DE8137353U1 - Transverse wall for railway wagons, in particular sliding and lockable partition - Google Patents

Description

FROM KREiSLER "SOHOHVSAtD '.E1SJH.OLD FUES FROM KREISLER KELLER SELTING WERNER

PATENT LAWYERS Dr.-Ing. by Kreisler 11973

Dr.-Ing. K. Schön wold, Cologne

Dr.-Ing. K. W. Eishold, Bad Soden

Dr. J. F. Fues, Cologne

Dipl.-Chem. Alek von Kreisler, Cologne

Dipl.-Chem. Carola Keller, Cologne

Dipl.-Ing. G. Selling, Cologne

Dr. H.-K. Werner, Cologne

December 18, 1981 Sch / Sd

DEICHMANNHAUS ΛΜ MAIN RAILWAY STATION

D-SOOO COLOGNE 1 Theodor Wuppermann GmbH, Friedrichstrasse 38, 5090 Leverkusen

Transverse wall for railway wagons, in particular sliding and lockable partition

The invention relates to a bulkhead for railway wagons, in particular a sliding and lockable partition wall, the supporting structure of which is vertical side posts "nd has extending between the posts, with the side posts firmly connected spars, on both sides of the Partition wall paneling made of panels made of wood, plastic, metal or steel is provided.

In covered railway wagons, the side walls of which can be opened up to half the length of the wagon, are slidable and lockable partitions are used as transport protection for the cargo, so that the cargo without its own Lashing down during transport in the longitudinal direction of the wagon cannot slip, which is the case with the load in many cases it is a matter of palletized goods, the transverse wall

Telephone: (022i) ^j raJ041 - Te \ e *: 'sSS2 & i7 dopa i , Telegram: Dompaien! Cologne

or partition wall of the load corresponding to a load of about Withstand 5 t at an impact speed of the wagon of at least 11 km / h, the area of the middle point of application of force through the load is between 40 and 120 cm high. The total weight of the bulkhead or partition should not exceed 200 kg.

A known lockable partition has vertically arranged side posts made of rectangular hollow profiles and between them lying horizontal spars as squared timbers, which are connected to the side posts with special clamps. At both On the sides of the scaffolding, the planking consists of screwed-on plywood panels. Another lockable partition consists of circumferential U-profiles and a slat-like frame made of wood with glued-on plywood panels.

It is also known to use light metal extruded profiles as multi-chamber hollow profiles for lockable partitions. The supporting structure has four extruded profiles arranged horizontally one above the other and two laterally vertically arranged extruded profiles, designed as multi-chamber hollow profiles with a truss structure are. In another known embodiment made of steel, the partition wall consists of laterally arranged vertically Rectangular hollow profiles with trapezoidal profiles lying between them.

In these known designs it has been found that, taking into account the permissible dead weight for the entire partition wall this the required load cases as well as the load cases occurring in practical operational use does not withstand. Bulges and wrinkles appear. Sometimes there are also cracks on the outer skin of the bulkhead.

The object of the invention is to create a transverse wall or partition for railway wagons of the type mentioned, which can withstand the required load bearing capacity, taking into account the weight limit, and which has sufficient buckling strength and flexural strength. The bulkhead | or partition wall of the initially mentioned type is characterized by DA I from that for spars profiles with infrequent% least partially located at least twice or at least gedoppel- - ■ th flanges are provided, in which the surface of the load Flansehe The subject area of the transverse wall or partition is facing and the thickness ratio between web and flange is at least 1: 2.

By using these profile shapes in a special direction With regard to the loading effect on the transverse wall or partition wall, there is an extraordinary increase in Cross-sectional parameters achieved with high inherent rigidity, but also high deflection due to an impact load, that the high moment of inertia at the moment of loading is supported by the surface friction between the individual profiles is caught elastically. There is an accumulation of material due to the double lying or folded flange parts specifically only available in the places where this is required in terms of stress. In addition, it follows from the other, less stressed areas a significant material saving. This allows the opposing demands of a high buckling strength and flexural rigidity can be met with a substantial weight saving. It is a big Load carrying capacity in relation to the force acting vertically on the surface of the transverse wall or partition wall with simultaneously achieved weight minimization guaranteed.

According to further features of the Erfinduncr may involve individual profiles or profiles to act composed cius the plurality Einzelprofi-> _k len, wherein each profile having a U-shape or Z-shape%. The profiles with their of- '-. fenen sides be arranged butting against each other. \

A special and expedient embodiment consists in that each two profiles are nested in mirror image, with the individual profiles having the same outline dimensions own. This has the advantage that one and the same profile is used for nesting. One can get the outline dimensions The size of the profiles to be nested also differ. In both cases there is a duplication the surface facing the transverse wall through a flange of each of the nested profiles. At least one Flange of a profile for itself have a doubling, so that the side of the overall profile facing the transverse wall is more as a duplication of the flanges. The embodiments of the profiles with the same outline dimensions have the essential advantage that for doubling or multiplying a.o.:g the flanges only a single profile is required, which reduces manufacturing costs and storage.

In a further embodiment, the profiles in their Be nested in one another in the longitudinal direction and have mutually adapted outline dimensions.

When doubling the flange of one and the same profile, the invention further provides that the deflection of the flange of the profile made of metal, e.g. steel, light metal, plastic, etc., if used as a single profile, arched, runs triangular or polygonal. Such a triangular guide acts at the deflection point of the Profilbandps similar to a framework structure, with the forces acting on it being absorbed by a sub-girder structure and transverse to the main load be derived. Advantageously, the folded flange leg extends so far that it is just before the web of the Profile ends. This improves the buckling behavior and increases the load-bearing width of the flange. Furthermore can the folded flange leg of the profile band have at least one bevel, which increases the load-bearing capacity

contributes perpendicular to the wall surface of the transverse wall. The flange parts of the profile spar can be doubled also have a multiple deflection. The profiles can also be Z-profiles with a vertical or angled web and be doubled or multiplied flange parts. Preferred cold steel profiles are used.

The nested profiles are expediently U-shaped and the open sides are plugged into one another. Here the one flange of the profile can have at least one inwardly directed bead. In addition, e'er can other Flange of the same profile also folded over at least once get lost. This gives an extraordinary absorption capacity for those acting on the transverse wall or partition wall Charges.

A further improvement of the property results from that the flange has an inwardly angled leg at its edge, one such flange leg can be designed to be folded over one or more times. In this way, the buckling resistance of the flange and the load-bearing width of the lben is also advantageous elevated. A further improvement in the buckling behavior of the transverse wall or partition wall can be achieved by introducing sinks Reach into the web, which are also band-shaped bindings can be formed, creating an orthogonal plate effect. This also improves the elastic shock absorption behavior effectively increased.

According to another feature of the invention, the profiles are provided with inwardly extending cranks between the web and the flange, which serve to hold planking parts. These cranks are preferably undercut, i.e. slightly inward, so that the cladding can connect tightly to the flange of the profiles without machining the end face.

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The cladding plate can be fastened to the rail profile in the area of the flanges of the profiles or in the area the crankings receiving the planking may be provided. This means that the planking also serves as an integral part Part of the wall construction. In addition, a further weight advantage is achieved through the interaction of the two structural members. This has a particularly beneficial effect on - for Support profile seen - unilateral load application, as is the case in most cases with the type of stress at partition walls occurs. In this case, the rigidity of the cladding plate, if it is thin-walled, by beads or the like. increase.

To reduce weight, cutouts can be made, especially in the profiles of the posts of the transverse wall or partition wall are arranged, which expediently according to the shear stress line are to be provided in a distributed manner. The holes can be closer to each other in the center of the post and get after outside a larger hole spacing from each other. These holes can be round, polygonal or square with rounded edges Corners be formed. The edges of the holes can be given an inwardly pointing bend.

For the steel profiles, it is advisable to use a high-quality steel

2 good ones with a yield point greater than 500 N / mm with high Extensibility used. As a result, a weight reduction can also be achieved and the continuous Individual impacts from the load can be absorbed even better elastically.

The invention is explained below with reference to the exemplary embodiments shown in the drawing.

1 and 1a show a cross section through a railroad car with a sliding and lockable partition

according to the invention, in the scheme. Fig. Ib is a partial section along the line I-I of Fig. 1. Figs. 1c and 1d show modified ones Profiles for Fig. 1b.

Fig. 2 to 6 show cross sections through the transverse or diagonal bars of the transverse wall to the partition, the Fig. 2a to 6a spars made of two opposing steel profiles represent.

7 to 12 illustrate steel profiles for the spars of the transverse wall or partition wall in connection with inserts glass fiber reinforced plastic on the flange parts of the Profiles.

Figs. 13 and 14 show examples of the connection of the skin panels with some profiles of Figures 1 to 6 in the scheme.

15, 15a, 16, 16a show a transverse wall in detail with Z-shaped profiles and at least doubled flanges.

FIGS. 17 to 20 illustrate exemplary embodiments of the connection of the spar profiles of a transverse wall or partition wall with the cladding plates in the scheme, FIG. 18 being a view in the direction of the arrow XVIII in FIG.

Figures 21-25 illustrate examples of profiles in which the profiles are of equal outline dimensions across to inner Longitudinal axis are nested together in order to achieve at least a doubling of the flanges.

26 to 35 show profiles of spars and posts of the transverse wall, which are put together in the longitudinal direction, pushed one inside the other are.

In a covered railway wagon 1 with a roof 2 / a loading area 3 and with sliding walls 4 on the sides, a partition 5 is arranged to be slidable in the longitudinal direction of the wagon * The partition 5 is attached to a shaft 6 and transversely by means of running wheels 7 on rails 8 can be moved to the partition wall surface. It has an actuating mechanism 9, by means of which the adjustable pins 10 and 11 can engage in the perforations of locking rails 12 and 13, whereby a locking of the partition wall 5 against plane-parallel displacement is achieved. The partition wall serves to secure the load located between the partition walls or a partition wall and a transverse wall of the wagon against slipping in the longitudinal direction of the wagon. The partition wall must be able to withstand a load resulting from 5 t of charge acceleration corresponding to 20 t of boost pressure at an approach speed of the wagon of 11 km / h without permanent deformation or bulging.

The transverse wall or partition 5 has a support frame made of vertical posts 15 and transversely or diagonally extending spars 16, 16a, which consist of cold profiles 17, which inward have flanges 18 extending over and are located on a web 19. The surface 20 of the flanges with their folded over The tape guide faces the surface of the transverse wall or partition wall that is subjected to the load 21. The thickness ratio between web 19 and flange 18 is due to the doubling of the same 1: 2 and can be repeated when the Flange leg 18a can also be increased to 1: 3 or 1: 4. The ratio of the flange width to the web height is advantageous about 1: 2. The deflection 22 of the flange 18 should be seen in section - arcuate, essentially triangular- or run polygonally, so that there is a framework effect. At the same time it is due to the arch-shaped Guiding the steel strip a gentle forming treatment

as well as higher elasticity achieved through softness in shape. The significant increase in the cross-sectional parameters is essential with respect to the force acting through the loading direction 21. Fig. 4 shows a profile in which the flange leg 18a is returned to the flange 18 after the deflection 22 to the parallel course, the leg 18c with can be fixedly connected to the flange 18, for example by riveting, spot welding or the like.

The web 19 is advantageously given band-shaped indentations 24 or beads 23, whereby the bulging behavior of the partition wall is essential is improved. The beaded flange 18 can be formed on the flange leg 18a by one or more folds 18b are stiffened. Such a stiffening hinders the movement caused by e.g. bending loads on the profile of the flange 18 to the central axis of the profile and thus increases the load-bearing capacity considerably. The folded thigh 18a of the profile band is expediently guided up to just before the web 19. Here, the flange leg 18a can with a fold 18b are guided into the corner of flange part 18 and web 19, the bead 23 as a contact surface can serve for the fold 18b. The bars can be perforated to reduce weight.

As shown in Figs. 2a to 6a, the steel profiles 17 can be connected to one another with the open sides, e.g.

by line welding 26, this results in addition to the already existing advantages nor the advantage of a high torsional rigidity as with all hollow profiles, in the present one Case with the essential influence of the at least doubled flanges with the result of an adequate increase the bending stiffness in the desired uniaxial direction in the case of the transverse wall or partition.

\ Fig. 7 to 12 show profiles 28 with strength and load-bearing

'!' · Ability-increasing effect through the use of insoles

29 made of high-strength glass fiber reinforced plastic material

'■' in combination with the steel profile. The insert 29 can be in the form

of strips and ribbons or cords and the like. The connection of these inserts 29, 30 made of plastic with the steel can by gluing, clamping, screwing, riveting or the like. be made. In the embodiment 11, the flange 28a is provided with beads 28b, in which the cords 30 made of glass fiber reinforced plastic are stored. Advantageously, the high-strength fiberglass-reinforced Plastic material has a tensile strength of 1500

2
N / mm and thus far surpasses the high-strength steel. The creep rupture strength is with 70% also as a

look very high strength value. The Ε module with 50,000 N / mm has a ratio to steel of approximately 4.2. Because the break is always in the tensile zone when the high-performance composite material is subjected to flexural tensile testing, the flexural strength can be at least can be equated with tensile strength. In the further connection with steel, which at the same time the externally Can take on protective function, ijine will be great improvement the load-bearing capacity of the cross-section is achieved without the weight of the construction as a result of the opposite To increase steel of low specific weight significantly.

The result is a composite cross-section of the spar or post profile with extreme light weight and maximum achievable tensile strength and flexural rigidity. The deposits off the plastic material mentioned can also be used as a tendon for the construction of the transverse wall or partition wall will. As a result of the considerably higher strength compared to steel, a high preload can also be achieved.

13 and 14 are examples of the manner in which the skin panels 32 are specifically designed as an integral part the wall construction are provided. The attachment of the

The cladding plate 32 with the spar profile is at least in the area of the deflected flange leg 18a of the flange

18 carried out. The attachment points |

% 33 and ö4 within the width of the flange of the steel profile, whereby the folded flange leg can also be included. Through this measure, a further weight advantage is achieved through the interaction of the two structural members as a result of the targeted connection between the supporting structure and the planking. The connection can be a line weld, spot weld, screw connection, rivet or the like. be. The support profile cross-section is increased considerably by the respective load-bearing width 3 5 of the cladding panel. The result is a restraint that has a beneficial effect in that both the Fcldmomente are greatly reduced, and a four-sided mounted plate with its favorable torque distribution is created. In addition, the load-bearing behavior of the connected structural parts is effected by influencing the load deformations, which is to be calculated as a rotary bedding. This has a particular effect in the case of one-sided load application - seen in relation to the support profile - as occurs predominantly with the type of stress on partition walls. By utilizing the rotary bedding effect, the result is that a rotation of the individual profiles, the axis of rotation of which lies outside the profile when the profiles are open in the pushing means, the rotation is suppressed in accordance with the rigidity of the cladding system.

The cladding plate 37 can advantageously be used for this purpose are additionally stiffened by beads 38. This achieves a very high overall torsional rigidity (Figs. 17 and 18). FIGS. 15-16a show line profiles of Z-shaped cross-section.

In the embodiments of FIGS. 19 and 20, with regard to the use of the cladding plate alc inte-

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As an integral part of the wall construction, a basically similar effect is achieved. In these steel profiles, the doubled flanges are offset by cranking, as shown in the case of the flanges 41 of the cold profiles 40, the load-bearing profiles extending to the outer edge of the planking to increase the load-bearing capacity. The offset flange legs 41a are firmly connected to the cladding plate 32 at least by means of a fastening device, for example a screw or a bolt. Even a single fastening point between the stepped flanges 41a and the cladding plate 32 already produces a restraint or rotary restraint effect, since in each case a counterforce builds up and causes a restraint. As a result of this effect, the cross-sectional shape of the flange ends is preserved, the support profile is stabilized and thus fully used for carrying. With this arrangement, too, the load-bearing capacity is increased by using a load-bearing width of the cladding panel.

In the exemplary embodiments of FIGS. 21 to 25, bars or posts are shown in cross section, each of which has two Profiles arranged in mirror image by nesting on the side are composed. The spar or post profile 44 consists of the two profiles 50, which are laterally nested in a mirror-image arrangement. Anyone can do this Profile can be equipped on the inside with at least one inwardly directed bead 51 and on the edge an inwardly angled tavern] 52. The two beaded flanges of the profiles are facing the area of the partition or transverse wall subjected to the load. At the free ends of the respective; Outside lying flanges of the profiles can be nested Profiles 50 be firmly connected by welds 5 3. The planking 54 can consist of sheet metal and at the points firmly adhered, e.g. by welding or also by riveting, gluing

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Or the like., Are connected.

The spar profile 45 of FIG. 22 has profiles 56 in which at least one flange 57 located on the outside is doubled by flipping it. The thickness ratio between the web and the flanges of the spar profile is thus increased to 1: 3 or even if the inner flange is doubled to 1: 4, which greatly increases the cross-sectional parameters in relation to those acting through the direction of loading Force. The planking 58 can also consist of a wood, chipboard or plastic panel

The spar or post profile 46 of FIG. 23 is also made two nested identical profiles 59 are composed, the web of each profile being additionally lent by beads 60 can be stiffened. The welds 53, e.g. dashed welds, result in the already existing advantages still have the advantage of great torsional rigidity of the entire spar profile with the essential influence through the at least doubled flanges with the Result, an adequate increase in the flexural rigidity in the desired uniaxial direction in the case of the transverse wall or partition wall to obtain.

Fig. 24 illustrates a post profile 47, also with lateral nesting of profiles 61 and 62. The profile 62 has a web bulge 63. This bar bulge 63 or crank runs undercut somewhat inwards on the parts 64. This has the advantage of planking 65 to be able to record more safely by jumping back. There is no need to bevel the planking 65 on the inside Edge. In the spar profile 48 of FIG. 2 5, the two identical profiles 66 are provided with web bulges 67 in order to to be able to accommodate the planking 65 in alignment with the respective outer surface of the flanges, which can be doubled,

wherein the recess can also be formed undercut here.

The further exemplary embodiments of the profiles in FIG. 26 to 34 represent profiles of spars or posts in which the profiles are pushed into one another in their longitudinal direction and have "matching" outline dimensions the profile 70 in FIG. 26, the outer profile 71 is provided with a web bulge 72 in order to accommodate the planking 73 to be able to. Within the profile 71, which is on the bulge of the web 72 opposite side can be open or closed, a profile 74 is provided in which the flanges of the Profile 71 are at least partially doubled. The inner profile 74 is due to the hook-shaped course 75 of the end parts stiffened. The profile 76 of FIG. 27 has an outer profile 71a which undercut at the crank or web bulge runs. The inner profile 74a engages directly in the crank. With the profile 78 of a post or Holmes, the web bulge 72b of the outer profile 71b is each provided with a return, which is via a weld seam 79 are connected to one another and to the inner separate profile 74. In addition, the inner profile 74b with inward beads 80 be equipped. In the case of the spar or post profile 82, the parts are for receiving the planking 73 designed as angles 81 which are welded to the profile 32. The whole thing can also be done with steel planking 83 (Fig. 29).

The profile 84 of FIG. 30 is made up of three different profile cross-sections 85, 86, 87 assembled and connected by welding, with a doubling of that facing the transverse wall Flanges or tripling is achieved. The profile 90 of Fig. 31 consists of two C-profiles 91, wherein the profiles 91 are provided with a wide bead 91a, in the reinforcement flat iron or plastic band 92 are stored and welded or glued.

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The profile 93 of FIG. 32 consists of C-profiles 94 as well the two hat profiles 95, which are firmly connected by welding, spots, gluing and the like. The connection of the C-profile 94 lies in the longitudinal center plane of profile 93. The ends of the profiles are each bevelled. The profile 96 in FIG. 33 corresponds essentially to the profile 93 in FIG. 32, but in the form of a post profile.

Fig. 34 shows a spar profile 97, which consists of two special profiles 98 is put together to form an overall profile, with a partial doubling of the flanges in the plane of the Transverse wall with inner stiffening ribs and a web bulge for receiving the planking 73 is provided.

35 shows a cross section through a transverse wall, in which the planking 99 between two posts 70 by means of the joints 100 are articulated. The panels 99 can be connected to one another by interposed profiles 101 be.

To reduce weight, the webs of the spar and / or post profile can be perforated. The spars and / or posts only need to be duplicated at the points, e.g. in the composite, where this is appropriate for the intended use what is necessary and useful is what contributes to weight reduction. In special cases a complete closely fitting doubling of the flanges.

The closed post-shaped steel profiles are above all provided in the lower part of the transverse wall or the partition wall both in the case of the spars and in the case of the posts, during the profiles above the middle of the height of the partition or the like. can be used in the form of open profiles.

Claims (22)

Expectations 1. Transverse wall for railway wagons, especially sliding ones and lockable partition wall, the supporting structure of which is vertical side posts and between the posts, with the side posts firmly connected spars, with a planking on both sides of the partition wall Plates made of wood, metal, plastic or steel is provided, characterized in that at least for the Spars (15,16,16a) profiles, (e.g. 17,27,40,44,45,70,76,90), with at least partial, at least double lying or doubled flanges, in which the surface of the flanges facing the area of the transverse wall or partition (5) subjected to the load and the thickness ratio • between web and flange is at least 1: 2 are. 2. Transverse wall according to claim 1, characterized in that the profiles (17,25,27,40) with their open sides to one another % are arranged butting. 3. Transverse wall according to claim 1, characterized in that two profiles (44,45,46) are arranged in mirror image to one another and laterally nested with at least one duplication of the flanges facing the transverse wall of different types Profiles are composed. 4. Transverse wall according to claim 1, characterized in that the profiles (70,76,90) are pushed into one another in their longitudinal direction and have matching outline dimensions. 5. Transverse wall according to claim 1 and 2, characterized in that the deflection (22) of the free flanges is arcuate, runs triangular or polygonal, and that the folded flange leg (18a) ends shortly before the web (19). 6- transverse wall according to claim 1 and 2, characterized in that that the profiles (25,27) Z-profiles with at least doubled flanges and vertical or inclined Are jetty. 7. Transverse wall according to claim 1 and 2, characterized in that the folded flange leg (18a) to ^: i the corner (18b) of the Profxls is guided. 8. Transverse wall according to claim 1 and 2, characterized in that that the folded flange leg (18a) of the profile has at least one bevel (18b). 9. Transverse wall according to claim 1 and 2, characterized in that the Flanr.chschenkel (18a) a multiple deflection exhibit. 10. Transverse wall according to one of claims 1 and 2 and 4 to 9, characterized in that between the folded over Flange legs of the steel profile (28) inserts (29,30) made of glass fiber reinforced plastic, e.g. epoxy resin, in Form of strips, ribbons or cords or the like. are arranged, and that the flare legs and the plastic insert by mutual connection, e.g. by gluing, clamping, screwing, riveting, etc., a load-bearing bond form. . Transverse wall according to one of Claims 1 and 2 and 4 to 10 characterized in that the fastening of the cladding plates (32) with the steel profile of the spar at least is carried out in the area of the folded flange leg (1Sa). 12. Transverse wall according to one of claims 1 and 2 and 4 to 11, characterized in that the spar (16) or the post (15) consists of two profiles set against each other with the open side, whose at least doubled The flanges are firmly connected to one another, e.g. by welding. 1 13. Transverse wall according to claims 1 and 3, characterized in that the profiles (44-48) have a U-shape, the same t Have outline dimensions and are plugged into one another with the open sides. γ 14. Transverse wall according to claims 1 and 3, characterized in that the profiles have a U-shape, the same designs ' ■ and have different outline dimensions in terms of size and are plugged into one another with the open sides. 15, transverse wall according to claims 1, 3, 13 and 14, characterized in that said one flange has a has the profile of at least \ inwardly directed bead (51) and the other flange of the same profile at least once folded (57) extends. 16. Transverse wall according to one of claims 1, 3, 13 to 15, da- '· - characterized by the fact that a flange of the profile is at its- § ner edge an inwardly angled leg (52) i has, and that the flange legs one or more times around | are trained. « 17. Transverse wall according to one of claims 1 to 16, characterized in that that the profiles between the web and flange inwardly extending cranks or bulges (41a, 67, 72) to accommodate paneling parts, and that the crankings and the like run undercut inwards. _ ί α ._ 18. Transverse wall according to one of claims 1 to 17, characterized / that the web is provided one or more times with beads (23, 60) and / or flat indentations (24) is. 19. Transverse wall according to one of claims 1 to 18, characterized in that that the flanges of the profiles are provided with beads (23, 51, 80). 20. Transverse wall according to one of claims 1 to 19, characterized in that the cladding plate (37,58,73) with | Beads (38) is provided. §, 21. Transverse wall according to one of claims 1 to 20, characterized in that » indicates that the webs of the spar or post profile I are perforated. 22. Transverse wall according to one of claims 1 to 21, characterized in that that the profiles as cold profiles are a high quality steel with a yield point of at least 500 N / mm ^ with high elongation. -