NO852720L - CAN TO AA COOL OR AA KEEP HOT GOODS TO BE INCLUDED IN THE CART. - Google Patents

Description

This invention relates to a vessel in accordance with the introduction to patent claim 1.

With the known construction method, the goods to be cooled are placed

and at least one cooling accumulator in the vessel's storage space.

It is then not possible to place the goods to be cooled and the cooling accumulator in an orderly position in relation to each other. This leads to the goods to be cooled and the cooling accumulator blocking each other by coming into contact with each other, with the result that it is impossible to remove the accumulator or the goods in an appropriate way. In order to take out or wrap one of these objects, it is then necessary to shake or move them or even take them out. The cooling accumulator is also not fixed to any particular place in the storage room so that the handling of the tub leads to the goods and the accumulator being displaced in relation to each other with the resulting disadvantages.

The purpose of this invention is to design a vessel of the kind mentioned at the outset in such a way that one achieves easy handling of the accumulator and the goods when inserting and removing, while at the same time it is possible to ensure an orderly placement of the accumulator and the goods in relation to each other in the recording room.

This task is solved using the features specified in the characteristics of the main requirement.

The most significant advantage of the invention is that the accumulator is fixed in the storage room and that both the accumulator and the goods, especially when this is in one piece, e.g. a bottle, which can be taken out of the reception room if desired, or can be inserted into the room, without the need to move or support the objects. Therefore, the design according to the invention is particularly suitable for vessels for eating and drinking, because the accumulator does not come into contact with the food or drink and can be replaced without difficulty whenever desired.

The designs according to patent claims 2 to 4 lead to large installation surfaces, so that an intensive heat release, or heat absorption is achieved. In the embodiment according to claim 3, the entire cross-sectional area of the receiving space is utilized. According to claim 4, the accumulator's capacity as a result of space utilization in the free space is maximum.

The embodiment according to claim 5 is advantageous because the container

is removable and handling is therefore improved also with regard to cleaning. At the same time, the fixing of the container in the house is secured according to requirement 6.

According to claim 7, it is possible to design the housing and the container

in one single piece. Features specified in claim 8 result in an increased installation surface. Thus, the ratio between the energy transmitted in the area of this installation surface and the energy emitted or absorbed by the accumulator's other surface is correspondingly greater. This means that the energy transfer between the accumulator and the goods takes place with less loss. At the same time, not only is a transfer of energy with less loss possible, but also a faster transfer, because relatively large transfer surfaces are available. The inventive design is not only suitable for a cylindrical contact surface, but also for planar contact surfaces. In the first case, the accumulator which is designed in accordance with the invention protrudes in a U-shape above the goods or the container, when the contact surface is brought back or concave, or the accumulator protrudes into the goods or into the container, when the contact surface projects forward or is convex. A particular advantage is the appropriate design of the container with a vaulted mantle surface or with a round cross-sectional shape.

The features specified in claim 9 are particularly suitable for handling containers for foodstuffs (oval containers) and beverage containers (round containers).

The design according to claim 10 is advantageous in that the accumulator can be introduced into the free space both with one and with the other end.

The features stated in claims 11 and 12 enable appropriate inventive design and at the same time advantages with placement of the accumulator between two or more containers. With regard to claim 11, the advantages mentioned in connection with claim 7 are also achieved.

The design according to claim 13 allows the accumulator to be formed from two identical accumulator parts placed between the construction rafts with the containers, which is particularly advantageous when the accumulator is placed between two or more (star-like arranged) containers. This design is advantageous in that, as a result of their relatively larger surface, the accumulator parts can be charged faster and, secondly, that you then get separate, internal accumulators that can also be used for other cooling or heating purposes.

When the tub's housing according to claim 14 is made of plastic material, the housing can be produced simply and cheaply, and when ordinary plastic material without particularly insulating properties is used, the insulating ability can be achieved by additional precautions on the inside or outside of the housing.

The features specified in claims 15 and 16 make the removal of the accumulator easier.

The invention will be explained in more detail below with the help of two examples and with reference to the drawings, where: Fig. 1 is a perspective view of a cooling vessel with an accumulator made in accordance with the invention,

fig. 2 is a front view, partly in section, of the cooling vessel according to fig. 1,

fig. 3 is a plan view of fig. 1, and

fig. 4 shows the accumulator part in perspective.

Fig. 5 shows a vertical section through a cooling vessel according to

another embodiment of the invention, and

fig. 6 is a plan view of fig. 5.

That in fig. 1, the cooling vessel 1 shown has one, seen in plan view, oblong receiving space 2 for two cylindrical inner containers 3 and a cooling accumulator 4 which is composed of two identical cooling elements 5. The inner containers 3 and the cooling elements 5 stand on the bottom of the cooling vessel 1. The length L of the receiving space 2 (fig. 3) is larger than twice the diameter D of the inner container 3 so that a distance a is present between the inner containers 3 and thus a free space designated by 6. In this free space the two cooling elements 5 are inserted, and the elements have cylindrical contact surfaces 8 which face outwards and which are adapted to the inner containers' 3 cylindrical outer surfaces. As mentioned, the inner containers 3 are essentially cylindrical in shape. Therefore, the construction rafts are also approximately cylindrical because they are directed approximately parallel to the central axes 9 of the inner containers 3. The other jacket surfaces of the cooling elements 5, namely the rear surfaces 11 opposite to the construction rafts 8 and the side wall 12, are prismatic surfaces, i.e. vertical surfaces which runs roughly parallel to a vertical axis. The arrangement is such that the inner containers 3 and the two cooling elements 5 fill out the horizontal cross-section of the storage space 2, and the cooling elements can be individually inserted from above with the necessary movement clearance into the storage space 2

and they can also be pulled out upwards.

The cooling elements 5 are not only. as desired, one or the other end 14 is inserted into the receiving space 2. The heights H of the cooling elements 5 are equal to and slightly greater than the depth of the receiving space 2, so that the cooling elements 5 protrude above the top 15 of the cooling vessel 1. This design allows the cooling elements 5 can be grasped at its upper end without being taken up in the inner containers 3, e.g. to pull these out together with the cooling elements 5.

A sheath 16, e.g. for inserting an only partially shown cutlery part 18, such as a fishing rod or the like.

The inner containers 3 can be used immediately for receiving goods to be cooled, e.g. beverages. The design described above is also suitable for cooling bottles which must then be inserted into the inner containers 3. For cooling the goods not shown, cooling elements 5 are therefore needed which must be "charged up", e.g. in a freezer box. The cooling elements 5 are then inserted

in the free space 6 between the inner containers 3, whereby the inner containers 3 will be kept at a distance from each other. The cooling elements 5 thus simultaneously contribute to the positioning or fixing of the inner containers 3. The "energy" collected in the cooling elements 5 is released to the inner containers 3, and the transfer of cold, resp. heat is transferred relatively loss-free because the transfer rafts, i.e. the contact surfaces 8, are relatively large and because the cooling elements 5 are in direct contact with the inner containers 3. The heat losses, respectively. the cooling losses are small because the construction rafts 8 are relatively large in relation to the side surfaces 12.

The cup-shaped inner containers 3 can consist of both plastic material and metal. By using metal, a faster transfer of energy is ensured as a result of the metal's better thermal conductivity and because a larger part of the inner container's 3 wall is included in the transfer.

According to the example, the housing of the refrigerator 1 consists of plastic material with low thermal conductivity, so that heat exchange between the surroundings and the receiving room 10 is counteracted, whereby the transfer of cold takes place with less loss. This effect can be increased by special additional insulation of the house.

Within the framework of the invention, it is also possible to design the cooling accumulator 4 in one piece. Furthermore, it is possible to arrange only one inner container 3 in the cooling vessel. In such a case, it may be sufficient to insert only one cooling element 5 in a free space which roughly encloses the cooling element next to the inner container 3, or to arrange two cooling elements 5 in one receiving space 2 with a square or rectangular horizontal cross-section on both sides of the inner container 3, so that the inner container 3 is located between two cooling elements 5. In such a case, approximately the entire outer surface of the inner container 3 is in contact with the cooling accumulator.

The housing 19 of the cooling vessel 1 has a rectangular, horizontal cross-section and consists of heat-insulating material. Out of the narrow sides of the housing 19 protrude horizontally running strips 20 which end at the top and which form grip strips. The top of the housing 19 is fitted or rounded slightly outwards and upwards, so that any liquid from the collection room 2 that finds its way to the top can drain off.

Within the scope of the invention, it is also possible to insulate the housing 19 using a special material, e.g. by arranging an internal or external insulation layer.

The cooling elements 5 preferably consist of a blow-molded housing 21 of plastic material which is filled with a medium 22 with a large cold storage capacity. After filling, the filling opening is closed, e.g. with a plug or by welding.

The embodiment according to the example in fig. 5 and 6 differ from the first in that two containers 25 are arranged which are made integral with the housing 26, i.e. that these cannot be removed from the housing. The containers 25 are formed in part by the housing wall 27 and a side wall 28 which surrounds a container space 29, where the semi-cylindrical curvature of the housing wall 27 and the side wall 28 together form a container space. 29 with round, horizontal cross-sectional shape. The side walls 28 are in one piece with the house wall 27 and the house bottom 31 and therefore contribute

also for bracing the housing 26 whose receiving space is denoted by 32 and surrounds the container spaces 29 and the space between them

free space 33 for the accumulator 34.

The accumulator is different from the first embodiment made in one piece, but has basically the same shape.

In accordance with the invention, it is also possible and advantageous to design the free spaces and also the container spaces so that they diverge slightly upwards. This can be achieved in a simple way by arranging side walls that slope upwards and outwards slightly, respectively. house walls, and where the accumulators' mounting surfaces and the side walls of the containers that must be inserted must then be inclined accordingly.

Such a design is advantageous because already after a small lifting of the accumulator or the relevant container, a larger clearance space is obtained in the free space, or the container compartment that allows the insertion and removal of the accumulators, respectively the containers easier. In accordance with the invention, it is also possible to use a shape other than cylindrical for the container's side walls facing the accumulator. These side walls can e.g. be flat or in the form of side wall sections running diagonally towards each other. For a food container, containers with an oval cross-section are particularly suitable. The cross-sectional shape of a drinking vessel, respectively beverage containers are of less importance, but round cross-sections for such vessels are preferable.

Claims (16)

1. Vessels for cooling or keeping warm goods that are to be placed in the vessel, in particular vessels for food or drink, consisting of a vessel-shaped body of substantially rigid and heat-insulating material or a house made in a heat-insulating manner with an open top or top vent openable receiving space for the goods and at least one accumulator with an essentially prismatic shape, characterized in that there is arranged in the receiving space (2, 32) an essentially rigid container (3, 25) for the goods with a horizontal cross-section that is smaller than the horizontal cross-section of the receiving space (2, 32) and that the accumulator (5, 34) is arranged in the free space (6, 33) created by the difference in cross-section and is form-lockingly fixed to the container (3, 25). 2. A vessel according to claim 1, characterized in that the side walls of the accumulator (5, 34) facing each other and the side walls of the container (3, 25) essentially rest against each other with their entire surface. 3. Vessel according to claim 2, characterized in that the accumulator (5) completes the free space (6). 4. Vessel according to claim 1, 2 or 3, characterized in that the side surface of the accumulator directed towards the container is a vertical cross-sectional surface of the receiving space. 5. Vessel according to one of claims 1-4, characterized in that the container can be inserted as a separate building part in the receiving space (2). 6. Vessel according to claim 5, characterized in that the side wall of the receiving space (2) narrowly surrounds the container (3). 7. Vessel according to one of claims 1-6, characterized in that the side wall (28) of the container (25) facing the accumulator (34) is formed in one piece with the housing (26) (Fig. 6). 8. Vessel according to one of the claims 1-7, characterized in that the side wall of the container (3, 25) facing the accumulator (5, 34) has a shape deviating from a plane, particularly a domed shape and that the opposite container (3, 25) facing side wall of the accumulator (5, 34) is a corresponding projecting or receding particularly concave contact surface (8). 9. Vessel according to one of claims 1-8, characterized in that the container (3) has a circular or oval, horizontal cross-section. 10. Vessel according to one of claims 1-9, characterized in that the roof surface (11) of the accumulator (5) facing the contact surface (8) and the side surfaces (12) running between them are symmetrical with the contact surface (8)'s plane of symmetry (E) . 11. Vessel according to one of claims 1-10, characterized in that at least two containers (3) are arranged diametrically or at least three containers (3) are arranged star-like in relation to each other in the receiving space (2) forming the free space (6) between them, and the accumulator (5) on mutually opposite sides has contact surfaces (8). 12. Vessel according to claim 11, characterized in that the receiving space (2, 32) has the shape of a long hole in the horizontal cross-section, that two containers (3, 25) with a horizontal cross-section with preferably the same diameter (D) are arranged in the receiving space and that the accumulator 5, 34) on opposite sides have concave contact surfaces (8). 13. Vessel according to one of claims 1 to 12, characterized in that the accumulator (5) consists of two or more identical parts which, with their rear surfaces (11) next to each other, are arranged next to or star-like in relation to each other. 14. Vessel according to one of claims 1 to 13, characterized in that the vessel's housing (19) consists of heat-insulating plastic material or of plastic material and is internally and/or externally thermally insulated by means of at least one separate layer. 15. Vessel according to one of claims 1 to 14, characterized in that the accumulator t5) on the side (14) which is directed upwards when the accumulator is inserted in the vessel (1) has a grip, a gripping socket or a gripping edge or the like. 16. Vessel according to one of claims 1 to 15, characterized in that the accumulator (5) projects above the vessel's (1) top and/or the containers (3) when the accumulator is inserted in the vessel (1).