The invention relates to a device and a method for sterilisation during the filling of preferably liquid foodstuffs into packaging containers with a preheating zone, a sterilisation zone, a drying zone, a filling zone and a sealing zone, which form a sterile space and are arranged immediately adjacent to one another and are sealed at the top by a cover which accommodates the necessary supply elements and supply lines.
When filling in particular, liquid foodstuffs into packaging containers, one must—for reasons relating to hygiene and shelf life—always pay particular attention to sterilisation. The actual sterilisation here takes place using known methods in which the surfaces to be sterilised of the—still open—packaging, preferably composite cardboard/plastic packaging, must come into contact for a predetermined time period with a sterilising agent, which subsequently, i.e. prior to the actual filling process, must be removed again from the surface of the packaging (DE 30 36 972 C2).
In order to make this sterilisation process as cost-effective as possible, there has been a shift to using H2O2, i.e. hydrogen peroxide, as a sterilising agent. An optimum effect is then achieved when the packaging units to be filled are heated in a first zone (preheating zone) in order to be able to carry out the sterilisation as quickly and efficiently as possible. The packaging units which are continuously moved along are transported from the preheating zone into the downstream sterilisation zone, where they are wetted with the sterilising agent, preferably H2O2. For this purpose, the liquid H2O2 is atomised using hot compressed air or superheated steam into an H2O2 aerosol, so that no larger, heavier droplets can condense on the packaging surface which could no longer simply be removed during the subsequent rinsing process.
It has been shown that the brief wetting with the H2O2 aerosol in a hot atmosphere is sufficient for any microbes present to be reliably killed off. By preheating the open packaging units, condensation of aerosol droplets is reliably prevented. In order, now, to remove the H2O2 aerosol from the packaging units once again, the packaging units pass through a further zone, that which is known as the drying zone. In this zone, the packaging units are flushed with hot sterile air at atmospheric pressure. Subsequently, in a filling zone, the actual filling of the packaging units takes place using means that are likewise known. Finally, the filled packaging units are sealed directly after the filling process in a sealing zone.
Since sterile conditions must be present in all the aforementioned five zones, the individual zones are to a large extent sealed off from the outside in order to be able to transport the packaging units inside a germicidal atmosphere. Although the use of H2O2 has proved itself for sterilisation, with the filling machines used it must be ensured, firstly for economic reasons and secondly for health reasons (hydrogen peroxide is a strong oxidising agent), that none of the H2O2 atmosphere reaches the room in which the filling machine is located.
Since the individual zones can always be only inadequately sealed off at the bottom and in particular in the direction of transportation of the packaging units because the packaging units—open at the top—are moved continuously through the device by means of cell chains that receive these units, a closing of inflow and outflow in the manner of an (air)lock is not possible. In the generic device for sterilisation (EP 0 726 203 B1) it has therefore already been proposed that all five zones named be amalgamated into a single sterile space and this be sealed using a collective removable lid, which has a cavity in which the distribution and supply elements are housed. However, this known device, too, is subject to the problems of the packaging units to be filled always being continuously transported.
The object of the invention is therefore to design and further develop the device, named at the beginning and described in more detail above, in such a way that penetration of microbes into the open packaging units passing through the treatment zones and into the sterile space formed by the treatment zones is reliably prevented. Over and above this, a simple construction of the device is desired in order, also, to minimise the cleaning and maintenance work (and costs) that is always necessary.
This object is achieved by there being provided, underneath the cover, essentially horizontal air guide elements having a plurality of openings and by these having sterile air supplied to them from above through the cover, so that underneath the air guide elements a laminar flow in an even downward direction is formed. By this means it is ensured that dust or microbes which could reach the interior of the device via the transport chains have no possibility at this point of rising against the laminar flow. Hence they remain in the lower section of the device and/or are transported from there further down and out of the device.
According to a preferred teaching of the invention, the air guide elements are arranged at least in the area of the drying zone, filling zone and sealing zone. The air guide elements may have different designs depending on the zone. On the one hand there may be an adaptation to the already pre-determined size of the respective zone but on the other, a specific orientation of the laminar flow can also take place depending on the zone and the (pipe)lines located therein.
According to a further embodiment of the invention, separating walls extending vertically from the cover in a downward direction as far as the respective air guide element are provided at the zone boundaries; these seal the zones off from one another in the upper section of the sterile space and thereby prevent a horizontal exchange of air, as a result of which the formation of a laminar flow in an even downward direction is further improved. By this means, a sterile air chamber can be formed for each individual zone.
Tests have shown that it is particularly suitable if, according to a further teaching of the invention, at least one pre-distributor element spanning the entire width of the device, to which sterile air is supplied via the supply pipe running vertically through the cover, is arranged in each sterile air chamber. Each pre-distributor element can have a plurality of openings at least on its horizontal base in order to let through the supplied air in a downward direction into the respective sterile air chamber. The pre-distributor element may for example consist of a U-shaped metal sheet.
According to a further preferred embodiment of the invention it is provided that a structure acting as an impact zone and not equipped with openings, such as for example an impact plate, is provided in each pre-distributor element, below the supply pipes. Such an impact plate ensures that the sterile air supplied to the pre-distributor chamber at a slight overpressure initially spreads horizontally within the pre-distributor and then is released evenly across the entire width of the device to the sterile air chamber.
Another embodiment of the invention provides that the openings in the air guide elements and/or the pre-distributor elements are chamfered on the inlet and/or outlet sides in order to minimise or if possible completely avoid turbulence in the sterile air upon passage through these openings.
According to a further teaching of the invention, all the openings in the air guide elements and/or pre-distributor elements are arranged so as to be evenly distributed. This allows particularly simple manufacture of these elements. However, it is also possible for the openings to be designed smaller or larger in particular sections, or to be arranged concentrated to a larger or smaller extent so as to take into account the prevailing geometry in the individual zones (through components etc.).
A further preferred embodiment of the invention provides that the air guide elements and/or pre-distributor elements are designed as perforated metal sheets. It is also possible, however, to use honeycomb sheets or similar. Preferably, the air guide elements or pre-distributor elements consist of stainless steel.
Alternatively, it is also conceivable for the air guide elements and/or pre-distributor elements to be designed as grid structures or the like.
Another teaching of the invention provides that the air guide elements and/or pre-distributor elements are attached to the cover so as to be detachable using retaining brackets or clasps. To this end, the air guide elements and/or pre-distributor elements can be equipped with lugs or hooks which correspond to the retaining brackets or clasps. By arranging the retaining elements on the air guide elements or pre-distributor elements appropriately, it can be ensured that these can only be attached in the device in the correct orientation.
According to a further preferred teaching of the invention, it is provided that the walls of the device running parallel to the direction of transport of the packaging units are designed as transparent panes and that in each pane and/or on the housing of the device a groove, running all the way round, is present which is connected to at least one of the pre-distributor elements. By this means, the pre-distributor chamber produced between the cover and the pre-distributor element, which is open on both faces, can perform the additional role of supplying the annular groove, running all the way around, with sterile air at slight overpressure. In this way, a barrier results which effectively prevents the penetration of microbe-containing air into the interior of the device.
The invention also relates to a method for sterilisation during the filling of preferably liquid foodstuffs into packaging containers, comprising the following steps:
a) Provision of a device for sterilisation during the filling of preferably liquid foodstuffs into packaging containers with a preheating zone, a sterilisation zone, a drying zone, a filling zone and a sealing zone, which form a sterile space and are arranged immediately adjacent to one another and are sealed at the top by a cover which accommodates the necessary supply elements and supply lines;
b) Provision of at least one cut section or packaging sleeve that can be moulded into a packaging unit.
For this method, the object of the invention is achieved by the packaging unit, of which there is at least one, moulded from a mouldable cut section or packaging sleeve and open at the top, being transported discontinuously or continuously through the preheating zone, the sterilisation zone, the drying zone, the filling zone and the sealing zone and in the process having applied to it, continuously, a laminar flow of sterile air that is directed evenly downwards.
Preferably, for the method in step a), a device according to one of claims 1 to 18 is provided.
According to a further teaching of the invention, the laminar sterile air flow has, at least in sections, an overpressure of 0.12 bar to 0.55 bar, preferably of 0.18 bar to 0.32 bar. The aforementioned overpressure is measured within the sterile chamber for example with the aid of a Prandtl tube.
Finally, it is provided according to a further development of the invention that the packaging unit, of which there is at least one, is transported at a transport speed of 0.8 m/s to 3.0 m/s, preferably at 1.2 m/s to 1.8 m/s through the zones.
The invention is explained in more detail below using a drawing depicting only one embodiment. In the drawings:
The sterile space formed by individual zones A, B, C, D, E is bounded by a housing (not shown) that goes all the way round. At the top, the sterile space is, according to the invention, bounded by the cover 1, of which only a frame 2, going all the way round, and a cover panel 3 are discernible. As already known from the generic prior art, all the supply elements are contained within the cover 1. At the bottom, the ‘sterile space’ is not constructively bounded; its lower extension must however reach to below the packaging units P, that are open at the top, and is indicated in
According to the invention, sterile air is now fed to the sterile space underneath the cover 1 through sterile air tubes which extend through the cover 1 and of which only sterile air nozzles 4 that protrude at the top are discernible. The sterile air nozzles 4 are supplied with sterile air via hoses (not shown). The supply elements comprise—in
The aforementioned supply elements are significantly easier to see in the perspective view in
Preheating connections 13 are connected to corresponding preheating nozzles 14, through which the packaging units P open at the top are flushed out with hot air or superheated steam in order to heat them, so that condensation of sterilising liquid in the interior of the packaging unit P is reliably prevented.
From
According to the invention, there are now several air guide elements arranged underneath cover 1 for the generation of a laminar sterile air flow directed downwards. In the drying zone C, in
It can also be seen in
In the perspective view in
The cross section in
Finally, it is apparent from
Number | Date | Country | Kind |
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10 2015 122 876.9 | Dec 2015 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/079772 | 12/5/2016 | WO | 00 |