because it has a flat surface. In addition, due to the flat surface of the disk 910, the valve 1000 is easily attached to the capping element 900.

11, a valve 1000 is attached to the capping member 900. It will be appreciated that the valve 1000 can be attached to the capping member 900 in a known manner, including snap-fit connection and the use of corresponding cavities and protrusions, if in use such connections provide a tight the joint of the valve with the closure element is tight enough to prevent their accidental disconnection during use, but providing ease of removal of the valve for cleaning.

In an alternative embodiment, the air inlet device includes a two-part closure member. In the illustrated embodiment, the closure element includes a disk part and a main part, which, acting together, allow fluid to flow to the nipple or nose of the vessel and, in addition, provide air to the vessel. The main part is attached to the valve or it includes a valve, which allows air to enter the internal volume of the vessel, but prevents the flow of liquid from the vessel through the air inlet device. A preferred embodiment of the main part of the closure element is equipped with a duck nose valve which is sensitive to pressure fluctuations. In another embodiment, such a valve is formed integrally with the main body. If necessary, an anti-bubble tube can be used with the air inlet device.

This embodiment of the invention will now be described with reference to the accompanying figures 12, 13A and 13B, which illustrate an alternative embodiment of an air inlet device 215 that can be used with a vessel, for example with a small bottle or mug for drinking.

The air inlet device 215 includes a main part 305 and a disk part 310. The disk part 310 and the main part 305 are combined to form both air inlet channels and fluid flow openings. Air inlet channels allow air to enter the valve and then pass into the internal volume of the vessel, while the liquid openings allow the liquid to flow out of the drinking vessel and enter the internal volume of the nipple or nozzle.

In the General case, the main part contains a valve, a large number of holes made in the main part for the liquid, and a large number of grooves available in the main part. The main part 305 of the air intake device 215 includes an outer ring 505 and an inner ring 510. The inner ring 510 is located inside the vessel, while the outer ring is seated and rests on the upper edge of the vessel (not shown). The inner ring 510 is preferably made with a slight inclination relative to the peripheral surface of the main part 305 in order to provide a seal on the inner surface of the vessel. An anti-bubble tube, which can be used if necessary, is attached to the main part and generally covers the valve, with the exception of the opening of the anti-bubble tube. This valve is essentially hollow inside and communicates with the air inlet channels of the main part of the closure element, which allows air to pass into the vessel. The valve is made with a hole or slot, which allows air to enter the internal volume of the vessel.

The disk portion 310 and the main body 305 are in shape corresponding to each other, i.e. the disk part and the main part act together, facilitating the inlet of air into the drinking vessel. In addition, the main part 305 contains a large number of grooves for air intake. The air inlet grooves 415 formed in the main body 305 are portions with recesses that connect the valve to the periphery of the main body where the air inlets are located. Air intake tubes 335 to allow air to pass from the atmosphere surrounding the drinking vessel into the internal volume of the drinking vessel are formed by placing the disk portion 310 on top of the air intake grooves 415 formed in the main part, thereby forming inlet tubes for air to enter the main part and, ultimately, to the valve and into the internal volume of the vessel. The disk portion 310 forms and seals the upper portion of the air inlet tubes 335. When the disk part is placed on the main part of the air inlet tube, it is formed completely by the intake pipes and grooves of the main part and the lower surface of the disk part and are sealed as a result of this arrangement with respect to the liquid flow openings. However, as the disc portion 310 is removed, the air inlet grooves 415 made in the main body become fully accessible.

Air enters the vessel through the openings 330 of the tubes and through the air intake tubes 335. The air inlet tubes 335 are in communication with a non-return valve 710 to create an unhindered air flow so that air can pass from the outside of the vessel sequentially through the inlet pipe openings 330, through the air inlet tubes 335, the valve 710 and the opening or slot 715 made in valve. External air can pass between the thread of the connecting ring and the thread on the outer surface of the vessel, made in the form of a baby bottle or mug for drinking in small sips, to the openings 330 of the air inlet tubes.

The air inlet device 215 is further provided with liquid openings 401 that allow liquids, such as milk mixture, juice, milk, etc., to flow out of the bottle or mug for drinking in small sips through the inlet device 215 air and pass into the nipple or nose. The fluid openings 401 can be of any shape such that the stiffness of the air inlet device 215 and the flow of fluid through the openings 401 is stiff. The fluid openings 401 are preferably formed by combining the liquid openings 424 in the main body (shown in FIG. 13B) ) of a closure element, and fluid holes 432 in its disk portion. The holes 424 for the liquid of the main part and the holes 432 for the liquid of the disk part can have various structural designs. The system of holes for the flow of fluid is formed as a result of combining a large number of fluid holes in the disk part with a large number of fluid holes made in the main part. The liquid openings in the main part and the liquid openings in the disk part preferably correspond to each other in shape. This provides stability to the air inlet device and isolates the liquid from the air inlet channels. This insulation prevents liquid from entering the air inlet ducts.

In the embodiment shown in FIG. 12 and FIG. 13A, the disk portion 310 further comprises a large number of fluid openings 432. In this case, each hole 432 in the disk part includes a protruding element 431, which defines the boundaries of the liquid hole 432 in the disk part and extends below the upper surface 371 of the disk part 310. Similarly, the liquid holes in the main part are formed by holes 424 that extend below the upper the surface of the main part and at least through some part of the thickness of the main part of the closure element. The protruding element 431 of the disk portion 310 is included in the main part, i.e. thereby the downwardly protruding element 431 seals the surface 451 of the channels 424 formed by openings for the passage of liquid in the main part 305. Such a seal of the liquid opening in the disk part and the corresponding liquid opening in the main part holds the disk part over the main part and prevents the flow of liquid into the air intake ducts.

Valve 710 allows air to enter the bottle and thereby minimize the vacuum generated therein, however, this valve prevents liquid from flowing into the bottle through the air inlet 215 and the occurrence of fluid leaks. The valve 710 is provided with an opening 715. In accordance with a preferred embodiment, the valve 710 is integral with the main body 305, i.e. the main body 305 and the valve 710 are molded as a single piece, or alternatively, the valve 710 may be connected in some way to the main body 305. During operation of the air intake device 215, the valve 710 typically extends into the vessel. According to one embodiment, the main body 305 comprises a portion for receiving and attaching the anti-bubble tube 800 to said main body 305. The anti-bubble tube 800 allows air flowing into the capsized vessel to reach the air pocket formed in the bottom of the vessel, as noted above. .

An air inlet device 216 in accordance with an alternative embodiment of the invention, which further comprises a two-part closure element is shown in FIGS. 14A, 14B and 15. The air inlet device 216 includes a closure element with the aforementioned disk part 310 and an alternative main body 306. The air inlet device 216 operates substantially in the same manner as the air inlet device 215 discussed above. However, the air inlet device 216 comprises a main body 306 provided with a duck nose valve 701, in which there is a slot 716 for air passage. The operational advantages of the duck nose valve 701 are that it is a more sensitive valve. Therefore, it opens faster under the influence of a very insignificant vacuum, which (due to air intake) allows you to drink from the vessel, and faster and more tightly closes under the influence of external air pressure or liquid pressure. A duck nose valve 701 communicates with air inlet tubes 336, which allows air to enter the vessel. According to a preferred embodiment, the main body 306 and the duck nose valve 701 are molded at the same time, most preferably from silicone.

The tongue 925, which is provided with the main part 306 of the closure element, allows the user to have a hand grip element on the main part 306 when pulling or separating the main part from the disk part 310. The tongue 925 can be made with external ribs 931 to create a friction surface for gripping tongue. When using the device or cleaning it, the main part 306 can be covered with a fluid, for example milk or a cleaning solution, and therefore it is useful for the user to have a tongue 925 to capture and easily separate the main part 306 from the disk part 310. Air inlet tubes 336 (shown on figv) are formed when placing the disk part 310 on top of one or more grooves 416, available on the main part 306. Grooves 416 for air passage, available on the main part 306, are areas in the form of recesses, ph miruyuschih channel through which air enters the main portion 306 and then to the valve and the internal volume of the vessel. When the disc portion 310 is removed, the air inlet grooves 416 made in the main body become fully accessible. When the disk portion 310 is mounted on the second main portion 306, the fluid openings 402 are sealed relative to the air inlet tubes 336 and allow fluid to pass to the nipple or spout. As shown in FIG. 14A, fluid openings 426 in the main body and fluid openings 432 in the disk portion 310 correspond to each other, and their articulation gives strength to the air inlet device 216. In particular, the downwardly extending member 431 of the disk portion 310 seals the surface 436 of the fluid openings 426 in the main body 306. In this embodiment, the main body 306 comprises three fluid flow openings 426.

The device for air intake, consisting of two parts (two parts), is easily assembled and disassembled by the user. It is important to note that the main part and the disk part in the disassembled state are easily cleaned, since almost all of their surfaces, which form the air inlet channels and fluid openings, are completely accessible and can be cleaned without using any special equipment. It is important to note that when the disc part and the main part are disconnected, the air inlet tubes are fully open and accessible for cleaning. This fact is essential for optimal hygiene. The air inlet tubes can be inspected visually in order to check and ensure their cleanliness, which gives confidence that the baby is given a clean bottle.

In some embodiments, the anti-bubble tube 800 may be formed with a heat-sensitive portion of a thermosetting material, for example, obtained from microencapsulated temperature-sensitive plastic. Such plastics allow the use of color change to indicate changes in the temperature of the liquid inside the vessel within certain limits.

The air inlet system may be made of plastic / rubber materials, for example silicone and thermoplastic rubber. The closure element may be made of various plastic / rubber materials, such as thermoplastic rubber. Particularly preferred material used in the air intake device is silicone, since it is easy to clean and safe to use. The anti-bubble tube 400 is preferably made of polypropylene, since it may be exposed to high temperatures, such as boiling water in the case of sterilization. In addition, polypropylene is easy to clean.

As noted above, all embodiments of the present invention are implemented in practice, essentially without the formation of vacuum and in the absence of fluid leaks.

From the above description, it is obvious that certain aspects of the present invention are not limited to the specific details of the exemplary embodiments illustrated herein, and therefore it is intended that those skilled in the art will come to mind with other modifications and practical applications or their equivalents. Accordingly, the claims will cover all of these modifications and practical applications, not beyond the scope and essence of the present invention.

Claims (10)

1. A device for admitting air into a drinking vessel having a tapping device and a connecting ring connecting the tapping device to the vessel, including:
a disk portion having a plurality of liquid openings, which are descending elements;
the main part, made of flexible material, containing many channels for the passage of air passing between the periphery of the specified main part and the only one made at the same time check valve, which in the open position allows air to pass into the drinking vessel, and in the closed position prevents leakage of liquid from the vessel, and also comprising a plurality of fluid openings in the main body corresponding to the descending elements and in conjunction with a seal therewith;
moreover, the disk part and the main part together form channels for the passage of air between the lower surface of the disk part and channels for the passage of air in the main part, while the channels for the passage of air allow air to enter the vessel through the valve. 2. The air intake device according to claim 1, further comprising an anti-bubble tube extending almost to the bottom of the vessel, wherein the anti-bubble tube is detachably connected to the main part and covers the valve from the outside, the anti-bubble tube capturing the volume of the air surrounding the valve when the valve is in the closed position, creating the effect of a "diving bell" in the anti-bubble tube. 3. The device for air intake according to claim 2, in which the anti-bubble tube is equipped with a temperature sensor made of thermosetting material, which serves to indicate the temperature of the liquid in the vessel. 4. The air intake device according to claim 2 or 3, wherein the anti-bubble tube comprises a lower part and an upper part, wherein the upper part of the anti-bubble tube generally encompasses the valve from the outside and the volume of its lower part is larger than the volume of the upper part. 5. A drinking vessel having a tapping device and a sleeve connecting the tapping device with the vessel, including:
a vessel for liquid; and
an air inlet device connected to a liquid vessel, wherein the air inlet device comprises:
a disk portion having a plurality of liquid openings, which are descending elements;
the main part, made of flexible material, containing many channels for the passage of air passing between the periphery of the specified main part and the only one made at the same time check valve, which in the open position allows air to pass into the drinking vessel, and in the closed position prevents leakage of liquid from the vessel, and also containing a plurality of liquid openings in the main body corresponding to the descending elements and being in connection with the seal therewith, thereby forming openings for fluids that allow fluid to flow out of the vessel and prevent fluid from entering the air passages of the main body;
moreover, the disk part and the main part together form channels for the passage of air between the lower surface of the disk part and channels for the passage of air in the main part, while the channels for the passage of air allow air to enter the vessel through the valve. 6. The drinking vessel according to claim 5, further comprising a nipple and a connecting ring attached to the vessel by means of a threaded connection, which connection seals the nipple from the air inlet device, and air passes between the threaded portion of the bottle neck and the threaded portion of the connecting ring, which made with the possibility of the passage of air between them and the entrance to the channel for the passage of air. 7. The drinking vessel according to claim 5, further comprising a nozzle and a connecting ring attached to the vessel by means of a threaded connection, which connection seals the nozzle from the air inlet device, and air passes between the threaded portion of the bottle neck and the threaded portion of the connecting ring, which made with the possibility of the passage of air between them and the entrance to the channel for the passage of air. 8. A drinking vessel according to any one of claims 5 to 7, further comprising an anti-bubble tube extending almost to the bottom of the vessel, wherein the anti-bubble tube is detachably connected to the main part and encompasses the valve from the outside, wherein the anti-bubble tube captures the volume of air surrounding the valve, when the valve is in the closed position, creating the “diving bell” effect in the anti-bubble tube. 9. A method of manufacturing a device for air inlet into a drinking vessel having a tapping device and a connecting ring connecting the tapping device to the vessel, comprising the following steps:
forming a disk portion having a plurality of liquid openings, which are descending elements;
the formation of the main part, made of flexible material containing many channels for the passage of air passing between the periphery of the specified main part and the only one made at the same time check valve, which in the open position allows air to pass into the drinking vessel, and in the closed position prevents leakage of liquid from the vessel into channels for the passage of air, and also containing many holes for liquid in the main part, corresponding to the descending elements;
the connection of the disk part with the main part for forming channels for the passage of air between the lower surface of the disk part and the channels for the passage of air of the main part, allowing air to enter the vessel through the specified channels for the passage of air and the valve, while the holes for the liquid of the disk part are hermetically connected to the holes for the liquid of the main part, forming holes for the liquid, which allow the liquid to flow out of the vessel and prevent the passage of liquid into the channels for air passage. 10. The method according to claim 9, further comprising connecting the anti-bubble tube to the main part and surrounding the valve from the outside, wherein the anti-bubble tube captures the volume of the air surrounding the valve when the valve is in the closed position, while the “diving bell” effect is created in the anti-bubble tube ".

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