CH710703A2 - Frame module, frame assembly and use of a frame module. - Google Patents

Abstract

A frame module (10) comprises a bottom part (12) and a plurality of wall parts (14), which are articulated on the bottom part (12). The bottom part (12) and the wall parts (14) are formed with a wave-shaped structure of elevations and depressions, wherein the parts are hinged to one another via their edge portions such that elevations and depressions are aligned congruent to each other. Further, the edge portions of the parts (12, 14) are recessed such that they are in a form-fitting mutual contact at a predetermined angle between the bottom part (12) and the respective wall part (14).

Description

The present invention relates to a frame module, a frame assembly and a use of a frame module according to the independent claims 1, 18 and 24.

A frame module is u.a. defined as a bearing element or transport element, comprising e.g. a container, a housing, a casing, a box, etc. A frame module is used e.g. for storing, closing, storing and / or transporting objects received therein. Another field of application of a frame module is the protection of objects received therein against external influences such as impacts and / or environmental influences such as increased humidity, drought, heat or cold. A frame module comprises a bottom part and at least two wall parts, which are attached to each other on the bottom part. Furthermore, a ceiling part may be provided.

In known frame modules from the prior art, the bottom part and the at least two wall parts are integrally formed with each other, for example by one-piece molding, deep drawing, etc. There are other frame modules known from the prior art, in which the wall parts by means of non- detachable fastening means are permanently attached to the bottom part, for example by means of screwing, nailing, riveting or by material bond, for example, soldering, welding or gluing. The disadvantage of this is that these prior art frame modules in the unneeded state, i. if they do not perform any of the functions, such as transport, storage and / or protection of stored items, take up much space or space.

There are more frame modules are known in which the wall parts are articulated movable on the bottom part. Examples of these frame modules are so-called folding crates. Here, the wall parts are each provided with hinge elements, e.g. projecting pins provided, which engage in respective openings of arms, which in turn are fixedly connected to the bottom part. In this way, the wall parts can be pivoted about the pivotally mounted in the openings pin in relation to the bottom part. The disadvantage of this is the cumbersome, time-consuming and error-prone construction. For example, the boom must be attached with much effort on the bottom part or hereby integrally formed. Also, the formation of the pin on the respective wall parts is a complex process. In addition, the pins and the openings of the boom must be very precisely aligned axially to each other, so that a smooth pivoting movement or folding movement is possible. These high demands on the necessary precise production also increases the cost of production. Another disadvantage is that these joints are very error prone. For example, one of the studs may become brittle or break off over time due to material fatigue. Another disadvantage of these known frame modules in the "folding crates" design is that the wall parts can be fixed only by very complex and therefore expensive elements in the erected state. For this purpose, usually a fixedly connected to the bottom part supporting element is provided, which comprises clamping elements for fixed or releasable clamping of the respective erected wall parts. For example, the non-hinged, lateral edge portions of the respective wall parts can be provided with elevations which engage in the erected state in corresponding recesses of the support elements and thus lock the respective wall part to the support member. The support elements may each be designed as an extension of the jib for receiving the pivot of the wall part or hereby integrally formed. The disadvantage of this is the high cost of forming the solid support elements. As a result, costs, effort and time for the production of the frame module are increased.

Another disadvantage of known frame modules of the prior art is that the forming surface elements, i. the bottom part, the at least two wall parts, the optional ceiling part, etc., often have an insufficient dimensional stability. In order to increase the dimensional stability to a sufficient degree, the material thickness of these parts must be increased, which is associated with a higher material usage and therefore with increased costs. In addition, frame modules whose surface elements have an increased material thickness disadvantageously have an increased weight. As a result, costs, such as transport costs, increased.

Known frame modules from the prior art often provide insufficient protection against external influences from the outside, in particular bumps. Known measures from the prior art for the protection of objects stored or transported in the frame module relate to a further increased material thickness of the surface elements. It is also known in the art to cover the inside and / or the outside of the frame module with shock absorbing elements, such as fillers, polystyrene, foam, etc. Another known measure for the absorption of shocks relates to the filling of the interior of the frame module with shock absorbing Elements, such as foam chips, provided with trapped air plastic films, etc. All these measures from the prior art are complex, increase the cost of materials and thus the weight and are expensive overall. The shock-absorbing elements required in the prior art are expensive to manufacture, energy-intensive and must be supplied to a laborious recycling cycle after use, which again increases the cost. Thus, the frame modules of the prior art in terms of both economic and environmental disadvantages.

Another disadvantage of known frame modules is the often poor stackability. Known frame modules are not or only very limited stackable. In order to improve the stackability measures are known in the art, such as locking elements on respective frame modules, which firmly or removably come to the stacking between adjacent (stacked or side by side) stacked frame modules when stacking. By providing these locking elements, the frame modules in the production time-consuming and expensive. In addition, the locking elements often interfere with the appearance of the frame module.

It is an object of the present invention to provide a frame module, a frame assembly and a use of a frame module, in which the disadvantages of the prior art are solved.

According to the invention, a frame module comprises a bottom part and a plurality of wall parts, which are articulated on the bottom part, wherein the bottom part and the wall parts are formed with a wave-shaped structure of elevations and depressions, wherein the parts are hinged to each other over their edge portions such that Elevations and depressions are aligned congruent to each other and the edge portions of the parts are recessed so that they are at a predetermined angle between the bottom part and the respective wall part in positive mutual abutment.

It is a frame module created in which reach the edge portions of the hinged wall parts in the erected state with corresponding portions of the bottom part in fixed abutment. At the same time, corresponding edge sections of the bottom part come into fixed contact with corresponding sections of the edge section of the respective hinged wall part. Noteworthy is the simultaneous (double) fixed system, so that maximum stability is given. In a hitherto unattainable manner, a frame module is thus created, in which the respectively erected wall parts without an additional locking element in at least one direction can be positively brought into mutual contact. By saving any additional means for locking the wall parts, the production of the frame module is simplified and material is saved, thereby reducing weight and costs. A particular advantage is the modular design of the wall parts and the bottom part, so that they can be produced in one and the same manufacturing process, which significantly reduces costs. Due to the wave-like structure of the bottom part and the wall parts, the frame module is simultaneously given a shock-absorbing feature. Thus, additional shock absorbing elements can be saved, thereby saving costs and weight. Also, the stackability of several frame modules is improved by corresponding elevations and corresponding recesses of each stacked frame modules interlock and thus provide a firm grip. In addition, forces acting on the frame module from above, e.g. caused by the weight of other above stacked frame modules, including the weight of objects stored therein, introduced via the wall parts directly into the bottom part. Thus, it is advantageously avoided that these forces by appropriate components for articulating the wall parts on the bottom part, e.g. Cardan shafts, etc., must be recorded. Therefore, these components need less complex design, have a lower weight and are generally cheaper.

Preferably, the wall parts are articulated by means of at least one shaft on the bottom part, wherein the at least one shaft is inserted through each of the bottom part and the wall parts correspondingly arranged openings. The openings are formed continuously in the axial direction of the pivot point of the articulation by respective webs of the elevations of the bottom part and the respective wall part. Through these openings, a shaft is inserted from one side. The inserted shaft can be secured against slipping by at least one fastening means. The outer diameter of the inserted shaft substantially corresponds to the diameter of the openings. It has proved to be advantageous if two waves are used per articulation of a wall part on the bottom part, which are respectively inserted through from both sides through the openings. Due to the inventive wavy structure of the bottom part and the wall parts they can be hinged to each other in the section of the respective surveys, wherein the pivot point or pivot point is chosen such that the bottom part and at least one of the wall parts come to rest one above the other in the folded state. Thus, the bottom part and the wall parts occupy the least possible space. Further advantageously, no intermediate features for articulating the wall parts to the bottom part, such as a boom or a support, as known in the art, to set the pivot point from the plane of the bottom part spaced need not be provided. Since according to the invention no intermediate fastening elements are necessary, the bottom part and the wall parts can be manufactured in modular construction. This simplifies mass productivity and therefore saves manufacturing costs.

Preferably, the recesses of the component are recessed at the edge portion and the elevations of the wall parts are recessed at the edge portion. Alternatively, preferably, the elevations of the bottom part are recessed at the edge portion and the recesses of the wall portions are recessed at the edge portion. By means of these embodiments, end faces strike in the region of the recessed portions of the elevations of the wall part against the respective upper sides of the correspondingly arranged elevations of the bottom part, as soon as the wall part is erected. At the same time, end faces in the area of the recessed portions of the depressions of the bottom part abut against the respective undersides of the correspondingly arranged depressions of the respective wall part. Corresponding dimensions, for example the dimensions of the recesses, etc., are chosen such that corresponding end faces and top sides as well as undersides, as described above, come into contact simultaneously at a predetermined angle. As a result, a particularly reliable and stable stop is created. In addition, the stop angle can be determined application-specific. Advantageously, no additional intermediate features are required to create this particularly reliable system. Further advantageous forces are introduced from above to the frame module on the wall parts directly and evenly distributed in the bottom part. Thus, high forces can act on the frame module, without this being damaged or becomes unstable.

Preferably, the recesses are in the longitudinal direction of the elevations and depressions along the flanks of which triangular. As a result, the production is simplified.

Preferably, the wall parts in the erected state each include an angle of substantially 90 ° with the bottom part and in the non-erected state in each case an angle of preferably 0 ° with the bottom part. As a result, a frame module is created, the wall parts in relation to the bottom part can be easily opened to 90 °. In the unused state of the frame module, the wall parts are pivoted in the direction of the bottom part and close with this in the folded state an angle of substantially 0 °. Thus, the frame module occupies a minimum space in the unused state. Therefore, the unused frame modules can be stored in a particularly space-saving and therefore inexpensive.

Preferably, the frame module further comprises a locking unit, designed for locking the wall parts in the erected state. Preferably, the locking unit comprises a front and / or rear wall which is substantially inserted at a front or rear side of the frame module between the wall parts such that they are locked in the erected state. As a result, a reliable locking unit is provided by the front and / or rear wall, which firmly locks the wall parts in the erected state. The front and / or rear wall serves or simultaneously serve to close the frame module against the outside.

Preferably, the front and / or rear wall are inserted into recess portions of the wave-shaped structure of elevations and depressions of the wall parts. The recess portions are defined as viewed from within the frame module as the recesses of the wall portions described above. These recesses or recess sections thus serve at the same time as grooves, which face the interior of the frame module in the erected state of the wall parts, for receiving the front and / or rear wall on both sides.

Preferably edge portions of the inserted into the recess portions of the wall parts front and / or rear wall are bent and / or bent so that they are free of play with the respective recess sections in Appendix. In other words, the edge portions of the front and / or rear wall are shaped such that they substantially or completely conform to the recess portions. For this purpose, these edge portions may be resilient, so that the front and / or rear wall is reliably clamped in the recess sections without further aids. The thus inserted into the recess sections front and / or rear wall remains or remain unchanged by means of the folded and / or bent edge portions in place and lock or close thus, without annoying rattling, reliable wall parts. By additional investment or engagement of the front and / or rear wall with the bottom part of the wall parts are further reliably locked in their raised position.

Preferably, the front and / or rear wall are formed for closing the open sides of the frame module. In this embodiment, the frame module is closed from all sides. For quick opening of the frame module, the front and / or rear wall can be hinged to, for example, one of the wall parts so as to be opened and closed by means of one-sided or two-sided pivoting. Alternatively, the front and / or rear walls may be provided with closure components, e.g. Alternatively, the front and / or rear wall can be provided with rolling shutter elements, comprising individually hinged lamellae hinged to one another, which can be easily rolled up when opening.

Preferably, the locking unit comprises alternatively or additionally a ceiling part which is connected to the respective further edge portions of the erected wall parts and keeps them spaced from each other. After the wall parts are placed on, for example, 90 ° in relation to the bottom part and are in contact with each other at this angle, those edge portions of the wall parts, which are opposite to the hinged edge portions, connected to the ceiling part. The ceiling part may in this case be formed corresponding to the bottom part. Also, the manner of connection of the ceiling portion with the edge portions of the wall portions may be made in the manner described above. By the attached ceiling part keeps the wall parts spaced, they are particularly reliable stabilized.

Preferably, the ceiling part is formed structurally corresponding to the bottom part. This embodiment allows the production of the bottom part and the wall parts in modular design. As a result, the mass productivity is simplified and therefore manufacturing costs are saved.

Preferably, the ceiling part is designed to come with the bottom of the bottom part in direct contact. In this embodiment, the removed ceiling part can be brought directly into direct contact with the bottom of the bottom part without any gap. As a result, takes the frame module in the unused state a minimum possible space. Thus, storage costs for storing the unused frame modules can be reduced.

Preferably, edge portions of the bottom part and / or the ceiling part are formed at least one of the distal ends, each with a stop, wherein the stops in the erected state of the frame module with corresponding edge portions of the elevations of the wall parts in abutment. In this embodiment, the bottom part and / or the top part can each be clamped with the wall parts in the manner of a snap connection in relation to one another. By means of this clamping, all parts without a separate fastening element, for example the at least one shaft which is pushed through the openings, can be provisionally assembled manually. By acting as the material of the parts, i. the bottom part, the ceiling part and the wall parts, a material with elastic properties is selected, these snap into each other by means of the stops. As a result, the assembly of the frame module is simplified. The stops may be formed as lugs or nubs, which are integrally connected to the bottom part and / or ceiling part, or are cast in one piece. The stops 18 need not be arranged at each distal end of the edge portions of the bottom part and / or the ceiling part. It may be sufficient to provide the stops 18 at every other, third, etc. distal end of the edge portions.

Preferably, at least the bottom part and / or the wall parts are made of a material which comprises plastic or foam, in particular polystyrene. As a result, a frame module is created, which is particularly stable and inexpensive to manufacture. In particular, when using polystyrene as the material of the bottom part, the wall parts, the ceiling part and / or the front and / or rear wall, a particularly lightweight frame module can be produced. As a result, costs are saved during transport and storage. In addition, especially when using the frame module as a transport container, bumps are absorbed better on the frame module from the outside, whereby impact forces are reduced to transported herein objects and thus better protected.

Preferably, the structure of at least the bottom part and / or the wall parts in cross-section assumes a triangular shape, a flattened triangular shape, a rectangular shape or another polygonal shape. By this shaping, the wall parts can be brought in the folded state directly with correspondingly shaped surface portions of the bottom part in abutment. One advantage is that the collapsed frame module occupies a space as small as possible. Another advantage is that, due to the nested engagement between the bottom part and the wall parts, they can not be displaced unintentionally in relation to each other. Thus, the folded frame module forms a stable unit, without the need for additional retaining elements must be provided. Another important advantage of the structure of the bottom part and the wall parts is the increased structural integrity of these parts. Thus, compared to frame modules of the prior art, the parts require less material wall thickness while maintaining high stability. This reduces the cost and weight of the frame module without sacrificing stability.

According to the invention, a frame assembly comprises a plurality of frame modules according to one of claims 1 to 17, which are arranged side by side and / or stacked in abutment.

Preferably, the frame modules are stacked one above the other such that respective elevations and depressions of the ceiling parts and the bottom parts interlock nested. Thus, a frame assembly is provided, the frame modules can not be adjusted unintentionally, as these interleaved engage engaged. Thus, these frame modules do not need to be fastened together by external or internal fasteners, thereby saving time in assembly and disassembly of the frame assembly. In addition, costs are saved because additional fasteners are eliminated.

Preferably, the frame modules are arranged side by side such that end faces of the elevations of the wall parts of each adjacent frame modules are in contact with each other. In this arrangement, respective bumps and depressions of the ceiling parts and the floor parts of each stacked frame modules interlock nested.

Overall, this results in a very stable frame assembly, which is individually assembled from individual frame modules.

Preferably, the frame assembly further comprises at least one double shaft, which comprises at least two parallel spaced shafts, each of the waves through the respectively on the wall part, bottom part and / or top part correspondingly arranged openings of each side by side and / or stacked Frame modules is pushed through. By simultaneously inserting the waves of the double shaft, respectively front and / or back into the openings of side by side and / or stacked or stacked frame modules, these frame modules are quickly and easily connected to each other. At the same time, the shafts of the double shaft serve respectively for fastening the floor parts and / or ceiling parts, each with associated wall parts. The double shaft thus fulfills a dual function, namely on the one hand for assembling respective frame modules (fixing the floor parts and / or ceiling parts with respective wall parts) and on the other hand for locking respectively adjacent frame modules. This dual function saves time and money.

Preferably, the frame modules each have identical dimensions. By the frame modules are formed with identical dimensions, they can be easily assembled into an overarching frame assembly. The frame modules can have the form of a triangle, a rectangle or any polygon in plan view. For example, frame modules, which have a hexagonal outer shape in plan view, can be assembled into a frame assembly which assumes a honeycomb structure. Thus, the stability of the resulting frame assembly can be further increased by appropriate choice of the outer shape of the individual frame modules. Also aesthetic requirements are met, which are set to the frame assembly.

Preferably, in each case a ratio between the height and width of the open sides of the frame modules is determined such that a product of a multiple of the height is equal to a product of a further multiple of the width. By appropriate selection of the relation between the height and width of the open sides of the frame modules, respectively viewed in front view and rear view, from this a total of a frame assembly can be assembled, which assumes the overall shape of a rectangle - regardless of the orientation of the frame modules (vertical or horizontal, upright or horizontal) in a respective stacking position. For example, the ratio can be equal to 4: 3. This embodiment allows the arrangement of four side by side upright aligned frame modules, on which three adjacent juxtaposed frame modules are placed, the overall dimensions of this assembled frame assembly as a whole: takes the form of a rectangle. Of course, the ratio can also make a difference.

According to the invention, at least one frame module according to one of claims 1 to 17 is used as furniture object, lamp element, residential object, transport container or storage container.

Embodiments of the present invention will be explained in more detail below with reference to figures. Show it: <Tb> FIG. 1 <SEP> is an enlarged view of the underside of a frame module in perspective view; <Tb> FIG. 2 <SEP> is an enlarged view on the underside of a bottom part in perspective view; <Tb> FIG. 3a-d <SEP> a plurality of succession views for explaining an operation of the frame module; <Tb> FIG. 4 is a side elevational view of a frame module with a folded wall portion; <Tb> FIG. 5 <SEP> is a side elevational view of a frame module with folded bottom part and wall part; <Tb> FIG. 6 <SEP> is an overall schematic view of a frame module in perspective view; <Tb> FIG. 7 <SEP> another schematic overall view of a frame module in perspective view; and <Tb> FIG. 8 <SEP> is a schematic front view of a frame assembly.

Fig. 1 shows an enlarged view of the underside of a frame module 10 in perspective view, and Fig. 2 shows an enlarged view of the underside of a bottom part 12 in perspective view. The frame module 10 comprises the bottom part 12 and a plurality of wall parts 14 (for illustrative reasons, only one wall part 14 is shown in FIG. 1). The wall part 14 is articulated on the bottom part 12. Here, the wall part 14 is rotatably connected by means of a shaft 16 on the bottom part 12, wherein the shaft 16 is inserted through each of the bottom part 12 and the wall part 14 correspondingly arranged openings.

The bottom part 12 and the wall part 14 are formed with a wave-shaped structure of elevations and depressions. In this case, the bottom part 12 and the wall part 14 are hinged to each other via their edge portions such that corresponding elevations and depressions are aligned congruent to each other. Furthermore, the edge portions of the bottom part 12 and the wall part 14 are recessed so that they are in a predetermined angle between the bottom part 12 and the wall part 14 in positive engagement with each other. This angle between the bottom part 12 and the wall part 14 includes in the embodiment shown in FIG. 1 an internal angle of 90 °. In this inner angle are tops of the elevations of the bottom part 12 with end faces of the elevations of the wall part 14 in abutment. One of these arrangements is highlighted in FIG. 1 by means of a circle marked A. Furthermore, end faces of the depressions of the bottom part 12 are in contact with upper sides of the depressions of the wall part 14. One of these arrangements is highlighted in Fig. 1 by means of a marked B encircling.

The shaft 16 may be designed as a wire. The angle between the bottom part 12 and the wall parts 14 can be set smaller than 90 °. For example, the interior angles can be adjusted such that the frame module 10 assumes an outer shape of a triangle, a hexagon or any other polygonal shape.

As shown in FIGS. 1 and 2, the edge portions of the bottom portion 12 are formed at their distal ends with a stopper 18, respectively. These stops 18 extend tab-shaped in the direction of the wall part 14 and reach in the erected state of the frame module 10 with respective corresponding edge portions of the elevations of the wall part 14 in abutment. As described above and highlighted by the marked B in FIG. 1, the recesses of the wall part 14 come to corresponding end faces of the bottom part 12 in abutment. By means of the stops 18, the bottom part 12 and the wall part 14 are held in this manner in the manner of a snap connection in relation to each other in this embodiment. By this clamping the bottom part 12 and wall part 14 without a separate fastening element, for example, the at least one shaft 16, temporarily assembled manually or clamped together. As a result, the assembly of the frame module 10 is simplified, since in this provisionally assembled state, the openings of the bottom part 12 and the wall part 14 are already aligned along a virtual line to each other. Thus, the shaft 16 can be very easily inserted through these openings. As a result, the assembly of the frame module 10 is very simplified.

The stopper 18 is integrally connected to the bottom part 12, or may be cast in one piece hereby. The stops 18 have slightly elastic properties, so that they snap onto the surfaces of the wall part 14, or engage them. The stops 18 may be formed as lugs or nubs. The stops may be formed with corresponding projections at those portions which face the wall part 14, which engage or snap into correspondingly shaped recesses of the wall part 14. As a result, bottom part 12 and wall part 14 are clamped even more firmly together.

Although described in Figs. 1 and 2 respectively as the bottom part 12, this part, due to the preferred modular design, as a ceiling part (described later) are considered. In this case, FIG. 1 shows a plan view of the frame module 10.

Referring to Figures 3a to 3d, operations for displacing the wall portion 14 from the erected position (Figure 3a), in which the bottom portion 12 and the wall portion 14 are perpendicular to each other, are in the folded position (Figure 3d). shown. Here, Fig. 3a corresponds to the state of the frame module 10 shown in Fig. 1 in the unfolded state. 3b and 3c show the frame module 10 with progressively reduced internal angle between bottom part 12 and wall part 14. In Fig. 3d, the frame module 10 is finally shown in the fully folded state. In this case, the bottom part 12 and the wall part 14 enclose an angle of 0 °, that is, the parts 12, 14 lie parallel to each other. In this state, the frame module 10 takes a small space as a whole. As a result, transport and storage costs are saved.

4 shows a schematic side view of the frame module 10 with the wall part 14 folded together. The structure of the bottom part 12 and of the wall part 14 assumes a flattened triangular shape in cross-section. In this way, the bottom part 12 and the wall part 14 can lie flat in the folded state, so that the bottom part 12 and the wall part 14 come to rest parallel to each other (see also Fig. 3d). In this state, the bottom part 12 and the wall part 14 occupy a small space. Another advantage is that the bottom part 12 and the wall part 14 can not be inadvertently adjusted transversely to the alignment of the elevations and depressions by the mutual engagement.

The bottom part 12 and the wall part 14 are articulated by the shaft 16 to each other. Here, the shaft 16 is inserted through in each case in webs of the bottom part 12 and the wall part 14 registered openings. In this state, the wall part 14 can be easily opened by means of the inserted through the openings shaft 16 in relation to the bottom part 12. Although not shown, more than one shaft 16 may be used, preferably two shafts are used, which are pushed through from the two longitudinal sides of the frame module 10 through the respective openings. The bottom part 12 and the wall part 14 may be made of paper material, e.g. Cardboard, of metal, e.g. Sheet metal, plastic or foam, in this case in particular polystyrene, be made. As a result, a particularly inexpensive and lightweight frame module is created.

Fig. 5 is a schematic side elevational view of the frame module 10 with the bottom portion 12 and wall portion 14 fully collapsed. In this state, the shaft (see Fig. 4) is removed. Thus, the bottom part 12 and the wall part 14 can come into direct support. The bottom part 12 and the wall part 14 can not be displaced by the mutual engagement unintentionally transversely to the alignment of the elevations and depressions to each other.

Compared to the state shown in Fig. 4, the bottom part 12 and the wall part 14 occupy an even smaller space. Such a folded frame module 10 can be transported in a particularly space-saving manner. In this case, the folded frame module 10 can be inserted into a correspondingly shaped transport carton. For example, after erecting or assembling the frame module 10, this transport carton can be placed flat on the surface of the bottom part 12, the side edges of the transport carton being supported against the surfaces of the wall parts 14. This thus clamped in the interior of the frame module 10 transport box can further increase the stability of the frame module 10.

As shown in both FIG. 4 and FIG. 5, the distal ends of the edge portions of the bottom portion 12 are provided with stops 18. These stops extend upwards in the shape of a tab and, in the unfolded state of the wall part 14, can engage corresponding surface sections thereof. As a result, the bottom part 12 and the wall part 14 can be provisionally clamped manually or put together.

6 and 7 each show a schematic overall view of the frame module 10 according to the invention in different embodiments. The frame module 10 shown in Fig. 6 comprises the bottom part 12, the two wall parts 14 and additionally a ceiling part 20. The bottom part 12, the wall parts 14 and the ceiling part 20 are formed with a wave-like structure of elevations and depressions. The ceiling part 20 additionally serves to lock the wall parts 14 in the erected state.

Fig. 7 shows a further schematic overall view of a frame module 10, in which the ceiling part shown in Fig. 6 is removed. The frame module 10 comprises in addition to the bottom part 12 and the wall parts 14 in addition a rear wall 22. This rear wall 22 is inserted into recess portions of the wavy structure of elevations and depressions of the wall parts 14. In other words, the rear wall 22, viewed from within the frame module 10, is inserted into respective recesses of the wall parts 14. The rear wall 22 is inserted from above onto the frame module 10 in the indicated arrow direction in the recess sections or depressions of the wall parts 14. The edge portions of the inserted into the recess sections or depressions of the wall parts 14 rear wall 20 are in this case bent or bent so that they come into play with the respective recess sections in abutment. The rear wall 22 is thus reliably held.

In addition, the rear wall 22 serves for reliably locking the wall parts 14 in their erected position. By additional engagement of the lower edge of the rear wall 22 with the bottom part 12, the stability of the frame module 10 is further increased overall. Although not shown in FIG. 7, the frame module 10 may further include a front wall attached to the front of the frame module 10 corresponding to the attachment from the rear wall 22. Also, although not shown in Fig. 7, the bottom part 12 and the rear wall 22 may be formed with a wave-like structure of protrusions and depressions.

In Fig. 8 is a schematic view of the front of a frame assembly 24 is shown. The frame assembly 24 comprises a plurality of assembled frame modules 10, which have identical dimensions and are combined to form an assembly. Here, the frame modules 10 are arranged side by side and one above the other. The frame modules 10 can in this case be arranged such that respective elevations and depressions of frame modules 10 stacked one above the other interleave each other. Since the stacked frame modules 10 thus engage with each other nested, the frame modules 10 stabilize each other. By appropriate choice of the structure of the elevations and depressions of the floor parts 12 and ceiling parts 20 of the individual frame modules 10, this stability can be further increased. It is preferred that their surfaces touch each other without interruption or cling to each other. More preferably, this structure is wedge-shaped. Here, the elevations and depressions of the floor parts 12 and ceiling parts 20 particularly preferably form the outer shape of a flattened triangle. Thus, frame modules 10 stacked on top of each other become "wedged" with each other, whereby the static friction of these frame modules 10 is increased with each other and thus overall stability is increased. Thus, a particularly large number of frame modules 10 can be stacked on one another without the frame assembly 24 becoming unstable. Likewise, the frame modules 10 can not be adjusted unintentionally. Thus, each adjacent frame modules 10 need not be secured together by external or internal fasteners.

Overall, a stable frame assembly 24 is provided, which is freely and modularly configurable according to the wishes of the user. Due to this modular design, the transport of the frame assembly 24 is also very easy overall. In the case of a change of location, only the individual frame modules 10 are removed, transported separately and reassembled to a frame assembly 24 at the new location. A particular advantage is that no tools are required for dismantling and assembling.

The frame modules 10 of the frame assembly 24 shown in Fig. 8 each have identical dimensions and in this case such external dimensions, in each case a ratio between the height and width of the open sides of the frame modules 10 is equal to 4: 3.

To define the terms height, width and length with respect to a respective frame module 10, a coordinate system is added to FIG. Here, the orientation in the x direction is defined as the width, the orientation in the y direction (into the plane of the page) is defined as the length, and the orientation in the z direction is defined as the height of the frame module 10.

In the above-mentioned ratio of 4: 3 is an arrangement of four side by side upright oriented frame modules 10, on which three side by side and longitudinally aligned frame modules 10 are placed allowed. With such a composition of the frame modules 10, the overall dimension of the frame assembly 24 assembled thereby assumes the overall shape of a rectangle. Of course, other conditions are selectable.

Claims (24)

A frame module (10) comprising a bottom portion (12) and a plurality of wall portions (14) hinged to the bottom portion (12), the bottom portion (12) and wall portions (14) having a wavy structure of protrusions and Recesses are formed, wherein the parts (12,14) are articulated to each other over their edge portions such that elevations and depressions are aligned congruent to each other and the edge portions of the parts (12,14) are recessed so that these at a predetermined angle between the Floor part (12) and the respective wall part (14) are in positive engagement with each other. 2. Frame module (10) according to claim 1, wherein the wall parts (14) by means of at least one shaft (16) are hinged to the bottom part (12), wherein the at least one shaft (16) through each at the bottom part (12) and to the Wall parts (14) correspondingly arranged openings (18) is pushed through. 3. frame module (10) according to claim 1 or 2, wherein the recesses of the bottom part (12) are recessed at the edge portion and the elevations of the wall parts (14) are recessed at the edge portion. 4. frame module (10) according to claim 1 or 2, wherein the elevations of the bottom part (12) are recessed at the edge portion and the recesses of the wall parts (14) are recessed at the edge portion. 5. frame module (10) according to any one of the preceding claims, wherein the recesses in the longitudinal direction of the projections and depressions along the flanks of which are triangular. 6. Frame module (10) according to any one of the preceding claims, wherein the wall parts (14) in the erected state each include an angle of substantially 90 ° with the bottom part (12) and in the non-erected state in each case an angle of preferably 0 ° with the bottom part (12) included. 7. frame module (10) according to any one of the preceding claims, further comprising a locking unit, adapted for locking the wall parts (14) in the erected state. 8. frame module (10) according to claim 7, wherein the locking unit comprises a front and / or rear wall (20), which is inserted substantially at a front or rear side of the frame module (10) between the wall parts (14) or are that they are locked in the erected state. 9. Frame module (10) according to claim 8, wherein the front and / or rear wall (20) is inserted into recess portions of the 'wavy structure of elevations and depressions of the wall parts (14) or are. 10. frame module (10) according to claim 9, wherein edge portions of the recess portions of the wall portions (14) inserted front and / or rear wall (20) are folded and / or bent so that they are free of play with the respective recess sections in Appendix. 11. frame module (10) according to any one of claims 8 to 10, wherein the front and / or rear wall (20) for closing the open sides of the frame module (10) is or are formed. 12. Frame module (10) according to claim 7, wherein the locking unit comprises a cover part (22) which is connected to the respective further edge portions of the erected wall parts (14) and keeps them spaced from each other. 13. Frame module (10) according to claim 13, wherein the cover part (22) structurally corresponding to the bottom part (12) is formed. 14. Frame module (10) according to claim 13 or 14, wherein the cover part (22) is adapted to come with the underside of the bottom part (12) in direct contact. 15. frame module (10) according to any one of claims 12 to 14, wherein edge portions of the bottom part (12) and / or the ceiling part (22) are formed at least one of the distal ends, each with a stop, wherein the stops in the erected state of the frame module (10) with corresponding edge portions of the elevations of the wall parts (14) are in abutment. 16, frame module (10) according to any one of the preceding claims, wherein at least the bottom part (12) and / or the wall parts (14) are made of a material which comprises plastic or foam, in particular polystyrene. 17. frame module (10) according to any one of the preceding claims, wherein the structure of at least the bottom part (12) and / or the wall parts (14) in cross-section assumes a triangular shape, a flattened triangular shape, a rectangular shape or other polygonal shape. 18. Frame assembly (24), comprising a plurality of frame modules (10) according to one of claims 1 to 17, which are arranged side by side and / or stacked in abutment. 19. Frame assembly (24) according to claim 18, wherein the frame modules (10) are stacked one above the other in such a way that respective elevations and depressions of the ceiling parts (22) and the bottom parts (12) nested intermesh. 20. Frame assembly (24) according to claim 18 or 19, wherein the frame modules (10) are arranged side by side such that end faces of the elevations of the wall parts (14) of each adjacent frame modules (10) are in contact. 21. Frame assembly (24) according to claim 20, further comprising at least one double shaft, comprising at least two parallel spaced waves, each of the waves by the respectively on the wall part (14), bottom part (12) and / or ceiling part (22) arranged correspondingly Openings of each side by side and / or stacked or stacked frame modules (10) is pushed through. 22. Frame assembly (24) according to any one of claims 18 to 21, wherein the frame modules (10) each have identical dimensions. 23. Frame assembly (24) according to any one of claims 18 to 22, wherein in each case a ratio between the height and width of the open sides of the frame modules (10) is determined such that a product of a multiple of the height equal to a product of a further multiple of Width is. 24. Use of at least one frame module (10) according to one of claims 1 to 17 as a furniture object, lamp element, residential object, transport container or storage container.