DE29602003U1 - Box-shaped cooler - Google Patents

Description

PATENT ATTORNEYS · · ··· · · * ' , * ·

DR..INO. H. NEGENDANK ,-&igr;«)/ '..' * ",J .;'. ' *"

HAUCK, GRAALFS, VVEHNERT, DÖRING, SIEMONS K-39583-19 HAMBURG - MUNICH - DÜSSELDORF

PATENT- U, LAWYER · NEUER WALL 41 ■ 20354 HAMBL'RG

CRYO GENESIS EUROPE LTD. 601, Bank of America Tower Harcourt Road, Central

HongKong

EDO GRAALFS, Dipl.-Ina. NORBERT SIEMONS. Dn-Ina. HEIDI REICHERT, Attorney at Law Neuer Wail 41, 20354 Hamburg P.O. Box 30 24 30, 20308 Hamburg Telephone (040) 36 67 55, Fax (040) 36 40 Telex 2 11 769 inpat d

HANS HAUCK, Dipl.-tn* WERNER WEHNERT, German Engineer Mozartstrasse 23, 80336 Munich Telephone (089) 53 92 36, Fax (089) 53 12

WOLFGANG DÖRING, Dr.-Ins. Mörikestraße 18, 40474 Düsseldorf Telephone (0211) 45 07 85, Fax (0211) 454 32 Telex 8 584 044 dopa d

DELIVERY ADDRESS/PLEASE REPLY TO:

HAMBURG,

February 2, 1996

Box-shaped cooling container

The invention relates to a box-shaped cooling container according to the preamble of claim 1.

From DE 32 2 0 992 it is known to clean radioactively contaminated workpiece surfaces with C02 dry ice particles. The dry ice particles are directed against the workpiece surface using a jet. The CO2 is in strand form, which must then be crushed or in the form of granules.

As a rule, a plant for producing dry ice particles is not located at the location where workpieces

Patent Attorneys · European Patent Attorneys · European Patent Attorneys · European Patent Office

Attorney! augeJassan at the Hifrncurj courts.*

Deutsche Bank AG Hamburg, No. 05 284.^7'(BL ₄ I*2(?0 _# 7?J(?00? -,PostlwnJ» HambuiB,»No.J28 42 206 (BLZ 200 100 20) Dresdner Bank AG Hamburg, No*93*3*60 35 *BLZ 200 800*00)

Surfaces must be cleaned. It is therefore necessary to provide transport containers to transport the dry ice particles to the place of application.

Such containers are well known. They are box-like and consist of an inner and an outer shell, for example made of glass fiber reinforced plastic or stainless steel, which are arranged at a distance from each other. The space between them is filled with polyurethane foam. The top is formed by a hinged lid, which is constructed accordingly. It is held in the closed position by suitable closures. For rational reasons, such a container has a minimum volume. The smaller a container, the smaller the usable volume per available transport volume.

The known containers that hold CO2 at a temperature of -78.5 ⁰ C or less have a number of disadvantages. For example, the weight is relatively high due to the materials used. The cost of manufacturing and the material is relatively high, and the weight also has a negative impact on transport costs. The high weight also makes handling such containers difficult. Transport is only possible with special vehicles.

Another disadvantage is that cold bridges form between the lid and the edge of a container, so that icing occurs in this area, which greatly increases the evaporation volume.

The lids of such containers are also heavy and must therefore be kept open by suitable measures. However, there is a risk that they will slam shut during the removal of CC^ granules.

Because of the polyurethane foam, the known containers are not made entirely of recyclable material. They must therefore be treated as hazardous waste, similar to household refrigerators. The use of four or more different materials makes the disposal or recycling of parts of the container very difficult.

It is also known to provide containers made of Styrofoam for objects that need to be stored and transported in a cool place. Although these are characterized by a relatively low weight, they are not suitable for transporting CC^ granules due to their low stability.

The invention is therefore based on the object of

To create a cooling container that has very good insulation properties despite low manufacturing and material costs, low weight and sufficient stability.

This object is solved by the features of claim 1.

According to the invention, the box-shaped container consists of an outer container and an inner container that fits into it, between which an insulating gap is formed. The preferably loose lid has a shoulder on the underside that can be inserted into the inner container. According to one embodiment of the invention, foamed polystyrene is provided as the insulating material, but in particular foamed polypropylene. It is known to produce foamed polypropylene granulate by compression molding to form molded parts that, in addition to very high insulation capacity, also have high stability. A container whose inner and outer containers are made of such a material therefore has the strength required for transport and handling. The hardness is also sufficient to withstand impacts and blows.

The inner and outer containers and the lid are preferably made of the same material. Since polypropylene in particular is fully recyclable, the material of a container can be reused to make a new container. Disposal is completely unproblematic, since no hazardous waste is generated. In addition, the containers can be used repeatedly for two years or more.

Because of the material used, the container according to the invention has a significantly reduced weight compared to known containers. While known containers have a ratio of packaging weight to filling weight of, for example, 1:3.5, this ratio in the invention is 1:20. This is particularly important when used as air freight. Furthermore, the container according to the invention requires very little energy for cooling. Compared to known containers, an energy saving of around 80% is achieved.

The container according to the invention is easy to handle and can be transported with little effort. Even at very low temperatures, which occur when CO2 granules are stored, the material remains sufficiently stable and impermeable to provide the desired insulation properties.

These are also influenced by the fact that a relatively small gap is arranged between the inner and outer containers. According to one embodiment of the invention, the width of the gap is, for example, 3 to 15 mm. Air or a noble gas can be accommodated in the gap if it is closed off by a suitable seal between the inner and outer containers. Alternatively, at least one layer of radiation-reflecting material can be arranged in the gap, for example aluminized paper or appropriately coated double-wall sheets or the like.

The material used in the cooling container according to the invention has sufficient vapor permeability so that pressure equalization occurs between the inside and the outside of the container. When transporting moisture-sensitive products, it is expedient according to one embodiment of the invention to arrange moisture-adsorbing material in the gap, for example zeolite, perlite or the like. The adsorbent simultaneously lowers the partial pressure in the gap and thus increases the insulating effect.

According to one embodiment of the invention, the gap is preferably formed by the fact that between the inner and outer

Spacers are attached to the container. These are preferably formed by ribs or webs that are formed on the outer wall of the inner container. They have, for example, a width of no more than 2 mm in order to keep the contact surface between the inner and outer container as small as possible. A grid or network of such webs can therefore be formed on the outside of the inner container, which ensure that the inner container is evenly spaced from the outer container.

The container according to the invention can also be used as a cooling container for other objects, for example for objects from the food sector or the like. When transporting such objects, for example fish, it is required that the packaging is hygienically impeccable. Since the material described above for the production of inner and outer containers has a relatively coarse surface structure, it is not suitable for direct contact with food. Therefore, one embodiment of the invention provides that a smooth-surfaced shell made of largely inert plastic film material can be inserted into the inner container. An inner shell made of deep-drawn film material can be used which is food-compatible and sufficiently sterile to protect the food during transport.

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The inner shell preferably has an outer flange on the upper edge which engages in a gap left between the upper edge of the inner container and the lid.

It goes without saying that in this case the lid's shoulder is also dimensioned so that it can be inserted into the interior of the inner shell.

In the case where the container according to the invention is used as a cooling container for food or the like and the formation of moisture within the inner shell cannot be excluded, an embodiment of the invention provides that at least one drain is provided in the bottom of the inner and outer container.

According to a further embodiment of the invention, a set of identical containers is provided in which the base on the underside has the same configuration as the underside of the lid such that an upper container placed on a lower container seals off the lower one in an insulating manner. A series of such containers can be stacked on top of one another so that an optimal storage and transport volume is created. In addition,

a design of the containers in such a way that, for example, when transporting CO2 granulate, the volume of the individual container can be made somewhat smaller. When using CC>2 granulate, this is removed over a certain period of time. If the lid is opened, the entire contents of a container are naturally heated too quickly. However, if the volume made accessible in each case is reduced using the containers according to the invention, the CO2 granulate in the containers arranged below them remains sufficiently cooled until the upper container is removed.

In the set of containers according to the invention, most of them are of identical construction. However, at least one container is to be provided which, according to an embodiment of the invention, has feet, preferably of standard pallet size, so that handling with the aid of a forklift or the like is possible. It goes without saying that only the topmost container in a container column or stack is closed by a lid.

In one embodiment of the invention, it is further provided that a gas-permeable partition wall is arranged in the inner container at a distance from its wall to form a compartment for receiving CO2, ice or the like.

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The partition wall can be designed as a removable insert. This makes it possible to store and transport food in a cool place using the container according to the invention without using a refrigeration unit. The partition wall is perforated so that the evaporating cold gas can be directed to the product.

The invention is explained in more detail below with reference to drawings.

Fig. 1 shows a section through two containers arranged one above the other according to the invention.

Fig. 2 shows a side view of the stack according to Fig. 1.

Fig. 3 shows an enlarged section through the upper region of one of the containers according to Fig. 1.

Fig. 4 alternatively shows a section through a wall of a container according to Fig. 1.

Fig. 5 shows an enlarged view of a corner region of a lower container of the stack according to Fig. 1 in a slightly modified embodiment.

.../11

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Fig. 6 shows a similar representation as Fig. 5, but with an additional precaution.

Fig. 7 shows a similar representation as Fig. 6, but with an additional precaution.

Fig. 8 shows a section through the wall of a container according to Fig. 1 with an illustration of the temperature curve.

In Fig. 1, two containers 10, 12 are stacked on top of each other. The upper container 10 has an outer container 14 in the form of a box with upright side walls and a base 16, which has a circumferential recess 18 on the outside. An inner container 20 is inserted into the outer container 14, which is shaped to match the outer container 14, but forms a gap 22 with it in both the base and the sextant wall area. At the upper edge, the inner container is provided with an outer flange 24, which is inserted into the outer container 14 so that the gap 22 is closed at the top. The inner and outer containers 14, 20 are closed by a lid 26, which has a circumferential recess 28 on the edge, so that a shoulder 30 is formed which can be inserted into the inner container 20.

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Inner and outer containers 14, 20 and lid 26 consist of a foamed polypropylene and are preferably manufactured by compressing foamed propylene granulate.

The lower container 12 has an outer container 32 which has the same external dimensions as the outer container 14, but has feet 34 in the base area corresponding to a standard pallet size. The internal structure of the lower container 12 is identical to the container 10, so that the same parts are provided with the same reference numerals. As can be seen, the lower container 12 is closed and sealed by the upper container 10, whereby the configuration of the base 16 of the upper container 10 corresponds to the configuration of the underside of the lid 26. If the lid 26 is removed, any number of containers 10 can be stacked on top of one another, whereby the topmost one is closed off by a lid 26, as shown in Fig. 2. If, as shown by dash-dotted lines, a third container is placed on the container 10, the lid 26 on the container 10 is of course no longer required.

Fig. 3 shows an upper corner of the container 10 according to Fig. 1. It can be seen that in the upper edge of the outer container

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14 a seal 36 is embedded, which interacts with the underside of the lid edge. The upper edge of the inner container 20 is slightly lower than that of the outer container 14, so that a gap 38 is formed, the function of which is discussed further below. The gap 22 contains, for example, air or a noble gas. As indicated in Fig. 4, the gap 22 can also accommodate a radiation-reflecting material 40, for example one or more layers coated with aluminum or the like or a double-wall plate provided with a radiation-reflecting surface. This further increases the insulating capacity of the container 10.

In Fig. 5 it is indicated that a tray 42 made of relatively thin, solid plastic material, for example deep-drawn film material, can be inserted into the inner container 20. This tray enables sensitive material to be accommodated in the container 10, for example foodstuffs. The inner tray 42 can, which is not shown in Fig. 5, have a circumferential outer flange which is received by the gap 38 according to Fig. 3 in order to secure the tray.

Fig. 6 shows a similar representation to Fig. 5. It differs from Fig. 5 only in that

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that a drain for liquid is created with the help of a tube 44 or the like, which is led through corresponding openings in the inner and outer containers 14, 20. The tube 44 also extends through an opening in the inner shell 42. If, for example, fish to be cooled is transported in the container 10, in which liquid is separated, then this can escape to the outside via the tube 44.

Fig. 7 differs from Fig. 6 in that a grate 46 or the like is additionally arranged on the underside of the inner bowl 42, onto which food or the like can be placed. The grate or the grid 46 prevents, for example, food from constantly lying in liquid that collects at the bottom of the inner bowl 42.

Fig. 8 clearly shows the temperature profile across the thickness of the walls of the inner and outer containers 14, 20. There is a very steep temperature gradient in the walls of the two containers, which is somewhat smaller in the area of the gap 22. As can be seen, the insulation serves to maintain a temperature of approximately -8O ⁰ C in the container 10 compared to an outside temperature of 2O ⁰ C.

. . ./15

As can also be seen from Fig. 1, partitions can be inserted into the inner containers 20, as shown in dashed lines at 50. They can be designed as inserts and are spaced from the wall of the inner container 20, so that compartments 52 are formed which can hold, for example, dry ice. This means that the containers can be used in particular for cooling food storage. The cold gases flow through the gas-permeable partition 50 according to the arrows 54 and pass over the contents of the containers.

.../16

Claims (20)

- 16 claims 1. Box-shaped cooling container, with a base, side walls and a lid made of heat-insulating material, characterized in that the base and side walls are formed by an outer container (12, 14) and an inner container (20) that can be inserted into the outer container (12, 14) to fit, an insulating gap (22) is formed between the outer and inner containers and the lid (26) has a shoulder (30) on the underside that can be inserted into the inner container (20) to fit. 2. Cooling container according to claim 1, characterized in that the insulating material is foamed polystyrene. 3. Cooling container according to claim 1, characterized in that the insulating material is foamed polypropylene. 4. Cooling container according to one of claims 1 to 3, characterized in that the gap (22) has a width of 3 to 15 mm. 5. Cooling container according to one of claims 1 to 7, characterized in that air or a noble gas is enclosed in the closed gap (22). . . ./17 I iS"s 6. Cooling container according to one of claims 1 to 4, characterized in that at least one layer (40) of radiation-reflecting material is arranged in the gap. 7. Cooling container according to claim 6, characterized in that an aluminized paper or a double-wall plate coated with aluminum is arranged in the gap (22). 8. Cooling container according to one of claims 1 to 5, characterized in that a moisture-absorbing material is arranged in the gap (22). 9. Cooling container according to one of claims 1 to 8, characterized in that a smooth-surfaced shell (42) made of largely inert plastic film material can be inserted into the inner container (20). 10. Cooling container according to claim 9, characterized in that the shell has a circumferential outer flange at the upper end, which engages in the gap (38) left free between the upper edge of the inner container (20) and the lid (26). 11. Cooling container according to one of claims 1 to 10, characterized in that the inner container (20) has a circumferential outer flange (24) on the upper edge, which is inserted in the outer container (14) to form the closed gap (22). 12. Cooling container according to one of claims 1 to 11, characterized in that a circumferential seal (36) is installed in the top of the outer container (14). 13. Cooling container according to one of claims 1 to 12, characterized in that the inner container (20) has ribs or the like on the outside, with which it is supported on the outer container (14) at a distance from the latter. 14. Cooling container according to claim 13, characterized in that the ribs have a width of approximately 2 mm. 15. Cooling container according to one of claims 1 to 14, characterized in that a drain (44) is provided in the bottom of the inner and outer container. 16. Cooling container according to one of claims 1 to 14, .../19 characterized by a set of identical containers (10, 12) in which the bottom (16) on the underside has the same configuration as the underside of the lid (26) such that an upper container (10) placed on a lower container (12) seals and insulates the lower container (12). 17. Cooling container according to claim 16, characterized in that at least one container (12) is provided with an outer container (32) which has feet (34) on the underside corresponding to the standard pallet size. 18. Cooling container according to one of claims 1 to 17, characterized in that the outer and inner containers and if applicable the lid are made of completely recyclable material. 19. Cooling container according to one of claims 1 to 18, characterized by at least one gas-permeable partition wall (50) in the inner container (20) at a distance from its wall to form a compartment (52) for dry ice or the like. 20. Cooling container according to claim 19, characterized in that the partition wall (50) is designed as a removable insert.