AT509421A1 - PACKAGING CONTAINER - Google Patents

Abstract

The invention relates to a packaging container (1) having a container casing (2) which has spaced apart first and second end regions (6, 7) in the direction of a longitudinal axis (5), a bottom (3) which in the section of the first end region (6 ), and with a functional element (4) in the section of the second end region (7). The bottom (3) and / or the functional element (4) is formed as a further component from a processable in an injection molding material and thereby formed on the container shell (2). In a connecting section (15, 18) between the container casing (2) and the component (3, 4) formed thereon, a wall thickness (17) of the container casing (2) is to a certain extent in a lower limit of 5%, in particular 15%, and an upper limit of 80%, in particular 50%, with respect to its undeformed initial thickness (16).

Description

25

··· ♦ M6: 05: 51 • * * * • · «« * • »· • * * * · 26-01-2010 5/45 -1 -

The invention relates to a packaging container comprising a container casing which has spaced apart in the direction of a longitudinal axis of first and second end portions, a bottom disposed in the portion of the first end portion, a functional element in the portion of the second end portion, wherein the bottom and / or the functional element is formed as a further component of a processable in an injection molding material and is thereby formed on the container shell.

From JP 9-207936 a packaging container has become known, the peripheral wall part of which is formed from a rolled-up blank plate. The bottom portion, the pillar-shaped frame member and the upper edge portion are formed and formed of a plastic material in the injection molding process. The peripheral wall part has a multilayer structure, wherein the carrier layer is formed of paper on which a variety of layers such as aluminum, polyethylene, nylon, a layer of a dry laminate and an unstretched polypropylene are applied. By a biaxially stretched film layer, the tensile strength of the peripheral wall portion is substantially increased, whereby a tearing in an accidental impact between the molded components and the peripheral wall part is avoided. To achieve otherwise unprotected cutting edges they were covered by the introduced plastic material and includes. Due to the high proportion of injection molding material in relation to the peripheral wall part, a simple and inexpensive disposal could not be ensured in all cases.

Another packaging container is known from JP 7-44605, in which from a curved Rohiingsplatte from a planar blank, the container wall is formed while the bottom, the entire upper opening edge and a column-shaped connecting seam for connecting the end portions of the blank plate made of a plastic material is. In order to facilitate the preforming of the Rohiingsplatte towards the container wall, are in the bending area or curvature of the blank plate M2010 / 00200

26/01 2010 E 15:53 [SE / EM NO A43R1 RtlonS 25 • * · * * * «« «« ♦ m · · · · · · · «« «*» · · · ♦ 6:06: 05 26-01-2010 6/45 -2- along the corner line cutting lines are formed to ensure permanent shaping. These incision lines are made in the region of the circumference such that they are arranged outside those sections to which the plastic material is molded. Here, too, a high proportion of plastic material was used to form the components molded onto the blank plate.

Another, cup-shaped receptacle has become known from JP 10-58482. In this case, the cup-shaped paper container is formed from a laminate material which has a paper layer as the main body and has a plastic layer on the inside or on the outside of the container. For this purpose, additional layers can be applied to the main body. Furthermore, a reinforcing frame is formed at certain points of the cup-shaped paper container by an injection molding process. In this case, a part of the reinforcing frame in the form of a bottom ring portion is formed on the inside of the paper container in the Übergangsbe-retch between the bottom and the container wall. A pillar portion of the reinforcing frame is disposed in the region of the opposite end portions for connecting them to the inside of the container wall. Finally, the upper opening edge portion is also formed of the plastic material and formed in the same manufacturing process with. In this embodiment, it is first necessary to form a complete paper container incl, bottom and then to this from the plastic by injection molding to form the reinforcing frame.

Another training possibility of a packaging container has become known from JP 58-33411. In this packaging container, both the container wall and the container bottom are formed from a blank, wherein again the impact areas in the transition area between the bottom and the container wall, the opposite end portions of the container wall and the upper opening wall portion are formed from a molded plastic material thereon. Here it is again necessary to form a complete paper container incl. Soil and then to mold these from the plastic by injection molding the reinforcing frame.

The present invention has for its object to provide a simple and inexpensive to produce packaging container, which has a high proportion of biodegradable materials and still has a high resistance to the end use. N2010 / Q0200 26/01 2010 DI 15:53 iSE / EM NR 8436] ®006 25 25 7/45 ............... 26-01-2010 • * • • · * * * * * * * * * * * * * * »• I 4 * * * * -3-

This object of the invention is solved by the features of claim 1. The advantage resulting from the features of claim 1 lies in the fact that the injection molding material to be processed is specifically formed only in those areas where this is required by the selected injection molding process. This can be found here with a minimum of material use Auslangen. The supporting and supporting function seen in the direction of the longitudinal axis takes over the container shell, to which the injection molding material is integrally formed. In order to increase the carrying capacity and stability of the entire packaging container, in particular in its bottom region, a compression of the wall thickness is specifically carried out so as to achieve a higher density of the material in the predetermined sections. This not only an intimate connection between the container shell and the injection molding material is achieved but also the moisture absorption difficult or completely prevented. Since the container shell usually runs through continuously up to its footprint, this support area is usually exposed to higher moisture accumulations, whereby the danger of a Auf-queliens of the container shell is made. This makes it possible to form the container shell in its overwhelming portion of a biodegradable material, such as paper or cardboard, which is then provided only at those points with the injection molding material, where this is necessary to complete the packaging container. Thus, open cut edges of the container shell can be used without the risk that the container shell during its intended use, such as storage in the cooling rack, takes damage.

Also advantageous is a further embodiment according to claim 2, since so by the choice of the injection molding process, a large number of design options for the formation of different functional elements is created. If the functional element is part of a closure device, it is possible, depending on the intended use of the packaging container, to mold the respective closure element to the container jacket. In the simplest case, it may be the formation of a flange-shaped seal seal. But this can also be the most diverse snap or threaded connections for other types of closure are formed, since in injection molding a much higher variety of shapes for the design is possible.

Also advantageous is an embodiment according to claim 3, as well as the bottom of the packaging container can be formed easily and with a material set kept as low as possible from the processable by injection molding material. Thus, N2010 / 00200

26/01 2010 DT 15:53 rSF./FM NR S43fil 131110 7 - 4- avoiding additional work to form a safe floor finish. Thus, the displays can be found with a simple blank to form the container wall, while still a bottom can be molded to the container shell with low material usage.

Due to the design according to claim 4, it is possible that in the center region of the bottom of the injection point for introducing the injection molding material can be selected and still a secure distribution of the Spritzgussmateriais is possible up to the bottom edge, possibly even up to the functional element. By the selected webs or the web cross-section not only the further transport of the softened injection molding material is facilitated, but there is also still a partial reinforcement of the container bottom. As a result, the remaining bottom wall can be formed with the lowest wall thicknesses in order to be able to further reduce the proportion of the injection-molding material to the total mass of the packaging container.

According to another embodiment variant according to claim 5, the possibility is created to form a defined footprint in the edge region of the packaging container, wherein the remaining soil is arranged at a distance from the footprint. This can be created a kind of hollow floor. The container shell, which nowadays mainly serves as an advertising or information surface, can thus be increased in its extent. In this case, an adaptation or change of the filling volume of the entire packaging container with a constant container size is easily possible.

Also advantageous is a development according to claim 6, since in one operation, starting from the injection point selected in the bottom region, formation of the section of the packaging container forming the open end region is also possible. Thus, in a single operation after the insertion of the container shell or the blank thereof into the injection mold, the plastic material softened to form the components to be molded thereon can be selectively distributed.

In the embodiment according to claim 7 is advantageous that the delay or uneven shrinkages of the packaging container are avoided after its production.

The development according to claim 8 ensures that in a simple manner similarly trained packaging containers can be stacked in each other, N2010 / 00200 26/01 2010 m IR: 53 I SP / FM NR A43R1 Ciinn »-5-« · 'amp &; 06: 54 26-01-2010 k «« · I 9/45 4 «· k ·« · 4 • «* * * * Without the jamming of each other during subsequent singling, it will be through the selected injection molding process possible to be able to train these simple and diverse, since in injection molding a higher design possibility exists.

As a result of the embodiment according to claim 9, an uninterrupted outer surface of the packaging container can be created which represents a high degree of design capability in the form of an advertising surface. In addition, the container shell can be provided with a high-quality print image, which then remains unchanged during the molding process of the injection molding material.

Also advantageous is an embodiment according to claim 10, since in conjunction with the applied print image depending on the arrangement and orientation of the connecting webs a high design possibility in the formation of the packaging container is provided. In addition, an all-round continuously smooth trained interior of the packaging container is created in its mantle area.

According to an embodiment as described in claim 11, a targeted forwarding of the softened injection molding material is achieved within the injection mold. As a result, even a complete filling of the entire mold cavity is ensured.

In this case, an embodiment according to claim 12 proves advantageous because in a single operation, the Anformung or the formation of the component to be produced by injection molding is made possible. Thus, the high mold variety can be exploited in the injection molding process, wherein at the end of the manufacturing process, a finished packaging container is present, which is only to be supplied to a filling with the product to be accommodated therein. Depending on the selected functional element then also the closure of the receiving space is ensured.

According to an advantageous embodiment according to claim 13, the possibility is created to be able to easily adapt the packaging container to a wide variety of applications.

However, an embodiment according to claim 14 is also advantageous since the container casing can be produced as a simple blank without high processing costs. Subsequently, the blank is placed only more positioned in the injection mold and during the production or introduction of the injection molding material also becomes a stable connection of the end sections the container shell ensured.

According to claim 15, this is formed before the introduction of the container shell this in its final spatial form and then formed thereon the components to be formed, such as the bottom and / or the functional element and / or the connecting webs. This would make it possible to produce the packaging container even with spaced apart injection points,

In the embodiment according to claim 16, a high possibility of variation for the formation of the container shell is provided, wherein this can then be matched exactly to the predetermined application. Depending on the selected layer structure packaging containers can be created so easy, which meet the requirements of the therein contained contents and still the proportion of injection molding material can be kept low in terms of disposal. Also possible is an embodiment according to claim 17, since the layers or layers corresponding to the respective application can thus be applied or provided on a carrier layer formed mostly of paper or cardboard. This in turn creates a high possibility of variation in the formation of the packaging container.

Finally, however, is also an embodiment as described in claim 18 possible, since so in the formation of the packaging container in the selection and arrangement of the components to be formed from the injection molding material, only such a small proportion is selected that the entire packaging container as a "paper container". applies and can be disposed of as a used unit without separation. Since these are mostly plastic materials, it is precisely these resources that should be greatly minimized.

For a better understanding of the invention, this will be explained in more detail with reference to the following figures.

Each shows in a highly schematically simplified representation:

1 shows a first embodiment of a packaging container, in perspective view: N2010 / 00200 9fi / mnnn m 1 S 5 Ä qp / PM nt? «Tici I ^ imn ..." .. **.: *** - "* 6 * 07: 23 26-01-2010 11/45: :: :: - 7

FIG. 2 shows the container casing as well as the components of the packaging container 1 according to FIG. 1 produced in the injection molding process, cut away in a view as well as a position distanced from one another; FIG. Fig. 3 shows the packaging container of Figures 1 and 2, in axial section. 4 shows a partial section of the bottom and of the container jacket according to FIG. 3 in an enlarged view; 5 shows a partial section of the functional element and of the container jacket according to FIG. 3, in an enlarged view; 6 shows the skeletal component produced by injection molding with the container jacket removed, in a perspective view; 7 shows a detail of the casing jacket in the region of its adjacently arranged end sections with a connecting web connecting the end sections, in section according to the lines VII-VII in FIG. 2; 8 shows a further embodiment of a packaging container, in perspective view; FIG. 9 shows the packaging container according to FIG. 8 in a view; FIG. 10 shows another embodiment of a packaging container, in perspective view; FIG. 11 shows the packaging container according to FIG. 10 in a view onto the tab; FIG. Fig. 12 in one another stacked packaging container according to FIGS. 10 and 11, in axial section; 13 shows a further embodiment of a packaging container with attached lid, in perspective view; FIG. 14 shows the packaging container according to FIG. 13, but with the lid removed, in a perspective illustration; FIG. FIG. 15 shows the packaging container according to FIG. 14, in plan view; FIG. Ν2010 / 00200 26/01 2010 III 15:53 ISE / EM NR 84361 Bl 011 25 · 25 · • «* · * · 1G? 07: 33 26-01-2010 • * · ··« · · * · · * «· #« «· · ·» · * * ♦ * «· ♦ 12/45

-8th-

16 shows a possible layer structure of the container shell in cross section;

17 shows a further layer structure of the container shell in cross section;

18 shows another layer structure of the container shell in cross section;

19 shows a further layer structure of the container shell in cross section;

20 is a partial section of the bottom and the Behättermantels another possible embodiment of a packaging container, in axial section and enlarged view;

21 shows a partial section of the bottom and of the container casing of another possible embodiment of a packaging container, in axial section and in an enlarged view;

22 shows a detail of the container jacket in the region of its end sections with a connecting web connecting the end sections, in plan view.

By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position. Furthermore, individual features or combinations of features from the different exemplary embodiments shown and described can also represent independent, inventive or inventive solutions. All statements on ranges of values in the description of the present invention should be understood to include any and all sub-ranges thereof, e.g. the indication 1 to 10 should be understood as encompassing all partial regions starting from the lower limit 1 and the upper limit 10, ie all partial regions starting with a lower limit of 1 or greater and ending at an upper limit of 10 or less, e.g. Eg 1 to 1.7, or 3.2 to 8.1 or 5.5 to 10. N2010 / 00200 26/01 2010 DI 15: 5.1 fSF / FH \ 'R «416 1 -9- * 10:07 : 47 26-01-2010 13/45 25

FIGS. 1 to 7 show a first possible embodiment of a packaging container 1, which comprises a container casing 2, a bottom 3 and at least one functional element 4. It should be mentioned at the outset that the packaging container 1 shown here and the packaging container 1 described below represent only one possible spatial form and these can be adapted depending on the intended use of the product to be packaged in their shape, size and appearance of the respective requirements. There are a variety of cross-sectional shapes such. round, angular, oval and any combination possible.

The container casing 2 has, in the direction of a longitudinal axis 5, spaced-apart first and second end regions 6, 7. In the present exemplary embodiment, the base 3 is arranged in the section of the first end region 6, wherein the functional element 4 is located in the section of the second end region 7.

The container casing 2 can be made of a wide variety of materials and material compositions in a different arrangement zueinender. In this case, both a single-layer and multi-layered design of the container shell 2 can be selected. This depends on the respective intended use or intended use of the packaging container 1.

Furthermore, it is possible to form the base and / or the functional element 4 from a material that can be processed by injection molding and thereby to be molded onto the container shell 2 during the manufacturing process. This requires that prior to the introduction of the injection molding material in the injection mold, not shown here before closing the same, the container shell 2 is inserted as part of the packaging container 1 in the mold cavity. Depending on the spatial shape of the packaging container to be produced, the container casing 2 is positioned in its preformed position within the mold cavity of the injection molding tool and then attached thereto to form the bottom 3 and / or the functional element 4 and further components of the packaging container 1 to be described below Material injected. By this injection process, a molding of the softened and processed Spritzgussmateriafs to the container shell. 2

As can now better be seen from FIG. 2, at least one connecting web 8 is provided between the base 3 and the functional element 4 in this embodiment of beispiet chosen here. This extends continuously between the bottom 3 and the functional element 4 and thus forms a skeletal skeleton, which also as N2010 / 00200 9 fi / Λ 1 9Λ1Λ ΠΤ f / 1711 MO ÜHßi Γ3ΐ Λ 1 1 25 25 14/45. ................. 26-01-2010 »* *« * * ♦ # * * YY t «* *« · ** ::: ...... .......... 10-

Reinforcement frame or the like. Can be called. Because the container casing 2 has already been inserted into the injection molding tool for the shaping process, the components, such as the base 3 and / or the functional element 4 and / or the connecting webs 8, are molded onto the container casing 2. to avoid subsequent deformation of the packaging container 1 after its production process, it is advantageous if several such Varbindungsstege 8 are seen with respect to the longitudinal axis 5 and over the circumference of the packaging container 1, distributed. Thus, a symmetrical distribution around the longitudinal axis 5 has proven to be favorable. In the present embodiment, four pieces of such connecting webs 8 are provided. Depending on the spatial shape and the receiving volume of the packaging container 1, the number of connecting webs 8 can be varied as desired. The less or less the number of connecting webs 8, the less material is used for the production of the injection molded part.

The connecting webs 8 shown here are arranged in this embodiment on one of the longitudinal axis 5 facing the inner surface 9 of the container shell 2. Regardless of this, it would also be possible to arrange the connecting web or webs 8 on an outer surface 10 of the container casing 2 facing away from the longitudinal axis 5. But it is also possible to provide the connecting webs 8 both in the region of the inner surface 9 and in the region of the outer surface 10. If the connecting webs 8 are provided both on the inner surface 9 and on the outer surface 10 of the container casing 2, the individual connecting webs 8 can be arranged either directly opposite to the inner surface 9 and outer surface 10 or offset from one another in the circumferential direction.

As can now better be seen from FIG. 6, in this depiction, for better clarity, the container casing 2 has been completely omitted in order to be able to better describe the associated and one-part component, which has been produced in the injection molding process. This one-piece component here comprises the base 3, the connecting webs 8 and the functional element 4.

The bottom 3 is also formed here completely from the processable by injection molding material. In the exemplary embodiment shown here, this comprises a bottom wall 11 and a tubular edge section 12 arranged in the peripheral region of the bottom wall 11 and facing the container shell 2. N2010 / 00200 26/01 2010 DI 15:53 ISF./EM NR 8436] 0014 25 25 15/45. . **. .......... 08.20 26-01-2010 ::: ·: - 11 -

In order to produce the molded part molded onto the container casing 2, it is provided here that the so-called injection point is selected in a center 13. So here both the bottom wall 11 and the bottom edge portion 12 is formed continuously from the processable by injection molding material. In order to save material or material for the formation of the bottom 3, in particular the bottom wall 11, the Auslangen should be found here with very low wall thicknesses. The wall thickness can here be e.g. between 0.2 mm and 0.5 mm. Since the supporting and supporting function of the packaging container 1 is to take place through the container casing 2, in the components produced by injection molding, attention is only to be paid to their intended use, this sometimes only encompassing the tightness and some of the components no longer having any supporting function. t i i i i Ϊ

In order to achieve an optimal distribution of the material introduced by the injection molding process, at least one web 14 extending down to the bottom edge section 12 should be provided in the bottom wall 11 starting from its center 13, this being an integral part of the bottom wall 11. Viewed from the cross section, the web 14 has a size which is sufficient to spend the introduced by injection molding, softened plastic material, starting from the injection point - here from the center 13 - towards the bottom edge portion 12 and werterer sequence to the connecting webs 8 and the functional element 4 can. Thus, the web 14 with respect to the remaining remaining bottom wall 11 to a greater thickness. The connection of the remaining remaining bottom wall 11 to the or the webs 14 can, as seen in the axial direction of the longitudinal axis 5, be chosen arbitrarily. It has proved to be favorable if the web or webs 14 project beyond the bottom wall 11 onto the side facing away from the functional element 4. It is thereby achieved that at the receiving space of the packaging container 1 facing side of the bottom 3, a planar formation of the same takes place. However, the web or webs 14 may also protrude beyond the bottom wall 11 on the side facing the receiving space or the further end region.

Furthermore, it can be seen from FIG. 6 that in the region of the bottom wall 11 of the bottom 3 a plurality of webs 14 are provided, which extend in a star-shaped or radially extending manner from the center 13 towards the bottom edge 12. Here again, a symmetrical with respect to the longitudinal axis 5 arrangement with respect to this seen over the circumference, advantageous. Likewise, the number of webs 14 should be equal to the number of connecting webs 8 selected. For a better distribution of the injection-molding material, starting from the center 13 to the components to be produced therefrom N2010 / 00200 2010 IIT 1R: KS ("R / RM NR fidilfi 1 Biniü 25. ·· * '··. * J6tt8: 37 26-01 -2010. "* * · · * *: ::: ::: Μ ......... • · ···« 16/45 - 12 - of the packaging container 1 is here provided that The web (s) 14, as seen in the direction of the longitudinal axis 5, are arranged circumferentially offset relative to the connecting web or webs 8. With a number of four connecting webs and the same number of webs 14, the offset between the individual webs 14 and the connecting webs 8 each formed at 45 °.

4, the connection of the bottom 3 is shown with its bottom edge portion 12 to the inner surface 9 of the container shell 2 on a larger scale. As described above, here the bottom edge portion 12 is formed in the axial direction approximately tubular and formed together with the bottom wall 11 to the inner surface 9 of the container shell 2 during its production. Thus, the bottom edge portion 12 forms a connecting portion 15 between the container shell 2 and the component formed thereon - in the present example, the bottom 3 - from. Furthermore, it can still be seen clearly here that the container casing 2 has an un-deformed initial thickness 16 next to the connecting portion 15, whereas in the connecting portion 15 a wall thickness 17 of the container container 2 is reduced by an amount in a lower limit of 5%, in particular 15%, and an upper limit of 80%, in particular 50%, with respect to the undeformed initial thickness 16 is reduced. However, this reduction of the wall thickness 17 with respect to the starting thickness 16 can also be formed in the region of the connecting webs 8 and in a further connecting portion 18 between the functional element 4 and the container shell 2, as best seen in FIG. 5. The functional element 4 is formed in this embodiment as part of the formation of a known seal closure and here comprises at least one circular-annular shaped flange. The formation of the functional element 4 as a sealant is well known in the case of the packaging containers produced so far. Therefore, the detailed description is omitted.

Furthermore, it can be seen from FIG. 4 that the bottom wall 11, viewed in the axial direction, is arranged at a distance from the first end region 6 in the direction of the second end region 7. This forms a so-called hollow bottom of the packaging container 1. By this measure, the appearance of the entire packaging container 1 can be made larger, for example, to be able to provide a figher surface area by the larger Behäitermantel 2 for printing or the like. The receiving volume of the packaging container 1 can then be varied depending on the distance from the first end region 6 here. The first end portion 6 constitutes a footprint for the packaging container 1 and is defined by an end face 19 of the N2010 / 00200 2ß / o1 2010 m

15:53 ISR / EM NR S43R1 ®niR - 13 - Jß: (yes: 5S 26-01-2010 1 7/45

Container shell 2 optionally formed in cooperation with the bottom edge portion 12. Thus, e.g. the bottom 3, in particular the bottom wall 11 between 1 mm and 5 mm or even more to Aufstandsftäche the packaging container 1 to be arranged inwardly.

By the above-described reduction of the initial thickness 16 of the container shell 2, a compression zone is formed in this region, whereby the absorption of moisture in the region of the end face 19 of the container shell 2 is minimized or even avoided. In most cases, the end face 19 is an unprotected cutting edge, which, if the material of the container casing 2 is suitably selected, is otherwise subjected to moisture absorption unprotected.

As now again better seen in FIG. 2, the container casing 2 is usually formed from a planar blank, which is erected, wound or rolled to form the Verpackungsbehäi-ters 1 according to its auszusteilenden spatial form to in this preformed position or Position can be inserted or inserted into the injection mold.

As a planar blank, the container shell 2 end portions 20, 21, which are arranged after erecting in a mutually opposite position.

Is an exclusive connection of the two end portions 20, 21 provided by one of the components previously described and produced in the injection molding process (bottom 3, functional element 4 and connecting piece 8), they are held to each other in position or connected to each other.

In Fig. 7, the two end portion 20, 21 are shown in a sectional plane in a vertical orientation with respect to the longitudinal axis 5, wherein here on the inner surface 9 of the container shell 2, a connecting web 8 is shown, which the two end portions 20, 21 in the vertical direction covers the longitudinal extent. In accordance with the selected length of the blank to form the container shell 2, the two end portions 20, 21 may be aligned in immediately opposite and abutting position. The more accurately the circumferential length of the container jacket 2 is formed, the lower the formation of the gap between the mutually facing end portions 20, 21st

Regardless of this, it would also be possible, in turn, to form the container casing 2 as a planar blank and, in its erected state, the mutually unconstrained N2010 / 00200 26/01 2010 DI 15; 53 [SE / EM NR S4361 © 017 - 14-25 * »yi 09:10 26-01-2010 18/45 immediately adjacent end portions 20, 21 connect to each other. This could be done for example by a so-called overlap shock, in which overlap the two end portions 20, 21 in the circumferential direction. In the interconnected state then the container casing 2 is formed, which can be inserted into the injection mold, not shown, and then the complete packaging container 1 is completed by injection molding of the components described above.

Regardless, however, it would also be possible for the skeletal or frame-shaped component to be formed from the injection-molding material and then to be clad first with the container mantle 2. In this case, the container shell 2 can be preformed as a jacket-shaped component and then joined together with the injection molded part. Furthermore, however, the blank prepared for forming the container shell 2 could also be applied to the skeletal or frame-shaped component from the injection-molding material in a winding or rolling-up operation. Depending on the selected joining process can then be necessary to bond between individual components.

FIGS. 8 and 9 show a further embodiment of the packaging container 1, which is possibly independent of itself, wherein the same reference numerals or component designations are used again for the same parts as in the preceding FIGS. 1 to 7. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding Figs. 1 to 7 or reference.

Basically, the packaging container 1 shown here corresponds to that which has already been described previously in FIGS. 1 to 7. This packaging container 1, in turn, also comprises the container casing 2, the bottom 3, the functional element 4 and the end regions 6, 7 distanced from one another in the direction of the longitudinal axis 5. In the region of the first end region 6, the bottom is again provided, which may correspond to that design. as previously described in Figs. 1-7.

In contrast to the embodiment described above, the functional element 4 is not formed as part of a SiegeJverschlusses with a sealing flange, but is in the form of a container collar 22. The container collar 22 in turn is approximately tubular and extending in the direction of the longitudinal axis 5 extending. This has on its side facing away from the longitudinal axis 5 outside parts of a snap closure, namely on the surface projecting locking elements 23. This will make it N20TD / 00200 9R / D1 ΟΠίΛ Γι 1 cf / T? \! For example, it is possible to snap open a lid or the like and, if desired, provide it with an opening guarantee band or the like. But it would also be possible to provide the locking element or the 23 on the longitudinal axis 5 facing the inside of the container collar 22 and also form on both sides of the container collar 22. This depends on the selected closure.

Regardless of or in addition to this, it would also be possible to simultaneously design a locking element 24, for example in the form of a lid or the like, in the course of the injection molding process. The connection can be made to the functional element 4 in the region of a radially projecting flange 25, as indicated in dashed lines in FIG. 9. The cover formed here as a closure element 24 may be connected or coupled, for example via a kind of film hinge or the like with the functional element 4, in particular its flange 25.

FIGS. 10 to 12 show a further embodiment of the packaging container 1, which is possibly independent of itself, wherein the same reference numerals or component designations are used again for the same parts as in the preceding FIGS. 1 to 9. To avoid unnecessary repetition, reference is made to the detailed description in the preceding Figs. 1 to 9 or reference.

This packaging container 1 in turn comprises the container casing 2 on which the bottom 3, the functional element 4 and the connecting webs 8 are integrally formed thereon by injection molding. Since this packaging container 1 shown here is formed almost identical to that, as has been described in FIGS. 1 to 7, the similar components will not be discussed in more detail.

The components formed from the injection molding material, namely the bottom 3, the functional element 4 and the connecting webs 8 are again in a single operation directly to the container edge! 2 molded. The functional element 4 is here in the region of the second end portion 7 in the form of a flange 26 which is formed in the circularly formed here packaging container 1 almost completely over the entire circumference with the same flange width continuously. In addition, it is indicated here even in the region of the functional element 4 that an additional tab 27 is provided on the flange 26 in the upper open end region 7. The tab 27 is penetrated by an opening 28. Thus, the tab 27 can serve with its opening 28, the entire packaging container 1, for example, at a bar or hakenför- N2010 / 002 00 26/01 2010 DI 15:53 [SE / EM NR 8436) 0019 25 • · '♦ 4 · · · 4 4 · μ · *; * · · · · * 4 * 4 4 · 1. * ΐ6: Ϊ9: 43 26-01-2010 20/45 4 4/16 "retaining element. which is not shown here, for the presentation there to support. In this embodiment shown here, the tab 27 extends approximately in parallel alignment with respect to the container shell 7 and almost in the same direction with respect to the longitudinal axis. 5

As can now better be seen from FIG. 12, additional stacking means 29 are provided in each case in the region of the individual connecting webs 8, which are web-shaped and protrude starting from the connecting webs 8 in the direction of the longitudinal axis 5. These can be formed during the injection molding process simultaneously with the other components also produced in the injection molding process. These serve in a known manner for nesting of similarly shaped packaging containers 1. The stacking means 29 may also be formed by partial projections, lugs, cams or the like. It is also the arrangement in the region of the connecting webs 8 is not mandatory.

Furthermore, in the transition region between the tab 27 and the peripheral flange 26, an additional bead 30 is formed. This bead 30 can, as indicated in FIG. 12, serve as a contact surface of packaging containers 1 stacked one inside the other so as to avoid additional, mutual entanglement or jamming.

FIGS. 13 to 15 show a further embodiment of the packaging container 1, which may be independent of itself, wherein the same reference numerals or component designations are used again for the same parts as in the preceding FIGS. 1 to 12. To avoid unnecessary repetition, reference is made to the detailed description in the preceding Figs. 1 to 12 or reference.

This packaging container 1 shown here is approximately the same design, as has been previously described in FIGS. 10 to 12. The spatial shape or cross-sectional shape of the packaging container 1 with respect to the longitudinal axis 5 seen, is hereby chosen differently between the first end portion 6 and the second end portion 7. Thus, for example, the cross-sectional shape in the region of the bottom 3 may be formed circular, wherein, however, in the open end region 7, an approximately oval cross-sectional shape is selected.

In the region of the end region 7 which is open here, in turn, the functional element 4 is shown in simplified form, which comprises the flange 26, which is designed to run almost peripherally. At its outer edge region, in turn, the previously described tab 27 is provided N2010 / 00200 26/01 2010 DI 15:53 ISE / EM NR 84361 01020 »* ♦ * 16:09:59 26-01-2010 21/45 - 17 - hen. Again, this can be provided in the region of the tab 27 an opening 28 passing through this.

In addition, it is also shown in FIG. 13 that the packaging container 1 can be closed in conjunction with the functional element 4 with a lid 31 in the manner of a snap closure. For the originality / insurance in turn appropriately trained separation strips or the like may be provided.

The arrangement and design of the bottom 3 and the connecting webs 8 between the bottom 3 and the functional element 4 can be carried out analogously to one of the embodiments described above according to FIGS. 1 to 12, wherein any combination of the individual components can be done with each other.

In all the embodiments of the packaging container 1 described here, it is provided that the introduction of the material which can be processed by the injection molding process takes place in the center 13 of the base 3. The distribution of the injection-moldable material in the region of the bottom wall 11 is usually via the extending between the center 13 and the bottom edge portion 12 webs 14 toward the bottom edge portion 12. The webs 14 can also be referred to as Flieshilfsstege, which in addition to the entire stiffening or Reinforcement of the bottom wall 11 serve. Due to the previously described circumferential displacement of the webs 14 in the bottom 3 with respect to the connecting webs 8, a continuous filling of the mold cavity takes place in the region of the bottom edge section 12 until the injection molding material reaches the connecting webs 8. Subsequently, the injection-molding material is passed on via the connecting webs 8 to the functional element 4, in which case a circumferential filling of the mold cavity space takes place to form the functional element 4. Depending on the selected cross-sectional shape of the mold cavity, the forwarding of the injection molding material is determined. In order to use a minimum amount of injection molding material in relation to the container casing 2, attempts are made to find the way with the smallest possible cross-sectional areas for forwarding or forming the bottom 3, the functional element 4 and the connecting webs 8.

As an example of the material savings on the injection molding material used here briefly an example is given. In one dimension of a packaging container 1 with a diameter in the region of the open end region 7 of about 105 mm and a height of 108.5 mm with conical design of the container shell 2, this results in the injection molding process with a wall thickness of 0.6 mm and a snap closure N +10 / 00200 26/01 2010 T) T 15:63 fSK / t-Ί NR 8436 1 131021 25 * · 16:10:15 26-01-2010 22/45 - 18 functional element 4 has a total mass of 22.7 g, The same embodiment of the packaging container 1, but with a smaller wall thickness of 0.3 mm, this leads to a total mass of 15 g. If a large part thereof is omitted in the area of the container casing and only a few connecting webs 8 are formed between the bottom 3 and the functional element 4, the total thickness of the connecting webs 8 is reduced to 10 g of the injection molding material used with a wall thickness of 0.6 mm.

This approach to reduce the total mass of the packaging container 1 to injection molding material is, inter alia, still an essential goal for the design of the packaging container 1 described here. So should a mass fraction of the container shell 2 with respect to the total mass of the packaging container 1 in any case be greater than 50%.

The main component of the container shell 2 should be selected from biodegradable or recyclable materials, such as paper and / or cardboard formed from cellulose. This main component of the container jacket 2 can also be referred to as a carrier layer or base layer. The container casing 2 may, however, also have a multilayer or multi-layer structure, these layers or layers being arranged both on the inner surface 9 of the container casing 2 facing the longitudinal side 5 and / or on the outer surface 10 of the container casing 2 facing away from the longitudinal side 5 or may be applied.

Depending on the intended use of the packaging container 1, it can serve for receiving or packaging foods, hygiene articles, toiletries, cleaning agents or detergents. The foods may be milk and / or dairy products. Cream, juice, alcoholic beverages, dry food and liquid foods act. Depending on the component of the packaging container 1 which is to be taken up and packaged, it can also have the following packaging properties for the packaged products, such as flavor protection, impermeability to grease. Opacity, UV protection b2w. Have oxygen impermeability. Furthermore, the entire packaging container 1 should also be heatable in an oven or the like and thus be formed as a total heat-resistant. If, for example, hot drinks are filled, care must also be taken to ensure that the packaging as a whole can be easily touched or handled. An important aspect of the entire packaging container 1 is N2010 / 00200 9fi / ni? O 1 ο ητ 1 ü: SS rSM / FH NR JU.Sfil

# * · # 16:10:31 26-01-2010 23/45 - 19- also that it is recyclable or compostable as a whole. For this purpose, the respective materials used should be selected according to these requirements.

Other layers of the container shell 2 in addition to the carrier layer formed predominantly of paper or cardboard may be, for example, metal foils, plastic films and optionally adhesive and binding materials. The plastics may, for example, be selected from the group of materials such as polymers, polyamides, styrenes, olefins, polyalkylene terephthalate, polylactide, polyester or a particular mcoobination, and mixtures thereof. The polymeric materials include, for example, low density polyethylene (PE-LD), low density polyethylenes and pigmented pigments incorporated therein, low density polyethylenes modified with maleic anhydride, high density polyethylenes (PE-HD), polypropylenes ( PP). The styrenes include, for example, yst polystyrenes (PS). Examples of alkyl acrylates include ethylvinyl alcohol (EMA). The olefins include, for example, the polyolefin (PO). Finally, for example, one of the polyalkylene terephthalates is the material polyethylene terephthalate (PET).

In the simplest case, a PE coating, for example in the form of a film, is applied to the carrier material formed from paper or cardboard, in order to make it possible to bond the injection-molded material to it. In this case, the coating can be applied only in sections, where the injection molding material is formed. On the outer surface 10 and / or the inner surface 9, a printed image not described in detail is preferably applied in a known manner. The total starting thickness 16 of the container casing 2 may be on the order of 0.2 mm, in particular 0.3 mm, and 1 mm, in particular 0.5 mm. Furthermore, it is also possible in the area of the container shell 2 embossments, such as logos, 3D characters or the like. Form. These can be formed either before inserting the blank to form the container shell 2 or even during the injection molding process by the injection molding tool and / or the injection molding process.

The material which forms the base 3 and / or the functional element 4 and / or the connecting web or webs 8 is to be chosen such that it can be processed by injection molding. For example, plastics and compostable materials or the like have proven themselves. Thus, for example, polypropylene (PP), polyamide (PA), polystyrene (PS), polycarbonate (PC) and unspecified further here designated, sprayable materials are used here. As cycle time for the injection molding process N2010 / 00200 26/01 20.10 TUE 15:53 TSF / RM NR 84361 K1023 16:10:48 26-01-2010 24M5 21 9 «hi t * * * * * (· · · l * · * * II * ♦ * * * * * * * * * * * * -20 -such a packaging container is selected for a period between 2 seconds and 6 seconds, especially between 3 seconds and 4 seconds ,

From the components described above for the formation of individual layers or layers of the container shell 2 or also the processable by injection molding materials, these are summarized here overview once again. These include polymers, polyamides, ethylvinyl alcohol, ketene dimers, styrenes, olefins, sulfates. Alkyl acrylates, adhesives. Cementing agents, polyalkylene terephthalates, polylactides and polyesters.

In the following FIGS. 16 to 19 possible and optionally separate arrangements or different layer constructions of the container casing 2 are shown, wherein this arrangement possibilities is only an example for a multiplicity of possible material combinations.

Thus, a first exemplary embodiment is shown in FIG. 16, wherein here a carrier layer 32 made of a fibrous layer, such as cardboard or paper, for example, is shown with a greater wall thickness or layer thickness.

In the area of later forming the outer surface 10 side of the support layer 32, starting from the outer surface 10, two further layers by the reference numerals 33 and 34 marked. In this case, the outermost layer 33 may be a layer of a polymeric material, as has already been described hereinbefore. The carrier layer 32 closer lying further layer 34 may also be formed of a polymeric material in which additionally pigment dyes are included. For example, these pigment dyes may be white.

On the side facing away from the support layer 32 side of the outer surface 10 are further layers or layers, starting from this with the reference numerals 35 to 39 are shown. The layer 35 is made of a polyamide, the layer 36 of an ethylvinyl alcohol, the layer 37 of a polymer, the layer 38 of a polypropylene optionally mixed with pigment dyes and finally the layer 39 in turn formed from a polymer.

FIG. 17 shows a further possible embodiment of a multi-layer or multi-layer container casing 2, the carrier layer having a greater thickness again being designated by the reference number 32. This here comprises a sulfate, which additionally comprises a chemical-thermo-mechanized pulp. In the relation N2010 / 00200 •> fi / m pnifi r> T γγ, κλ irf / fm nr «λλρι Ηιπρλ

2S

··. 16:11:04 26-01-2010 25/45 -21 -reich the outside 10 is applied to the support layer 32, a layer 40 of a sulfate. Starting from the carrier layer 32 towards the inner surface 9 of the container shell 2 further layers 41 to 43 are arranged here. Thus, the layer 41 is formed of a sulfate, the layer 42 of a biodegradable polyester and finally the layer 43 of a polylactide.

In the case of the layer structure of the container casing 2 shown in FIG. 18, the carrier layer 32 having a greater wall thickness is again formed from a fibrous material, such as a cardboard or paper. Starting from the outer surface 10, the container casing 2 here still comprises the two layers 44, 45. The outermost layer 44 is here made of a low-density polyethylene (PE-LD) and the layer 45 of a high-density polyethylene (PE -HD). Starting from the carrier layer 32 toward the inner surface 9, the two layers 46 and 47 are arranged. In this case, the layer 46 lying closer to the carrier layer 32 is likewise formed from a high-density polyethylene (PE-HD) and the further layer 47 is formed from a low-density polyethylene (PE-LD).

Finally, another possible layer structure of the container casing 2 is shown in FIG. 19, which in turn comprises the carrier layer 32 having a greater wall thickness and additional layers 48 to 52. The outer surface 10 facing layer 48 is formed from a low density polyethylene (PE-LD). The further layers starting from the carrier layer 32 toward the inner surface 9 are formed here by a polyamide layer 49, an ethylvinyl alcohol layer 50, an adhesive layer 51 and a layer 52 made of a low-density polyethylene (PE-LD).

In all the above-described layer structures of the container shell 2, an unspecified printed image can also be arranged at any position or position in order to ensure the labeling of the packaging container 1 in conjunction with the container shell. Since the nature and attachment of the not illustrated here dargesteliten Druckbil-the well known, this will not be described in detail.

FIG. 20 shows another embodiment of a subarea of the packaging container 1, which is possibly independent of itself, wherein the same reference numerals or component designations are again used for the same parts as in the preceding FIGS. 1 to 19. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding figures 1 to 19 or reference. N2010 / 00200 OR / ni!> Fi fi ft ητ r ςΒ / b «νϊβ« λτκι 1 23 ί ί! : i -22-

This is Deiai! In order to achieve a better and more jointless connection of the bottom 3, in particular its bottom edge portion 12, in the here lower and the longitudinal axis 5 facing inner region of the container shell 2 prior to molding of the bottom 3, a chamfer 53, shown in dotted lines, such as a phase or the like, is formed. This can be done for example by appropriate removal of material on the container shell 2. If already applied layer material of the container casing 2 is removed again, care must be taken to ensure a proper connection between the injection-molded material for the formation of the components and the container casing 2.

Again, there is again a reduction of the initial thickness 16 of the container shell 2 in dependence on the selected inclination of the chamfer 53. Furthermore, it is shown here that the bottom wall 11 in the axial direction distanced to the end face 19 of the container shell 2 out towards the second end portion 7 possible is.

FIG. 21 shows a further embodiment of a partial region of the packaging container, which may be independent of itself, in its bottom region, again using the same reference numerals or component designations for the same parts as in the preceding FIGS. 1 to 20. To avoid unnecessary repetition, reference is made to the detailed description in the preceding figures 1 to 20 or reference.

In this embodiment shown here, the bottom 3 projects beyond the end face 19 of the container shell 2 on the side facing away from the second end portion 7. The bottom 3 in turn includes the relatively thin bottom wall 11 and the approximately tubular bottom edge portion 12. The bottom edge portion 12 in turn connected to the Behältermantei 2. Also in this embodiment shown here, the initial thickness 16 of the container shell 2 in the connecting section 15 is again reduced by the integrally formed bottom edge portion 12.

By overlapping or under grasping the end face 19 of the container shell 2, an open end edge or face 19 is avoided in this section. This prevents the ingress or ingress of moisture. FIG. 22 shows a further embodiment of a partial region of the packaging container, which may be independent of itself, in its jacket region, where N2010 / 00200 9 '/ η i 9n ίη m riEVT ™ MP 1 ΙΤΐΛ 9 £ 25' 16:11:36 26 -01-2010 27/45 · · «* • · * * * * * III ·« «» · »# * * * * * * * * * * * * * * * · * »*

• 4 > Again, the same reference numerals or Bauieilbezeichnungen for the same parts as in the preceding Figures 1 to 21 are used. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding figures 1 to 21 or reference. Similar to that already described in FIG. 7, it is shown here that the two mutually facing end sections 20, 21 overlap circumferentially. This makes it possible that a connecting web 8 is also arranged in this overlapping region and by this the mutual fixation of the two end portions 20, 21 takes place. The previously described compression of the container casing 2 is again carried out, whereby a nearly planar surface is formed on the outer surface 10. At a compression of 50%, the overlapping end portions 20, 21 have the previously described undeformed initial thickness 16 of the container shell 2.

The Ausführungsbeispieie show possible embodiments of the packaging container 1 and, the container casing 2, it being noted at this point that the invention is not limited to the specifically illustrated embodiments thereof, but also various combinations of the individual embodiments are mutually possible and this variation possibility due to Teaching for technical action by objective invention in the skill of those working in this technical field is the expert. So are all conceivable embodiments, which are possible by combinations of individual details of the illustrated and described embodiment variant, includes the scope of protection.

For the sake of the order, it should finally be pointed out that for a better understanding of the structure of the packaging container 1, this or its constituent parts have been shown to be partly un-scaled and / or enlarged and / or reduced in size.

The problem underlying the independent inventive solutions can be taken from the description.

Above all, the individual in FIGS. 1, 2, 3, 4, 5, 6, 7; 8, 9; 10, 11, 12; 13, 14, 15; 16; 17; 18; 19 embodiments form the subject of independent solutions according to the invention. The relevant objects and solutions according to the invention are to be found in the detailed descriptions of these figures, N2010 / 00200 26/01 2010 DI 15:53 (SE / EMNN 8436] @ 027> · 16:12:32 26-01 -2010 32 / 45, * * * · * * "" t * * * * 4 m, t »l ** · '" I * * * # * * * i * t * * * * «» · · * *'

REFERENCE NUMBERS

Packaging container 41 Layer Container jacket 42 Layer Bottom 43 Layer Functional element 44 Layer Longitudinal axis 45 Layer End region 46 Layer End region 47 Layer Connection web 48 Layer Inner surface 49 Layer outer surface 50 Layer bottom wall 51 Layer bottom edge portion 52 Layer center 53 Bevel

web

connecting portion

initial thickness

Wall thickness

connecting portion

face

end

end

container collar

locking element

closure element

flange

flange

Flap opening

stacking means

bead

cover

support layer

layer

layer

layer

layer

layer

layer

layer

Layer N2010 / 00200 26/01 2010 DI 15:53 [SE / EM NR 8436] @ 032

Claims (18)

1. Packaging container (1) comprising a container casing (2) having in the direction of a longitudinal axis (5) spaced from each other first and second end portions (6, 7), a bottom (3) in the portion of the first end portion (6) is arranged, a functional element (4) in the section of the second end region (7), wherein the bottom (3) and / or the functional element (4) is formed as a further component of a processable in an injection molding material and thereby to the Container wall (2) is formed, characterized in that in a connecting portion (15; 18) between the container casing (2) and the molded component (3, 4) has a wall thickness (17) of the container shell (2) in an extent in one lower limit of 5%, in particular 15%, and an upper limit of 80%, in particular 50%, with respect to its undeformed initial thickness (16) is reduced. 2. Packaging container (1) according to claim 1, characterized in that the functional element (4) is selected from the group of seal closure, screw cap, snap closure. 3. Packaging container (1) according to claim 1 or 2, characterized in that the bottom (3) comprises a bottom wall (11) and a tubular ausgebiideten and the container shell (2) facing bottom edge portion (12) and both the bottom wall (11) as Also, the bottom edge portion (12) are formed continuously from the processable by injection molding material. 4. Packaging container (1) according to one of the preceding claims, characterized in that the bottom wall (11) starting from a center (13) at least one down to the bottom edge portion (12) extending web (14), wherein the web (14 ) has a greater thickness with respect to the remaining bottom wall (11). N2010 / 00200 9 R / O 1 9010 111 IR · RA [SF / FM NP SJSLP P? 10 9Ä 16:12:03 26-01-2010 29/45 25 * * • 4 »*« * * · * »« · «* * * • * * * * *« * * * · * * * * * * * t *••••••••••••••••••••••••••••••••••••••••••••••••••••••••• 5. Packaging container (1) according to one of the preceding claims, characterized in that the bottom wall (11) seen in Axialrichlung distanced from the first end portion (6) towards the second end portion (7) is arranged. 6. Packaging container (1) according to any one of the preceding claims, characterized in that between the bottom (3) and the functional element (4) at least one connecting web (8) is provided and the connecting web (8) continuously between the bottom (3) and the Funktionsetement (4) is formed and the connecting web (8) adjacent to the container shell (2) is integrally formed. 7. Packaging container (1) according to any one of the preceding claims, characterized in that with respect to the longitudinal axis (5) and over the circumference more of the connecting webs (8) are provided. 8. Packaging container (1) according to one of the preceding claims, characterized in that on at least one of the connecting webs (8) in the direction of the longitudinal axis (5) projecting stacking means (29) is formed. 9. Packaging container (1) according to one of the preceding claims, characterized in that the one or more connecting webs (8) on one of the longitudinal axis (5) facing the inner surface (9) of the container shell (2) are arranged. 10. Packaging container (1) according to one of the preceding claims, characterized in that the one or more connecting webs (8) on one of the longitudinal axis (5) averted outer surface (10) of the container shell (2) are arranged. 11. Packaging container (1) according to one of the preceding claims, characterized in that the one or more starting from the center (13) of the bottom wall (11) extending webs (14) in the direction of the longitudinal axis (5) with respect to the or the connecting webs ( 8) are arranged circumferentially offset. N2010 / 00200 26/01 2010 DI 15; 53 [SE / EM NO. 8436] @ 029 Μ # * * * * • ι «* * * * * *« * · »♦ * * * * * * * • v * * * '4 «1 I» »* * * mm * * • t * • M 16:12:16 26-01-2010 30/45 - 3 12. Packaging container (1) according to any one of the preceding claims, characterized in that the bottom (3), the one or more connecting webs (8) and the functional element (4) form a one-piece component. 13. Packaging container (1) according to one of the preceding claims, characterized in that the processable by injection molding material from the group of polypropylene (PP), polyamide (PA), polystyrene (PS), polycarbonate (PC) is selected. 14. Packaging container (1) according to one of the preceding claims, characterized in that the container casing (2) is formed as a planar blank prior to molding one of the components (3, 4, 8) and in its erected state each other immediately adjacent end portions (20 , 21) are aligned in a mutually opposite position and the connecting web (8) covers the two end portions (20, 21) in the direction perpendicular to their longitudinal extension. 15. Packaging container (1) according to one of the preceding claims, characterized in that the container casing (2) is formed as a planar blank prior to molding one of the components (3, 4, 8) and in its erected state each other immediately adjacent end portions (20 , 21) are interconnected. 16. Packaging container (1) according to any one of the preceding claims, characterized in that the container casing (2) at least one component selected from the group of cellulose, such as paper or cardboard; Aluminum, polymers, polyamides, ethylvinyl alcohol, ketene dimers, StyroJe, Oiefine, sulfates, alkyl acrylates, adhesives, binders, poly (ethylene terephthalate), polylactides, polyesters. 17. Packaging container (1) according to one of the preceding claims, characterized in that the container shell (2) has a multilayer layer structure, N2010 / 00200 26/01 2010 Dl 15:53 FSE / EM NR 84301 01030 2S 16:12:28 26 -61-2010 I 31'45 -4- 18. Packaging container (1) according to one of the preceding claims, characterized in that a mass fraction of the container shell (2) with respect to the total mass of the packaging container is greater than 50%. Rundpack AG by attorneys Partner Lawyer GmbH N2010 / 00200 26/01 2010 DI 15:53 [SE / EM NR 8436] @ 031