DE8914674U1 - Kit for the assembly of frame structures in the construction sector with associated building elements including profile frame supports - Google Patents

Abstract

A sectional bar with at least one rigid gusset is composed of a flat bottom (101) with two opposite legs (102) that extend at an angle to the bottom and end each along their top edge with a flange (103) that extends parallel to the bottom. The flange is if necessary provided along its outer edge with an edge (104) that forms an angle to the plane of the flange. The sectional bar is cut in such a way that a rigid gusset is obtained by bending around the bottom or the plane of the flanges. This makes the sectional bar useful for a variety of applications, for example a plurality of assembled sectional bars with a right-angled gusset form a mobile flood protection dam.

Description

Construction kit for the assembly-related production of frame structures in the construction area with associated column elements including profile frame supports.

The innovation concerns a kit for the assembly-based production of frame structures in the construction sector with building elements including profile frame supports with at least one frame corner and linear bars joined in a force-locking manner via a cutting figure or cutting edge elements.

The sowing kit according to the invention can be used in a technically advanced manner in almost all sowing areas due to the special figuration and modular coordination of the central component "profile frame support". This results in

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-Yes-

new construction methods and sow mills as well as new types of construction systems. The central construction element, the profile frame support, has an unusual variety of possible applications. This makes the technology so amazingly simple and can be used effectively in many areas of application. With the help of the sow kit according to the invention, new types of sow mills can be created, so that a contemporary, surprisingly simple construction phase is initiated.

The subject matter of the invention is illustrated in the drawing using examples.

Figures 3.1 to 3.12 show new modifications to the profile frame support in its corner, in longitudinal section and from below.

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Figures 3.13 to 3.22 present technical modifications for the joint of the profile bars, mainly in the area of the bars in the bar area and in the plan view of the*

Fig.3.2 to Fig.3.5 show further figurations of the frame corner formation, in bar length section, with the exception of Fig.3.23 and Fig.3.26, which show subsections.

The rig.. 3.48 to 3.51 represent the new installation method

Use in general building construction such as halls and residential buildings*

Fig. 3. 52 shows the elevation of the profile frame support as a central element in the use in parking garages and factory buildings, mainly above ground.

Fig. ^3.53 shows the functional combination of the profile frame girder in bridge construction, connected with cornice girders, railings and guard rails in bridge construction.

Fig. 3.54 to 3.56 show modifications of the profile frame support in the construction of earth-covered garages.

nie Pia, 3.57 and 3.58 show the use of the profile frame beam in building construction, where opening roofs, used primarily in greenhouse construction, can be created.

Fig. 3.59 shows the assembly method of a profile frame support in the case of a two-hinged frame with a central support, which is used as a lifting element.

Fig. 3.60 shows a profile frame carrier which is used for quick

u assembly is swung in as a bridge, equipped with f

Swimming chambers. l<

Fig. 3.61 and 3.62 show the profile frame support in plan view, in use as a bridge construction element for an inclined bridge.

The fin*3.63 bi» 3*bo represent a profile frame support with a corner, as a central element for mobile high water protection and mobile vessel construction.

Figures 3.81 to 3.84 show a profile frame girder as a retaining wall element in earthworks.

Fig. 3.85 to 3.99 show the profile frame support in its puncture as the only central component for the manufacture of above- and underground containers of any puncture type, such as silo goods, garbage can containers, bathing pools, puncture basins in sewage treatment plant areas and storage of liquids of any kind.

The variance of the profile frame support in terms of shape and structural echo triggers various modifications of the frame corner design to optimize the specific application. Accordingly, the solution to the problem of the subject matter of the invention is on the one hand limited mainly to the modules of the frame corner, on the other hand extended to almost all structural forms and construction tasks in civil and structural engineering.

In principle, essence, and important details the solution can be described as follows:

From a profile bar (1,2) with a central flange (3,4), free-standing flanges (5,6), with the connecting web (18) and with the final angle (17), a frame support at the corner is predetermined in terms of geometry for the future structure by means of cutting figures (15,16,23), either by only partially separating the bar via the cutting figure or by completely separating it for assembly reasons, in which case the ends of the separation are specially shaped towards the cutting figure (7,8,10,11,27,30). To improve the frictional connection and ensure the bending stiffness, additional connecting elements are introduced in addition to screw connections (14) and welding (14a) (9,12,13,20,21,19,27,29,193,1913,31,78,33,34,19C).

Ideally, and in solving most construction tasks, the beams are bent at the tendons (7*9 or 10, 11) according to the frame angle and pressed together during assembly by screws (1^) or welding (14a). The ends can also be held together by additional compression elements (9,7.a, ). Tension and compression elements can also be used (20,21,33,3^,36), depending on the optimized construction process or the favorable construction form. The beams are then stretched and the final construction lengths are then restored by joints. In order to utilize the cross-sections in the joint, the areas are not reduced by screwing, etc. On the other hand, the surface to be butted is supplemented by welded-on metal elements (25, 25a, 25b, 25c and 25d) which are held in connecting plates (Zk) and transmit the impact forces across the butt joint. The connecting plates are pressed onto the surfaces to be butted by screws (lk) .

Instead of welded-on force elements, the end faces can be cam-shaped (27) to provide a force-locking effect. The connecting plates can also be clamped to the end faces (97\ ).

can also be used for the force-locking connection in the frame corner.

Mainly when using the profile frame beam in general building construction, additional forms of frame corner formation are particularly advantageous. The installation of the bar with the upper central flange (3,4) promotes the bending (17) towards the central axis. When bending the frame corner, the angles, cut like the webs (18) and the free-standing flanges (5,6) interlock and accommodate the connecting elements (14,14a) for the frictional connection. The frictional connection in the central flange (3,4) or in the free-standing flanges can be created by pressure and tension elements such as preferably screws (33,36).

the connection is made with support brackets (34). Instead of screws (36), special bolts (19©) can also be used to ensure the force transfer in a separate flange. In general building construction, such as hall construction, house building, the profile frame girder is preferably installed with the central flange (3**0) facing upwards. The final angle (17) represents the support for the surface-forming supporting structure for the individually installed girders. The surface-forming supporting structure then supports the ceiling, roof or south (4l,«2/. It is preferably a beam (4o) which also supports the ceiling (44) with insulation (43). In simple hall construction, the central flange can also be installed downwards and the final angle (17) can be angled in the area of the support of a purlin (40a) or the supporting leg of a roof covering (Ala) for fixing. The inherent rigidity of the profile frame girder in each bar axis is so high that it is so stable as a frame that it no reinforcement to the main trad axis is required. This means that a hanging element (45) or another movable roof (46) can be used between the individual free-standing profile frame supports to divide the surface. The stability is increased by the purlins (4o, 4Oa) or by the roof covering (4la) or by a special cross member (5a).

In residential building, each frame takes on the load-bearing function for an entire floor (la, Ib). The load-bearing structure consists either of individual frames that are mounted to one another in a force-locking manner or of a main frame from the foundation (47) to the ridge, to which separate frame supports are then inserted for the individual floors (la).

g In garage and factory building construction, the frame carrier

as in bridge construction wall and ceiling function (lb).

It can be arranged in a row, as in bridge construction, or it can be used as a free-standing frame, with the area formation between them being taken over by special load-bearing elements (4l, 4la). The frame can be single-span or multi- span. can be represented in a field manner using pendulum supports (48).

The stiffening traverse (5a.) tibernicamt in bridge construction
mainly at the edge beam additionally the task of j holding the cornice beam (49) of the bridge railing (49a) &Aacgr; and the guard rail post (49c) in such a way that a Ii rigid standing rod (49b) is placed on it. Ij

The crossbar (5&) is screwed to the angle (17) (l4),
The profile frame support is also used for single and
multi-row, earth-covered garages, where he either
as a single-corner frame (le) rigidly attached to a foundation structure
as sheet pile wall (47a) or as a two-corner frame
(Id), where it represents floor, wall and ceiling, or similar to a bridge construction as a square frame, or generally as a polygonal frame. This type of construction is also used in protective construction.

The profile frame support is also used in the areas
where it is a movable frame that allows the roof to be opened ( 50,51). It can be designed in several parts, in an upper leg (li,) in a lower leg (1 g) and
in a corner part (lh). The opening in the foundation is secured
by a joint. The opening of the roof (50) is
a lifting and pulling device (51) ensures that
the space of the frame corner is installed, whereby then a /

Joint (20,21) allows the rotation. The leg for I, the Vand (lk) is then firmly attached to the foundation. | The design enables a quick assembly of bridges in such a way that the locking part can be
polygonal frame (1,2) is either raised, or
in the area of the later fundaaentee print (50b)
is used or in the case of multiple spans the pendulum support (48a) § is used as a lifting element (50a) which receives tensile forces. When mounting the profile frame support
for water bridges, one-piece rod parts,
Preferably the middle bar is attached to a floating body
by dense bridge» (52) #*fl» or only partially developed« as well as the later Pundaaente also old
Visual bodies (51)« ·» which either pressure is exerted
is used to trigger the transition (50) or to open the frame

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The frame girder also allows the inclination to be reduced in bridge construction. Ep (2) is separated into a wedge-like edge girder (2a) which is then finished off and given stability by a cornice girder (k9) . The extent of the inclination determines the number of wedge girders (2a, 2b). The profile girder with an ice-sweet corner has a particularly wide range of applications. The support on the air side (35) is given different shapes and additional elements (5 _** at5^b _f £*M;,56, 54e, ⁵¹ »«!, 57.57 _^ ,58,59.61 and 62) depending on the conditions of use. In the case of mobile flood protection, the closing angle can be supplemented by additional legs (63), which are pressed together by a bracket (66) in order to make screwing unnecessary, whereby the joint space is tightly closed with sealing elements (67 , 67 a, 67 e). The additional legs can be given different shapes (63 a, 63 c). The bracket (66) is then modified accordingly (66a, to 66 c). As a mobile vehicle, the frame girder is used in a linear or curved manner transverse to the direction of flow (70) on the base (72). In the embankment area, it can be given an additional abutment structure (71a). The frictional connection in the base can be improved by webs (56) or wedge stools (57b), or bearing profile bars (61) supported by piles (62).

For mobile weir construction, the profile frame support (1,2) is also used in such a way that a horizontal linear rod (73) supports it in a bend-resistant manner, so that it acts as a wall with its protruding leg (2). The horizontal rod (73) can be partially shortened in the toa basin area so that openings (74) are created to relieve the bottom water pressure. The toa basin closure can also be made using a profile frame support (1,2).

The cross-sectional shape (3,4,5,6,18) of the profiled sheet allows the installation of a fish pass in a particularly advantageous way by cutting open the central flange (k) and bending it against the direction of flow (70), the space between the central flange (4) and the webs (18) is formed by a cover strip (75) in a flow pipe, whereby the deck wall in the bottom area is bent in a flow-dynamically favourable manner against the flow depth (70) so that the above -ground water reduces the outflow into the underwater area and causes a loJc flow (76) which becomes a steering channel (77) which offers mobile ¥e*i2 l>au. I also particularly recommend that the The profile frame support simultaneously represents the supporting element for the combined turbine (78) and the turbine receives the water flow through flow channels in the area of the profile frame support and releases it into the downstream water.

The profile frame girder is particularly suitable for supporting tasks in earthworks. Its bearing conditions can be secured or improved or adapted to the special soil conditions by bearing profiles (6*1) or by horizontal profile bars (73) or sheet pile walls (47a), whereby one leg (2) then takes on the cantilever function and the other leg (l) the wall function. The earth pressure is directed directly into the ground. The individual frame girders can be installed in slats in simple construction operations*

The profile frame girder is used in tank construction mainly in its form as a double frame with different leg lengths, both for quick assembly for above-ground tanks or basins and for underground tanks or basins. For elevated tanks, the bar (2) runs vertically, the legs (l) form floor troughs as a cover. The front sides are linear bars (Sd) where they are extended in the corner areas and take on the supporting function and rest on the floor.

f-_*A*iJ irtihfriWtWjilj'*-*·

In the ceiling area and in the funnel area, the legs (i) are coupled in a tension-resistant manner by tension elements (80,81). Earth shafts are equipped with two-corner frames in such a way that the bar forms the floor in one axis (2) and the legs (l) direct the earth pressure to the floor. These earth containers are particularly suitable for the additional accommodation of a garbage container that has the profile Tävme aasful.lt (1 l)» This can be filled from above (86) and can have a lid (85). Emptying is preferably carried out by removing the container. The disadvantageous above-ground installation is avoided.

The underground containers can also be more structured; the lid can be a frame support combination. The container spaces can also have horizontal floors and covers in which the legs (l) are at right angles to the bar.

Depending on the function, the abutting profile frame supports are sealed in the angles (17). Elastic sealing elements (88, 88 a, 88 b) are pressed into the abutting surfaces. The pressing force is introduced via brackets or profile bars (89). The joints in the bar length axis are solved by covering the joint space with profile tabs (90, 91) on both sides, giving the joint space a seal (88b), and giving the profile tabs openings in which force transmission elements (92) are inserted, which are firmly attached to the end areas of the flanges, preferably by welding. Screws (14) in the joint space press the profile tabs onto the abutting surfaces.

Polygonal containers are also assembled using biangular or polygonal profile frame supports in such a way that they are installed in a bearing-like manner and form a closed wall element in sections. The leg lengths are preferably unequal (1 m, In,) and are joined together in a force-fitting manner. Each corner side can be formed either by bars (2) or by the two unequal length legs (In, In). Special functional containers with special wall shapes are made 1» of the

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The walls are structured in such a way that their sides (Ip, Iq, Ir) have the functionally determined lengths. The walls thus formed for rainwater treatment or similar functions receive linear profile bars as soil protection, with their aheights (83) running parallel to the direction of flow.

Claims (1)

· Dipl. Phys. H. Seidel "'**""' PoU, »ta&eegr;vv&agr;IHn Datura: 20.3.90 K ¹ MM^l &igr; ¹ " ⁶ ""··!" Characters: 970/009 Kr. Muliid jfi. Inn Tel. 08637/883 AZ: 6 89 14 674.3 Protection claims 3.1. Kit for the assembly of frame structures in the construction sector with building elements including profile frame supports with at least one frame corner and linear rods joined in a force-locking manner via a cutting figure or cutting edge elements, characterized in that the profile rod (1, 2) always has a special cutting figure in its web (18), either in the central flange (2, 4) or in its free-standing flanges (5, 6) or in both flanges to form a rigid or articulated frame corner and all, or at least one cutting end is or is bent in the alignment of the post (1) or the transom (2) and the bending angle of the rod originates either in the central flange (3, 4) or in the edge flange (5, 6), and the overlapping, also angled ends (7, 8 or 10, 11) are connected by screws (14) or welding (14a) to Bending stiffness or have a shock pressure surface for flexibility. 3.2. Kit according to claim 1 ₁ , characterized in that between the flanges (3,4,5,6) and the webs (1Θ) along the edge a sectional figure which runs along a flange (15,16), and the cut ends (7,9)Vand/or _the other flange has the cut ends (10,11JiTIn the alignment of the bolt (2) or the stem (i) bent and at least one abutting surface is guided in a retaining angle (9). 3.3. Kit according to claim 1, characterized in that a cutting surface abuts against a holding element (12 or 13). 3.4. Kit according to one of the preceding claims, characterized in that the cut ends have friction-locking joint tabs (20) with joint bolts (21). 3.5. Kit according to one of the preceding claims, characterized in that the cut ends are bent and the outer surfaces touch each other as angles and are held by screws (14) or a holding profile. 3.6. Construction according to one of the preceding claims, characterized in that the
Cut ends are non-positively connected to the flange ends by means of cut supplementary elements (19), whereby the web is cut at an angle. 3.7. Kit according to one of the preceding claims, characterized in that the ends of one flange overlap (eg 7,9) and the ends of the other flange are butted and
are force-locked to an additional element. 3.8. Kit according to one of the preceding claims, characterized in that one flange end (8a) is angled and the flange end abutting thereon is fastened by welding (14a). 3.9. Kit according to one of the preceding claims, characterized in that the joints in the bolt (2) or in the stem (1) are formed by force elements (25 to 25d) which are applied to the flange surfaces. V welded and inserted into connecting plates (24 to 24d) and the impact forces are transferred across the butt joint, whereby the connecting plates (24) are secured by screws (14)
are printed on the contact surfaces. ä- - 3.10. Kit according to one of the preceding claims, characterized in that the abutting areas are deformed in the manner of cams (27) and connecting plates have cams (27) of the same shape. 3.11. Kit according to one of the preceding claims, characterized in that the cut ends on the corner of the frame have cams (27) and are pressed into one another by screws (14). 3.12. Kit according to one of the preceding claims, characterized in that the cams are held at the cut ends by connecting plates (29) which hold the ends of the cut surfaces. 3.13. Kit according to one of the preceding claims, characterized in that the central flange (3,4) is bent and the free-standing flanges (5,6), the web (18) and the angles (17) are cut and connected by screws (14) or welding. 3.14. Construction according to one of the preceding claims, characterized in that the · cut, non-angled flanges are coupled together in holding elements (13) or clamping elements (19,9). 3.15. Kit according to one of the preceding claims, characterized in that a cut surface lies in a notch, and that a reinforcing member (31) is arranged in the notch area. 3.15. Kit according to one of the preceding claims, characterized in that the cut surfaces are connected in a force-locking manner by screws (33, 36) and are guided in holding brackets (34). 3.17. Kit according to one of the preceding claims, characterized in that the profile frame support (1, 2) with its central flange located at the top and the free-standing flanges (5, 6) with the leg (17) for flat-forming support structures (40 with 41, 42, 43, 44) located therebetween forms a Tx>ag element. 3.18..Kit according to one of the preceding claims, characterized in that the individual profile frame members (1, 2) are connected either by a suspension system (45) or a movable truss (48). 3.19. Kit according to one of the preceding claims, characterized in that the profile frame supports (1, 2) are connected to the angles (17) by transverse purlins (40a) or roof elements (41a) or by traversals (5a) via screws. 3.20. Construction kit according to one of the preceding claims, characterized in that a support unit is formed from individual beam supports and other beam supports , which can be used as a storey in building construction. 3.21. Kit according to one of the preceding claims, characterized in that a 'supporting unit with a profile support is formed as an individually acting central support element with surface-forming, transverse supporting elements (41, 41a), the frame being designed as a single-span or as a multi-span structure by means of pendulum supports (48). 3.22. Kit according to one of the preceding claims, characterized in that the profile frame support is connected as an edge support in bridge construction to a traverse (Sa) which carries a sill support (49), the railing (49s) and the guide rail (49c). : ■■.* "J 3.23. Kit according to one of the preceding claims, characterized in that the Profile frame supports as single-corner, two-corner or multi-corner is designed, and d ^r 3 the cantilevered part (Ie) serves as the ceiling of a mobile garage room or as a two-corner frame (Id) forms the floor, wall and ceiling of a mobile garage or as a polygonal frame forms an entire mobile garage or shelter (If). 3.24. Construction kit according to one of the preceding claims, characterized in that the profile frame support is multi-articulated, with an upper leg (Ii) serving as a roof or as a transom, a lower leg (Ig) serving as a wall or as a post, which are connected in a force-fitting manner by a corner part (la). &Ggr; 3.25. Kit according to one of the preceding claims, characterized in that || a mobile profile frame carrier, which is used for greenhouses and sports halls, in the roof apex a for openings movements (50) suitable lifting element (52) is attached. 3.26. Kit according to one of the preceding claims, characterized in that the wall part &igr; (Ig) has a joint. &bull; . i , -B- 3.27. Kit according to one of the preceding claims, characterized in that a swivel joint (20, 21) is arranged in the flange of the wall part (Ik). 3.28. Kit according to one of the preceding claims, characterized in that in a mobile frame construction for bridging water surfaces, the bar is completely or only partially designed as a floating body (52) and the foundations (51) designed as a box serve as additional floating bodies. 3.29. Kit according to one of the preceding claims, characterized in that the profile frame supports are connected to one another to form a mobile inclined bridge, the bar of one or more profile frame supports (2a and 2b) being cut at an angle to form a wedge (2a, 2b) which is closed off and stabilized by the cornice support (49). 3.30. Kit according to one of the preceding claims, characterized in that a single-cornered frame with a bearing leg (1) rests on two bearings (54, 55) in a tilt-proof manner and is connected to a wall leg (2) forms the storage function when the frame is used for a mobile flood protection system, whereby the individual frame supports are to be tightly connected via specially shaped angles (17b) and the free-standing flanges (5,6) are positioned downwards and the central flange (3,4) serves to cover the drainage cavity. 3.31. Kit according to one of the preceding claims, characterized in that the sealing bearing (54) is formed by a bearing part (53a) which rests on an elastic profile (54, 54a, 54c, 54d). 3.32. Kit according to one of the preceding claims, characterized in that the bearing is designed as a vertical web (54e) which is connected to a sealing apron part (56) via a seal. 3.33. Kit according to one of the preceding claims, characterized in that an elastic element (55) is provided as the main bearing, which is inserted into a Z-profile (57) and that spurs (59) are inserted into the element (55). - 10 - - 10 - 3.34. Baiftatz according to one of the preceding claims, characterized in that the apron part (56) is shaped like a sawtooth (5B) downwards. 3.35· Kit fish 5&idiag;&pgr;6&iacgr;&idigr;&idigr; uST VGrsngsriSifusn nrispruchs, dsdurch characterized in that a linear profile bar (61) serves as the main bearing. 3.36. Kit according to one of the preceding claims, characterized in that the closing angle (17b) is provided with additional legs (63 to 63c) and the coupling leg has a counterpart leg (64 to 64b), the intermediate space being filled by a sealing element (67 to 67e) which is pressed by a bracket (66 to BBc) which is adjustable in the pressing effect (66a, 66b). 3.37. Kit according to one of the preceding claims, characterized in that the profile frame support (1, 2) is pre-assembled in an arched shape with triangular additional elements which are inserted into its leg areas and, if necessary, interact with an abutment (71a). - 11 - &bull; ft - 9 § &igr; t &PSgr; --· - 11 - 3.38. Construction according to one of the preceding claims, characterized in that the profile frame supports are connected to form a support unit by a cap profile (60, 60a). o.ja. Dsusacz after a wide range of springs, a a characterized by that the main bearing is a wedge stool (57b). 3.43. Kit according to one of the preceding claims, characterized in that a plurality of profile frame supports (1, 2) in conjunction with horizontal linear profile bars (83) resting on the profile frame supports form a mobile weir, the bar area being designed as a stilling basin, and shortened bars forming openings for the relief of bottom water pressure and a smaller profile frame support closing off the stilling basin. 3.41. Kit according to one of the preceding claims, characterized in that that to form a mobile fish pass of the central flange of the damming stem (4) towards the sole :' is cut open and bent and that a cover wall (75) together with a web (18) and the central flange (4) - 13 - - 12 - forms a flow tube, wherein the cover wall (75) in the i lower area is bent and an opening is free- ■■'■> ')■ through which the attractant current (76) for the fish pass 1| can flow, which can be extended by control bodies. |J ')■ 3.42. Sow kit according to one of the preceding claims, characterized in that the
mobile weir is coupled to a turbine (78) which is
the stem (2) of the profile frame support and that an opening for the driving water for the turbine (78) :■, is provided in the stem (2). 3.43. Construction according to one of the preceding claims, characterized in that profile frame supports (1,2) are connected to form a lamella-like earth retaining wall which is supported on a profile bar (61). 3.44. Construction kit according to one of the preceding claims, characterized in that the profile frame support with a thin lower leg (1) as a bearing
and its bolt (2) is designed as a wall and is connected to the
counter-rotating stem (2a) takes over cantilever function. - 13 - 3.45. Kit according to one of the preceding claims, characterized in that the vertical leg of a profile support is designed as a wall and the other leg (2) as a cantilever arm. 3.46. Batiitz according to one of the preceding claims, characterized in that two-corner frames are connected to form a mobile high silo in such a way that the bar (2) and the vertical wall and the posts (1) form the sod hopper and the cover, whereby the opposite supports are coupled in a bending and tensile-resistant manner at the ends of the posts, and in the corners the bars are extended linearly and thus form the supporting tips of the structure (82). 3.47. Construction kit according to one of the preceding claims, characterized in that in a square mobile high silo the funnel and the bottom are formed by oblique cuts in the stems and in the case of an elongated cross section the front wall (83) is formed by linear rods, the rods serving as supports (82) in the edge region. 3.48. Construction according to one of the preceding claims, characterized in that biangular · · I - 14 - Profiled frame supports are used to form mobile earth cavities, with their bars forming the floor and the posts forming the walls (1). 3.49. Construction kit according to one of the preceding claims, characterized in that mobile earth cavities formed with profile frame supports {1.2} are provided with a cover (8&>. 3.50. Kit according to one of the preceding claims, characterized in that in the case of earth containers formed with coupled profile frame supports, the bar (2) runs vertically and the diagonally or horizontally running posts (1) form the floor and ceiling. 3.51. Kit according to one of the preceding claims, characterized in that profile frame supports used in mobile container construction are sealed in their angles (17) with elastic sealing elements (88, 88a) which are held by screwing or pressing brackets. 3.52. Kit according to one of the preceding claims, characterized in that the cross joint of profile carrier yarns by two-sided profile - 15 - - 15 - tabs (90,91) which cover the joint space into which a seal (88b) is inserted, where the profile tabs (äü, $i) are pressed onto the joint surfaces and force-fittingly grip force transmission elements (92) which are force-fittingly attached to the flange surfaces, preferably by welding. 3.53. Kit according to one of the preceding claims, characterized in that a plurality of profile frame supports form polygonal winches for containers, whereby either the bar (2) or a shorter and a longer post (Im ₁ In) form a corner wall and the supports are coupled in a force-fitting manner at the ends of the posts. 3.54. Kit according to one of the preceding claims, characterized in that the fcck walls are of the same length or of different lengths (Ip, Iq, 1?). 3.55. Kit according to one of the preceding claims, characterized in that ;, _: elongated functional containers the linear profile bars (83) form the bottom and the rod axis is parallel to the container axis.