EP4029807A2 - Insert element for an internal packaging, internal packaging and packaging unit - Google Patents

Abstract

The invention relates to an insert element (1) for forming an inner packaging (2) for a packaging unit (3), comprising at least a first outer layer (4), a second outer layer (5) and a honeycomb core layer (6) arranged between them, with side edges (7) of the insert element (1), the first outer layer (4) is deformed in the direction of the opposite second outer layer (5), in particular folded or pressure-pressed or punched, in such a way that the first outer layer (4) is at least half of an overall height (H) of the honeycomb core layer (6). The invention also relates to an inner packaging (2) and a packaging unit (3).

Description

The invention relates to an insert element for forming an inner packaging for a packaging unit. Furthermore, the invention relates to an inner packaging for a packaging unit with at least one such insert element and a packaging unit with an outer packaging and such an inner packaging.

Packaging units made of cardboard and/or cardboard are known from the prior art. A second layer of cardboard, for example to reinforce an outer packaging, is used as the inner packaging. Additional insert elements are also known, such as filling materials in the form of corrugated cardboard or cushioning materials that are placed in the outer packaging. Packaging units made of plastic and/or styrofoam are known for transported goods that have to be kept cool, such as food, drinks or medicines. Furthermore, packaging units with so-called cool packs are known.

The invention is based on the object of specifying an insert element for forming an inner packaging for a packaging unit which is improved compared to the prior art and is in particular more sustainable and reusable. Furthermore, the invention is based on the object of specifying an inner packaging for a packaging unit that is improved compared to the prior art and an improved packaging unit.

The object with regard to the insert element is achieved according to the invention by the specified features of claim 1. With regard to the inner packaging, the object is achieved by the specified features of Claim 8. With regard to the packaging unit, the object is achieved according to the invention by the specified features of claims 9 and 10.

Advantageous configurations of the invention are the subject matter of the dependent claims.

The insert element according to the invention for forming an inner packaging for a packaging unit comprises at least a first outer layer, a second outer layer and a honeycomb core layer arranged between these, the first outer layer being deformed in the direction of the opposite second outer layer on the side edges of the insert element in such a way that the first outer layer has at least one Half of a total height of the honeycomb core layer covers. The first outer layer is, for example, folded, pressed, in particular pressure-pressed, or punched, in particular pressure-punched.

The covering in sections is sufficient to seal the honeycomb core layer in the area of the side edges of the insert element in a largely media-tight manner, in particular airtight, in order to avoid cold or heat losses and/or moisture damage caused by air currents. In other words: by means of the deformed outer layer, the honeycomb core layer is sealed media-tight, in particular airtight, in the area of the side edges of the insert element. The honeycomb core layer forms an insulation layer or insulating layer and a stability layer for the insert element. An insulation value of the insert element is designed, for example, in such a way that the temperature of a transport item is maintained as far as possible for up to at least 24 hours. By covering the honeycomb core layer on the side edges of the insert element, air circulation and/or air exchange, which can lead to a loss of temperature, is avoided. As a result, for example, a cold chain of frozen or deep-frozen goods to be transported, for example foodstuffs or medicines or the like, is not interrupted.

In a development, in the deformed state, an outer edge of the first outer layer runs essentially parallel to an outer edge of the second outer layer and/or to a level of the second outer layer. Sections of the honeycomb core layer are visible between the outer edge of the first outer layer and the outer edge and/or plane of the second layer. For example, the honeycomb core layer is also deformed in this area, for example pressed or stamped or, for example, compressed.

The side edges of the insert element, in particular the honeycomb core layer in the area of the side edges, are sufficiently closed by the deformation of the outer layer, so that no additional post-processing of the side edges, for example by an additional side plate and/or additional gluing of the edges of the outer layers, is necessary. For example, no additional separate panels, plies or layers are required to close the honeycomb core ply in the side edge regions. Furthermore, even side edges can be achieved in a simple manner and in a few process steps.

The advantages achieved with the invention consist in particular in the fact that only a few and uncomplicated process steps are necessary for the production of such an insert element. The insert element is provided, for example, as a blank. For example, the insert element is provided as a polygonal, e.g. quadrangular, blank. The cut part comprises a first planar outer layer, in particular a first cover layer or cover skin, a second planar outer layer, in particular a second cover layer or cover skin, and a honeycomb core layer, in particular a support core, which is arranged between the two outer layers. The honeycomb core layer is connected, for example glued, to the first outer layer and the second outer layer.

The blank can be provided or produced in a simple manner. For example, two outer layers made of paper, cardboard and/or cardboard and a honeycomb core layer made of cardboard and/or cardboard are provided as raw material. These are connected to each other and then cut into variable blanks. Waste and material losses are reduced or even avoided. This enables material savings with regard to the environmental balance and sustainability and cost savings in manufacturing. The insert element and thus the inner packaging form a sustainable alternative to conventional polystyrene packaging. It is also possible to automate the production, whereby mechanical processing of the raw materials and/or the cut parts for the production of the insert element, the entire production process and transport sequences are optimized.

The cut part or the insert element is designed as a sandwich panel with a honeycomb core. Dimensions and/or shapes of the cut part can vary depending on the use or application and the dimensions and/or shapes of an outer packaging or outer packaging.

After using the insert element as inner packaging for a packaging unit, the insert element can be reused. The insert element is formed entirely from recycled or recyclable cardboard and/or cardboard, for example. This fulfills the requirements for developing a sustainable, environmentally friendly and biodegradable cartridge.

In a development, the insert element has a compressive strength of at least 2 to 5 kg/cm ² , for example 3 to 4 kg/cm ² , in particular 3.5 kg/cm ² . The insert element can be used not only as an insulating and/or insulating inner packaging element, but also as a stabilizing inner packaging element. The inner packaging is formed, for example, by an insert element or by a plurality of insert elements and can be inserted into an outer packaging or into an outer packaging. Such inner packaging makes it possible to thermally insulate and/or insulate an accommodation space and also to provide stability, so that several packaging units with goods to be transported, such as several wine bottles with a high weight, or without goods to be transported, are arranged one above the other for transport and storage, in particular stacked, can become. This avoids the packaging unit buckling and/or being deformed or transported goods are damaged. The insert element forms, for example, a stable insert that protects against impact and is also thermally insulating.

In a further development, the honeycomb core layer is deformed at least in the area of the deformed first outer layer, in particular the side edges. In particular, the first outer layer and the honeycomb core layer are bent, pressed or stamped together. Thereby, openings of the honeycomb core sheet, which are open toward the skin sheet, are completely closed in the side edge portions.

In a development, the first outer layer and at least one associated area of the honeycomb core layer have a bevel of 45°. For example, the insert element is designed in such a way that it has a plurality of sections that can be folded relative to one another. The partial sections each have a bevel of 45° on their side edges, so that when folded relative to one another they each form a corner angle of 90°. One advantage is that the partial sections support each other in a stable manner and the respective side edges, in particular in the area of the deformed outer layer and the honeycomb core layer, are largely sealed in an airtight manner.

In a further development, the insert element has six partial sections which can be shaped, in particular folded, to form an inner packaging with a receiving space. The sections are connected to one another via a common outer layer. The insert element has in an initial state, i. H. in an expanded state, a body mesh with six connected sections. The insert element, in particular therefore a one-piece insert element, can form an inner packaging with a receiving space in the folded state. The respective section is, for example, essentially rectangular, for example, square. Another suitable form of packaging can also be produced.

In a development, the insert element has two or three sections or only one section. The subsections are each about their bevels having side edges connected to each other. In the case of two sections, three insert elements can be connected to one another via the side edges and form an inner packaging with a receiving space. With three sections, two insert elements are sufficient to form an inner packaging with a receiving space. Of course, differently designed insert elements can be combined with one another. Depending on the number of sections, the insert element has an associated body mesh. Accordingly, several insert elements can form an inner packaging in a folded and assembled state. In other words, multiple body meshes can form an inner package when folded and assembled.

For example, a first insert element has four partial sections arranged parallel to one another. The sections are arranged in a row, for example, and are connected to one another via the second outer layer. In a folded state, the first insert element forms, for example, a frame with four sides and two opposite openings. A further insert element, each with a partial section, can be used in each of the openings. The inner packaging consists of a total of three insert elements. The insert element with four partial sections can also form a T-shaped body network. For the complete formation of an inner packaging, the insert element with a T-shaped body mesh can be connected to a further insert element with two partial sections, and in particular can be assembled in the respective folded state. The further insert element comprises two partial sections arranged in parallel, which form an L-profile in the folded state.

The insert element can also have five partial sections which, when folded relative to one another, form a box which is open in one direction. An insert element with five sections can have a cross-shaped body network, with one of the sections forming an inner packaging base and four further sections projecting perpendicularly to the inner packaging base and forming inner packaging sides.

If the insert has only one section, six inserts are needed to form an inner package. Of course, several insert elements can be used in an outer packaging to form different packaging shapes. The inner packaging forms a compact container, in particular a compact receiving unit.

In a further development, the insert element comprises two sub-sections which are connected to one another via the second outer layer, each sub-section comprising a honeycomb core layer and a first outer layer. A respective connecting area of the two sections forms a hinge, by means of which the two sections are held so that they can be folded relative to one another. In particular, the second outer layer forms a hinge in the area between two side edges of the two sections. Such an insert element, comprising at least two sections, accordingly has a common, one-piece first outer layer, a common, one-piece second outer layer and a one-piece honeycomb core layer.

To form two subsections, a pre-cut part with predetermined or pre-determinable dimensions is cut in a desired area along the first outer layer, for example the pre-cut part is halved. Subsequently or at the same time, the side edges are formed. The first outer layer and, optionally, the honeycomb core layer are deformed along the cutting edge. Known stamping and/or pressure and/or pressing tools can be used here. The respective tool is attached to the first outer layer and deformed in the direction of the second outer layer, for example pressed or punched. This enables easy cutting and shaping of the insert element, in particular the side edges of the insert element. The insert element is in the form of a sandwich panel, which means that several insert elements can be arranged, in particular stacked, flat on top of one another for sale, shipping, transport and/or storage. Such an arrangement or stacking takes up little space, such as storage space. In a further development, the outer layers and the honeycomb core layer are made from the same material. For example, the outer layers and the honeycomb core layer are each formed from cardboard and/or cardboard.

In a development, the honeycomb core layer is connected to the respective outer layer by means of a biodegradable adhesive. For example, an adhesive made from plant products, such as modified starch and/or natural resin, is used. For example, the honeycomb core layer is connected to the respective outer layer by means of a glue, for example wood glue and/or white glue, in particular water-soluble glue.

The inner packaging according to the invention for a packaging unit comprises at least one insert element as described above, the insert element having a number or a plurality of partial sections which, when folded and/or assembled with respect to one another, form a thermally insulated receiving space. The insert element is designed in such a way that air circulation and/or air exchange, for example within and/or through the honeycomb core layer, is or is prevented. The insert element and/or the partial sections optionally has or have additionally a predetermined stability in relation to an acting weight. The insert element has a compressive strength of 3.5 kg/cm ² , for example. Of course, the inner packaging can also be used as an outer packaging.

“Foldable relative to one another” is understood to mean that the partial sections can be arranged essentially perpendicularly to one another along their side edges, in particular longitudinal edges, with a corner angle of approximately 90° being formed. In this case, adjacent side edges of the sections, in particular their bevels, lie on top of one another. The side edges of each section or each insert element are designed to correspond to one another, in particular to complement each other. The second outer layer of a respective insert element holds the sections together.

The bevels of two adjoining partial sections can be or are arranged relative to one another in such a way that gaps are avoided. In the folded and/or assembled state, the partial sections can be arranged or are arranged essentially perpendicularly to one another. This achieves a higher level of tightness at the corners of the inner packaging.

The packaging unit according to the invention for accommodating a number of objects, in particular transport goods, comprises an outer packaging and an inner packaging as described above, the inner packaging being insertable into the outer packaging and forming a thermally insulated accommodation space when inserted. In the inserted state, the inner packaging optionally also has a predetermined stability in relation to an acting weight.

An optional packaging unit according to the invention or a development of the packaging unit described above for accommodating a number of objects, in particular transport goods, comprises an outer packaging and an inner packaging, the inner packaging being insertable into the outer packaging and the inner packaging and the outer packaging being made of the same material. For example, the outer packaging and the inner packaging are formed from recycled and/or recyclable material, such as cardboard and/or cardboard. This meets the requirements for creating a sustainable, environmentally friendly and biodegradable packaging unit. Furthermore, the packaging unit can be reused, for example as a storage box or carton, as a shipping, transport, relocation and storage box.

In a further development of the packaging unit, the inner packaging is formed from two insert elements, each of which comprises at least a first outer layer, a second outer layer and a honeycomb core layer arranged between them, with the first outer layer being deformed towards the opposite second outer layer on the side edges of each insert element in such a way that the first outer layer covers at least half of an overall height of the honeycomb core layer.

The inner packaging can be inserted into the outer packaging in a simple manner and can be assembled or assembled together with this to form a packaging unit. At the same time, the inner packaging can be easily separated from the outer packaging. In the separate state, the outer packaging and the inner packaging, in particular their insert element(s), can be stored or shipped or disposed of in a flat state in a space-saving manner.

In a further development, the insert elements each have three sections connected to one another, with the three sections of an insert element forming a U-shaped insert element in a folded state. In other words: the insert element forms a U-profile when folded.

In a further development, the respective partial sections of an insert element are connected to one another via the second outer layer, each partial section comprising a honeycomb core layer and a first outer layer, and the side edges of each partial section having a 45° bevel.

In a further development, the partial sections can be folded and/or assembled relative to one another in such a way that adjacent side edges lie on top of one another and form a corner angle of 90°.

In a development, the honeycomb core layer is deformed at least in the area of the deformed first outer layer.

Figuren 1A und 1B

schematisch in zwei Ansichten eine Ausführungsform eines Einsatzelements zur Ausbildung einer Innenverpackung für eine Verpackungseinheit,

Figuren 2A und 2B

schematisch in zwei Ansichten eine weitere Ausführungsform eines Einsatzelements zur Ausbildung einer Innenverpackung für eine Verpackungseinheit,

Figur 3

schematisch einen vergrößerten Ausschnitt eines Teilbereichs des Einsatzelements,

Figuren 4A und 4B

schematisch ein Zuschnittteil zur Herstellung eines Einsatzelements oder mehrerer Einsatzelemente,

Figuren 5A bis 5D

schematisch eine Verpackungseinheit, umfassend eine Außenverpackung und eine Innenverpackung mit zwei Einsatzelementen,

Figuren 6A und 6B

schematisch eine Verpackungseinheit, umfassend eine Außenverpackung, eine Innenverpackung und einen Abstandshalter, und

Figuren 7A bis 7C

schematisch in Draufsichten weitere Ausführungsformen von Einsatzelementen mit unterschiedlichen Anzahlen von Teilabschnitten zur Ausbildung einer Innenverpackung.

Exemplary embodiments of the invention are explained in more detail below with reference to drawings. Show in it:

Figures 1A and 1B

schematically in two views an embodiment of an insert element for forming an inner packaging for a packaging unit,

Figures 2A and 2B

schematically in two views a further embodiment of an insert element for forming an inner packaging for a packaging unit,

figure 3

schematically an enlarged detail of a portion of the insert element,

Figures 4A and 4B

schematically a cut part for the production of an insert element or several insert elements,

Figures 5A to 5D

schematically a packaging unit, comprising an outer packaging and an inner packaging with two insert elements,

Figures 6A and 6B

schematically a packaging unit comprising an outer packaging, an inner packaging and a spacer, and

Figures 7A to 7C

Schematic plan views of further embodiments of insert elements with different numbers of sections for forming an inner packaging.

Corresponding parts are provided with the same reference symbols in all figures.

Figures 1A and 1B schematically show an embodiment of an insert element 1 for forming an inner packaging 2 for a packaging unit 3, as in FIGS Figures 5A to 5D shown. while showing Figure 1A the insert element 1 in a perspective view and Figure 1B in a side view.

The insert element 1 is a sandwich panel with a honeycomb core. In particular, the insert element 1 is a honeycomb panel made of layers of paper, cardboard and/or cardboard.

The insert element 1 comprises at least a first outer layer 4, a second outer layer 5 and a honeycomb core layer 6 arranged between these. The honeycomb core layer 6 has, for example, a honeycomb structure, in particular a honeycomb structure. The outer layers 4, 5 are in their initial state Z1, for example a still unprocessed state, such as in Figure 4A shown, flat sheets of cardboard and/or cardboard.

The honeycomb core layer 6 has, for example, a plurality of honeycomb walls 6.1, which are connected to one another in such a way that a plurality of honeycomb openings 6.2 are formed between them, as shown in FIG figure 3 to see. The honeycomb core layer 6 is arranged between the two outer layers 4 and 5 in such a way that the honeycomb walls 6.1 and the honeycomb openings 6.2 run essentially perpendicular to them. To produce the honeycomb core layer 6, ie to connect the honeycomb walls 6.1 to one another, a biodegradable adhesive, for example glue, is also used, for example, to ensure an environmental and/or sustainability balance.

On all side edges 7 of the insert element 1, i. H. on all four side edges 7 in the embodiment shown, the first outer layer 4 is deformed in the direction of the opposite second outer layer 5 in such a way that the first outer layer 4 covers at least half of a total height H of the honeycomb core layer 6 . In this case, the first outer layer 4 is, for example, folded over in the direction of the second outer layer 5, bent, pressed, in particular pressure-pressed, or stamped, in particular pressure-stamped or stamped.

In the deformed, in particular mechanically deformed, state, an outer edge 4.1 of the first outer layer 4 runs essentially parallel to an outer edge 5.1 of the second outer layer 5 and to a plane of the second outer layer 5 in a side view. Between the outer edge 4.1 of the first outer layer 4 and the Outer edge 5.1 and/or level of the second outer layer 5, the honeycomb core layer 6, in particular a honeycomb wall 6.1, is visible in sections. For example, the honeycomb core layer 6 is also deformed in the areas of the side edges 7, for example pressed, punched or, for example, compressed. In particular, the honeycomb core layer 6 is compressed in these areas, in particular plastically deformed.

The side edges 7 of the insert element 1, in particular the honeycomb core layer 6 in the area of the side edges 7, are sealed sufficiently airtight by means of the deformation of the outer layer 4 and additionally the honeycomb core layer 6. As a result, no additional post-processing of the side edges 7, for example by an additional side panel and/or additional gluing of the edges of the outer layers 4, 5, is necessary. The outer edges 4.1 of the first outer layer 4 are each deformed at an angle of 45° in the direction of the honeycomb core layer 6 and the second outer layer 5, in particular pressed or stamped. In addition, the honeycomb walls 6.1 are also deformed below the outer edges 4.1, for example plastically deformed, in particular compressed in the direction of the second outer layer 5. The side edges 7 each have a bevel F of 45°.

In an arrangement of several insert elements 1, each of which has side edges 7 with bevels F of 45°, the insert elements 1 can each be arranged perpendicular to one another, so that in an assembled and/or folded state Z2, as in Figures 5C and 5D shown schematically, in each case a corner angle Ew of 90° can be formed or is formed. This increases stability in relation to an acting weight G, for example when a plurality of packaging units 3 are stacked one on top of the other. For example, an inner packaging 2 or packaging unit 3 according to the invention can have a compressive strength of at least 3.5 kg/cm ² . Acting weight forces G are indicated, for example, with arrows in Figure 5D marked. In addition, the stability is increased in relation to impacts and/or vibrations that can act on the packaging unit 3 with the inner packaging 2 during shipping and/or transport, for example. Figures 2A and 2B show another embodiment of the insert element 1, wherein Figure 2A the insert element 1 in a perspective view and Figure 2B show the insert element 1 in a side view.

In the illustrated embodiment, the insert element 1 comprises three partial sections 1.1 which can be folded towards one another. The partial sections 1.1 each have a bevel F of 45° on their side edges 7, so that in the folded state Z2 they each form a corner angle Ew of 90°. The side edges 7 are in airtight contact with one another. In particular, in this state Z2, two adjacent deformed outer edges 4.1 and two adjacent honeycomb walls 6.1 that are deformed at the same time are arranged adjacent to one another.

The sections 1.1 are connected to one another via the second outer layer 5. Each section 1.1 comprises a honeycomb core layer 6 and a first outer layer 4. In an initial state Z1, the insert element 1 comprises a continuous, flat first outer layer 4, a continuous, flat second outer layer 5 and a continuous honeycomb core layer 6. By means of a conventional pressing, stamping, for example -, or stamping process, the subsections 1.1 can be produced. In the initial state Z1, for example a spread out and stackable state, the insert element 1 has an I-shaped body mesh K1. In the folded and assembled state Z2, the insert elements 1 form an inner packaging 2 with an inner packaging base 2.2, four inner packaging walls 2.3 and an inner packaging lid 2.4, as in Figures 5B and 5C marked in more detail.

A respective connecting region V of two sections 1.1 forms a hinge, by which the two sections 1.1 are held in a manner that they can be folded in relation to one another. The connection area V is therefore a folding, folding and/or buckling area. In particular, the second outer layer 5 forms a hinge in the area between two side edges 7 of two sections 1.1. The three sections 1.1 can be folded relative to one another in such a way that they form a U-shaped insert element 1 in a folded state Z2. There are two insert elements 1, each with three sections 1.1 Can be assembled or assembled via its U-shape in such a way that a closed inner packaging 2 can be formed or is formed.

figure 3 shows schematically an enlarged section of a partial area of the insert element 1, the first outer layer 4 and a corner area of the honeycomb core layer 6 being shown partially transparent. The enlarged section shows a corner area of the insert element 1 or a section 1.1 of the insert element 1. In the side edge areas, the first outer layer 4 and honeycomb walls 6.1 and thus also the honeycomb openings 6.2 of the honeycomb core layer 6 are deformed. The diameter of the honeycomb openings 6.2 can vary depending on the desired strength and stability of the honeycomb. For example, the honeycomb openings 6.2 each have a diameter of 30 mm. An overall height H of the honeycomb core layer 6 can vary, for example, depending on a desired thickness and stability of the inner packaging. For example, the honeycomb core layer 6 has an overall height H of 30 mm to 50 mm.

Figures 4A and 4B show a cut part 8 in an initial state Z1 for the production of an insert element 1 with, for example, three sections 1.1 or several individual insert elements 1, with the cut part 8 shown being able to produce, for example, three insert elements 1 each with only one section 1.1. show it Figure 4A a top view and Figure 4B a side view.

The cut part 8 has a common, one-piece first outer layer 4 , a common, one-piece second outer layer 5 and a one-piece honeycomb core layer 6 . The honeycomb core layer 6 is connected to the first outer layer 4 and the second outer layer 5, for example glued. A biodegradable adhesive is used as the adhesive to ensure an environmental and/or sustainability balance.

To form a plurality of individual insert elements 1, the blank 8 shown is cut into three parts, for example along the lines L, and optionally deformed along the lines L at the same time or subsequently. In addition, all remaining side edges 7 are deformed.

To form an insert element 1 with three interconnected partial sections 1.1, the blank 8 is deformed along the two lines L shown without cutting through the second outer layer 5.

Known cutting and/or punching and/or pressing tools can be used. The respective tool 9 is attached to the first outer layer 4 and deformed in the direction of the second outer layer 5, for example pressed, punched or stamped. This enables simple cutting and shaping of the insert element 1, in particular the side edges 7 of the insert element 1. In particular, the outer edges 4.1 of the first outer layer 4 are deformed in each section 1.1 at an angle of 45° in the direction of the honeycomb core layer 6 and the second outer layer 5, in particular pressed or stamped until the outer edge 4.1 of the first outer layer 4 covers at least half of the total height H of the honeycomb core layer 6.

Figures 5A to 5D show schematically a packaging unit 3, comprising an outer packaging 10 and an inner packaging 2 with two insert elements 1. In particular, show the Figures 5A to 5D a construction process for providing the packaging unit 3. The outer packaging 10 is made of cardboard and/or cardboard. The side edges 7 of the sections 1.1 mutually support one another by means of their chamfers F in such a way that the stability of the inner packaging 2 is increased in relation to acting weight forces G and/or the application of forces.

Figure 5A shows the use of a first insert element 1 in the outer packaging 10. The outer packaging 10 consists of, for example, four side walls 10.1, a base 10.2 and a number of cover elements 10.3. The outer packaging 10 includes a receiving space 10.4, in which the Insert elements 1 to form the inner packaging 2 can be arranged. The first insert element 1 is inserted essentially in a U-shape into the receiving space 10.4. In other words: the insert element 1 has a U-profile in relation to one another when the partial sections 1.1 are in the folded state.

Figure 5B shows the outer packaging 10 with an inserted first insert element 1. A first section 1.1 is placed on the base 10.2, with an adjacent second section 1.1 resting against one of the side walls 10.1. A third subsection 1.1 adjacent to the second subsection 1.1 can in a final state Z3, as in Figure 5D shown, are used as the lid of the inner packaging 2. Before that, the third section 1.1 can be folded outwards around the connection area V and supported on an edge of the outer packaging 10.

Figure 5C shows the use of the second insert element 1 to form a receiving space 2.1 of the inner packaging 2. The second insert element 1 is inserted in a U-shape into the receiving space 10.4 of the outer packaging 10. If the second insert element 1 is arranged in the receiving space 10.4, the partial sections 1.1 of the second insert element 1 lie against the remaining side walls 10.1 of the outer packaging 10 and form a receiving space 2.1 together with the partial sections 1.1 of the first insert element 1 that have already been used. After arranging an item to be transported, the third section 1.1 of the first insert element 1 can be folded in the direction of the receiving space 2.1. The cover elements 10.3 of the outer packaging 10 can then be folded in the direction of the receiving space 10.4 of the outer packaging 10 and closed.

In the mutually folded state Z2 of the sections 1.1 or the assembled state Z2 of the insert elements 1, such as in Figure 5D shown, the sections 1.1 or the insert elements 1 form a thermally insulated receiving space 2.1, the inner packaging 2 being given a predetermined stability by means of the insert elements 1 Reference to an acting weight force G has. The insert elements 1 are designed in such a way that air circulation and/or air exchange, for example within and/or through the respective honeycomb core layer 6, is or is prevented. The respective insert element 1 has, for example, a compressive strength of at least 3.5 kg/cm ² .

The bevels F of two adjoining sections 1.1 are arranged relative to one another in such a way that gaps are avoided. In the folded and/or assembled state Z2, the partial sections 1.1 are arranged essentially perpendicular to one another. This achieves greater tightness at the corners of the inner packaging 2 and greater stability.

The packaging unit 3 is, for example, a 1-material packaging unit. In particular, the inner package 2 and the outer package 10 are formed from the same material. For example, the outer package 10 and the inner package 2 are formed from recycled and/or recyclable material, such as cardboard and/or cardboard. This meets the requirements for forming a sustainable, environmentally friendly and biodegradable packaging unit 3. Furthermore, the packaging unit 3 can be reused, for example as a storage box or carton, as a shipping, transport, moving and storage box.

Figures 6A and 6B show schematically a packaging unit 3, comprising an outer packaging 10, an inner packaging 2 and a spacer 11. It shows Figure 6A a use of the spacer 11 in the receiving space 2.1 of the inner packaging 2 and Figure 6B shows the packaging unit 3 with the spacer 11 inserted. The spacer 11 is provided, for example, to form a further receiving space 12 for receiving objects. The spacer 11 can also be used as a stabilizing element and/or separating element. For example, two areas of the receiving space 2.1 of the inner packaging 2 can be separated from one another by means of the spacer 11. The spacer 11 is designed as a simple cardboard and / or cardboard layer with four foldable side walls 11.1 and a floor connecting them 11.2. In the inserted state, in particular the end state Z3, the side walls 11.1 are arranged perpendicularly to the base 11.2 and rest on the partial sections 1.1 of the insert elements 1. The base 11.2 forms a separating base and/or receiving base.

Figures 7A to 7C show schematic plan views of further embodiments of insert elements 1 with different numbers of sections 1.1 for forming an inner packaging 2. In the folded and assembled state Z2, the insert elements 1 form an inner packaging 2 with an inner packaging base 2.2, four inner packaging walls 2.3 and an inner packaging lid 2.4. Depending on how the insert elements 1 are inserted into the corresponding outer packaging 10, another section 1.1 can form, for example, an inner packaging base 2.2, an inner packaging wall 2.3 or an inner packaging lid 2.4.

Figure 7A shows a formable inner packaging 2 with two insert elements 1, each insert element 1 having three sections 1.1. In the initial state Z1, the insert elements 1 have an L-shaped body mesh K2. The partial sections 1.1 are arranged relative to one another in such a way that in the initial state Z1, ie in an unfolded state, they together form an L-shape. In the folded state Z2, the insert elements 1 thus each form a corner area of the inner packaging 2.

Figure 7B shows a formable inner packaging 2 with two insert elements 1, wherein a first insert element 1 has four sections 1.1 and a second insert element 1 has two sections 1.1. In the initial state Z1, the first insert element 1 has a T-shaped body mesh K3. In the initial state Z1, the second insert element 1 has an I-shaped body mesh K4. Depending on how the insert elements 1 are used in the corresponding outer packaging 10, a different section 1.1 can be used, for example Form inner packaging base 2.2, an inner packaging wall 2.3 or an inner packaging lid 2.4.

Figure 7C shows a formable inner packaging 2 with two insert elements 1, wherein a first insert element 1 has five sections 1.1 and a second insert element 1 has one section 1.1. In the initial state Z1, the first insert element 1 has a cross-shaped body network K3. The second insert element 1 is a single plate. In the folded state Z2, the first insert element 1 forms, for example, an inner packaging base 2.2 and four inner packaging walls 2.3. The second insert element 1 designed as a single part forms, for example, an inner packaging lid 2.4.

Alternatively, a single insert element 1 can be made with a conventional unfolded body mesh of a cuboid to form an inner package 2 and used. The insert element 1 has, for example, six sections 1.1 connected to one another.

REFERENCE LIST

1

insert element

1.1

section

2

inner packaging

2.1

recording room

2.2

inner packaging bottom

2.3

inner packaging wall

2.4

inner packaging lid

3

Packaging Unit

4, 5

outer layer

4.1, 5.1

outer edge

6

honeycomb core layer

6.1

honeycomb wall

6.2

honeycomb opening

7

side edge

8th

blank part

9

Tool

10

outer packaging

10.1

Side wall

10.2

floor

10.3

cover element

10.4

recording room

11

spacers

11.1

Side wall

11.2

floor

12

recording room

Eh

corner bracket

f

chamfer

G

weight force

H

overall height

K1 to Jun

body mesh

L

line

V

connection area

Z1

initial state

Z2

State, in particular folded and/or assembled state

Z3

final state

Claims (15)

Insert element (1) for forming an inner packaging (2) for a packaging unit (3), comprising at least a first outer layer (4), a second outer layer (5) and a honeycomb core layer (6) arranged between them, with side edges (7) of the insert element (1), the first outer layer (4) is deformed in the direction of the opposite second outer layer (5), in particular folded or pressure-pressed or stamped, in such a way that the first outer layer (4) is at least half of the total height (H) of the honeycomb core layer (6 ) covers. Insert element (1) according to claim 1, wherein the honeycomb core layer (6) is also deformed at least in the area of the deformed first outer layer (4). Insert element (1) according to claim 1 or 2, wherein the first outer layer (4) and at least one associated area of the honeycomb core layer (6) have a bevel (F) of 45°. Insert element (1) according to one of the preceding claims, comprising at least two sections (1.1) which are connected to one another via the second outer layer (5), each section (1.1) comprising a honeycomb core layer (6) and a first outer layer (4). Insert element (1) according to Claim 4, in which the sections (1.1) can be folded towards one another in such a way that adjacent side edges (7) lie on top of one another and form a corner angle (Ew) of 90°. Insert element (1) according to one of the preceding claims, wherein the outer layers (4, 5) and the honeycomb core layer (6) are formed from the same material. Insert element (1) according to one of the preceding claims, wherein the honeycomb core layer (6) is connected to the respective outer layer (4, 5) by means of a biodegradable adhesive. Inner packaging (2) for a packaging unit (3) with at least one insert element (1) according to one of the preceding claims 1 to 7, wherein the insert element (1) has a number or a plurality of partial sections (1.1) which are folded in relation to one another and/or or assembled state (Z2) form a thermally insulated receiving space (2.1) and/or have a predetermined stability in relation to an acting weight force (G). Packaging unit (3) for receiving a number of objects, comprising an outer packaging (10) and an inner packaging (2) according to claim 8, wherein the inner packaging (2) can be inserted into the outer packaging (10) and in the inserted state (Z3) has a thermal forms an isolated receiving space (2.1) and/or has a predetermined stability in relation to an acting weight (G). Packaging unit (3) for accommodating a number of objects, comprising an outer packaging (10) and an inner packaging (2) according to claim 8, wherein the inner packaging (2) can be inserted into the outer packaging (10) and wherein the inner packaging (2) and the Outer packaging (10) are formed from the same material. Packaging unit (3) according to Claim 9 or 10, in which the inner packaging (2) is formed from at least two insert elements (1), each of which has at least a first outer layer (4), a second outer layer (5) and a honeycomb core layer (6 ) include, wherein on side edges (7) of each insert element (1) the first outer layer (4) in the direction of the opposite second outer layer (5) is deformed in such a way that the first outer layer (4) covers at least half of an overall height (H) of the honeycomb core layer (6). Packaging unit (3) according to Claim 11, in which the insert elements (1) each have three sections (1.1) connected to one another, the three sections (1.1) of an insert element (1) forming a U-shaped insert element ( 1) train. Packaging unit (3) according to claim 12, wherein the respective partial sections (1.1) of an insert element (1) are connected to one another via the second outer layer (5), each partial section (1.1) comprising a honeycomb core layer (6) and a first outer layer (4). and wherein the side edges (7) of each section (1.1) have a bevel (F) of 45°. Packaging unit (3) according to one of claims 11 to 13, wherein the partial sections (1.1) can be folded and/or assembled relative to one another in such a way that adjacent side edges (7) lie on top of one another and form a corner angle (Ew) of 90°. Packaging unit (3) according to one of Claims 11 to 14, the honeycomb core layer (6) being deformed at the same time, at least in the region of the deformed first outer layer (4).

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