DE102015102142A1 - Cooling element for beverage cans, self-cooling beverage can and method - Google Patents

Abstract

The invention relates to a cooling element for a beverage can. In particular, the invention relates to a cooling element which cools the contents of the can quickly. The invention further relates to a self-cooling beverage can and a method for cooling a beverage can. The cooling element comprises a reaction space enclosed by liquid-tight outer walls, in which a first reactant can be stored, and a storage space in which a second reactant can be stored, wherein the reaction space and storage space are separated by a mechanically destructible membrane, and the storage space is completely inside the Reaction space is arranged. It is characterized in that the membrane consists of a liquid-tight elastic material and can be placed under tension when storing the second reagent. The method is characterized in that the membrane is mechanically destroyed to achieve a cooling reaction, and an active mixing of the reaction space by means of mixing takes place.

Description

introduction

The invention relates to a cooling element for a beverage can. In particular, the invention relates to a cooling element which cools the contents of the can quickly. The invention further relates to a self-cooling beverage can and a method for cooling a beverage can.

State of the art and disadvantages

Beverage cans (hereinafter also referred to as "cans" for short) have long been known from the prior art. They are used for storage and transportation of "still" or carbonated, so under pressure, drinks.

Typically, the beverage is taken out of the can. For this purpose, the same is opened by means of a closure by the user. This closure is typically designed as a single closure, but there are also concepts for reclosability known. An example of such a concept is in the document EP 2 614 010 A1 shown. The closure is integrated exclusively in the lid of the can. The remaining body of the can ("body", usually cylindrical side wall with bottom) is unchanged compared to conventional, non-resealable cans, which is advantageous for manufacturing.

The base material for beverage cans is usually an aluminum alloy. The body is deep-drawn, the top edge crimped (bent outward), the lid is prepared separately and attached gas-tight and liquid-tight, for example by means of Auffalzen on the body.

Because canned beverages are predominantly preferentially consumed chilled, but transport and storage take place at normal ambient temperatures, it is desirable to sufficiently cool the can before consumption. This can be done in the simplest case by means of longer storage in a refrigerator. However, because of their high stability and low weight, cans are often brought to places where such refrigerators are not available (in the car, on walks, ...). Thus, there is a desire for a can, which nevertheless provides a sufficiently cool content regardless of known, in particular current-driven cooling devices. It is particularly desirable that the cooling takes place sufficiently fast.

From this need, a variety of concepts have been developed to cool a can by means of an integrated, preferably energy self-sufficient, cooling device.

The cooling principles are in particular the adiabatic expansion of a gas (Joule-Thompson effect), adiabatic cooling (evaporation cooling), and the use of salt mixtures into consideration.

An example of a self-cooling can with salt mixture is in the document EP 0 286 382 A2 shown. Accordingly, inside the can is a shielded from the drink, but accessible from the outside cylindrical container (cooling element). In this, a salt (eg ammonium nitrate) or a solvent (eg water) are stored separated by a membrane in two chambers. In a channel which is accessible from the outside through the lid of the can, and which is preferably initially closed with a protective cover, a needle is arranged. This passes through a first chamber limiting the outward end and ends in the rest position just before the membrane in the first chamber. To initiate the cooling, the needle is actuated by pressing from the outside. It penetrates the separating membrane so that salt and solvent can mix and extract heat from the environment. This leads to the desired cooling effect.

Two other examples of a self-cooling can are in the document DE 2 150 305 A1 disclosed. Even after one of these solutions, the interior of the cooling element is accessible from the outside to actuate the cooling mechanism and thus trigger. According to another solution, an actuatable from the bottom of the can forth, designed as a "double bottom" designed cooling element, in which the membrane is severed by means of a mandrel which is movable by pressing the outer bottom in the direction of the membrane.

However, the solutions known from the prior art have the disadvantage that the cooling process can take a considerable amount of time.

Object of the invention and solution

The object of the invention is therefore to provide a cooling element for a beverage can, with which a faster cooling effect can be achieved.

The object of the invention is also to provide a beverage can with a disadvantage of the prior art avoiding cooling element.

The object is achieved by a cooling element according to claim 1 or a beverage can according to claim 11, as well as a method for cooling a beverage can according to claim 13. Preferred embodiments are given in the dependent claims, the description and the figures.

description

The cooling element according to the invention will first be described below. Subsequently, a description of a beverage can with the cooling element according to the invention. Finally, a description of the method according to the invention is given.

The cooling element is intended to be introduced into a beverage can for cooling its contents.

The cooling element comprises a reaction space enclosed by liquid-tight outer walls, in which a first reactant can be stored, and a reservoir, in which a second reactant can be stored, wherein the reaction space and reservoir are separated by a mechanically destructible membrane. The spaces are preferably filled with a liquid and / or a solid. Particularly preferably, the reaction space is filled with a solid, in particular a salt, and the storage space is filled with a solvent, in particular water. By mixing the two substances, a chemical reaction is initiated, in the course of which heat is removed from the environment.

In addition, the storage space is arranged completely in the interior of the reaction space. In other words, the separation of the two reactants is not achieved by a two half-spaces separating planar membrane, but the reservoir consists essentially of the membrane, which is closed on all sides, and so a cavity, namely the reservoir, enclosing and thus provides.

According to the invention, the membrane is made of a liquid-tight elastic material or comprises such a material, and can be put under tension when storing the second reagent. Both linear behavior materials and a non-linearly behaving (rubbery) material such as an elastomer, rubber, vulcanized rubber, silicone rubber, or elasticity-comparable materials preferably have moduli of elasticity in the range of 10 ⁷ to 10 ⁸ N / m ² are suitable. The material should also be liquid-tight; Accordingly, porous or even textile materials are out of the question, since otherwise undesired premixing of the liquid with the solid reactant can occur.

The advantage of a membrane made of an elastic material lies in the particularly effective possibility of the mechanical destructibility of the same, which will be discussed later.

According to a preferred embodiment, the storage space is formed by a balloon or bag which can be filled with the second reagent. In other words, a bag made of an elastic material is filled with the second reactant, whereby the bag expands elastically according to the amount of the filled agent. It is clear that a limit must not be exceeded, from which an inadvertent tearing of the bag becomes too probable. However, it is also clear that after filling, the bag should have a taut surface on all sides, with smaller non-smooth or non-elastic areas, e.g. a closure area are unproblematic.

After filling, the balloon preferably has a volume which is at least 1.2, preferably at least 1.5, and particularly preferably at least 2 times greater than the volume in the unfilled state. Accordingly, the material is capable of withstanding strains of 20%, 50%, or more preferably more than 100% without tearing.

The advantage of a storage space designed as a balloon lies in its ease of manufacture and filling. The advantage of a stretched in the way of filling reservoir is in a further improvement of the easy destructibility of the membrane (and thus the walls of the reservoir), since such a reservoir after a minor initial damage virtually spontaneously spontaneously destroyed (ruptures).

Particularly preferably, the balloon-like storage space has an elongated shape. It therefore has a longitudinal axis which is significantly larger than a transverse axis perpendicular thereto. It may therefore preferably have the form of an oblong cylinder closed on both sides, the two ends being e.g. hemispherical or otherwise rounded, or may be configured flat conclusion. The shape of an elongated cushion, which optionally has a peripheral connecting seam, is conceivable.

The advantage of this form lies in the easy filling. In addition, beverage cans usually have an elongated, cylindrical shape, so that a correspondingly shaped cooling element with a correspondingly shaped storage space on the one hand allows a particularly good space utilization, and on the other hand provides a particularly large area for heat transfer, resulting in a stronger, faster cooling of the can contents.

According to a particularly preferred embodiment of the cooling element, the volume of the storage space is filled next to the second reactant with a pressurized gas. This means that a gas such as an air bubble is contained in the interior of the storage space, which is compressed due to the tension of the membrane, thus therefore is under pressure.

Experiments have surprisingly shown that the presence of a gas bubble in the reservoir, which claims approximately between 3% and 50%, preferably between 10% and 30%, and more preferably between 15% and 25% of the volume of the reservoir, bursting the membrane promotes or even makes possible.

Thus, a mechanical penetration of the membrane, which is indeed associated with a deformation of the same, easier to achieve when the deformation of less resistance is opposed. This is easier in the area of a gas bubble than in solid filled areas. Also, the solid surrounding the membrane on the membrane such a high friction that the membrane without said gas bubble does not necessarily tear, but only perforated or cut, so that the liquid then exits only slowly. By contrast, with gas bubble and membrane tension, the balloon bursts clearly more reliably, as could be shown in experiments.

According to a further embodiment, the cooling element has an externally operable means for mixing the reaction space. "Outside" means that the means for mixing is operable by a user holding the box in hand, for example, without opening the can, and in particular without the food space provided for storing the beverage.

The device is accordingly suitable for generating turbulences in the interior of the reaction space by means of mechanical action, wherein the energy required for actuation can be provided by the user.

The advantage of such a device is the fact that by actively mixing the two reactants they can react better and more completely than would be the case with a mere diffusion. In fact, it has been found that a pure diffusion mixture may take several days, with no useful cooling effect being observable, whereas active mixing results in minute reaction times within which a correspondingly high cooling is achievable.

According to one embodiment, the means for mixing on a rotatably mounted about an axis of rotation in an outer wall of the reaction chamber and this passing through stirring hooks, on whose outside the beverage can lying distal end a manually operable handle is attached or attachable.

"Hook" means any type of geometry, which can be achieved by a possibly repeatedly bent rod, and which extends through the cooling element at least partially parallel to the direction of its longitudinal axis. Preferably, the device passes through the reaction space almost completely in the direction of the longitudinal axis, and has at least one, preferably two or more mixing arms, which extend at least partially parallel and bent straight or helical in order to achieve the best possible mixing. Optionally, additional mixing aids, such as wing panels, e.g. be attached from foils to the mixing arms.

The advantage of such a stirring hook is the same in the space-saving operation, since the typically associated with its outer end handle for actuating only needs to be rotated, which does not or only slightly changed the length of the can.

Preferably, the rotatable means for mixing is also rotatably mounted on the opposite end of the reaction space to the passage. This can be done in a simple manner in that the device has an extension there, which is supported on the inner wall of the reaction space, said inner wall at the support point, a storage, for example, a circular recess, which cooperates with the extension.

It is clear that, if the cooling element is completely housed in the can, the can must also have a corresponding passage for the axis of rotation of the means for mixing.

According to a preferred embodiment of the handle this is button or plate-like design and has at its peripheral edge recesses or ribbing to improve the handling, and / or has on its side facing away from the can outside one or more finger hollows, which also improve the handling. After another Embodiment, the handle is designed hinged, so that it can be folded out of the recessed bottom portion of the box if necessary, to allow easy rotation of the device for mixing. Of course, any other known from the prior art for this purpose constructions are usable.

According to another embodiment of the means for mixing this has a along a longitudinal axis axially slidably mounted in an outer wall of the reaction chamber and passing through this rod, at its proximal end a preferably arranged approximately perpendicular to the axis of the rod mixing structure is attached, and at its distal End of a manually operable handle is attached or attachable.

Accordingly, this embodiment is actuated not by rotation but by alternating axial movements of the mixing structure. The mixing structure is sized and designed so that it can be pushed while moving through the liquid-solid mixture and this causes turbulence. In this case, the mixed structure separates the reaction space into two variable-volume half-spaces, the two half-spaces, of course, not being separated in a liquid-tight manner, but rather a flow through the mixing structure being possible, leading to the desired turbulence. The mixing structure may be configured, for example, as a perforated plate or as a not too fine grid, which or which is approximately perpendicular to the direction of movement and thus to the longitudinal axis.

The mixing structure can be fixed or flexible. A flexible mixing structure has the advantage that one does not have to completely raise a surrounding solid (salt) in order to destroy the membrane with a lancing device (see above) attached to it (this would, however, be necessary in the case of a solid mixing structure).

It is clear that, if the cooling element is completely housed in the can, the can must also have a corresponding passage for the longitudinal axis of the means for mixing.

The advantage of such a device for mixing is the very good and rapid mixing of the two reactants and the ability to create a stable means by simple means, since no torsional, but essentially only axial forces act on the device.

According to a further embodiment of the cooling element, this further comprises a lancing device for mechanically destroying the membrane. A lancing device is therefore a component which is suitable for effecting the destruction of the membrane by means of concentration of forces. This is achieved in that the lancing device has one or more tips, which can be brought into contact with the membrane of the storage space, as soon as the desired cooling effect is to be caused. It is clear that the lancing device must be constructed and arranged in such a way that it can not previously interact with the membrane in such a way that it is destroyed even with stronger movements of the can.

The advantage of the lancing device is the simplification of the destruction of the membrane, since due to the concentration of force less external forces are to be provided. In addition, the destruction of the membrane is controlled possible as without lancing device.

According to one embodiment of the lancing device, it passes through an outer wall of the reaction space and can be actuated directly from the outside. This means that the forces required to actuate the lancing device, for example for moving them into the vicinity of the membrane or even into it, are transmitted to the tip by an actuating device which is mechanically directly connected to the tip. Such an actuator is, for example, an externally accessible lever, a tear thread or a needle.

It is clear that, if the cooling element is completely housed in the box, the box must also have a corresponding passage for the lancing device.

The advantage of an externally accessible lancing device lies in the possibility of being able to apply relatively high forces to the membrane due to the direct mechanical coupling.

According to another embodiment of the lancing device, this is arranged completely in the interior of the reaction space, and it can be actuated directly or indirectly by means of the device for mixing from the inside. This means that the lancing device itself does not have its own mechanically accessible externally accessible actuator, but is housed entirely inside the reaction chamber.

For actuation, the lancing device can be actuated directly by means of the mixing device. This means that the lancing device, for example in the form of a needle, is attached directly to the device for mixing and, when moving the device, is carried along by it and pierced into the membrane.

To operate the lancing device but also be indirectly actuated. This means that it is not connected to the means for mixing, but is, for example, on the inner wall of the reaction chamber. By pressing the means for mixing either the pantry is moved so that it is pressed against the lancing device, or the first flat fitting against the inner wall lancing device, for example, due to a hinge-like attachment, entrained by the onset of movement of the device for mixing of this and so unfolded in the interior of the reaction chamber, where it finally comes in contact with the membrane and destroys it.

The advantage of an internal lancing device is to be seen in the simpler design, since no penetrations through the reaction space and possibly the can are required for the lancing device. The provision and operation of a separate actuator omitted, since the lancing device is activated together with the means for mixing. In other words, the means for mixing serves as an actuator.

It will be understood that all of the listed embodiments are merely exemplary illustrations of the inventive idea, and not a limitation of the invention. It is also clear that the examples, as far as technically possible and reasonable, can also be combined with one another without departing from the inventive idea.

The invention also relates to a self-cooling beverage can.

Preferably, the cooling element is fixed with at least one of its outer walls on at least one of the inner walls of the can, so that it can not move freely inside the can. Preferably, can and cooling element can also have a common wall. This is particularly preferably the underside of the can, which is formed by a correspondingly adapted outer wall of the cooling element.

A can constructed in accordance with the invention has the advantage of being able to cool down particularly quickly to a desired temperature. For the rest, reference is made to the above explanations in order to avoid repetition.

The invention also relates to a method for cooling a beverage can, wherein the latter comprises a cooling element which has a reaction space with a first reaction agent and a reservoir arranged completely in the reaction space with a second reaction medium, wherein the reaction space and reservoir are provided by a mechanically destructible, elastic and prestressed membrane are separated from each other. For an explanation of the mechanical structure and relationships, reference is made to the above explanations in order to avoid repetition.

According to the invention, the elastic and prestressed membrane is mechanically destroyed to achieve a cooling reaction, and an active mixing of the reaction space by means for mixing takes place. In other words, the at least partial destruction of the elastic membrane eliminates the separation between the reservoir and the reaction space, and the two reactants come into mutual contact. In order to bring about the fastest possible cooling down, it is necessary to achieve the fastest possible and uniform mixing of the two reactants, which takes place in an active manner. In this case, "active" means that turbulences are generated inside the reaction chamber by a mechanical aid, namely the means for mixing, and not only slow diffusion processes lead to a cooling reaction.

By active mixing a much faster cooling of the can is achieved.

According to a preferred embodiment, the membrane is set under tension by the filling with the second reactant, so that it automatically ruptures during mechanical destruction. In other words, the membrane which is elastic according to the invention expands by way of filling with the second reactant; In this case, the surface of the storage space, which is formed by the membrane, set under tensile stresses. This process is similar to the known filling of a balloon with gas or liquid. If the filled balloon is only slightly damaged at one point, it spontaneously ruptures (bursts) without further action. At the same time, the membrane, which can now relax again, contracts sharply and thus releases the volume of the storage space no longer surrounded by walls.

The advantage of a stretched in the way of filling storage space is therefore in a significant improvement of the easy destructibility of the membrane (and thus the walls of the storage space), since such a reservoir after a minor initial damage virtually automatically destroyed further (ruptures). The contact area between the two reactants is then significantly larger than in a conventional, engraved separation membrane, since this provides an opening for the exchange of funds, the exchange but only slowly, as it has to drain through the relatively small opening. In addition, the spontaneous rupture of the membrane releases the mechanical forces stored in it, which contribute significantly to a further mixing of the two reactants.

According to a preferred embodiment, the mechanical destruction is achieved by acting on the membrane by means of a lancing mechanical forces which are provided directly or indirectly from the inside to the lancing device directly from the outside, or by means of the means for mixing the lancing device. In other words, the required initial minor damage to the membrane is achieved by means of the lancing device described above. This can, as also described above, directly from the outside, or activated directly or indirectly by means of the means for mixing, so moved in the direction of the membrane, to damage them. It is clear that hereby a relative movement is meant; Thus, the same effect of the damage is achieved in that the membrane of the storage space is moved in the direction of the lancing device, which is preferably done by manipulation with the means for mixing.

According to one embodiment, the beverage can is re-closable, thus has a closure mechanism which is operable from the outside and leads to an at least approximately liquid-tight closure of the spout. In this way, the drink can be cooled before opening and the can be closed again after opening.

Since such mechanisms have moving parts, it is advantageous to arrange these moving parts so that they do not interfere with the operation of the cooling element or. This is ensured by the arrangement of the closure on the upper side and the components of the cooling element on the underside of the can serving for the actuation.

As stated, the cooling element according to the invention solves the known from the prior art problem of slow cooling. This is achieved by optimizing the contact surfaces of the two reactants, which lead in contact with the cooling effect, by the reservoir of one of the two reactants is formed by an elastic and prestressed membrane which is disposed within the reaction space with the other reactant, wherein by a From the outside initiable tearing of the membrane a very good and fast mixing of the two reactants is possible.

figure description

The invention will be explained in detail below with reference to exemplary embodiments shown in FIGS.

1 shows a beverage can with a first embodiment of a cooling element in a sectional view before initiating the cooling process.

2 shows the beverage can 1 when inserting the lancing device.

3 shows the beverage can 1 damaging the membrane of the storage room.

4 shows the beverage can 1 during mixing of the reaction space.

5 shows a beverage can with a second embodiment of a cooling element in a sectional view before initiating the cooling process.

6 shows the beverage can 5 when inserting the lancing device.

7 shows the beverage can 5 during mixing of the reaction space.

8th shows a beverage can with a third embodiment of a cooling element in a sectional view before initiating the cooling process.

9 shows the beverage can 8th when triggering the lancing device.

10 shows the beverage can 8th during mixing of the reaction space.

11 shows a beverage can with a fourth embodiment of a cooling element in a sectional view before initiating the cooling process.

12 shows the beverage can 11 when triggering the lancing device.

13 shows the beverage can 11 during mixing of the reaction space.

14 shows a beverage can with a fifth embodiment of a cooling element in a sectional view before initiating the cooling process.

15 shows the beverage can 14 when triggering the lancing device.

16 shows the beverage can 14 during mixing of the reaction space.

17 shows a beverage can with a sixth embodiment of a cooling element in a sectional view before initiating the cooling process.

18 shows the beverage can 17 in a plan view as a sectional view.

19 shows the beverage can 18 when triggering the lancing device during the mixing of the reaction space.

In the 1 a beverage can with a first embodiment of a cooling element is shown in a sectional view prior to initiating the cooling process.

The beverage can 1 initially resembles a conventional can, as it has been commercially available for a long time. It may have an internal volume of, for example, 500 ml, 330 ml for the beverage (not shown), and the remaining interior volume for the cooling element 2 are provided. The can is (as well as all cans shown below) with the closure (no reference) shown down.

The cooling element 2 includes one of liquid-tight exterior walls 3 enclosed reaction space 4 in which a first reagent can be stored (not shown). The first reactant is preferably a solid.

The cooling element 2 also includes a pantry 5 in which a second reagent can be stored (not shown). This second reagent is preferably a liquid. Furthermore, the pantry contains 5 an optional gas bubble 6 , which is formed for example by an inert gas or air.

reaction chamber 4 and pantry 5 are due to a mechanically destructible membrane 7 separated from each other. Accordingly, the membrane encloses 7 the volume of the presently elongated storage space 5 and essentially forms its spatial boundaries. Like from the 1 The storage room is visible 5 completely inside the reaction space 4 arranged. In other words, the reaction space 4 encloses the storeroom 5 Completely.

The membrane 7 consists of a liquid-tight elastic material such as rubber or rubber. Thus, it can be put under tension when storing the second reagent, comparable to a balloon. This means that (possibly including the volume of the gas bubble 6 ) more second reagent in the pantry 5 can be filled as the volume of the pantry 5 allowed in the relaxed state. Due to the extensibility of the membrane according to the invention 7 this widens, so that more second reagent can be filled, wherein the membrane 7 increasingly being put under tension. Possibly. The tension can also exclusively or additionally through the gas bubble 6 be generated by under pressure a correspondingly large volume of gas in the pantry 5 is filled. It is clear that the pantry 5 must be closed liquid and gas tight after filling.

Furthermore, the cooling element 2 an externally operable means for mixing 8th of the reaction space. This has the task of mechanically mixing the interior of the reaction space 4 to enable. The illustrated embodiment has a rotatable in the overhead outer wall of the reaction space 4 mounted and this passing, present one-armed stirring hook 9 on. At its distal end (at the top of the picture) is a manually operated handle 10 appropriate. It is clear that the storage must at least be liquid, preferably also pressure-tight, so that liquid contained in the reaction space can not escape to the outside at any time. This is a septum 11 provided of elastic material. According to the embodiment shown, this is arranged in a cavity between two plastic discs, which in turn the outer end of the cooling element 2 form and close tightly with its sidewalls.

In order to initiate the cooling process, the membrane must first 7 be destroyed so that the first and second reactants come into contact with each other and the cooling reaction can get started. In 2 it is shown that this is a lancing device 12 , which is designed here as a needle, in a channel 13 can be introduced (small arrow, step 1). This channel 13 pervades both the handle 10 , as well as in the picture overhead outer end of the reaction space 4 , This lancing device 12 as well as the others, described below, serve or serve the concentration of forces for the purpose of facilitating the destruction of the membrane.

3 shows the situation with inserted lancing device 12 , This passes after insertion (step 2) now the handle 10 and the septum 11 and reaches through the reaction space 4 the pantry 5 , There she can see the prestressed membrane 7 to damage. As shown penetrates the lancing device 12 the place of the storeroom 5 in which is the gas bubble 6 located.

Subsequently, the lancing device 12 back out of the canal 13 be removed (step 3).

By piercing the membrane 7 This tears on automatically, similar to a bursting balloon. The in the storeroom 5 contained second reactant comes abruptly with the surrounding reaction space 4 in contact, and the cooling reaction begins.

To further accelerate the cooling reaction, as in 4 now shown the device for mixing 8th operated by rotation (step 4) about its axis of rotation. The small curved arrows at the bottom of the picture symbolize turbulence generated by the rotation inside the reaction space. Thus, its content is actively mixed, and the cooling reaction can be particularly fast and complete.

After the beverage (not shown) sufficient due to the heat transfer through the wall of the reaction space 4 has cooled through, the can 1 turned over and opened by means of the lock.

The 5 to 7 show a further embodiment, according to which the lancing device 12 permanently in the tin 1 remains. Her head is hidden under a deformable cover (no reference). By pressing on this cover ( 6 , Step 1) reaches the reservoir (not shown) and destroys the membrane (not shown). By operating the device for mixing 8th ( 7 , Step 2) becomes the reaction space 4 mixed. At the same time breaks the tip of the lancing device 12 due to the movement of the stirring hook 9 so that it is no longer in the way of its further movement. The lancing device may preferably have a predetermined breaking point for this purpose. According to an alternative embodiment, the tip folds over, preferably also around a predetermined bending point.

The advantage of this embodiment is the simpler and safer operation, since the lancing device 12 no longer out of the can 1 must be removed.

In the 8th to 10 is shown a further embodiment in which the lancing device 12 designed as a ripcord with retaining ring. How out 8th Recognizable the externally accessible ripcord runs on the outside of the membrane 7 along. By pulling on the retaining ring ( 9 , Step 1) ruptures the membrane. By operating the device for mixing 8th ( 10 , Step 2) becomes the reaction space 4 mixed.

Another embodiment of the lancing device is in the 11 to 13 shown. Accordingly, the lancing device 12 designed as a lever. As in 11 recognizable, the fulcrum is for example in the area of the septum 11 arranged. Under control 10 is an elongated depression introduced, from which a slider 14 protrudes.

By pressing the slider 14 in the direction of the arrow ( 12 , Step 1), the lever tilts, and the tip of the lancing device 12 penetrates the membrane 7 which is ripping. Subsequently, by means of the mixing device 8th the reaction space 4 be mixed ( 13 , Step 2). In the construction shown, the tip of the lancing device 12 after pressing the slider 14 such in the vicinity of the axis of rotation of the device for mixing 8th tilted, that it does not hinder the rotation of the same. This is achieved by the portion of the stirring hook that is close to the axis of rotation and extends transversely to the longitudinal axis 9 is arranged further in the direction of the longitudinal axis than the tip of the lancing device 12 , A possible grinding of the tip on the axis of rotation, however, is unproblematic.

The advantage of this embodiment is the ease of use and the whereabouts of the lancing device 12 at the can 1 ,

Another embodiment of the lancing device is in the 14 to 16 shown. According to this embodiment, the means for mixing comprises 8th an axially displaceable in an outer wall of the reaction space 4 stored and passing through this rod 15 on, at its proximal (inner) end of a mixed structure 16 is attached, and at its distal (outer) end of a manually operable handle 10 is appropriate.

According to this embodiment, the lancing device 12 completely inside the reaction space 4 arranged, and it is directly by means of mixing 8th operated from the inside.

As in 14 recognizable passes the rod 15 the sealing septum 11 , The axial direction passes through the can 1 in the picture in the vertical direction (longitudinal axis).

To destroy the membrane 7 will be the device for mixing 8th by means of the handle 10 drawn parallel to the longitudinal axis in the axial direction of the can ( 15 , Step 1). The at its distal end also arranged lancing device 12 approaches the membrane 7 and destroy them. Due to the bias of the membrane 7 and its sudden relaxation takes up little space, so they 16 , Step 2) not hindered. This is done by mixing the device 8th several times in the axial direction is moved back and forth. The mixed structure 16 , which is designed here as a perforated plate leaves a part of the Mixtures of first and second reactants pass through their openings, creating turbulence, which favor mixing in the desired manner.

Another embodiment of the lancing device is in the 17 to 19 shown. According to this embodiment, the lancing device 12 completely inside the reaction space 4 arranged, and it is indirectly by means of the mixing device 8th operated from the inside.

17 shows that the lancing device 12 is present in the form of three pointing in the direction of the reaction chamber interior cutting, and on the inner wall of the reaction space 4 is appropriate. In the sectional view after 18 it can be seen that the sheaths of lancing devices 12 first to the wall of the reaction space 4 are folded. Preferably, two lancing devices 12 in the reaction room 4 present, which are folded in the opposite direction. Thus, the membrane 7 protected against accidental damage. If the device is to mix 8th , as in 19 shown in rotation (step 1), so takes the stirring hook 9 with its longitudinally extending arms (in the 19 perpendicular to the image plane) the cutting edges of the lancing device 12 with, so that these in the interior of the reaction space 4 protrude and the membrane 7 can destroy.

LIST OF REFERENCE NUMBERS

1

Soda can, can

2

cooling element

3

exterior walls

4

reaction chamber

5

pantry

6

gas bubble

7

membrane

8th

Device for mixing

9

stirring hook

10

Handle

11

septum

12

lancing

13

channel

14

pusher

15

Rod

16

mixed structure

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2614010 A1 [0003]
• EP 0286382 A2 [0008]
• DE 2150305 A1 [0009]

Claims (15)

In a beverage can ( 1 ) for cooling its contents einbringbares cooling element ( 2 ), comprising a reaction space enclosed by liquid-tight outer walls ( 4 ), in which a first reagent can be stored, and a storage space ( 5 ) in which a second reactant can be stored, wherein reaction space ( 4 ) and storeroom ( 5 ) by a mechanically destructible membrane ( 7 ) are separated from each other, and the storage space ( 5 ) completely inside the reaction space ( 4 ), characterized in that the membrane ( 7 ) consists of or comprises a liquid-tight elastic material and can be placed under tensile stress when storing the second reagent. Cooling element ( 2 ) according to claim 1, wherein the storage space ( 5 ) is formed by a balloon which can be filled with the second reagent. Cooling element ( 2 ) according to claim 1 or 2, wherein the storage space ( 5 ) has an elongated shape. Cooling element ( 2 ) according to one of claims 1 to 3, wherein the volume of the storage space ( 5 ) is also filled with a pressurized gas. Cooling element ( 2 ) according to one of the preceding claims, characterized in that it comprises an externally operable means for mixing ( 8th ) of the reaction space ( 4 ) having. Cooling element ( 2 ) according to claim 5, wherein the means for mixing ( 8th ) a rotatable in an outer wall of the reaction space ( 4 ) and these passing through stirring hooks ( 9 ), at whose distal end a manually operable handle ( 10 ) is attached or attachable. Cooling element ( 2 ) according to claim 5, wherein the means for mixing ( 8th ) an axially displaceable in an outer wall of the reaction space ( 4 ) and passing through them ( 15 ), at its proximal end a mixed structure ( 15 ) is attached, and at the distal end of a manually operable handle ( 10 ) is attached or attachable. Cooling element ( 2 ) according to any one of claims 1 to 7, further comprising a lancing aid ( 12 ) for mechanically destroying the membrane ( 7 ). Cooling element ( 2 ) according to claim 8, wherein the lancing aid ( 12 ) an outer wall of the reaction space ( 4 ) passes through and can be actuated directly from the outside. Cooling element ( 2 ) according to claim 8, wherein the lancing aid ( 12 ) completely inside the reaction space ( 4 ) and directly or indirectly by means of the mixing ( 8th ) is actuated from the inside. Self-cooling beverage can ( 1 ) comprising a cooling element arranged and fastened inside thereof ( 2 ) according to any one of the preceding claims. Self-cooling beverage can ( 1 ) according to claim 11, wherein it is reclosable. Method for cooling a beverage can ( 1 ), which is a cooling element ( 2 ) comprising a reaction space ( 4 ) with a first reagent and a completely in the reaction space ( 4 ) arranged storage space ( 5 ) having a second reactant, wherein reaction space ( 4 ) and storeroom ( 5 ) by a mechanically destructible, elastic and prestressed membrane ( 7 ) are separated from each other, characterized in that to achieve a cooling reaction the membrane ( 7 ) is mechanically destroyed, and an active mixing of the reaction space by means for mixing ( 8th ) takes place. The method of claim 13, wherein the membrane ( 7 ) is set under tension by the filling with the second reactant, so that it automatically ruptures during mechanical destruction. A method according to claim 13 or 14, wherein the mechanical destruction is achieved by applying to the membrane ( 7 ) by means of a lancing device ( 12 ) mechanical forces acting directly on the lancing device ( 12 ) from the outside, or by means of mixing ( 8th ) directly or indirectly to the lancing device ( 12 ) are provided from the inside.

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