EP2389487A1 - Modular container system - Google Patents

Abstract

The invention relates to a modular container system for creating cuboid modular units for living or working purposes, which are arranged next to and on top of each other. In order to enable cost-effective warehousing, easy transportation, fast assembly, and a flexible and variable installation, it is proposed that a modular unit comprises the following: a) a floor (1) or ceiling element (2) serving as the lower base, comprising connector parts (3) for detachably fastening two mutually opposing face wall elements (4), b) two face wall elements (4) comprising connector parts (3') for the detachable fastening to the lower floor (1) or ceiling element (2) and comprising connector parts (3'') for detachably fastening an upper ceiling (2) or roof element (7), and connector parts (203) for the connection to side wall elements (5, 6, 105, 106), c) two side wall elements (5, 6, 105, 106) comprising connector parts (103) for the connection to the face wall elements (4), d) and a ceiling (2) or roof element (7) serving as an upper covering, comprising connector parts (3) for the detachable fastening to the face wall elements (4).

Description

 Title: Modular Container System Applicant: Gunnar Peck

The invention relates to a modular container system for creating adjacent and successive cuboid room cells for living or working.

Office containers of the type mentioned are used wherever solid, immobile facilities are considered unprofitable or uneconomical. Containers of the aforementioned type are particularly intended to be able to provide fast and flexible habitable space available, for example, for use as an office, hospital, operating room and the like. Usually such containers are cuboid, prefabricated space cells, which are assembled side by side and stacked on site to form a building.

A disadvantage of the known container systems is that they can not be changed and can only be adapted to changing room concepts with great difficulty. This requires a complicated provision of different types of containers, which causes long service lives. This is especially true for custom made containers. As a result, use of materials, capital commitment and warehouse space requirements are high. The transport of the containers is uneconomical, since rebuilt spaces must be transported, which require a lot of cargo and frequent trips. In addition, heavy cranes are needed for lifting, loading and depositing containers at the warehouse and on site.

The object of the invention is therefore to propose a modular container system that allows cost-effective storage, easy transport, fast assembly / disassembly and flexible and variable assembly and disassembly.

This object is achieved in that a room cell each comprises: a) serving as a lower base floor or floor ceiling element with Connector parts for releasably securing two opposing end wall elements, b) two end wall elements with connector parts for releasable attachment to the lower floor or floor ceiling element and with connector parts for releasably securing a top floor or roof element and connector parts for connection

Side wall elements, c) two side wall elements with connector parts for connection to the end wall elements, d) serving as an upper cover floor or roof element with connector parts for releasable attachment to the end wall elements. This container system has numerous advantages over the known container systems. Thus, a complete room cell is assembled on site from the described individual elements. Previously, the individual elements can be stored and transported to save space, whereby the storage and transport costs are lower than in the known container systems. Another advantage is that a crane with a lower load capacity can be used during assembly, since the individual elements have a lower weight than a complete room cell. An additional advantage is that the individual elements only have to be plugged together in the construction of the container system by means of connectors. It is not necessary, for example, to screw the individual elements or connect in any other way. This results in a fast and cost-effective installation and disassembly.

Advantageous embodiments are specified in the subclaims and are explained below.

A connector is formed from at least two connector parts, wherein at least one connector part is provided on each of the elements to be connected to each other. A connector part has a groove with at least one parallel thereto extending bung, so that in a plugged connector parts of connectors consisting of grooves and bounces engage positively with their contact surfaces. As a result, a simple but secure connector is possible without further fasteners are necessary. The side wall elements are formed as a trapezoid with a lower base side and a parallel to this upper base side and two equal trapezoidal legs. Leg and lower base side each form an inner angle greater than 90 °, whereby the surface of the side wall elements tapers towards the lower floor or floor slab element and widened towards the upper cover. The connector parts for connection to the end wall elements run along the trapezoidal legs and have their inclination. The connector parts of the end wall elements for connection to the side wall elements have the same direction of inclination and can be connected to them. As a result, a component of the force, which is generated by the weight of the trapezoidal side wall element, acts in a horizontal direction, ie parallel to the base sides. As a result, the connector parts of the side wall elements and the end wall elements are connected to each other with force and pressed together. In each case a side wall element is firmly clamped between two end wall elements.

For each two space cells arranged side by side, a common, inner side wall element is provided as an inner wall. As a result, in contrast to conventional containers, a side wall is saved.

All end wall elements and the outer side wall elements of the container system, which are not inner walls, form the outer walls of the container system.

The inner side wall elements have connectors with two bumps and a double groove arranged therebetween, so that in the connected state, the two bumps of the two connector parts of two juxtaposed end wall elements engage together in the double groove and each one of the two bounces of the inner side wall element in each case a groove Connector part of an end wall element engages to connect two end wall elements and connect them to an inner side wall member. The common side wall element can thereby firmly connect two end wall elements with one connector part on the trapezoidal leg. The bottom, floor ceiling or roof elements are formed as, preferably rectangular plates, each having a top, a bottom and four side surfaces, wherein the connector parts are arranged for connection to the end wall elements in particular each on two opposite side surfaces and the longitudinal axes of the groove and Bung run parallel to the side surfaces. The underside of the floor elements lies in the assembled state of the container system directly on the floor surface and the top of the floor elements faces the floor ceiling or roof element. The roof elements form with their top the upper end of the container system. The

Floor slab elements form with their upper side the floor of an upper room cell and with their underside the ceiling of a lower room cell.

The end wall elements have an upper and a lower connector part. When building the container system, the end wall elements are plugged with the lower connector part on a floor or floor ceiling element and on the upper connector part a bullet or roof element is inserted.

For the floor elements connector parts are provided with a groove and a bung, which are arranged on the top of the floor elements, so have to a bullet or roof element, so that the lower

Connector parts of the end wall elements can be plugged onto the top of the bottom element.

For the roof elements connector parts are provided with a groove and a bung, which are arranged on the underside of the roof elements, so have a floor or ceiling element so that the roof elements with its bottom on the upper connector parts of the end wall elements can be plugged.

For the floor slab elements connector parts are provided with a groove and a bung, which are arranged at the top of the floor slab elements, so that the lower connector parts of the end wall elements the top of the floor slab elements are pluggable. In addition, further connector parts with grooves and bounces are provided for the floor slab elements, which are arranged on the underside of the floor slab elements, so that the floor slab elements can be plugged with their underside on the upper connector parts of the end wall elements.

The side wall elements for the top floor have fastening elements for fastening the roof elements in the contact area of the roof elements.

The fasteners are designed as longitudinally extending thickening or longitudinal projection with a holding surface for the roof elements, so that in the installed state, the side wall elements exert by their weight with the support surface a force on the roof elements and secure them. This is made possible in that the side wall elements are not load-bearing, but are suspended or plugged into the end wall elements.

The outer side wall elements have a cover plate, which is preferably rectangular. Through the cover plate, the end wall elements are covered.

The floor, floor slab, end wall, side wall and roof elements have a seal, preferably a hard rubber layer, at the locations or areas where they may contact each other in the connected condition. As a result, the space cells are sealed against environmental influences, such as rain, moisture, outside temperatures and the like and protected.

Since the end wall panels are always exterior walls, they have doors and / or windows.

The inner or outer sidewall elements may have through openings or doors.

The individual components of the container system, such as floor elements, floor slab elements, end wall elements, side wall elements, Roof element, and the like consist of aluminum profiles, which form a frame. This ensures great stability with low weight. Likewise, the connector parts consist of aluminum profiles. On the frame veneers are arranged, with the outside wall panels and roof surfaces made of galvanized, weatherproof

Corrugated metal sheets and the inside wall, floor and ceiling panels made of scratch and impact resistant plastic panels. The contact surfaces of the connector parts are to be provided with a sealing hard rubber layer to avoid weathering. The cavities of the components can be filled as required with heat, sound or fire insulating materials.

By type and amount of filling the required weights of the components can be precisely adjusted. In the cavities, heaters, air conditioners, lighting, switches / controllers, etc. and channels for the supply lines, communication lines, roof drainage, etc. can be pre-installed.

The invention will be described by way of example with reference to a drawing, wherein further advantageous details are shown in the figures of the drawing.

Functionally identical parts are provided with the same reference numerals. In order to distinguish between functionally identical parts on different components, the reference numerals have partial indices.

The figures of the drawing show in detail:

Figures 1 to 4 are side views of the container system in different chronologically following states of construction;

Figures 5 to 9 are plan views of the container system in the various chronologically following setup states;

Figures 10 to 15 are front views of the container system in the various chronologically following setup states; and Figures 16a to 23 are perspective views of the container system in different chronologically following states of construction.

FIGS. 1 to 15 described below show the container system in various setup states. In chronological order, the construction of a two-storey container system with a ground floor and an upper floor is shown in a side view, in a plan view and in a front view. For the sake of clarity, elements are shown partially "floating" above their plugged position, and the arrows next to the "floating" elements indicate the direction in which the element is placed on top of another. In addition, some components or components that are hidden by other components, shown in phantom to give an idea of their position in the container system.

Since the figures 1 to 4 described above are side views, only one floor 1, floor ceiling 2, and roof element 7 and only the inner side wall element 5 are shown.

FIG. 1 shows a side view of the container system with a bottom element 1, which forms a base for the end wall elements 4 and the side wall element 5. The end wall elements 4 and the inner side wall element 5 are shown for clarity not in the plugged, but above an inserted position.

The bottom element 1 is a rectangular plate with a top 14, a bottom 15 and four side surfaces 16. With its underside 15, the bottom element 1 rests on a bottom surface 19. The top 14 forms a walkable floor. At the two opposite side surfaces 16 of the bottom element 1 connector parts 3 are attached. The

Connector parts 3 of the bottom element 1 and the end wall elements 4 consist of a groove 8 with a parallel thereto extending bung 9, so that when plugging both elements, a connector is formed from two connector parts, the grooves 8 and 9 snaps positively engage with each other. In the end wall elements 4 are the lower Grooves 8 'and bungs 9' hidden and therefore shown in phantom. The grooves 8 and bumps 9 of the bottom element 1 are arranged on the upper side 14 of the bottom element 1. On these connector parts 3, the corresponding lower connector parts 3 'of the end wall elements 4 are attached. The lower connector parts 3 'have with their contact surfaces down, ie in the direction of the bottom element. 1

The inner side wall element 5 is formed as a trapezoidal plate with a lower base side 11 and an upper parallel to this side 12 and two equal length trapezoidal legs 13. Leg 13 and lower base side 11 each form an inner angle greater than 90 °, whereby the surface of the side wall element 5 tapers towards the bottom element 1 and widened towards the top. The upper base side 12 is thus longer than the lower base side 11. Along the two trapezoidal legs 13 are connector parts 103 (not shown, see Figure 17) arranged for connection to the end wall elements 4, wherein the trapezoidal connector parts 103, the inclination of

Trapezoidal thighs 13 have. Matching connector parts 203 (see also FIG. 17), which have a corresponding inclination direction, are arranged on the end wall elements 4. In this way, each of the connector parts 3 of side wall element 5 and end wall elements 4 are firmly connected.

Due to the trapezoidal shape of the inner side wall member 5 and the inclined connector 3 acts a component of the force generated by the weight of the trapezoidal side wall element 5 in the horizontal direction, ie parallel to the base sides 11, 12. Thereby, the connector parts 3 from the side wall element. 5 and the end wall elements 4 connected with force and pressed together. By this frictional connection, the side wall element 5 is firmly clamped between the two end wall elements 4. The outer side wall elements 6, which are not shown in FIG. 1, likewise have the described trapezoidal shape.

The end wall elements 4 have upper connector parts 3 "each with a groove 8" and 9 "bung, the contact surfaces facing upward upper connector parts 3 "can either a bullet 2 or a roof element 7 (not shown) are inserted.

At the points or areas where the elements 1, 4, 5 come into contact with each other in the connected state, they are coated with a hard rubber seal. As a result, a seal against moisture, weather conditions and the like is guaranteed.

FIG. 2 shows a side view of the container system from FIG. 1 with the base element 1 shown in dashed lines, two attached end wall elements 4 and an inner side wall element 5 which is inserted between the two end wall elements 4. Above these elements further elements to be installed are shown, which hover above their intended position for illustration. These are a floor slab element 2, two further end wall elements 4 and a roof element 7 as top cover.

The floor slab element 2 is a rectangular plate with a top 14 ', a bottom 15' and four side surfaces 16 '. The base surfaces correspond to the base surfaces of the bottom element 1 and the roof element 7. By the bottom element 1, the two plugged end wall elements 4, the side wall element 5, the floor slab element 2 in the plugged state and another side wall element 5, not shown, a closed space cell is formed. The underside 15 'of the floor slab element 2 forms the ceiling. The top 14 'forms a walk-in floor for a legend, another room cell.

At the two opposite side surfaces 16 'of the floor slab element 2 a total of four connector parts 3a, 3b are attached. These connector parts 3a, 3b consist, as in the bottom element 1 and the end wall elements 4 of a groove 8 with a parallel thereto extending bung 9, so that when mating two elements, a connector of two connector parts 3 is formed, the grooves 8 and 9 bouts form-fitting manner to grab. The two opposing connector parts 3a are arranged on the upper side 14 'of the floor slab element 2, that is to say in FIG. 2 in the direction of the roof element 7, so that the lower connector parts 3' of the end wall elements 4 of a further projectile can be plugged onto the upper side 14 'of the slab elements 2 , The end wall elements 4 are identical for all floors or floors.

In addition, two further opposing connector parts 3b are provided for the floor slab elements 2, which are arranged on the underside 15 'of the floor slab element 2, ie in the direction of the floor element 1, so that the slab elements 2 with their underside 15' on the upper Connector parts 3 "of the end wall elements 4 are pluggable.

Furthermore, a roof element 7 is shown that serves as an upper cover for the top floors. Corresponding connector parts 3 are likewise provided for the roof elements 7, which are arranged on the underside 15 "of the roof elements 7, thus pointing in the direction of the floor slab element 2 in FIG. 2, so that the roof elements 7 with their underside 15" contact the upper connector parts 3 ". the end wall elements 4 are pluggable.

FIG. 3 shows all the elements 1, 2, 4, 5, 7 from FIG. 2 in the assembled state. Above these elements is shown an uppermost inner sidewall member 105 which hovers above its intended position for illustrative purposes.

From Figures 1 to 3, the following sequence results in the assembly of the individual elements to a two-storey container system: First, at least one bottom element 1 is set with its bottom 15 on the soil surface. Then the end wall elements 4 are placed on the or the bottom elements 1. Between the end wall elements 4, the inner and (not shown) outer side wall elements 5, 6 for the first floor, so the ground floor, put. Thereafter, on the end wall elements 4 a or several floor ceiling elements 2 inserted. On the floor slab elements 2 then further end wall elements 4 are inserted. On the end wall elements 4 then at least one roof element 7 is inserted. Finally, between the end wall elements 4 further inner and outer side wall panels 105, 106 for the second floor, so the upper floor, plugged. These top ones

Sidewall elements 105, 106 differ from the sidewall elements 5, 6 used for other floors in that they have a thickening 17 in the contact area of the roof elements 7. The thickening 17 is arranged on the upper, longer base side 12 of the trapezoidal side wall elements 105, 106. In the inserted state, the side wall elements 105, 106 press by their weight with the thickening 17 on the roof elements 7 and thereby fix them.

FIG. 4 shows the finished assembled container systems with inserted topmost side wall element 105. Hidden parts of components are shown in dashed lines. The container system consists of a ground floor 110 and an upper floor 120. However, the container system according to the invention is not limited to these floors. In principle, any number of projectiles can be stacked on top of each other. A limitation arises only by the static load and the load-bearing capacity of the elements, in particular those of the end wall elements. 4

The loads of the structure are largely borne by the Stirnwandelelemente 4, while the side wall elements 5, 6 transmit only small forces.

The figures 5 to 9 described below show a plan view of the container system in various states of construction. In chronological order, the construction of a two-storey container system with a ground floor and an upper floor is shown.

FIG. 5 shows a plan view of three floor elements 1 which form the base of the container system. A floor element 1 consists of a rectangular plate resting on a floor surface 19 (not shown). The top 14 forms a walkable floor. At the two opposite short ones Side surfaces 16 of the bottom element 1 is in each case a connector part 3 attached. This consists of a groove 8 with a parallel thereto extending bung 9. On a total of four connector parts 3, an end wall element 4 is attached in each case.

The three floor elements 1 are at the opposite long

Side surfaces 16 'arranged side by side. These long side surfaces 16 'have no connector parts. However, the container system according to the invention is not limited to the number of three floor elements 1 shown. In principle, any number of floor elements 1 can be arranged next to one another, with the respective top side 14 of a floor element 1 forming the base area for a room cell.

FIG. 6 shows a plan view of three floor elements 1 from FIG. 5 with all six end wall elements 4 plugged on. The arrangement of the floor elements 1 shows that the end wall elements 4 are always exterior walls.

FIG. 7 shows the three base elements 1 with plugged-on end wall elements 4 from FIG. 6. In addition, the inner side wall elements 5 and the outer side wall elements 6 are also attached. Only the outer side wall elements 6 together with the end wall elements 4, the outer walls of the container system. The outer side wall elements 6 differ from the inner side wall elements 5. The inner side wall elements 5 are not only used to separate a room cell, but also have the function to connect two end wall elements. For this purpose, the plug connectors 3 of the inner side wall elements 5 have two bumps 9 with a double groove 10 arranged therebetween.

The two bumps 9 of the two connector parts 3 of two juxtaposed end wall elements 4 engage together in a double groove 10 and are thus connected to the inner side wall element 5. A side wall element 5 thereby connects to one each Connector part 3 on the trapezoidal leg 13 (not shown) two end wall elements 4. So there is a plug connection of three elements. As a result, a particularly fast construction is possible.

FIG. 8 shows the container system from FIG. 7, wherein in addition three floor slab elements 2 (not shown), six upper face wall elements 4 (not shown) and three roof elements 7 are attached. The construction state corresponds to that shown in FIG. The roof elements 7 are like the floor 1 and floor ceiling elements 2 in plan view substantially rectangular. In contrast to these, they have on their long sides recesses 22 which form a slot 23 at two adjacent roof elements 7.

To complete the construction, the uppermost outer sidewall members 106 are inserted into the recesses 22 and the uppermost inner sidewall members 105 are inserted into the slots 23 (see Figure 9).

FIG. 9 shows the container system from FIG. 8 with inserted topmost inner and outer side wall elements 105, 106 in the completely assembled state. These top side wall elements 105, 106 differ from the side wall elements 5, 6 for other floors in that they have a thickening 17 for fastening the roof elements 7 in the contact area of the roof elements 7. The thickenings 17 cover the recesses 22 or the slots 23. In addition, the top side wall elements 105, 106 press by their weight with the thickening 17 on the roof elements 7 and fix it thereby.

Figures 10 to 15 show a front view of the container system in various states of construction. The construction of a two-storey

Containersystems with a ground floor 110 and an upper floor 120 is shown in chronological order as in Figures 1 to 4 and 5 to 9.

FIG. 10 shows a front view of three floor elements 1 arranged next to one another. A left-hand floor element 1 'is shown in FIG End wall element 4 with a window 18 attached. This bottom element 1 'is covered by the end wall element 4 and is therefore shown in dashed lines. The hidden connector parts 3 are also shown in dashed lines. The middle end wall element 4 is shown floating above its inserted position for reasons of clarity.

Figure 11 shows the three inserted end wall elements 4 of Figure 10, which are inserted into three floor elements 1 shown in dashed lines. The outer left side wall member 6 is complete and the associated, a space cell forming inner side wall element 5 is half inserted. Another inner sidewall member 5 and an outer sidewall member 6 are shown floating. On the side wall element 5, 6, the connector parts 3 are shown hatched. At the two inner side wall elements 5, a double groove 10 is provided for connecting two end wall elements 4. The vertical arrows indicate the insertion direction.

FIG. 12 shows the container system in a structural state with floor elements 1 (dashed lines), end wall elements 4 for the first and second floor, inner 5 and outer side wall elements 6 (shown in dashed lines), floor slab elements 2 and a roof element 7. Concealed connector parts 3 are shown in dashed lines.

FIG. 13 shows the two-storey container system as in FIG. 12 with a ground floor 110 and plugged-on end wall elements 4 and roof elements 7 for the upper floor 120.

14 shows the container system of FIG. 13 with a fully inserted uppermost outer sidewall member 106 and a half-inserted uppermost inner sidewall member 105 and two levitated sidewall members 105, 106. The topmost sidewall members 105, 106 are different from the sidewall members 5 , 6 for the other floors in that 7 thickenings 17 are provided in the contact area of the roof elements. The Thickenings 17 have in the direction of the roof elements 7 on a chamfered support surface 20 for the roof elements 7. The side wall elements 105, 106 exert by their weight with the support surface 20 from a force on the roof elements 7 and fix it thereby. Since the side wall elements 105, 106 are not load-bearing, but are suspended or plugged into the end wall elements 4, they exert a force on the roof elements 7 by their weight and fix them with the holding surface 20. For this purpose, the roof elements 7 have corresponding inclined surfaces 217 the holding surfaces 20. The thickenings 17 of the uppermost inner side wall elements 105 have two holding surfaces 20 arranged opposite one another, while the holding surfaces 20 of the uppermost outer side wall elements 106 each have only one holding surface 20.

FIG. 15 shows the finished container systems with a total of six room cells on two floors 110, 120.

Figures 16 to 23 described below show the above-described components of the container system in a perspective side view, for reasons of clarity, surfaces of the components are shown partially transparent to allow, as in a wireframe model, a view into the interior of the components and their function to illustrate.

FIG. 16a shows a perspective side view of the floor element 1, which forms the base for the two end wall elements 4 and the side wall elements 5 (not shown). The end wall elements 4 are not shown in the inserted, but shown above their inserted position for clarity.

The bottom element 1 is a rectangular plate on the two opposite side surfaces 16 attached connector parts 3. On these connector parts 3, the corresponding lower connector parts 3 'of the end wall elements 4 are attached. At the two longer side surfaces 16 each have a support bar 21 is provided. This serves as a support for the side wall elements 5, 6, 105, 106. The End wall elements 4 also have upper connector parts 3 "for floor ceiling 2 or a roof element 7 (not shown).

The connector parts of all components 3 or 3 'and 3 "consist of a groove 8 with at least one parallel thereto extending bung 9, so that when mating a connector of two connector parts is formed, which engage positively in one another.

16b shows an enlarged perspective partial view of the bottom element 1 from FIG. 16 with the plug connector 3, which consists of a groove 8 with a bump 9 extending parallel thereto, and the support strip 21.

FIG. 17 a shows a perspective view of the floor element 1 with two end wall elements 4 from FIG. 16, the end wall elements 4 being attached to the floor element 1. The trapezoidal inner sidewall member 5 is shown floating above its inserted position (see Figure 19). For inserting the side wall element 5 in the end wall elements 4 inclined connector parts 103, 203 are provided. The trapezoidal connector parts 103 are arranged along the two trapezoidal legs 13 and have their inclination. At the end wall elements 4 matching side connector parts 203 are arranged, which have a corresponding inclination direction.

The end wall elements 4 thus have a total of four connector parts, an upper 3 "and a lower 3 'connector part and two inclined side connector parts 203rd

The inner sidewall member 5 may have a door or opening (not shown) as a passageway for an adjacent compartment.

As FIG. 17b shows in a detailed view of the end wall element 4, a side connector parts 203 of the end wall element 4 consist of a side groove 208 with a side bump 209 extending therefrom. The trapezoid connector parts 103 have corresponding grooves and bungs (not shown), so that when plugged together Connector of two connector parts 103 and 203 is formed, which engage positively in one another. All connectors described here have similar features and the same operating principle.

FIG. 18 shows the bottom element 1 and the end wall elements 4 from FIG. 17a, but with an additional outer shown floating

Side wall element 6. This consists of a trapezoidal plate 30, which corresponds to the inner side wall element 5 of Figure 17. In addition, it has a square cover plate 31 connected to the trapezoidal plate 30. The square cover plate 31 is shown transparent and thus shows the trapezoidal plate 30 arranged behind the viewing direction.

FIG. 19 shows the bottom element 1 and the two end wall elements 4 from FIG. 17a. In addition, two outer side wall elements 6 are inserted into the end wall elements 4. The rectangular cover plate 31 covers the side surfaces of the end wall elements 4 completely. Above its inserted position, a floor slab element 2 is shown suspended. It has at its shorter side surfaces in each case an upper 3a and a lower connector 3b and on the longer side surfaces in each case a support bar 21 for supporting side wall elements 5, 6, 105, 106. The floor slab element 2 may have an opening with a staircase (not shown) to allow access to a lower or upper floor.

FIG. 20 shows the floor element 1 and the two end wall elements 4 from FIG. 17 a and additionally a roof element 2 suspended above its inserted position.

FIGS. 21 and 22 each show a perspective side view of a top inner sidewall member 105 and a topmost sidewall member 106. These top sidewall members 105, 106 are different from the sidewall members 5, 6 used for the other bottom stories in that they are in the contact region of FIGS Roof elements 7 have a thickening 17. The thickening 17 is at the upper, longer base side 12 of the trapezoidal side wall elements 105, 106th arranged. When inserted, the side wall elements 105, 106 press by their weight with the thickening 17 on the (not shown) roof elements 7 and fix it thereby.

FIG. 23 shows a perspective side view of a complete space cell of the container system according to the invention. The room cell comprises a floor element 1, two end wall elements 4 inserted into the floor element 1, a roof element 2 inserted into the end wall elements 4, a top outer side wall element 106 placed on the end wall elements 4, which is shown as transparent, and a topmost inner wall placed on the end wall elements 4 Side wall element 105.

The described container system can be stored and transported in a space-saving manner, can be set up quickly and easily by means of the connectors and can be flexibly inserted and expanded.

LIST OF REFERENCE NUMBERS

1. floor element

2nd floor slab element

3. connector part

4. end wall element

5. Inner sidewall element

6. Outer side wall element

7. Roof element

8. Groove

9. Bungling

10. double groove

11. Lower base

12. Upper base

13. Trapezium legs

14. Top of the floor, floor ceiling or roof elements

15. Bottom of the floor, floor ceiling or roof elements

16. Side surface of the floor, floor ceiling or roof elements

17. Thickening

18th window

19th floor surface

20. Holding surface

21st support bar

22nd recess

23. slot

30th trapezoidal plate

31. cover plate

103. Trapezoidal connector part

105. Upper inner sidewall element

106. Top outer sidewall element 110. Ground floor

120th floor

203. Side connector part

208. Side groove

209. Side bump 217. Sloping surfaces

Claims

claims

1. Modular container system for creating juxtaposed and successive cuboid room cells for living or working, characterized in that a room cell each comprises: a) serving as a lower base floor (1) or floor slab element (2) with connector parts (3) for releasable attachment of two opposite end wall elements (4), b) two end wall elements (4) with connector parts (3 ') for releasable attachment to the lower floor (1) or floor slab element (2) and with connector parts (3 ") for releasable Fastening an upper floor ceiling (2) or roof element (7) and connector parts (203) for connection to side wall elements (5, 6, 105, 106), c) two side wall elements (5, 6, 105, 106) with connector parts (103) for connection to the end wall elements (4), and d) serving as an upper cover floor ceiling (2) or roof element (7) with connector parts (3) for releasable attachment the end wall elements (4).

2. Modular container system according to claim 1, characterized in that in each case a connector part (3, 103, 203) has a groove (8, 208) with at least one parallel thereto extending bung (9, 209), so that in an assembled connector parts (3, 103, 203) existing connectors grooves (8, 208) and bounces (9, 209) engage positively with their contact surfaces.

3. Modular container system according to claim 1 or claim 2, characterized in that a) the side wall elements (5, 6, 105, 106) as a trapezoid having a lower base side (11) and a parallel to this upper base side (12) and two equal long trapezoidal legs (13) are formed, wherein the trapezoidal legs (13) and lower base side (11) each form an internal angle of greater than 90 ° degrees and thereby the surface of the side wall elements (5, 6, 105, 106) to the bottom floor (1) or floor slab element (2) tapers towards the top and Floor slab (2) or roof element (7) widened out, wherein trapezoidal connector parts (103) for connection with the end wall elements (4) along the trapezoidal legs (13) extend and have their inclination, and b) the side connector parts (203) of the end wall elements (4 ) for connection to the side wall elements (5, 6, 105, 106) have the same direction of inclination in order to connect to them.

4. Modular container system according to one of the preceding claims, characterized in that a common, inner side wall element (5, 105) is provided as an inner wall for each two space cells arranged side by side.

5. Modular container system according to one of the preceding claims, characterized in that all end wall elements (4) and the outer side wall elements (6, 106) of the container system form the outer walls of the container system.

6. Modular container system according to one of the preceding claims, characterized in that the inner side wall elements (5, 105) have plug connectors (3) with two bumps (9) and a double groove (10) arranged therebetween, so that in the connected state, the two bouncing (9) of the two connector parts (3) of two side by side arranged end wall elements (4) engage in the double groove (10) and each one of the two bends (9) of the inner side wall element (5, 105) in each case a groove (8) of the Connector part (3) of an end wall element (4) engages to connect two end wall elements (4) and to connect them with an inner side wall element (5, 105).

7. Modular container system according to one of the preceding claims, characterized in that the bottom (1), floor ceiling (2) or roof elements (7) as, preferably rectangular, plates each having a top (14), a bottom (15) and four side surfaces (16) are formed, wherein the connector parts (3) for connection to the End wall elements (4) in particular each on two opposite side surfaces (16) are arranged and extend the longitudinal axes of the groove (8) and bung (9) parallel to the side surfaces (16).

8. Modular container system according to one of the preceding claims, characterized in that the end wall elements (4) have an upper (3 ") and a lower connector part (3 ').

9. Modular container system according to one of the preceding claims, characterized in that for the bottom elements (1) connector parts (3) are provided with a groove (8) and a bung (9) on the top (14) of the bottom elements (1 ) are arranged so that the lower connector parts (3 ') of the end wall elements (4) on the upper side (14) of the bottom element (1) can be plugged.

10. Modular container system according to one of the preceding claims, characterized in that for the roof elements (7) connector parts (3) are provided with a groove (8) and a bung (9) on the underside (15) of the roof elements (7 ) are arranged so that the roof elements (7) with its underside (15) on the upper connector parts (3 ") of the end wall elements (4) can be plugged.

11. Modular container system according to one of the preceding claims, characterized in that for the floor slab elements (2) connector parts (3) are provided with a groove (8) and a bung (9) on the top (14) of the floor slab elements (2 ) are arranged so that the lower connector parts (3 ') of the end wall elements (4) on the top (14) of the floor slab elements (2) are pluggable and that for the floor slab elements (2) further connector parts (3) with grooves (8) and bouncing (9) are provided, which point at the bottom (15) of the floor slab elements (2), so that the floor slab elements (2) with its underside (15) on the upper connector parts (3 ") of the end wall elements (4) are pluggable.

12. Modular container system according to one of the preceding claims, characterized in that the side wall elements (105, 106) for the top floor in the contact region of the roof elements (7) fastening elements (17) for fastening the roof elements (7).

13. Modular container system according to one of the preceding claims, characterized in that the fastening elements (17) are designed as longitudinally extending thickening or longitudinal projection with a holding surface (20) for the roof elements (7), so that in the installed state, the uppermost side wall elements (17). 105, 106) exert a force on the roof elements (7) with the holding surface (20) by their weight and hold them firmly.

14. Modular container system according to one of the preceding claims, characterized in that the outer side wall elements (6, 106), a cover plate (31), which is preferably rectangular.

15. Modular container system according to one of the preceding claims, characterized in that the components of the container system at the locations or areas where they can come into contact with each other in the connected state, have a seal, preferably a hard rubber layer.

16. Modular container system according to one of the preceding claims, characterized in that the end wall elements (4) doors and / or windows (18).

17. Modular container system according to one of the preceding claims, characterized in that the side wall elements (5, 6) have passage openings or doors.