DE4130905A1 - Plastic foodstuffs package - has dish stiffened on inside by plastic-coated welded cardboard strip forming collar - Google Patents

Abstract

The foodstuffs package comprises a deep-drawn plastic dish covered by a composite plastic sheet welded to its top peripheral flange. The dish is of thin composite non-rigid soft sheet material, and is stiffened on the inside at the walls at least using a section of cardboard plastic-coated on both sides and welded to it at separate points. The cardboard is in strip form, folded to fit against the inside of the dish, welded together at the overlapping ends so as to form a collar-type structure stable in three dimensions. The soft sheet material can comprise a protective outer layer, an O2- and CO2-proof intermediate one, and a sealing inner one. The outer layer can be of corona-processed polyethylene with high melting point, or polyester, and the intermediate layer of ethylene vinyl alcohol. Polyethylene which can be peeled can be used for the sealing layer. ADVANTAGE - Greatly reduces amount of plastic which cannot be recycled.

Description

The invention relates to a container for the Verpac food, with a deep-drawn bowl made of plastic and one on top Flange section all around firmly connected, preferred wise welded cover in the form of a plastic Composite film, according to the preamble of the claim 1. The invention also relates to a method for the production of a food container according to Preamble of claim 16 and a Vorrich tion to carry out a method of manufacture a food container according to the preamble of Claim 24.

Packaging container of the type described above who which is used and used especially for food det, which due to their slight perishability in be especially during transport and storage Influences from outside, such as B. from excessive temp influences of light or nature must be protected. These containers therefore do not only have to be sufficient dimensionally stable and preferably stackable, but above it also be such that the opened in the container goods taken preferably hermetically against the order given, especially compared to an oxygen-containing Atmosphere is shielded. Another is important criterion for these containers in it see that the manufacture or processing of Container as well as the filling simply performed can be, preferably a space-saving, li Manufacturing plant located near should be aimed for.  

These manufacturing plants have the advantage that they mo dular can be built so that the individual Ar processing stations depending on the container to be manufactured individually compiled and thus economical can be placed.

A conventional container of this type consists in the Rule of two parts, namely a deep-drawn one Plastic shell with top flange and one cover welded to it in the form of a plastic Composite film. This plastic composite film has re a carrier material layer from, for example axially stretched polyamide or polyester, a carbon di oxide or oxygen barrier layer made of ethylene vinyl Alcohol (EVOH) and a sealing layer for sealing the cover with the rest of the shell, with the seal layer usually made of a polyethylene plastic system exists. The bottom of the container, i.e. H. the deep drawn plastic shell of the container becomes higher valuable packaging made of a plastic composite film produced. To save weight, use form stable films, for example based on polystyrene a thickness in the range between 700 and 1000 µm. The In this case, the polystyrene base layer again bears a barrier layer made of an ethylene vinyl alcohol system and a polyethylene seal facing the cover layer that is thermoweldable with the cover. These foils are suitable for both negative and also for positive deformation with and without mechani shear stretching of the film. This way Container shapes of different designs and strengths speed with relatively easy to control machines manufacture, including the retrofitting of the Verpac system when switching from one product to another which can take place relatively quickly.  

When using polyvinyl chloride (PVC) as mecha nically stabilizing layer of the composite rigid film manages to reduce the wall thickness of the bottom film without strength reduce losses. Nevertheless, the a considerable selection of materials per packaging Amount of plastic needed due to the composite construction has the disadvantage that it is a recycling, d. H. can no longer be recycled can.

This problem was recognized early on and tries to build food packaging so that the proportion of plastic that is no longer reusable could be reduced. For example, from the DE-GM 73 30 156 a container made of a laminate be knows who a cardboard layer and at least one tig has a polyester top layer. The main one Liche application of this laminate is in the Use seen to manufacture a container that to cook or reheat food suitable for people. The laminate becomes this Appropriately tailored, then by folding and Pressing into a bowl-shaped shape, where the waiters coming on top of each other when folded Join the surface parts together by heat sealing be increased. Such a container can, however also with a plastic composite film of the above do not hermetically seal the described type, whereby especially in the corner areas of the container great oxygen permeability occurs and due to the missing top flange is a connector with a cover film is not possible.

In the German patent 10 36 153 a Vor direction for producing flat packs described, which consist of thermoplastic coated paper, that is cut and folded so that since  Upper packaging edges bent outwards arise over the then in a capping station a plastic cover sheet welded all around becomes. This known method can also be used do not produce a container that is compatible with sensitive water meets the required tightness criteria. There with is to be considered that with particularly high packaging, evacuation of the pack or back-gassing the pack with a protective gas, such as e.g. B. carbon dioxide is required. Has carbon dioxide a volatility that is about a factor of 4 higher than that of oxygen. Perishable goods can therefore be in a package according to DE-PS 10 36 153 do not keep. Otherwise, that can be Processes known from this document do not use depth Combine drawing systems of conventional design without here make radical changes to the system.

After all, attempts have been made to match containers to build up the preamble of claim 1 so that the shell is both a piece of cardboard and a Plastic part made of thermoformed plastic film pointed. Examples of such containers are in GB-PS 11 36 885, GB-PS 10 43 215 and DE-PS 20 34 154 described. In the case of GB-PS 10 43 215 one is off a box cut folded container over a circumferential, upper angled flange area with connected to a retracted plastic mold. Since the Ver bond between plastic lining and cardboard however, only cut in the flange area hen, the plastic lining is also in this Case still relatively stiff, because the au outside cardboard blank forms a reinforcement and only partially used to stiffen the container shell can be pulled. After all, this process requires a significant amount of cardboard. An integration  of the process in conventional, commercially available Verpac system is also not possible.

In the case of the container according to GB-PS 11 36 885 is even if a folded cardboard blank with lined with a plastic system, which then also all-round, angled flange for attachment forms a cover film. To the plastic film in through the negative form with inserted cardboard blank Being able to draw in vacuum is the cardboard blank designed so that it is smaller in area than that External surface of the drawn plastic film. The stiffening function of the cardboard blank is therefore also relatively in this known case limits.

A perfect, stiffening sheathing of a wan NEN-shaped plastic container with a reinforcement Material cutting from cardboard is in DE-PS 20 34 154 described. In the manufacture of such a container However, ters is a relatively complex one built tool required. First, the cardboard blank folded into a negative form, which with egg interacts with the upper stamp, by means of which then a Foil sheet is pressed into the mold. For folding of the cardboard blank a suction stamp is used dung, the cardboard blank with a relative movement between suction pad and negative form. To the Plastic film with the inner surface of the cardboard Being able to connect firmly, shape the plastic film using the upper stamp the space between the upper stamp and molded art a pressure medium fed, which then the Final shaping of the container and firm adhesion of the fo caused by the folded blank. This Her position procedure is difficult without major Conversion measures with Verpac on the market  kungsmaschinen according to the preamble of claim 24 carry out.

The invention is therefore based on the object Containers for packaging food according to the Generic preamble of claim 1, which is there characterized by that for the manufacture of the container ters required amount of non-recyclable or non-recyclable plastic significantly reduced is, but at the same time still the highest Tightness values are ensured. The structure of the Container should also be such that he with her conventional, preferably linear Verpac kungsmaschinen according to the preamble of claim 24 can be manufactured with as little conversion effort as possible can without the performance of this packaging seem to affect. Another job of Invention consists in the simplest possible Ver drive to the manufacture of such a container create that is in the process at Marktüb seamless packaging machines. Close Lich another object of the invention is a device for performing this method create the container with the least possible high quality device technology can be produced.

The above-mentioned objectives of the invention the regarding the creation of the container with the Merk paint of claim 1, with respect to the method the method steps of claim 16 and with respect the device for performing the method with the Features of claim 24 solved.

According to the invention, the previously used composite Hard film made of polystyrene (PS) or polyvinyl chloride (PVC) through a soft film composite, d. H. an extreme  flexible composite film that is replaced in relation to Hard films have a much lower surface stiffness Has. This soft film composite maintains the containers The structure stabilizing the shape with a cardboard box cut that into the bowl-shaped, very thin-walled composite film is used so that it Flat reinforcement of the soft film composite. Because the box Cutting on both sides with a plastic coating is provided, there is the advantage that the flat Connection between the stiffening cardboard blank and the soft composite film brought into a container shape in the shortest possible time, for example through a selective len or area-covering thermal welding process can be put. At the same time, the two-sided Coating of the cardboard blank also ensures that with high clock frequency from strip-shaped blanks box-like, spatially stable cardboard inserts can be placed by the overlapping Folded sections are thermofused. The processing The cardboard coated on both sides is too spatial stable container inserts with a collar-like structure can be done with such a high number of cycles that the manufacturer carton blanks in parallel with processing the soft composite film in the continuous deduction of a supply roll is carried out. Because fiction according to the already folded and spatial form bile cardboard cut into the molded trough of the Soft film composite is used, result in the positional alignment between the cardboard blank and soft film composite no problems. The one sta bile collar structure, folded and at least at least selectively thermofused cardboard blank with a relatively robust gripper device handled and accordingly exactly over the in the Composite soft film molded recesses positio be kidneyed. The risk of being very thin-walled soft Foil composite when inserting the cardboard blank  injure is diminished. By the invention It is possible to take measures with a soft foil Ver to work bundsystem, which is only a thickness in the loading has between 150 and 200 µm. This way ge the amount of plastic in the packaging that can no longer be recycled can, compared to conventional containers to about Decrease 20%. If, for example, at a ago conventional hard polystyrene film with a thickness of 750 µm and a film width of 425 mm per 1000 m of film 333 kg of recyclable plastic fell, this plastic part is replaced by the Measures according to the invention reduced to about 70 kg. The plastic coating of the cardboard blank can extremely thin-walled, for example with a thickness of run about 12 microns, so that this package plastic waste is of no importance.

The structure of the container according to the invention is independent gig of the tightness of the collar-like used Cardboard cut, especially in the area of the corner edges completely sealed to the outside. The invention Containers are therefore also suitable for packaging drive where the interior of the packaging evaku iert and / or after filling with a stabili medium is back-gassed. It arises on this A very high quality packaging, but only a fraction of it non-recyclable plastic. Here comes the Construction of the container of the application according to the invention very economical manufacturing process quality. Because of the molded trough of the composite film used cardboard blank from a strip-shaped Material obtained is obtained during production of the spatially stable carton blank insert an opening on the bottom regularly, which is advantageous ter way can be used, the preformed  Soft film composite during the insertion of the box cut from above to stabilize by an air flow sieren. The positioning accuracy of the carton cut in the preferably deep-drawn composite film can be further improved in this way and the risk of damage to the very thin-walled Ver bundle film is noticeably reduced.

The construction of the container according to the invention enables a manufacturing process that works seamlessly and without Losses in process performance running conventional packaging machines, such as one have been circumscribed, can be incorporated. The he can build such packaging systems linearly be maintained according to the invention. It's just him required, the step of filling the container one step ahead with the goods to be packaged to be delivered, in which the composite soft film exits fende cardboard blank in the preformed, preferably deep-drawn form is used. The invention Device for carrying out the manufacturing process for more environmentally friendly food packaging by simply upgrading from already on the market sensitive packaging systems can be obtained. The Throughput of the packaging system does not have to be can be reduced. It's just an additional one To provide facility with which either already fer delivered or in parallel by continuous delivery processing of cut and punched cardboard blanks obtained, spatially sta bile, d. H. erected and by thermal welding stabilized cardboard blanks in the deep-drawn ver bundle film can be used. The remaining ingredients the conventional packaging line can remain unchanged to be kept.  

Advantageous developments of the invention are counter stood the subclaims. In claims 2 to 15 are advantageous embodiments of the container itself outlined, the claims 17 to 23 form the inventions manufacturing process according to the invention and in the An sayings 25 to 39 are advantageous developments the device for performing the method under Protection.

A high quality packaging results yourself with the training according to claim 2. Such Soft film composite systems are on the market with Qua lities available that correspond to the application area concerned offers are optimally adapted. Already with thicknesses of about These soft film composite systems are 150 µm safe, d. H. Can be processed with little damage, even if deeper Containers must be molded.

The outer layer of the soft film composite system is preferably of a polyamide plastic, one in front treated, for example corona-treated polyethylene len plastic with a high melting point or a poly ester plastic formed. The use of polyethylene len for the outer layer brings additional price Advantages.

If the sealing layer of the container according to claim 5 trained, it can not be easily recyclable soft film composite very easy from the rest separate part of the container. Nevertheless, over the sealing layer and the plastic coating the cardboard blank a very stable connection, at for example by using a thermal welding process Manufacture rens, so that the mechanical stiffening of the flexible soft film composite through the box is maintained long-lasting.  

According to the invention, the barrier layer is still of an ethylene vinyl alcohol (EVOH or EVAL) is formed. However, according to the invention, the thickness of the plastic jacket of the container is greatly reduced, opened the construction of the container according to the invention is possible speed, the thickness of this ethylene vinyl alcohol layer in Ratio in relation to total strength. This allows the Protective effect for the food can be improved, without reducing the amount of non-recyclable plastic to have to lift noticeably.

When the cardboard blank completely the shell wall lined and a bottom bent inside flange, there is a very good, stiffening Effect of the cardboard blank insert for the deep-drawn gene soft film. Nevertheless, the use can be made out very simply designed, strip-like cardboard cut with individually selected folds or Form fold lines. The after in A bent bottom flange gives the cardboard insert even if the overlapped fold sections are single are spot welded, a very high torsion stiffness. Due to the flat connection of the Kar clay insert with the outer casing from the Soft film composite transfers this torsion-resistant speed directly on the thermoformed soft foil Ver bund, which means that even with heavy packaging casual against overstressing or overstretching protects. By choosing the cut of the box can specifically influence the location and size of the bottom side be taken towards the opening, which is advantageous also happens with regard to the goods to be packaged. The structure of the cardboard blank according to claim 6 has therefore the special advantage of the container with a Minimum cardboard consumption sufficient stability to rent.  

Preferably, the width of the bottom flange is so ge chooses that it ranges between 10 and 40% of Be container width is.

For particularly heavy packaging, it is advantageous to further develop the cardboard blank according to claim 8 and also on the top with a circumferential, facing away angled edge flange. Because of the two side coating of the cardboard can also this Edge flange by thermal welding of folded, and fold section overlapping in the folded form Produce from a strip-shaped blank. The resistance of the container to twisting gene is additionally improved in this way. About that In addition, the upper, peripheral edge flange offers one Protection for the edge of the deep-drawn soft film when Insert the cardboard blank. It has shown, that widths of a few mm already verver this effect support casually.

With a plastic coating on the cardboard blank according to claim 10, the cardboard insert on the one hand erect very easily and secondly in the up aligned form economically to a torsion resistant Create structure, preferably thermowelded eat. The plastic coating according to claim 10 goes with the sealing layer of the soft film composite system a connection that is as secure as it can be established quickly one that is long-term stable even at low temperatures is. The container according to the invention is therefore suitable especially for deep-freeze packaging. Nevertheless, the cardboard blank can be cut after opening the container and according to the consumption of the packaged Separate the goods very easily from the soft film composite system, what the environmental friendliness of the invention Be additionally improved.  

Already with basis weights of about 200 to 300 g / m ² , a very torsion-resistant container insert can be produced, which, in combination with the surrounding composite film, creates a container which is in no way inferior to the conventional container made from deep-drawn composite rigid film.

Due to the double-sided coating of the box Section ensures that the food with does not come into contact with the cardboard material itself. For this area can therefore be recycled cardboard. H. an inferior carton can be used.

The cardboard coating is also preferably by one peelable plastic formed so that the consumer is in a few easy steps, the rever valuable components of the packaging from the non separate recyclable components.

A particularly advantageous further development of the inventor Process according to the invention for the production of food Telbehälters is the subject of claim 17. With the This further training succeeds in the packaging plant training very compact. Another advantage of this Design is that the negative form for the production of the indentations in the soft film composite at the same time as the positioning of the soft foil connection the ge regarding the cardboard blanks to be used can be used. This can reduce the work accuracy of the manufacturing process, the Risk of damaging the flexible film composite system is already very small in that the Cardboard insert is plastic coated on both sides.

The inventive method of flat exit a soft film composite with a spatial stable, d. H. rigid cardboard blank leaves  perform in different ways. It is for example possible to cut the cardboard in strips fenform and the spatial cardboard structure only in the already deep-drawn composite film put. More advantageous, especially with regard to the use of conventional packaging equipment however, the development of claim 18, according to the the cardboard blank in the already folded state in the plastic film brought into the form of a shell becomes.

The development of the method according to claim 21 leads to particularly stable containers. The interlocking between cardboard blank and plastic composite film to an even higher stability of the container and an even better bracing together with the non-surface stable soft film composite. About that it also has this type of side wall design Advantages when flushing the product with gas.

If the molded trough of the plastic film during inserting the cardboard blank through air flow is stabilized, incorrect control can occur even with very thin-walled soft film composite systems men can be reliably excluded. Will be beneficial however, this stabilizing air flow with a Combined suction flow from the counter shape to the Outside of the soft film composite is applied.

The device for performing the method can consistently with conventional components from marktübli Chen packaging systems are executed. A closer one Go to the developments of the device according to claims 25 to 39 is therefore at this point unnecessary. These training courses are aimed in particular depends on the soft film composite during transport through the packaging system as effectively as possible  NEN and the clock frequency of the device to hal hal The device according to the invention is also suitable for the production of several containers in one area walkway and in a workstation what object of claim 37.

Further advantageous configurations are the subject of the other subclaims.

Below are schematic drawings several embodiments of the invention in more detail tert. It shows

Figure 1 is a schematic plan view of a plant for the manufacture of a food container according to the invention.

Fig. 2 is a schematic sectional view according to II-II in Fig. 1;

Fig. 3 is a schematic sectional view according to III-III in Fig. 1;

Fig. 4 shows the view according to IV in FIG. 3;

Fig. 5 shows the detail "V" in Fig. 6;

Fig. 6 is a schematic sectional view according to VI-VI in Figure 1 with a somewhat modified th shape of the used cardboard cut;

Fig. 7 on an enlarged scale a section according to VII-VII in Fig. 1;

Fig. 8 the section according to VIII-VIII in Fig. 6 - rotated 90 ° - in the region of a side wall, which is equipped with a device for forming stiffening beads;

Fig. 9 is a perspective view of the lower tool half for receiving the Kartonzu section;

Fig. 10 in an enlarged scale a partial sectional view of the sealed container in the region of the upper edge flange;

. FIG. 11 is a perspective view of corresponding to the lower mold according to Fig 9 upper mold;

Fig. 12 shows a first embodiment of a cut box in the unfolded state;

Fig. 13 shows a further embodiment of a carton blank in the unfolded state;

FIG. 14 is a perspective view of a corner edge of the blank according to Figure 13 from folded cardboard insert. and

Fig. 15 is a side view of a plant for the implementing of the method for producing a container.

In Fig. 1, the reference numeral 20 denotes a composite film wound on a roller, as it is offered on the market by the company "WALKI" in various versions with different protective properties. This composite film is a soft film composite, for example with the following structure:

The outer layer forming a mechanical protective shield is formed, for example, from a polyamide, a pretreated, preferably corona-treated polyethylene, preferably with a high melting point, or a polyester plastic. The thickness of this layer is, for example, 30 µm. This mechanical protective layer is followed by a barrier layer made of ethylene vinyl alcohol (EVOH or EVAL), which is effective for oxygen and carbon dioxide. The side facing in the representation according to FIG. 1 upper layer is formed by a sealing layer, which is preferably formed by a peelable or from peelable polyethylene plastic or -Kunststoffsystem. The term “soft film composite” is to be understood in the following to mean a composite film which is flexible, ie which is not inherently stable. The wall thickness of this soft film composite is preferably in the range between 150 and 200 μm, the EVAL barrier layer having a thickness in the range between 4 and 30 μm and the sealing layer having a thickness in the range between 50 and 100 μm.

The composite film 20 is drawn off, for example, in a width of approximately 400 to 500 mm from a roller 22 and fed to the linearly structured packaging system, which largely includes work stations, such as are realized in conventional packaging machines, for example from the "Multivac" company. The main stations of the packaging machine are described in more detail below:

30 denotes a deep-drawing station in which the composite film 20 preheated by means of a heating device 32 is negatively deformed in the deep-drawing process. For this purpose, a negative mold tool 34 which can be moved back and forth in the vertical direction (arrow B) is provided, in which four negative molds 36 are formed. The negative mold 34 is therefore suitable for the simultaneous production of four deep-drawing operations. However, it should be emphasized at this point that the invention is not limited to the special arrangement and shape of the containers shown. Much more can be made by replacing the negative mold 34 in the area of the deep-drawing station 30 any type of packaging and also of packaging groups without leaving the basic concept of the invention.

Each negative mold 36 is connected via a line duct system 38 to a negative pressure connection 40 , so that a negative pressure can be generated un timed below the composite film 20 drawn over the negative molds 36 , with which the composite film can be brought into the shape shown in FIG. 2 , which represents the outer shape of the later, finished food container. As can be seen from FIG. 1, four indentations are introduced into the composite film 20 per tool stroke. The indentations are identified in FIG. 1 by reference number 42 .

From the thermoforming station 30 , the composite film or the soft film composite runs intermittently by means of a transport chain to a work station 50 , in which - preferably in one work step - a corresponding number of cardboard blanks 52 set up in a torsionally rigid manner are inserted into the group of four 42 . The composite film 20 is still connected over the entire area in the area of this workstation, which can best be seen from the illustration according to FIG. 3. The thin soft film composite 20 is not - emphasized in the illustration according to FIG. 3 - supports ge between the individual indentations by a guide rail. The exact positioning of the indentations 42 in the work station 50 takes place with the aid of egg nes lower tool part 54 , which is movably guided by columns 58 in the vertical direction and has recesses 56 inside, which form the negative of the final shape of the packaging to be produced. In detail, the depth T of the inner recess 56 is equal to the dimension V of the indentation 42 . The rest of the contour of the inner recess 56 corresponds to the shape of the indentation 42 , so that when the lower tool 54 is moved upward, a flat, full contact of the United film 20 on the lower tool 54 is established. With the reference numeral 60 , a transport plate and die is shown below, which is also movably mounted in the vertical direction and is held on a swivel arm 62 with a swivel axis 64 . The transport plate 60 has a number of projections in the form of positive molds 66 corresponding to the number of inner recesses 56 , with which cardboard blanks to be described in more detail below, brought into box-like form, can be transported from a folding station 70 to the workstation 50 and inserted into the indentations 42 .

The cardboard blanks 52 (see FIG. 3) are obtained from a cardboard coated on both sides, which is wound on a cardboard roll 72 . In the embodiment shown in FIG. 1 of the container manufacturing, filling and sealing system, the manufacture of the cardboard blanks 52 takes place synchronously and in time with the processing of the soft film composite 20 . 74 with a cutter is denoted with which the cardboard sheet 76 into strips 76 - is 4 divides - 1 Up to 76th The number of strips corresponds to the number of containers to be processed simultaneously in one work step. The strips 76 - 1 to 76 - 4 subsequently run into a folding device 78 , in which the individual strips are provided with such a blank and such folding lines 80 that a single strip in a cardboard folding device 82 each has a cup-like cardboard insert 52 arises, which is held in position by the individual positive molds 66 on the transport plate 60 . In Fig. 1, the cardboard inserts 52 located on the underside of the transport plate 60 are merely indicated with dashed lines, only two of such cardboard inserts are shown for simplicity.

The transport plate 60 is upstream a Einrich device 84 , in the individual correspondingly cut strips 86 - 1 to 86 - 4 erected in box shape and in the area of the overlapping Falzab sections firmly connected to each other, preferably ther welded so that at the exit of the device 84 spatially stable, torsion-resistant cardboard cardboard cut inserts 52 are present, which are detected by means of the trans port plate 60 and positioned precisely by a clocked, cyclical pivoting movement, which is indicated in FIG. 1 by the arrow S, over the interior recesses 56 of the lower tool 54 the workstation can be positioned exactly. Instead of the continuous manufacture of the cardboard inserts, it is also possible to supply these inserts in batch mode to the system and to deliver them "just in time" to the work station 50 using the transport plate 60 .

In order to simplify the manufacture of the cardboard insert and also with regard to the subsequent further processing of the insert, the cardboard 76 is provided on both sides with a plastic coating which consists of a thermally weldable polyethylene plastic (PE). The thickness of this plastic coating is, for example, in the range between 10 and 15 μm and the arrangement is preferably such that the coating is easily peelable, ie peelable. The core material of the coated cardboard 76 consists of so-called recycling cardboard and a basis weight in the range between 200 and 300 g / m ^{2 is} preferably selected for the cardboard blank. In a set up and at least at certain points welded state of ge falzten and folded cardboard strip 86-1 bis 86-4, the use of the best on the wall portions 88 can be transported. The folding of the cardboard strips 86 takes place in coordination with the shape of the positive mold 66 in such a way that the cardboard insert 52 surrounds the positive mold 66 in a form-fitting manner. The height H of the cardboard insert essentially corresponds to the dimension V of the indentation 42 or the depth T of the inner recess 56 in the lower mold 54 .

In order to secure the cardboard inserts 52 against falling during the transport into the position according to FIG. 3, a multiplicity of strip-like or rib-shaped pistons 90 arranged in rows are slidably slidably received in the side wall of the positive mold 66 . The control spaces 92 lying behind these strip-shaped or rib-shaped pistons 90 are connected to a channel system 94 . If the control spaces 92 are pressurized in a time-controlled manner via the channel system 94 , the rib-shaped pistons 90 can extend slightly against the force of return springs 96 over the wall 98 and come into frictional engagement with the inner surface of the walls 88 of the erected carton 52 . This state of the strip-shaped pistons 90 is indicated in FIG. 11 on the side wall 98 facing the observer, while the rib-shaped pistons 90 are shown in the retracted position in the adjacent side wall.

It has already been described that the Kar toneinsätze of strips 86-1 bis 86-4 are formed.

In the erected and torsionally rigid, preferably thermofused state of the Falzstrei fens in the simplest embodiment, a Ge is formed with a circumferential collar formed by the wall sections 88 and a substantially right angle standing open floor 100 , the bottom flanges bent from the inside 102 is formed. The width B 102 of these flanges is an adjustable fraction of the total width W of the container.

Due to the perforated bottom 100 there is the possibility to support the latter via the transport plate 60 when inserting the carton 52 into the indentations 42 . For this purpose, a compressed air duct system 104 is provided in the transport plate 60 and the associated holder, with which an air flow indicated by the arrows 106 can be generated in a time-controlled manner. The air flow emerges from the bottom end face of the positive molds 66 and is directed into the interior of the moldings 42 , so that when the lower tool 54 is moved upwards, the full contact of the deep-drawn composite film 20 on the inner wall of the recess 56 is promoted. The compressed air duct system 104 can also be used in addition to control the stroke movement of the rib-shaped pistons 90 .

The illustrations according to FIGS. 1 and 3 differ in so far apart as the cardboard insert according to Fig. 1 is not only equipped with a bottom flange 102 but zusätz Lich still with a top edge flange 108 with egg ner wahlbaren width B 108. However, this top edge flange 108 is only beneficial if particularly heavy packaging is to be produced. Fig. 4 shows this top flange 108 clearly visible. Hatched areas 110 are indicated at which folded folding sections of the cut box overlap in the erected form. A flat or selective thermal welding preferably takes place in these areas. Since the cardboard is coated on both sides, a firm connection of these overlapping areas can be ensured regardless of the folding method.

Fig. 6 shows the location between the lower tool 54 and the transport plate 60 as the upper tool shortly before reaching the bottom dead center of the transport plate 60th The lower tool 54 has already reached the top dead center. The cardboard insert 52 lies together with the composite film 20 against the inner contour 56 of the lower tool 54 . The positive molds 66 of the transport plate 60 are positively immersed in the moldings. The cardboard insert 52 is thereby flat both in the area of the wall sections 88 and in the area of the bottom flange 102 and - as far as existing - also in the area of the upper edge flange 108 ge against the composite film 20 pressed. When pressed together, the upper flange 108 which may be present - see FIG. 10 - can be compressed somewhat so that the thickness D 108 becomes smaller than the wall thickness D 52 . The composite film 20 is not overstressed, since it in turn is supported flatly on the surface contour of the lower tool 54 . In the closed state of the tool parts 54 , 60 , a heating device designated 112 be actuated, so that in the area of the contact sections between the cardboard insert 52 and the composite film, a spot or area welding takes place at the points 118 . This weld covers the entire contact area between the cardboard insert 52 and the film 20th The cardboard insert thus stiffens the flexible, ie slack, soft film over a large area, so that the dimensional stability of the cardboard insert 52 is completely transferred to the soft film composite 20 .

In particular, when particularly stable containers have to be made, the inner recesses 56 in the lower tool part 54 are designed in such a way as can be seen in the detail according to FIG. 9. In this case, a series of elongated depressions 116 are formed in wall surfaces 114 , which are flush with the strip-shaped pistons 90 in the fully retracted state of the positive molds 66 . This state can be seen in the section according to FIG. 8.

Preferably, when the heaters 112 are fourth, the duct system 94 is opened with compressed air, so that the rib-shaped or strip-shaped pistons 90 perform a full stroke to the outside and the carton 52 together with the outer skin from the soft film composite Press 20 into the recesses 116 against the force of the return springs 96 . This creates a substantially vertically beaded profile of the side walls of the container, which leads to an increase in the stability of the container. When the control pressure in the channel system 94 is reduced, the springs 96 press the pistons 90 in question again. The beaded shape of the side walls is retained, however, and also contributes to an improvement in the areal connection between the cardboard insert 52 and the soft film composite 20 .

Fig. 5 is a sectional view of the connection between insert 52 and carton Weichfolien- shows an enlarged view of the container immediately after the completion of laminate 20. This diagram shows the multi-layer structure of both the coated cardboard and the soft film composite. 52 - 1 denotes the core area made from recycled cardboard. 52 - 2 was the Be are coating films of thermally weldable polyethylene (PE) indicated that have up to 15 microns, a thickness of about 10 degrees. 118 denote those positions at which a Thermoverschweißung between the coating film 52-2 and a sealing layer 20-3 of the soft film combination is produced twentieth The sealing layer is preferably made of peelable, ie peelable polyethylene (PE plastic). 20 - 2 denotes the oxygen and CO ₂ barrier layer made of ethylene vinyl alcohol (EVAL) and 20 - 1 the outer layer forming the mechanical protection, which is either made of a polyamide, a pretreated, preferably corona-treated polyethylene with a high melting point or a Polyester plastic is formed.

The thus stiffened indentations 42 finally leave the workstation 50 and are fed to a food loading station 120 and then to a sealing station 130 . In the Dar position shown in FIG. 1, the filling station 120 is not shown, since this station does not differ from conventional filling stations. In the sealing station 130 , a conventional cover composite film 132 runs into the system. The cover film 132 is continuously pulled off a roll 134 and fed via deflection rolls 136 , 138 . The sealing processing station 130 in turn has a lower support tool 140 which interacts with a sealing plate 142 . The sealing plate 142 is heated up and down movable and partially to a Thermoverschwei Ssung to the one-dot chain in Figure 1 advantage shaded areas VS between the cover film 132 and the sealant layer 20 -. To effect 3 of the soft film combination 20.

Fig. 10 shows the state of the container after sealing Ver. This figure shows that the cover film 132 nestles tightly around the existing top edge flange 108 and is thermally welded to the soft film composite 20 in the area VS. FIG., 10 shows that also the cover film 132 is formed as a composite film, wherein a sealing layer 132 - 3 of the gel layer 20 to - 3 comes to lie against. With 132-2 an oxygen and / or CO ₂ is designated barrier layer of ethylene vinyl alcohol (EVAL). The inside of the packaging is therefore surrounded on all sides by a composite film with a barrier layer.

Fig. 7 shows in detail how the seal plate 142 must be formed in order to seal the container in the manner according to the invention. You gelplatte has in the event that the cardboard insert has an upper edge flange 108 , correspondingly formed recesses 144 , between which flat webs 146 remain, which coincide with the sealing areas VS. In the area of these flat webs 146 , partial heating devices 148 are provided which can also extend into the area of the top edge flanges 108 . Additional devices, such as, for example, not shown in the illustrations. B. an evacuation device or a back-gassing device. However, it should be emphasized at this point that these devices can, of course, be used with the plant according to the invention for the production and filling of the food containers.

After passing through the sealing station 130 , the individual containers hang over the cover film 132 and the still connected soft film composite 20 together. The filled and sealed containers then pass into a cutter 150 . In this device 150 , the containers are cut along lines lying in the sealing areas VS. Such a parting line is designated by a dash-dotted line in FIG. 10 with 152 . The cutting device 150 preferably has a longitudinal cutting knife 154 and a transverse cutting knife 156 . The containers 158 separated behind the cutting device 150 can then be removed and suitably packed.

Finally, with reference to FIGS. 12 to 14, before partial cuts with corresponding folds for the cardboard coated on both sides will be described. FIG. 12 shows a cut cardboard strip with which a cardboard insert according to FIG. 4 can be produced. The fold lines are marked with dashed lines. The hatched areas represent the overlap areas in which a thermo-welding of the surfaces that overlap is carried out in order to produce a torsionally rigid spatial structure.

An embodiment of the cardboard strip cut, with which a peripheral flange 108 'is adjustable, is shown in Fig. 13, 14. The thick lines represent the margins of the cut or incision lines. The thin lines are fold lines. The blank of FIG. 13 is folded at the corners as can be seen in the perspective view of Fig. 14. In the erected state, the fold lines 160 , 162 come into contact with one another. The intermediate folding line 164 delimits an outwardly folded flap, which is preferably pivoted into a wall plane of the upright set and is thermover welded to this surface. The edge flanges 108 'overlap in the area Ü and are also thermowelded there.

Fig. 15 shows an overview of a Seitenan view of the system for producing egg ner food packaging. Those stations of the system that correspond to the previously described work stations are identified by identical reference numerals. In this overall view, beyond the representation according to FIG. 1, a filling station designated 120 can be seen. The feed point of the cover film 132 can also be seen in detail. The Dar position shown in FIG. 15 shows that the system according to the invention for the production of the container differs from a conventional packaging system only with regard to the workstation 50 . The remaining stations 30 , 120 , 140 and 150 can be taken over in the same training, if necessary with minor redesigns from a conventional system.

The concept of container production according to the invention even allows stations 30 and 50 to be combined into a unit Z, which results in a very compact system.

Of course, deviations from the above-described invention are possible without leaving the basic idea of the invention. For example, it is also possible to additionally work with positive molds in the area of the deep-drawing station 30 if particularly deep containers are to be produced. These positive shapes can then be used to preform the soft film composite 20 before the deep-drawing process in order to rule out extreme film stretching.

It is also not necessary to cut the box with an edge flange on the top - all around or not - to train. In this case, the Ver sealing station because the sealing plate is a one can get more sophisticated form. If a top, from angled edge flange of the cardboard blank or use is not provided, is also simplified the training of the heating devices, since these then the No longer cover the area covered by the edge flange have to.  

Finally, the device can also be modified in this way be that the feeder for the erect Cardboard inserts separated from the upper form in the ar work station, d. H. from the stamp.

The construction of the container described above results in a food packaging which, as can best be seen in FIG. 10, forms an envelope which is impermeable to oxygen and CO ₂ on all sides. The manufacturing process is kept as simple as possible, whereby conventional packaging systems can be used with the same clock frequency and with the least possible conversion effort.

Claims (39)

1. Container for the packaging of food, with a deep-drawn plastic shell and thus a cover welded around the top via a flange section in the form of a plastic composite film, characterized in that the shell ( 42 ) of a thin-walled, not surface stable in itself Soft film composite system ( 20 ) is formed and stiffened on the inside at least in the area of the shell wall by a cardboard blank ( 52 ) which is plastic-coated on two sides and welded to the shell ( 42 ) at least at discrete points ( 118 ) and which consists of a strip-shaped blank ( 81 - 1 to 86 - 4 ) with the fold ( 80 ) adapted to the inner contour of the shell ( 42 ) and has a spatially stable, collar-like structure by welding selected fold sections ( 110 ; Ü) which overlap in the folded final shape. 2. Container according to claim 1, characterized in that the soft film composite system ( 20 ) of the shell ( 42 ) of a multi-layer composite film ( 20 ) with a mechanical protective shield-forming outer layer ( 20 - 1 ), a lying in the middle area oxygen - And CO ₂ barrier layer ( 20 - 2 ) and an inner sealing layer ( 20 - 3 ) is formed. 3. A container according to claim 2, characterized in that the outer layer ( 20 - 1 ) is formed by a PA system, a pretreated, for example corona-treated polyethylene (PE) system with a high melting point or a polyester-plastic system. 4. A container according to claim 2 or 3, characterized in that the barrier layer ( 20 - 2 ) is formed by an ethylene-vinyl alcohol system (EVOH). 5. Container according to one of claims 2 to 4, characterized in that the sealing layer ( 20 - 3 ) is formed by a preferably peelable polyethylene (PE) system. 6. Container according to one of claims 1 to 5, characterized in that the cardboard blank ( 52 ) completely lines the shell wall ( 42 - 1 ) and has an inwardly bent bottom flange ( 102 ). 7. A container according to claim 6, characterized in that the bottom flange ( 102 ) has a width (B 102 ) which is between 5 and 40% of the container width (W). 8. Container according to one of claims 1 to 7, characterized in that the cardboard blank ( 52 ) has a circumferential, outwardly angled edge flange ( 108 ; 108 ') on the upper side. 9. A container according to claim 8, characterized in that the edge flange ( 108 ; 108 ') has a width (B 108 ) between 2 and 10 mm, preferably 5 mm. 10. Container according to one of claims 1 to 9, characterized in that the plastic coating ( 52 - 2 ) of the cardboard blank ( 52 ) is formed by a thermally weldable polyethylene (PE) system. 11. Container according to one of claims 1 to 11, characterized in that the soft film composite system ( 20 ) has a thickness (D 20 ) in the range between 150 and 200 microns. 12. Container according to one of claims 1 to 11, characterized in that the cardboard blank ( 52 ) has a weight per unit area in the range between 200 and 300 g / m ² . 13. Container according to one of claims 1 to 12, characterized in that the plastic coating ( 52 - 2 ) of the cardboard blank ( 52 ) has a thickness (D 20 ) between approximately 10 and 15 microns. 14. Container according to one of claims 1 to 13, characterized in that the cardboard blank ( 52 ) as the carrier material ( 52 - 1 ) has a recycling cardboard. 15. Container according to one of claims 1 to 14, characterized in that the plastic coating ( 52 - 2 ) of the cardboard blank ( 52 ) is formed from a peelable (peelable) plastic, preferably on the basis of polyethylene (PE). 16. A method for producing a food container in particular according to one of claims 1 to 15, in which a plastic film is placed in a mold in a bowl shape and the bowl filled with the food and then by means of a sealing film, if necessary after performing an evacuation and / or protective gassing process step is gas-tightly connected to an upper flange of the shell, characterized in that

• a) the plastic film ( 20 ), at least in the area of the walls ( 42 - 1 ) and in the transition to the bowl bottom ( 42 - 2 ) made of stiff, plastic-coated cardboard blank ( 52 ) is inserted into the shell ( 42 ) before filling, and
• b) the cardboard blank ( 52 ) used is firmly connected to the plastic film ( 20 ) at selected areas ( 118 ), preferably thermowelded.

17. The method according to claim 16, characterized in that the insertion of the cardboard blank ( 52 ) and its connection to the plastic film ( 20 ) at one and the same working position ( 50 ). 18. The method according to claim 16 or 17, characterized in that the cardboard blank ( 52 ) in the folded state in the shell-shaped plastic film ( 42 ) is used. 19. The method according to claim 18, characterized in that the cardboard blank ( 52 ) from a strip-shaped blank ( 86 - 1 to 86 - 4 ) is formed, which has an inner contour of the shell shape GE brought plastic film ( 42 ) corresponding fold and after folding by connection, in particular welding selected, overlapping fold sections ( 110 ; Ü) in the folded final shape has received a spatially stable, collar-like structure with partially open bottom surface. 20. The method according to claim 19, characterized in that the cardboard blank ( 52 ) in the shell-shaped plastic film ( 42 ) is used after the selected, overlapping in the folded form folding sections ( 110 ; Ü) firmly connected to each other have been. 21. The method according to any one of claims 16 to 20, characterized in that the cardboard blank ( 52 ) is interlocked at least in the region of the side walls ( 42 -1) of the container with the opposite wall of the plastic sheet ( 20 ) in the form of shells. 22. The method according to any one of claims 16 to 21, characterized in that the trough-shaped trough ( 42 ) of the plastic film ( 20 ) during the insertion of the cardboard blank ( 52 ) is stabilized by an air flow ( 106 ). 23. The method according to claim 22, characterized in that the air flow ( 106 ) through the bottom opening ( 100 ) of the carton blank ( 52 ) is directed into the interior of the trough ( 42 ). 24. Device for carrying out the method for producing a food container according to one of claims 1 to 15, in particular for carrying out the method according to one of claims 16 to 23, with egg ner molding station for forming a trough in a plastic film and the molding station ( 30 ) one of a food filling station ( 120 ) downstream sealing station ( 140 ), characterized in that the food filling station ( 120 ) is preceded by a work station ( 50 ) in which a plastic film in the shell ( 42 ) before filling ( 20 ) at least in the area of the walls ( 42 1 ) and in the transition to the tray bottom ( 42 - 2 ) stiffen the cardboard blank ( 52 ) coated with plastic on both sides, and select the cardboard blank ( 52 ) with the plastic film ( 20 ) th areas ( 118 ) are firmly connected, preferably ther welded. 25. The apparatus according to claim 24, characterized in that the work station ( 50 ) has a trough-like deformed plastic film ( 42 , 20 ) positively receiving, lower negative mold ( 54 ) and an upper positive form that can be brought into alignment with this overlay ( 66 ), wherein the cardboard cut ( 52 ) can be pressed flat against the plastic film ( 42 , 20 ) in the closed state of the mold and can be firmly connected to it by at least partial heating ( 112 ) of the negative mold ( 54 ). 26. The apparatus of claim 24 or 25, characterized in that in the upper positive mold ( 66 ) is formed a channel system ( 104 ) through which the trough-shaped plastic film ( 42 ) stabilizing fluid flow through the approach to the negative mold ( 54 ) 106 ) directed to the plastic film ( 42 ) who can. 27. The device according to one of claims 24 to 26, characterized in that the two mold halves ( 66 , 54 ) of the work station ( 50 ) are vertically movable. 28. Device according to one of claims 24 to 27, characterized in that the positive mold ( 66 ) is designed as a transport device ( 60 , 62 ) for the cardboard blank ( 52 ). 29. The device according to claim 28, characterized in that the transport device ( 60 , 62 ) between the work station ( 50 ) and a folding station ( 70 ) can be moved back and forth. 30. The device according to claim 29, characterized in that the folding station ( 70 ) has a heating device ( 84 ) for welding overlapping folded sections in the folded final shape ( 110 ; Ü). 31. The device according to one of claims 28 to 30, characterized in that the positive shape ( 66 ) in the loading area of the trough wall ( 42 - 1 ) opposite side surfaces ( 98 ) a series of essentially lei most or rib-shaped pistons ( 90 ) which extends parallel to each other essentially perpendicular to the horizontal edges of the positive mold ( 66 ) and can be brought from a recessed position into a protruding position by means of a pressure fluid actuation ( 94 ). 32. Apparatus according to claim 31, characterized in that the strip-shaped or rib-shaped piston ( 90 ) in the closed state of the positive mold ( 66 ) and negative mold ( 54 ) existing mold corresponding Ver recesses ( 116 ) in the side walls of the negative mold ( 54 ) are opposite, into which the Kartonzu cut ( 52 ) together with the molded plastic o lie ( 20 ) is deformable. 33. Apparatus according to claim 31 or 32, characterized in that the rib-shaped pistons ( 90 ) are resiliently supported. 34. Device according to one of claims 26 to 33, characterized in that the side walls ( 114 ) and the adjoining edge regions of the negative mold ( 54 ) are equipped with a heating device ( 112 ). 35. Device according to one of claims 24 to 34, characterized in that the work station ( 50 ) at the same time forms the molding station of the plastic film ( 20 ). 36. Device according to one of claims 24 to 35, characterized in that the molding station ( 30 ) has a deep-drawing tool ( 34 ) into which the plastic film ( 20 ) can be drawn in with pressure support after suitable preheating. 37. Device according to one of claims 24 to 36, characterized in that each station of the pre direction is so constructed that in each case in an Ar  processing a group of containers, can be coated or finished. 38. Device according to one of claims 24 to 37, characterized in that the container over the plastic film ( 20 ) coherently transported through the Vorrich device, and that the sealing station ( 130 ) has a separating device ( 150 ) is connected to the the individual containers ( 156 ) are separated. 39. Device according to one of claims 24 to 38, characterized in that the sealing station ( 130 ) has a heated sealing plate ( 142 ), the relief and / or the heating device ( 148 ) of the type adapted to the shape of the cardboard blanks used ( 52 ) is that the seal between the plastic film ( 20 ) and a cover film ( 132 ) is tightly sealed all around by the weld seam outside the cardboard blank ( 52 ).