WO1992007767A1 - Container system, in particular a container system for transport and/or packing - Google Patents

Abstract

The invention concerns a modular container system made up of matching modules which are identical as regards certain dimensions so that they can be combined to give different containers.

Description

 Container system, in particular transport and / or packaging container system

The invention relates to a universally applicable container system, in particular a transport and / or packaging container system.

The usual cardboard packaging is still used for the transport and other storage of goods today, but they are disadvantageous in several respects. On the one hand, there is no orderly return of the cardboard packaging to the manufacturer, but rather the cardboard packaging is passed on as waste and, if necessary, is returned to a recycling process as waste paper. Cardboard packaging is not suitable as reusable packaging. In addition, such packaging systems are not stable, especially when there is moisture, there is a risk of softening of the carton packs, so that the goods fall out during transport or storage.

REPLACEMENT LEAF The object of the invention is to develop a container system which can be used in a variety of ways, can be handled easily, is of robust construction, is suitable as reusable packaging and is also easy to produce.

According to the invention, a container system is realized which is made up of modular basic elements. These basic elements can be combined to form containers. There is a wide variety of possible combinations based on just a few basic elements. The basic elements are preferably made of plastic, so that a stable container-like container system results. One advantage of the containers or containers or basic elements described in detail in the description is that, for example in the case of a container composed of two basic elements, the upper basic element can be removed and then the lower basic element, optionally with an intermediate frame arranged above it, as a display. or display element can be used on a shelf or the like. Opening the containers is also very simple, in that only the uppermost basic element is removed or is pulled off to the side. The basic elements are preferably staggered in height, so that, for example, when using only four modular basic elements of different heights, there is a very large number of possible variations for a container.

Suitable fastening mechanisms, such as tensioning straps, cords and the like, but in particular also snap links, tensioning links, notches, tongue and groove connections, allow the container to be fixed, which can be unlocked for the removal of the goods. In an advantageous embodiment, these fastening means can also be a direct component of one of the modular components, for example form the frame element, in that joints are provided in the corners of the frame element and a buckle-like tensioning and

REPLACEMENT LEAF Closing element is provided, which forms a frame element wall.

The basic elements are characterized in particular by a bottom and circumferential side walls of different heights, it also being possible expediently to add frame elements which have no bottom and thus serve to increase the container height.

Overall, these measures result in a number of advantages, for example the basic elements can be stacked one inside the other, in particular due to the slightly conical design of the side walls, so that little space is required when they are returned. Display packs are used so that the container with the goods can be transferred directly to a shelf. Further advantages are the stable design and the weather resistance and the suitability of these systems for repeated use after returning the system to the manufacturer. Furthermore, the system is characterized by a large variety of possible combinations due to the modular structure of basic elements. In addition, these basic elements result in a closed package or container, so that the goods are protected from the outside. The packaging is also suitable for receiving advertising information and the like. Finally, handles can be created in the side walls by recesses or recesses. The plan of the containers is also tailored to the dimensions of the pallets available, so that a large number of containers can be accommodated on a pallet without an overhang. The basic elements with a low height can be used as a tray or lid, the basic elements with a greater height than troughs and the like. Preferred exemplary embodiments of the invention are described below with reference to the drawing. Show in it

REPLACEMENT LEAF FIGS. 1 to 6 different views and combinations of basic elements of a container system,

FIGS. 7 to 14 views of basic elements and combinations of these elements of a further embodiment of a container system,

FIGS. 15 to 20 views of basic elements and combinations of these elements of a further embodiment of a container system, FIGS. 21 to 24 views of basic elements and combinations of these elements of a further container system of the invention and FIGS. 25 to 30 further details .

FIG. 1 shows an overview of an embodiment of a container system of a preferred embodiment with a total of four basic elements of similar construction, but of different heights. The basic elements 1 to 4 which can be combined with one another as desired are shown in FIG. 1, on the left in the external view and on the right in the sectional view. The base element 1 is formed by a flat container with a rectangular outline and has four peripheral side surfaces and a container base. The elements 2 to 4 differ from the basic element 1 in the height of the side walls. The side walls are inclined slightly conically outwards from the bottom, so that the empty base elements can be stacked one inside the other to save space.

In FIG. 1 below, various combinations of basic elements for forming containers of different sizes are shown. It follows that a wide variety of possible combinations can be realized with the four basic elements 1 to 4.

If necessary, the basic elements assembled to form a container can be arrested, for example by slightly overlapping the containers or by

REPLACEMENT LEAF tongue and groove connections are realized on the end faces. The superimposed basic elements can, however, also be fixed by means of tensioning straps, cords, packaging films and the like. The advantage of the container system is not only the variety of possible variations, but also the fact that the transport container can also be used as a display container, for example by placing the container on a shelf and removing the upper basic element. The basic elements are designed in such a way that they can all be combined with one another.

Figure 2 shows the basic elements 1 to 4 in a larger representation. Figure 3 shows three examples of combinations, on the left a flat container by placing two basic elements 1 on top of one another, a medium-sized container by placing basic elements 2 and 1 on top of one another and a somewhat higher container by putting two on top of one another Basic elements 2 is formed. Figure 4 shows a container on the right, which is composed of two basic elements 4. The container arranged next to it is formed from a basic element 3 and a basic element 2 placed on it in reverse order. The container located next to it results from the fact that a basic element 1 is used instead of the basic element 2 placed on top.

FIG. 5 shows a container formed from a basic element 3 and 2, which is stacked on further containers which are composed of basic elements. In this case, cutouts 5 can be provided in the side walls of the basic elements to form handles. FIG. 5 shows at the top left that a variety of different containers, each constructed from the basic elements 1 to 4, can be stacked on a pallet. In FIG. 5 at the top right one can see that containers can be transported in a very space-saving manner when empty, because due to the conical design of the basic elements, they can be stacked one inside the other. FIG. 5 shows on the left an example of a locking of the two assembled basic elements, shown larger in FIG. 6. A wide variety of fastening mechanisms for fixing the two basic elements to one another can be implemented here. FIG. 6 shows a latch which acts on a tendon or a hook member, so that when the latch or swivel lever 6 is actuated, the fixing of the two basic elements can be released and the upper basic element can thus be lifted off the lower basic element.

The further exemplary embodiment of a container system described with reference to FIGS. 7 to 14 is described with reference to three basic elements 7 to 9. FIG. 7 shows an overall overview of the container system, the basic elements 7 to 9 being highlighted in the middle. The base element 7 is a flat, bowl-shaped base element consisting of a base with four circumferential side walls, the base showing a rectangular outline. The side walls are again slightly tapered outwards. The basic element 7 can serve as a cover. The basic element 8 is constructed similarly to the basic element 7, but the side walls are higher. Shown in the exemplary embodiment, the base element 7 has side walls with a height of 37.5 mm, whereas the height of the side walls of the base element 8 is twice as large. Finally, 9 denotes a frame element which is constructed analogously to the base element 8, but has no bottom. In the exemplary embodiment shown, this frame element has side walls with a height equal to the height of the side walls of the base element 8. Of course, other heights can be realized if necessary, for example a frame element that is twice as high as the frame element 9. As a result of the conical design of the basic elements, they can again be stacked very cheaply into one another when empty, as can be seen in FIG results on the left. On the far left in FIG. 7, various combination examples are shown, each composed of the basic elements 7 to 9. Depending on how

REPLACEMENT LEAF many frame elements 9 are interposed, containers of any size can be realized. FIG. 7 shows a container on the right in a disassembled representation, which consists of a lower base element 7, four frame elements 9 and a cover element, either element 7 or 8, placed thereon. This container can be realized by removing or adding the frame element. In the exemplary embodiment shown, the basic elements are fastened to a container by means of tensioning straps 10 wound around the basic elements. As can be seen in particular from FIG. 10, corresponding recesses 11 are formed in the side walls of the basic elements. As a result, the tensioning straps can be received flush and do not protrude beyond the outer surface of the container formed from the basic elements. Instead of such straps, cords and other fastening elements can also be used. The tensioning straps have the advantage that the basic elements cannot be used as containers by any third party because they generally do not have any packaging devices with tensioning straps available. A so-called second-use use is thereby excluded, which ensures the return of the containers. Finally, FIG. 7 shows that the basic dimensions of a basic element are preferably 200 x 150 mm, which allows the containers to be accommodated well on the euro pallets, and offset stacking is also possible. Of course, the basic elements can also be designed with other dimensions, but here again an integer multiple of the dimensions of 200 x 150 mm is preferably used.

FIG. 8 shows a larger representation of the basic elements 7, 8 and 9. FIG. 9 shows a container in a disassembled representation, which is formed from a basic element 7 as a base part, two frame elements 9 as frame walls and a basic element 7 as a lid , whereby the basic elements are held by two straps. To fix the basic elements to each other are in the mutually facing edge sides

REPLACEMENT LEAF the basic elements tongue and groove designs are provided. These tongue and groove designs are generally designated 12. These tongue and groove designs are arranged in mirror image on the opposite sides, so that the basic elements can be used as desired. As can be seen in particular from FIG. 9, the basic elements at their uppermost edge section at 13 are again slightly conically inclined outwards, this cone angle being somewhat larger than the cone angle of the lower section 14 of the basic elements. FIG. 11 shows a variety of containers, each made up of the basic elements 7 to 9 in a stacked position, as can be accommodated on a pallet. In the figure on the left, the basic elements are shown stacked one inside the other. As can be seen from a comparison of the left and the right representation in FIG. 11, there is a substantial saving of space when stacked one inside the other, the stacked basic elements requiring 70% less space than the assembled containers in the right representation. The tongue and groove principle can be seen from FIG. FIG. 13 shows the different arrangement of the tongue and groove configurations on opposite side walls, with a tongue configuration 12a on one side wall being associated with the corresponding groove configuration 12b on the opposite side wall. In the embodiment according to FIG. 14, the basic elements of each container are held together by attachable clamping elements 15. Other suitable fastening mechanisms can also be implemented.

The design of a container system according to FIGS. 15 to 20 is characterized by a uniform basic element 16, i.e. a basic element made of all-round side walls and a floor, which, however, is staggered in height, as can be seen from FIG. 15 at the top right. As a result, a wide variety of packaging or transport containers can again be realized via the basic elements 16 with different heights, as can be seen from FIG. 15 at the top left. This

EBSATZBI ΓΓ Base element 16, as can best be seen in FIG. 17, has a lower wall section 17 and an upper wall section 18, which is set slightly outwards relative to the lower wall section 17, the two wall sections 17 and 18 being connected to one another via a shoulder 19. It goes without saying that, as in the previous case, these basic elements are expediently formed in one piece from plastic. As a result of this design, the empty basic elements can be stacked well into one another, which results in a space saving of 50% compared to the container, composed of the same basic elements. The box principle also results from FIG. 15 at the bottom left. In the case of the container system, the containers are formed by placing two basic elements of the same or different heights with the ends open at the top. Here too, tongue and groove configurations are possible in the mutually facing edge sides for fixing the assembled basic elements. FIG. 19, however, shows a clip which, after the basic elements have been assembled to form a container, can be snapped from the outside via superimposed edge configurations of the basic elements, so that the basic elements are locked together to form a container. By pulling off the snap elements 20, the containers are unlocked so that, for example, the lid can be removed and the lower basic element can be placed on a shelf as a display pack. These snap connections are expediently provided on all four side walls of the basic elements, but if necessary the locking can also only take place on opposite side walls. This results, for example, quite clearly from FIG. 16. If necessary, further basic elements can be used, for example by using a basic element 16 without a base, which results in a broadening of the possible variations of the container system.

The container system according to FIG. 21 and the following has certain similarities to the container system according to FIGS. 15 to 20

ATZBLATT However, in the case of the basic elements, which are otherwise of identical design, only half of the upper edge section 22 set outward is formed in the region of the longitudinal side walls and closes off by an obliquely running edge section 24. This container system has the advantage that after the upper half has been lifted off, the lower half results in a corresponding display pack or display container in which the rear region is a support for the goods accommodated in the pack. A slightly conical design of the side walls also enables the stacking of the individual basic elements 21. Different height configurations of the basic elements 21 make it possible to form different combinations of containers, as are shown, for example, with reference to FIG. 21. FIGS. 23 and 24 show a fastening mechanism, it being possible for a button 26 to be fitted with a fit from the longitudinal side of the basic elements via a pin 25 formed in the basic elements. The pin 25 is composed of two pin halves, with one pin half being assigned to a base element. The button for opening the container is pulled out via a tab 26a which can be pressed into a recess after the button has been pushed onto the pin so that this tab does not protrude outwards when the container is in use.

The individual basic elements are expediently each produced in one piece, a foldable design of the frame elements also being suitable if required, the side walls of the frame elements then being connected to one another via a film hinge or an articulated hinge. This would offer the advantage that the frame elements could then be transported folded when empty. It is also possible to divide the frame elements into individual frame walls, which can be plugged together via tongue and groove connections.

REPLACEMENT LEAF FIG. 25 shows an embodiment similar to the container shown in FIG. 23, but here, as indicated by the arrow, the upper container part 27 can be pulled off laterally relative to the lower container part 28, ie towards the front. This offers the advantage that when the container is put together, composed of the elements 27 and 28 on a shelf, the container can easily be opened by pulling off the upper container element 27, so that the receptacles contained in the lower container element 28 are then received on the sales shelf Goods are placed as a sales unit. For this purpose, it is expedient to provide a downwardly projecting projection 29 in the manner of a strip on the upper container element 27, which can be formed in one piece with the end wall 30 and serves as a stop element on the lower container element 28. In the exemplary embodiment shown, a strip 31 drawn upwards is likewise provided on the rear wall with respect to the lower container element 28 in order to give the two container elements assembled better support. 32 with a closure of the container is identified, which can be designed in a particularly simple manner functionally in the manner of a crown cap closure and is provided on both sides of the container. This is a very easy to manufacture and easy to use closure element, which also ensures originality, because when the container is opened for the first time there is a corresponding deformation on the crown cap, so that manipulation in the sense of opening the container is noticed immediately. Of course, this means that the crown cap overlaps a ring formed by the two container elements 27 and 28, on which the crown cap is anchored for the purpose of fastening the two elements 27 and 28.

FIG. 26 shows the disassemblability of the container, which is very important for the invention, a frame element 33 which is open at the top and bottom being pluggable with a base in the manner of a tray 34, the base 34 being in the manner of a drawer in which according to the arrow the frame element element 33 can be inserted. In the simplest embodiment, the base 34 is trough-shaped, ie flanges with a low wall height are formed on the two opposite edges of the base plate, and in a further development, as shown in dashed lines, the rear wall can also be designed in the manner of a flange wall.

FIGS. 27, 29 and 30 show an embodiment in which the frame element 9 is in principle designed analogously to the embodiment in FIGS. 7 to 14, that is to say open at the top and bottom. The peculiarity is that this frame element 9 according to FIG. 27 is simultaneously designed as a fastening means, in that joints are formed at 35 in the corners and the frame element 9 is divided on its narrow wall 36, so that the frame element can be folded up. Because of the tensioning and closing mechanism 37, the frame element 9 can be tensioned and closed, so that it also represents the fastening means. As. Clamping and closing means use a mechanism similar to the clamping and closing mechanism of an oven mold, i.e. a collapsible tensioning tab that keeps the frame element 9 tensioned and closed in the folded dead position. According to FIG. 27, the frame element 9 is seated on a base element 8. FIGS. 29 and 30 show details of this embodiment.

FIG. 28 shows a table, the longitudinal dimensions of a container being indicated on the outside in the column “outside” and the length dimensions of the same container being indicated on the inside under the column “interior”. The "Wall" column contains the thickness dimensions of the walls. The stated dimensions, which serve only as an example for the intended grading of the dimensions, enable the containers with different sizes to be stacked very well. An essential feature is that the wall thickness of the wall of the next larger container is made thicker in accordance with the ratio of the length of the side walls. With the outer dimension of 600 mm, for example for the larger container and an outer dimension of

REPLACEMENT LEAF The wall thickness of the smaller container 10 is 300 mm for a smaller container, whereas the wall thickness of the larger container is 20 mm. This takes into account the fact that with the dimensions mentioned, for example, two smaller containers can be placed on a larger container. Since the two smaller containers then bring two additional walls, if the wall of the larger container, which takes up the measure of the thickness of the two additional walls of the smaller container, is thickened, a flush closure of the containers is ensured when stacked on top of one another . If the outer dimensions of the smaller container are 400 mm, the wall thickness of the smaller container is 15 mm. The corresponding gradations are shown in the table in FIG. 28 for various adapted external dimensions of a modular container system.

FIG. 31 shows a further embodiment of a foldable frame element 9, the articulated hinges shown in FIG. 32 being provided at two diagonally opposite corners and the other two corners being formed by film-like hinges 39. As a result, the frame element 9 can be folded up. The hinge 38 according to FIG. 32 is distinguished by a long service life because several hinge eyes are realized.

In the embodiment shown only schematically in FIG. 33, the joints in the corner regions of a frame element 9 are indicated by 40 and mechanical closure means 41 by 41, so that at 41 the frame element 9 can be divided and thus two frame element halves 9a and 9b arise, as shown in Figure 33 below. Because of the joint 40, the halves 9a and 9b can be folded together again.

REPLACEMENT LEAF

Claims

 DEMAND COMPLEXES:

1) Container system, constructed from modular basic elements which can be combined with one another to form a packaging or transport container.

The basic elements are adapted to each other. Four basic elements (1 to 4) are preferably used which are identical in their basic dimensions, but differ in height. The difference in the heights is expediently graded or staggered; in particular, one base element has a height of 37.5 mm, the next larger one has a height twice as high, namely 75 mm, the third element has a height of 150 mm, that is double the height of the lower basic element, the fourth basic element having a height which corresponds to the total height of the basic element (2) and the basic element (3). If necessary, other graduations, especially other heights, are also suitable.

The basic elements themselves consist of a bottom and side walls, the side walls being closed all around. Appropriately, however, recesses or cutouts can be arranged in the side walls to form handles. The side walls are expediently inclined conically outwards and at a slight cone angle, so that the empty basic elements can be stacked one inside the other.

EBSATZBLATT The containers are formed by the composition of two basic elements, which are joined together with their open ends. The basic elements can be plugged together, wherein in particular tongue and groove connections are formed on the upper edges of each basic element and expediently on opposite side walls in a manner reversed from one another.

The locking or fastening of two basic elements to a container is possible by means of suitable fastening mechanisms, for example a pivoting lever or bolt or clamping bracket which can be actuated from the outside and which engages over, engages with, or engages with a corresponding element of the other basic element of the container is tensioned.

2) Container system in broad correspondence to claim complex 1), but preferably consisting of three basic elements, namely basic element (7) as a tray / lid, basic element (8) as a tray / lid and basic element (9) as a frame. The basic element (9) consists only of side walls, but has no bottom. However, the two other basic elements also have a base in addition to the side wall. Any number of frame elements (9) can be used to design containers of different heights consisting of a lower base element (7) or (8), an upper base element (7) or (8) and frame elements (9) arranged between them.

The basic elements are expediently fixed to a container by means of tensioning straps, cords or the like. Tongue and groove connections are also suitable for locking the basic elements in the assembled position. The conical design of the side walls allows stackability.

E A gradation of the height of the side walls is also expedient. In a preferred embodiment, the lowest basic element has a side wall height of 37.5 mm, the further basic element (8) double the height and the frame element the same height as the higher basic element (8). Of course, starting from a different side wall height of the base element (7), the base elements (8) and (9) can also be dimensioned differently in height. The staggering of the height of the side walls can also be different. The container system can expediently be expanded by adding frame elements of different heights.

3) Third set of claims:

Container system consisting of basic elements that differ in height. Each base element has a bottom and a lower side wall section, which is adjoined by an upper side wall section which is slightly offset all the way out. The transition between the upper and lower edge section is expediently formed by an integral shoulder. The basic elements are expediently staggered in height. A preferred staggering is height h for the lowest container, 2h for the next larger container, 3h for the next container and nh for the following containers, where n is formed by integers.

If necessary, frame elements can also be integrated here that are based on the basic element but have no floor. Due to the special embodiment, the basic elements can be stacked in boxes. Here too, as in the other complexes of claims, there are suitable fastening elements

REPLACEMENT LEAF can be used to fix the corresponding basic elements to form a stable container. As in the other complexes of claims, a snap element is suitable here, which can be inserted from the outside into recesses in the walls of the basic elements and overlaps and holds together two designs of two basic elements.

4) Complex claim of another container system:

Container system made of basic elements, largely analogous to claim complex (3), but only half of the upper wall sections are provided, in that the upper wall section extends across a narrow side and only up to half on both longitudinal sides. The upper wall section ends on both sides with a slope. Basic elements placed one above the other overlap in the sloping area. Fastening elements can also be used here analogously to the previous complexes of claims. In particular, just as in the other complexes of claims, a push-on button is suitable, which overlaps a pin formation of two basic elements and thereby holds the two basic elements together.

REPLACEMENT LEAF