DE8911464U1 - Crossbar holder for connecting the crossbars of a supporting structure for raised floors - Google Patents

Description

Traverse holder for mutually connecting the traverses of a supporting structure for raised floors

The invention relates to a traverse holder for mutually connecting the traverses of a supporting structure for raised floors according to the preamble of claim 1.

Such a traverse holder is known from the French patent application 2 050 197. In this traverse holder, the holding arms consist of a cross-shaped flat material, to the underside of which a tubular connecting element is attached, e.g. by welding. At its end facing the ground, the connecting element has a nut firmly attached to it, with the help of which the traverse holder can be screwed onto a threaded rod of the floor support. Such a traverse holder consists of several parts and can only be manufactured in several work steps. In particular, attaching the connecting element to

the underside of the connecting section of the holding arms is complex and expensive. The traverse holder known from British patent application 1 300 982 has holding arms that are at approximately right angles to one another with side walls that are bent in the direction of the connecting element for the floor support. The connecting element is attached in a complex manner to the underside of the connecting section of the holding arms and has a longitudinal notch on its outside. This traverse holder is screwed with its connecting element into a vertical tube of a floor support. Such a traverse holder is complicated to manufacture, so that high production costs are to be expected.

The invention is based on the object of creating a traverse holder of the type specified above, which is simpler in construction and more cost-effective to manufacture.

This object is achieved according to the invention in a traverse holder by the features of claim 1.

With the help of the tabs pressed out of the flat material and bent towards each other, the connecting element is connected in one piece to the crossbar holder, so that the latter can be manufactured from the flat material in one operation, e.g. by punching and bending. These tabs, which protrude vertically from the connecting section of the holding arms, form a simple plug-in guide for the crossbar holder on a tubular element of a floor support. Such a plug-in guide can be manufactured very quickly and also offers the advantage that the crossbar holder can be removed from the tubular element of the floor support at any time. A solid, non-

A detachable connection between the traverse holder and the floor support is therefore neither provided nor required. This makes the entire support structure very flexible and variable in terms of exchanging the traverse holders. It is therefore easily possible, for example, to exchange a cross-shaped traverse holder for a T- or L-shaped traverse holder. It is also advantageous that part of the flat material of the support arms is used as the material for the connecting element, so that additional materials are not required. Such a traverse holder can therefore be manufactured quickly and inexpensively and thus as a mass product. Complex manufacturing processes are no longer necessary.

Preferably, the tabs rest on the inner wall of a tubular floor support, which can, for example, have a circular or rectangular cross-section. Since the tabs rest on the inner wall of the floor support over their entire length, a good distribution of stress from the connecting element to the connecting section of the holding arms is ensured, particularly in the case of transverse loads. Supporting the connecting elements on the inner wall of the floor support also has the advantage that the force can be introduced from the radially inner area of the cross member via the holding arm directly to the floor support located underneath, since the front edge of the cross member is arranged vertically above the tubular wall of the floor support. Such a design is advantageous in that almost no tipping moments can occur, at least in the radially inner area.

It is also advantageous to provide each holding arm in its radially outer area with a preferably rectangular

It is therefore advisable to form a locking opening for the crossbeam, as the crossbeam can then be easily anchored in the holding arm and secured against displacement in the normal and transverse directions of the holding arm. An additional operation is not required for punching out the locking openings; rather, these can ^be produced at the same time as punching out the crossbeam holder and pressing the ^tabs out of the flat material. The production costs of the entire crossbeam holder therefore increase only insignificantly, so that an inexpensive option for detachably fastening the crossbeam to each holding arm is created. It is particularly advantageous to use the opening created when the tab is pressed out of the flat material as the locking opening for the crossbeam, as this means that one operation is used to simultaneously produce both the connecting element and the locking opening for the crossbeam.

With the help of the U-shaped cross section of the support arm with side walls bent towards the side of the plug-in guide, the stability of the support arm and thus of the entire crossbar holder is increased. In particular, it is possible to secure the crossbars supported on each support arm against twisting with respect to the longitudinal axis of each support arm. The provision of such side walls is also possible without any problems with a crossbar holder made of flat material using the same work step with which the entire crossbar holder is manufactured. In this case, the crossbar holder is therefore a stamped and bent part. Such a manufacture of the crossbar holder in one work step is particularly possible if each radially inner rear edge of each side wall is inclined, rising towards the connecting section, since such a

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rather, the traverse holder can be easily made from a cross-shaped flat material. In particular, if the angle of inclination is around 45°, additional measures are not required that would otherwise prevent the traverse holder from being made in just one step. The inclined rear edge also has the advantage that when the traverse is attached,

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Floor support guides the tubular element of the floor support in the direction of the connecting element, so that the crossbar holder can be attached to the floor support quickly and easily. When attached, the tubular element therefore automatically slides along the rear edge in the direction of the tabs that are bent towards each other.

It is also advantageous to provide a screw in a threaded hole centrally located in the connecting section of the support arms, the head of which at least partially overlaps the front edges of the crossbars placed on the support arms of the crossbar holder _. This ensures that when the screw is tightened, the front edges of the crossbars rest on the crossbar holder, so that a uniform surface is created for the support of the floor panels. The floor panels can then be easily pushed over the crossbars and the crossbar holders without any risk of jamming. This makes it easy to place the floor panels on the supporting structure.

It is also advantageous to angle the support arms slightly, preferably in the range of 2 to 6°, towards the side of the plug-in guide relative to their connecting section, so that the crossbeam only

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area of the connecting section rests on the traverse holder. The bending of the holding arms almost completely prevents the occurrence of biting moments on the holding arm, since the vertical weight force mainly caused by loading the raised floor is transferred directly from the raised floor via the front edge of the traverse to a vertical, tubular element of the floor support. In this case too, the traverse holder is designed as a stamped and bent part. Since the holding arms do not have to absorb any bending moments, they can have a lower wall thickness overall, which has a ^positive effect on the material costs and on the force required for the punching and bending process. Even the slight bending of the holding arms does not result in a shorter work step, but can be carried out together with the punching of the holding arms from the flat material and the pressing out and bending of the tabs. Since all the traverses are arranged with their front edges close to the connecting section of the support arms, this measure alone enables a uniform, level alignment of the traverses and thus of the raised floors placed on them. Alternatively, it is also possible to design the upper surface of the support arms to be curved, with the radially outer edge of each support arm being arranged 1 to 5 mm below the radially inner area of the support arm. This design has the advantage that in the transition area between the connecting section and the radially outward-facing part of the support arm, there is no angled edge but a sliding transition. This ensures that the traverse is supported evenly on the traverse holder at all times.

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An embodiment of the subject matter of the invention is explained in more detail below with reference to the drawings. They show:

Fig. 1 is a schematic perspective view of part of a support structure for raised floors with a cross member, a cross member holder and the upper section of a floor support;

Fig. 2 a side view of the traverse holder ;

Fig. 3 the front section of the cross member according to Fig. 1; and

Fig. 4 is a section along the line IV-IV in Fig. 3.

Fig. 1 shows the upper part of a support structure 1 for raised floors. The support structure has a crossbar holder 2 for connecting the crossbars 3 to one another, which consists of four holding arms 4 made of flat material that are at right angles to one another. The holding arm 4 arranged at the top left in Fig. 1 is covered by the crossbar 3 and is therefore not visible.

The cross-shaped traverse holder 2 has a connecting section 5 between its holding arms 4, into which the holding arms converge. A connecting element 6 for a floor support 7 protrudes vertically downwards from the level of the holding arms 4 and the connecting section 5. According to Fig. 1, the connecting element is made of lap-

The four tabs 8 are formed, which are pressed or punched out of the flat material of each holding arm 4 and bent towards each other. The four tabs 8, two of which are arranged opposite each other, thus form sections of a steel guide 11 for the floor support 7 (see also Fig. 2).

The tabs 8, which are pressed out of the flat material and bent vertically downwards, have side edges 12, L (see lower right holding arm in Fig. 1), which are aligned parallel to each other and lead to an approximately semicircular lower edge 14. However, it is also possible to arrange the side edges 12 and 13 conically, tapering radially downwards towards each other and to make the lower edge 14 triangular or rectangular. According to Fig. 1, the tabs 8 are arranged in the crossbar holder 2 in such a way that it can be inserted into an upper end 15 of a cylindrical tubular floor support 7, indicated in dash-dotted lines in Fig. 1. In this case, the tabs 8 rest against the inner wall of the floor support 7 (not shown in detail). Furthermore, it is possible to arrange the tabs 8 outside the upper end 15 of the base support 7 so that they are supported on the outer wall of the upper end.

Each holding arm 4 has a rectangular locking opening 17 for the cross member 3 in its radially outer region 16. The radially outer region 16 of each holding arm 4 has angled edges 18, 19 (cf. lower right holding arm in Fig. 1), with the rear edge 22 of the locking opening 17 being arranged approximately at the height of the rear end of the angled edges 18, 19 (lower right holding arm in Fig. 1). According to Fig. 1, the locking opening is square; however,

It is also possible to provide a circular, triangular or elliptical opening. The locking opening 17 can also be arranged closer to the front edge 23 of the holding arm or closer in the direction of the opening ?A. created by the tab 8 pressed out of the flat material.

Preferably, the radially inner edge 25 of the opening 24 close to the connecting section 5 and the locking opening 17 are arranged approximately such that the distance between the opening 24 and the locking opening 17 is approximately the same as the distance between the front edge 23 of the holding arm 4 and the radially inner opening 17.

It is also possible not to provide a locking opening 17 in the radially outer area 16 of the holding arm 4, but to use the opening 24 as a locking opening for the cross member J z».*.

According to Fig. 1 and 2, each holding arm 4 has, apart from its radially outer region 16, a U-shaped cross section with side walls 26 bent towards the side of the plug-in guide 11. Each side wall 26 has a front edge 27 and a rear edge 30, the former being arranged to point towards the radially outer region 16 and the latter pointing towards the upper end 15 of the base support 7. According to Fig. 1, both edges are inclined, the angle of inclination A relative to the lower edge 31 of the side wall 26 being approximately 45° in each case (see Fig. 2). The front edge 27 can also have a different inclination than the rear edge 30, the angle of inclination being between 0 and 90°. With an angle of inclination of 0°, the side walls 26 and thus also their front and rear edges are omitted.

A threaded hole 32 is provided centrally in the connecting section 5 of the holding arms 4, in which a screw 33 is seated. The screw 33 has a head 34 which is designed as a countersunk head according to Fig. 2. The head 34 is dimensioned and arranged in the connecting section 5 in such a way that it overlaps the front ends 35 of the crossbars 3 placed on the holding arms 4 of the crossbar holder 2. The screw 33 is designed as a Phillips screw according to Fig. 1.

As shown in more detail in Fig. 2, the holding arms 4 are slightly angled relative to their connecting section 5 in the direction of the side of the plug-in guide 11, with the angle B being in the range of 2 to 6°. However, it is also possible to design the upper surface 36 of each holding arm 4 to be curved in the longitudinal direction of the holding arm and to arrange the radially outer front edge 23 of each holding arm 1 to 5 mm below the radially inner region 37 of the holding arm 4 (not shown in more detail). It is also possible to design the upper surface 36 of each holding arm 4 to be flat or slightly curved transversely to the longitudinal direction of the holding arm.

The traverse holder 3 is shown in more detail in Fig. 3 and 4

The front area 40 of the cross member 3 tapers towards the front edge 35, preferably at an angle of 45°. The cross member holder has a U-shaped cross section with a horizontally running upper wall 41 and vertically adjoining side walls 42 and 43 (see Fig. 4). In the upper wall 41, the cross member 3 has a tab 44 which is pressed out of the flat material and extends towards the side walls.

42, 43 is bent parallel to these. This creates an opening 45 in the upper wall 41. The length of the opening 45 is slightly smaller than the length of the locking opening 17. Alternatively, the tab 44 can also be pressed out of the flat material of the cross member 3 transversely to the side walls 42, 43 and bent downwards. In this case, the width of the opening 45 is slightly smaller than the width of the locking opening 17.

The distance between the side walls 42 and 43 of the cross member 3 is selected so that the cross member can be attached to the support arm 4 with little play. The vertically extending width of the side walls 42, 43 of the cross member 3 corresponds approximately to the width of the side walls 26 of the support arm 4. However, it is also possible for the width of the side walls 42, 43 of the cross member 3 to be selected to be larger or smaller than the width of the side walls 26 of the support arm 4.

The manufacture of the truss holder and the assembly of the supporting structure are described in more detail below.

The traverse holder is made of flat material, such as sheet metal or plastic. To produce the traverse holder 3, the flat material is first cut briefly at its diagonal ends, then the traverse holder is produced as a stamped and bent part in one step by producing the locking opening 17, the tabs 8 pressed out of the flat material and bent and the side walls 26 bent towards the side of the plug-in guide simultaneously or in quick succession. At the same time, the hole for the threaded hole 32 can be punched into the traverse holder.

If a screw 33 is required to span the front edges of the crossbeams, it is only necessary in a second step to cut the thread for the screw 33 into the flat material.

The crossbar holder 3 is then placed without the screw 33 on the upper end 15 of the floor support 7 so that the tabs 8 bent towards each other rest against the inner wall of the floor support. The crossbars 3 are then pushed onto the support arms 4 so that the tabs 44 engage in the locking openings 17 or in the opening 24 of the tabs 8. The crossbar 3 is thus secured against displacement relative to the support arm. Finally, the screw 33 is screwed into the threaded hole 32, whereby the head 34 overlaps the front edges 35 of the crossbars 3 and is pushed in the direction of the connecting section 5. The front edges 35 of the crossbars can be inclined in accordance with the flat head of the screw, so that ultimately a smooth, flat surface is created for the raised floors.

If the support arms are angled relative to their connecting section, the crossbeam rests only with its front edge on the crossbeam holder near the connecting section 5, so that when the raised floor is loaded, the force to be absorbed is transferred directly from the crossbeam via the crossbeam holder to the upper end of the floor support. It is clear that the slight bending of the support arms can take place during the manufacturing process described above.

Claims (11)

·'- i'3 - ' " Claims 1. Crossbeam holder for mutually connecting the crossbeams of a supporting structure for raised floors, consisting of several holding arms made of flat material which are approximately at right angles to one another, in the connecting section of which a connecting element for a floor support is arranged which protrudes approximately at right angles from its plane, characterized in that the connecting element (6) is formed from tabs (8) which are pressed out of the flat material and bent towards one another and form the sections of a plug-in guide (11) for the floor support (7). 2. Traverse holder according to claim 1, characterized in that the tabs (8) rest against the inner wall of a tubular floor support (7). 3. Crossbar holder according to claim 1 or 2, characterized in that each holding arm (4) has a preferably rectangular locking opening (17) for the crossbar (3) in its radially outer region (16). 4. Traverse holder according to claim 3, characterized in that the locking opening (17) is the opening (24) created by the tab (8) pressed out of the flat material. title I
I · · · i5 5. Traverse holder according to one of claims 1 to 4, characterized in that each holding arm (4) has a U-shaped cross section with side walls (26) bent towards the side of the plug-in guide (11). 6. Traverse holder according to claim 5, characterized in that the radially inner rear edge (30) of each side wall (26) is inclined, rising towards the connecting section (5). 7. Traverse holder according to claim 6, characterized in that the angle of inclination (A) is approximately 45°. 8. Crossbeam holder according to one of claims 1 to 7, characterized in that a screw (33) is provided which is seated in a threaded bore (32) arranged centrally in the connecting section (5) of the holding arms (4), the head (34) of which at least partially overlaps the front edges (35) of the crossbeams (3) placed on the holding arms of the crossbeam holder. 9. Traverse holder according to one of claims 1 to 8, characterized in that the holding arms (4) are slightly angled relative to their connecting section (5) in the direction towards the side of the plug-in guide (11). 10. Traverse holder according to claim 9, characterized in that the angle (B) is in the range of 2 to 6°. 11. Traverse holder according to one of claims 1 to 8, characterized in that the upper surface (36) ,'■- of the holding arms (4) in the longitudinal direction of the holding arms I ₁ curved and the radially outer leading edge | (23) of each support arm (4) 1 to 5 mm below the | radially inner area (37) of the holding arm V _r is arranged.