EP0581121A1 - Process and apparatus for the oxygen-free packaging of goods - Google Patents

Abstract

The invention relates to a process and an apparatus for the oxygen-free packaging of goods. Attached to a container (10) for receiving the goods is a substance-receiving device (4), into which a substance, especially a liquid gas, capable of gas generation is metered. The substance located in the substance-receiving device (4) is made to generate gas and the gas obtained overflows into the container interior (5, 9). The gas displaces the oxygen located in the container interior (5, 9) and escapes into the atmosphere via the container edge (12). After the flushing of the container interior (5, 9), the container (10) is closed in a gas-tight manner by means of a cover (2). At the same time, the connection between the substance-receiving device and the container interior (5, 9) is also broken, so that gas can no longer overflow into the container. A passage orifice to the substance-receiving device (4) is provided in the cover (2), so that the gas obtained as a result of the gas generation of remaining substance can escape into the atmosphere. <IMAGE>

Description

The invention relates to a process for the oxygen-free packaging of goods in containers, in which the goods are filled into the container and the interior of the container is flushed with a gas before the container is closed in a gas-tight manner, and a device for carrying out the method.

For some goods, especially food products, it is advantageous to store them in the absence of oxygen, e.g. ensure their durability. Various methods are known for creating an oxygen-free atmosphere within a package.

A common packaging method is, for example, to evacuate the package and then seal it. However, this can only be carried out with flexible packings, since otherwise the pack can easily be damaged by forces arising from the vacuum. In addition, this method is associated with an enormous expenditure on equipment. Elaborate vacuum chambers and at least one powerful vacuum pump are required. In addition, problems arise with products with low-boiling aromas, such as coffee, since these are then lost to the product due to the vacuum.

A further development of the above-mentioned method consists in back-gassing the evacuated pack with inert, oxygen-free gas and then closing it. This method can then also be used to pack product in rigid containers.

Another packaging method involves purging the package with an inert, oxygen-free gas. The pack is then closed. However, packages filled with lumpy product are not obtained with sufficient oxygen freedom afterwards by flushing with inert gas in a reasonable time.

It is also known to achieve an oxygen-free atmosphere within the package by binding oxygen in the package with chemicals. However, this method is used for food packaging e.g. due to improper use of the chemicals by children.

Finally, it is known from DE-OS 36 25 081 to use gaseous nitrogen for flushing the headspace of containers, which is produced by evaporation from metered liquid nitrogen. If this method is used for packaging multi-compartment menu trays, such as those used for finished food products, different amounts of liquid nitrogen must be metered into the compartments for different compartment volumes so that sufficient gaseous nitrogen is available in accordance with the amount of air to be displaced. This requires a complex liquid nitrogen metering system with several metering points. In addition, experience has shown that the liquid nitrogen does not collect in the dosed amount at a preferred location in the shell, but rather distributes itself at random to uneven amounts. This entails considerably fluctuating evaporation times for the liquid nitrogen. For this reason, the Seal the trays until the liquid nitrogen has completely evaporated in at least 99 out of 100 trays. Otherwise, residues of liquid nitrogen in the sealed shell would lead to excess pressure in the shell after evaporation, which would at least result in undesired bulging of the lid or even bursting of the packaging.

The object of the present invention is to design a method of the type mentioned at the outset and a device for carrying out the method in such a way that oxygen-free packaging of goods takes place in a simple and economical manner without the disadvantages of the previous methods and devices mentioned.

This object is achieved in that a substance capable of gas evolution is poured into a substance receiving device attached in or on the container, the substance located in the substance receiving device is brought to gas evolution, the resulting gas is transferred into the container interior, the container interior with the Gas is flushed and after the container is closed, the gas generated in the substance receiving device is no longer transferred into the interior of the container, but is instead released into the atmosphere.

A liquid gas, in particular liquid nitrogen, is expediently used as the gas-developing substance. But dry ice (CO₂ snow) is also suitable. The decisive factor is that the substance, for example in the liquid or solid state, is filled into the substance receiving device and then caused to develop gas, that is to say can be brought to vaporization, for example.

The main difference from the prior art is therefore that the substance capable of gas evolution is not metered directly into the interior of the container, but into a separate substance receiving device, which in the simplest case can be designed as a cup which is attached in or on the container. The gas produced in the substance receiving device by the gas evolution is transferred into the container interior, for example via connecting lines or in the simplest case via a gap formed by the cup rim and the container lid. After the interior of the container has been flushed with the gas, the container can be closed without having to consider whether substance is still contained in the substance receiving device. The gas resulting from the evolution of gas from the remaining substance is namely no longer transferred into the interior of the container after the container has been closed, but is instead released into the atmosphere. In the simplest case, this is achieved by eliminating the gap between the substance receiving device and the container lid when the container is closed by the container lid, and piercing the container at the point directly above the substance receiving device. In this way, the gas resulting from the substance remaining in the substance receiving device can no longer lead to an undesirable bulging of the lid or to bursting of the packaging.

If food is to be packaged, an inert gas, in particular liquid nitrogen, is expediently used as the gas-developing substance. The gaseous nitrogen produced by the evaporation of the liquid nitrogen in the substance receiving device displaces the oxygen from the container and forms an inert atmosphere in the interior of the container, which increases the shelf life of the food. Another option is dry ice (CO₂ snow) to fill in the substance absorption device. The resulting CO₂ gas displaces the atmospheric oxygen in the container and creates a CO₂-containing atmosphere in the interior of the container. By selecting the appropriate substance capable of gas evolution, the most favorable container interior atmosphere for the goods to be packaged can be set. For example, liquid helium can also be used as a gas-developing substance to create a helium atmosphere in the interior of the container.

The gas evolution of the substance in the substance receiving device is preferably accelerated by the supply of heat. For this purpose, the substance absorption device can, for example, be electrically heated or hot air can be supplied to the substance absorption device.

According to a particularly preferred embodiment of the invention, a gas is blown into the substance receiving device filled with the substance. The injected gas is transferred into the interior of the container together with the gas resulting from the substance and thus supports its flushing action. In addition, the gas evolution of the substance is intensified by the injected gas.

In a further variant of the invention, the substance in the substance receiving device is at least partially converted into the gaseous state in a first step and a gas is blown into the substance receiving device in a subsequent second step. Since the gas evolution of the substance is usually initially stronger and gradually subsides, the decreasing gas evolution can be increased again in the second step. Overall, the additional blowing of gas into the substance receiving device results in the advantage that less substance is required to rinse the container.

Advantageously, gaseous nitrogen or a mixed gas, in particular an N₂ / CO₂ mixed gas or an N₂ / CO₂ / O₂ mixed gas with possible proportions of argon, helium or carbon monoxide is blown into the substance receiving device. A heated gas is preferably used to further intensify the gas evolution of the substance.

It is recommended that at least such an amount of substance be filled into the substance receiving device that is sufficient to flush the interior of the container free of oxygen after the evolution of gas. If additional gas is blown into the substance receiving device, the amount of substance can be reduced accordingly.

The invention further relates to a device for carrying out the method with a container which can be filled with goods and closed in a gastight manner.

According to the invention, the container has a substance receiving device which is essentially designed as an interior surrounded by a wall and can be filled with a substance capable of gas development, the interior of which is in communication with the container interior in the unlocked state of the container and with the atmosphere in the closed state of the container.

The substance receiving device is expediently attached to the fumigation point in the container, so that the gas resulting from the substance can rinse the entire container at the same time.

If one assumes that the container essentially consists of a single-compartment or multi-compartment shell with a shell edge surrounding the shell in the vertical direction at the top, as is the case, for example, in the packaging of finished food products is used, the substance receiving device is designed according to a particularly preferred embodiment essentially as a cup arranged in the shell, for example in a conical or cylindrical shape with a cup rim surrounding the cup in the vertical direction at the top. The rim of the bowl and the rim of the cup run in a common horizontal plane, so that the bowl and cup can be closed with a common cover. In the unlocked state of the bowl, gaps are provided between the bowl edge and the cover and between the cup edge and the cover, ie the cover is at a short distance above the cup and bowl edge. In this state, the gas formed in the substance receiving device, ie in the cup, can pass into the interior of the shell, flush it with oxygen-free and be released to the atmosphere via the outer edge of the shell. To close the shell, the cover is lowered onto the shell so that the gaps between the edge of the shell and the cover are closed when the shell is closed. The gas can no longer pass from the cup into the bowl interior. At the same time, the cover of the bowl is pierced at the point immediately above the cup after the bowl has been closed. The cover thus has, in the closed state of the shell, an opening to the interior of the cup through which, due to the gas evolution of the substance remaining in the cup, gas can escape to the atmosphere after evaporation.

According to a development of the inventive concept, a valve is arranged instead of the opening in the cover, which closes the path from the outside into the cup interior, while it opens the way from the cup interior to the outside.

To support the gas development, a heating device is provided in the area of the substance absorption device. This can consist, for example, of an electric heating plate, via which the containers are transported during the packaging process. It is also possible to arrange a hot air blower in the vicinity of the liquid absorption device.

According to another preferred embodiment of the invention, a gas feed line is provided which is directed into the interior of the substance receiving device. Via this gas supply line, e.g. gaseous nitrogen are blown into the substance receiving device, which on the one hand intensifies the gas development and on the other hand supports the purging effect of the gas formed from the substance.

To further intensify the gas development, the wall of the substance absorption device preferably has knobs in order to improve the outer surface and thus the heat transfer from the outside.

The invention enables a uniform gas purging of the container from one point and creates an independence from time fluctuations in the gas development. Substance dosing in excess is also possible. With the method according to the invention, oxygen-free packaging of goods in containers is achieved without expensive equipment, such as e.g. Vacuum pumps and vacuum chambers would be required. The process according to the invention creates an oxygen-free atmosphere in the containers within a short time, which also ensures packaging and storage of oxygen-sensitive products. In this way e.g. Foods are permanently protected from oxidation processes so that their shelf life is improved.

The invention is particularly suitable for packaging finished food products in single or multi-compartment menu trays.

In the following, the invention will be explained in more detail with reference to exemplary embodiments schematically shown in the figures.

Figur 1:

einen Querschnitt durch eine Menüschale mit zugeordneter Siegelvorrichtung

Figur 2:

eine Draufsicht auf die in Figur 1 dargestellte Menüschale

Figur 3:

eine perspektivische Darstellung der Menüschale

Figur 4:

eine perspektivische Darstellung einer einfächrigen Menüschale.

Show it:

Figure 1:

a cross section through a menu tray with an associated sealing device

Figure 2:

a plan view of the menu tray shown in Figure 1

Figure 3:

a perspective view of the menu tray

Figure 4:

a perspective view of a single compartment menu tray.

In the following exemplary embodiments, a liquid gas, namely liquid nitrogen, is used as the substance capable of gas evolution. Therefore, the substance absorption device is referred to below as the liquid gas absorption device.

The menu tray 10 shown in FIG. 1 has a liquid gas receiving device 4 designed as a cup, which is arranged at a point in the center of the menu tray 10 that is favorable in terms of fumigation technology. To purge the menu tray 10 with nitrogen gas, the liquid gas receiving device 4 is filled with liquid nitrogen. A heating element 3 arranged below the liquid gas receiving device 4 is brought up to the liquid gas receiving device 4 in order to support the evaporation of the liquid nitrogen located in the liquid gas receiving device 4. The resulting gaseous nitrogen passes over the upper rim 11 of the liquefied gas absorption device 4 into the area above 9 of the menu tray 10 located food product arranged headspace 5 above. The nitrogen gas displaces the air located in the head space 5 of the menu tray 10 and exits into the atmosphere via the tray edges 12. The path of the nitrogen gas is illustrated in the drawing by arrows.

A cover film 2 is held at a short distance above the menu tray 10, so that gaps are formed between the cup edge 11 and the cover film 2 and between the bowl edge 12 and the cover film 2 through which the nitrogen gas can pass. After the head space 5 of the menu tray 10 has been rinsed free of oxygen, the menu tray 10 is closed by means of a sealing device 1 arranged above the menu tray 10. For this purpose, the cover film 2 is pressed onto the bowl edge 12 and cup edge 11 and attached to sealing surfaces 8. The menu tray 10 is thus sealed gas-tight. Since the gap between the cup rim 11 and the lid film 2 has also been eliminated, nitrogen gas can no longer pass from the liquid gas receiving device 4 into the head space 5 of the menu tray 10. By means of a piercing device 7, the cover film 2 is pierced at a point immediately above the liquid gas receiving device 4. This allows nitrogen gas, which is produced by evaporating liquid nitrogen remaining in the liquid gas receiving device 4, to escape to the atmosphere without damage. It is therefore not necessary to wait until all of the liquid nitrogen has evaporated before the menu tray 10 is sealed, in order to prevent the package from bursting open due to the subsequently evaporated nitrogen.

In order to support the purging action of the nitrogen evaporated in the liquid gas receiving device 4, gaseous nitrogen can additionally be blown into the liquid gas receiving device 4. This can be done, for example, by a nitrogen gas supply arranged instead of the piercing device 7 respectively. This also intensifies the evaporation of the liquid nitrogen in the liquid gas receiving device 4.

In Figure 2, the menu tray shown in Figure 1 is shown in plan view. In this illustration it can be clearly seen that the liquid gas receiving device 4 is arranged at a fumigation point in the center of the multi-compartment menu tray. The path of the nitrogen gas is again shown by arrows. In addition, the sealing surfaces 8, on which the lid film rests after the menu tray has been sealed, can be seen clearly.

Figure 3 shows a perspective view of the menu tray shown in Figures 1 and 2. The arrow illustrates the metering of liquid nitrogen into the liquid gas receiving device 4.

A single-compartment menu tray is shown in FIG. 4, the liquid gas receiving device 4 being arranged in a corner of the menu tray.

The menu tray is preferably pre-sealed with the cover film in the area in which the liquid gas receiving device 4 is located. This prevents some of the evaporated nitrogen from ineffectively escaping to the atmosphere in the direction facing away from the interior of the shell via the edge of the shell. An undesired escape of the evaporated nitrogen can also be prevented by an appropriate design of the sealing tool used to seal the cover film.

In all the figures, the same device parts are designated with the same reference numbers.

Claims (14)

Process for the oxygen-free packaging of goods in containers, in which the goods are filled into the container and the interior of the container is flushed with a gas before the container is closed in a gas-tight manner, characterized in that a substance capable of gas evolution is introduced into or in the container (10) attached substance receiving device (4) is filled, the substance located in the substance receiving device (4) is brought to gas development, the resulting gas is transferred into the container interior (5, 9), the container interior (5, 9) with the gas is flushed and after the container (10) has been closed, the gas produced in the substance receiving device (4) is no longer transferred into the container interior (5, 9) but is released into the atmosphere. A method according to claim 1, characterized in that liquid nitrogen is used as the substance. A method according to claim 1, characterized in that dry ice (CO₂ snow) is used as the substance. Method according to one of claims 1 to 3, characterized in that the substance receiving device (4) is heated. Method according to one of claims 1 to 4, characterized in that at least such an amount of substance is poured into the substance receiving device (4) that is sufficient to flush the interior of the container (5, 9) free of oxygen after the evolution of gas. Method according to one of claims 1 to 5, characterized in that a gas is blown into the substance receiving device (4) filled with the substance. Method according to claim 6, characterized in that gaseous nitrogen is blown into the substance receiving device (4) filled with the substance. A method according to claim 6, characterized in that a mixed gas, in particular an N₂ / CO₂ mixed gas or an N₂ / CO₂ / O₂ mixed gas, is blown into the substance-receiving device (4) filled with the substance. A method according to claim 6, characterized in that a heated gas is blown into the substance receiving device (4) filled with the substance. Device for carrying out the method according to one of claims 1 to 9 with a container which can be filled with goods and which can be closed in a gas-tight manner, characterized in that the container (10) has a substance receiving device which is essentially designed as an interior surrounded by a wall and can be filled with a substance capable of gas evolution (4), whose interior is in the unlocked state of the container (10) with the container interior (5) and in the closed state of the container (10) with the atmosphere in connection. Apparatus according to claim 10, wherein the container is essentially designed as a single-compartment or multi-compartment shell, which can be closed gas-tightly with a cover, with a shell edge surrounding the shell in the vertical direction at the top, characterized in that the substance receiving device (4) is essentially as in the shell (10) arranged cup (4) is formed with a cup edge (11) surrounding the cup (4) in the vertical direction at the top, the bowl edge (12) and the cup edge (11) running in a common horizontal plane and in the unlocked state Shell (10) gaps are provided between the shell edge (12) and the cover (2) and between the cup edge (11) and the cover (2), which are closed when the shell (10) is closed, and the cover (2 ) in the closed state of the bowl (10) has an opening to the interior of the cup. Device according to claim 10 or 11, characterized in that a heating device (3) is provided in the area of the substance absorption device (4). Device according to one of claims 10 to 12, characterized in that a gas feed line is provided which is directed into the interior of the substance receiving device (4). Device according to one of claims 10 to 13, characterized in that the wall of the substance receiving device (4) has knobs.

Images