DE8712119U1 - Node element for connecting bar elements - Google Patents

Description

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D-2000HAMBURQB2 OR. J.'D. FRHR. von UEXKÜLL

DR. ULRICH GRAF SfÖLBERG PIPL>ING. JÜRGEN SUCHANTKE

SIPL.-INQ. Arnulf huber

DR. ALURD von KAMEKE DlPL.-BlOL. INGEBORG VOglker

Lüdeniann & Go«

Workshops for exhibition stands

Segebeiger Chaussee 175 24401 su/do

2000 Norderstedt-September 1987

Node element for connecting bar elements

The invention relates to a node element for connecting rod elements to a lattice or lattice structure or the like, with at least two anchoring openings for connecting rod element ends.

A known node element of this type has the shape of a cube with 6 or more flat contact surfaces, and in the center of each contact surface there is a threaded hole into which a threaded bolt connected to the end of a rod element can be screwed.

This well-known node element enables the connection of several rod elements according to its contact surfaces at angles that are determined by the orientation of the contact surfaces.

The known node element is suitable for many applications, but cannot be used if the alignment of one or more bar elements in relation to one or more other bar elements is to take place at angles that are not angles at which the contact surfaces of the node element extend to each other.

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It is the object of the invention to create a node element for connecting rod elements which makes it possible to connect ^several rod elements to one another at practically any angular orientation.
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To solve this problem, a node element of the type mentioned at the beginning is designed according to the invention by a substantially spherical circumferential flange with anchoring openings provided at diametrically opposite locations for receiving a hammer bolt attached to the rod element and by at least one circumferential groove with its center plane normal to the diametrical for anchoring hammer bolts attached to rod elements. The circumferential groove is preferably

!S nut on a great circle.

The essentially spherical node element according to the invention therefore not only enables the fastening of two rod elements at two predetermined, diametrically opposite locations, but also the fastening of rod elements in a plane perpendicular to the diametrical line and in the area of the entire circumference, so that the user can carry out an alignment or positioning in a continuous area of 360°, at least as far as the fastening of the rod element in the circumferential groove is concerned, whereby of course several rod elements can also be anchored in the circumferential groove.

It should be mentioned that it is known to use rod elements with hammer bolts attached to their ends to build lattice and truss structures, for example in trade fair and exhibition construction, in shop fitting, in the manufacture of supporting structures and other small structures, where the hammer bolt is fixed non-rotatably in the rod element.

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is fixed and has an elongated head so that it can be inserted into a longitudinal hole in a ^certain orientation of the rod element and then brought into a position that engages behind the edge area of the elongated hole by turning the rod element about its longitudinal axis. In this anchoring or locking position of the hammer bolt, an Inibus screw located transversely to the longitudinal axis in the rod element is tightened - which engages in a recess in the rear end area of the hammer bolt and through

-\Q this engagement pulls the hammer bolt further into the rod element so that its head comes into clamping engagement with the edge area of the elongated hole and thereby a firm connection is created between the rod element and the part having the elongated hole* Such a system has, for example, been sold for a long time by the applicant under the name "KANYA ^H.

'If, as already mentioned above, the circumferential groove lies on a great circle, i.e. on the "equator" of the spherical node element, there can also be two additional circumferential grooves running parallel to the circumferential groove and accommodating hammer bolts, each of which lies at the height of the bisector between the center plane of a circumferential groove and the diametrical line.

The provision of these additional circumferential grooves results in additional anchoring options for rod elements, which can be anchored in the direction of the additional circumferential groove in a range of 360°, so that the rod elements extend at an angle of 45° on the one hand with respect to the rod elements that are fastened in the anchoring openings, and on the other hand also at an angle of 45° with respect to the rod elements that are fastened in the circumferential groove lying on the great circle. In this way, the possibility for the connection

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Formation of bar elements at different angles even further enlarged*

In order to manufacture the node element according to the invention as simply as possible, it can be constructed from at least two node components lying flat against one another in the central plane of the circumferential groove and connected by a screw bolt running coaxially to the diametrical line; i.e. the node complement can be composed of node components which are easier to manufacture and does not need to be manufactured in one piece from solid material.

Each of the node components can consist of two sub-elements connected by the screw bolt, of which one forms one side wall and half the base of the circumferential groove and the other the anchoring opening, i.e. the node components to be connected to each other are divided into sub-elements that are even easier to manufacture.

If the node element has the additional circumferential grooves mentioned above in addition to the circumferential groove, one partial element can form one side wall and one groove base surface and the other partial element can form the other side wall and one groove base surface of the additional circumferential groove, wherein the two groove base surfaces of the additional circumferential groove preferably run perpendicular to one another.

_3Ü The invention is explained in more detail below with reference to the figures showing an embodiment.

Figure 1 shows a side view of a node element.

Figure 2 shows the node element from Figure 1 in a top view.

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Figure 3 shows the node element from Figures 1 and 2 in section and, in an exploded view, a rough rod element and the hammer bolt to be fastened in it.
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The node element shown is spherical and consists of four sub-elements 9, 10, 11, 12 (Figure 3) which are connected to one another by means of a screw bolt 7 extending along the axis 3 so that they lie flat against one another. The screw bolt has a slot (not shown) at one end for a screwdriver, which can be used to screw it in. This structure results in a spherical body which has an anchoring opening 1, 2 on diametrically opposite sides on the axis 3, which, as Figure 2 shows, has the shape of an elongated hole in the opening area and whose longitudinal edges protrude into the opening, as indicated at 21 and 22 in Figure 3. The receding side walls 23, 24 of the anchoring opening 1 continue below the projections. The anchoring opening 2 is also designed accordingly.

As will be described later, this shape of the anchoring openings allows the head 37 of a hammer bolt 36 (Figure 3) to be inserted into the anchoring opening with its longitudinal extension in the direction of the longitudinal extension of the slot-shaped opening area of the anchoring opening and, by turning the associated rod element, to be brought into a transverse position in which the head 37 of the hammer bolt 36 engages behind the projections 21, 22 and thus firmly connects the rod element to the node element.

I The nodal element has, in addition to the connection openings 1 and 2 in the contact plane 8 of the partial elements I

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9 and 11 has a circumferential groove 4, the central plane of which coincides with the contact plane 8 and is normal to the axis 3 and which is located in the "equatorial region", i.e. on a great circle of the spherical node element. As can be seen in Figure 3, the circumferential groove 4 has projecting outer edge regions corresponding to the edge regions 21, 22 of the anchoring opening 1, whereby these projecting edge regions of the circumferential groove 4 extend along the entire circumference. In Figure 3, only the upper edge region 13, the adjacent, recessed sixth wall region 14 of the circumferential groove 4 and one half 15 of the groove base of the circumferential groove 4 are provided with reference symbols. These form parts of the sub-element 9, while the corresponding parts of the lower half of the circumferential groove 4 in Figure 3, which are formed by the sub-element 1t, are not designated.

The head 37 of a hammer bolt 36 can be inserted into the circumferential groove 4 in the same way as described in connection with the anchoring opening 1 by rotating the rod element containing the hammer bolt so that the longitudinal extension of the head 37 of the hammer bolt 36 is in the circumferential direction.

If the hammer bolt 37 is then inserted into the circumferential groove 4, the rod element is rotated so that the head 37 of the hammer bolt 36 engages behind the projecting edges of the circumferential groove 4, of which only the edge 13 is designated.

The upper edge area of the part element 9 forms together with the outer edge area of the part element 10 a circumferential groove 5 and the lower edge area of the part element 11 forms with the outer edge area of the part element 15 a circumferential groove 6 (Figure 3). The circumferential grooves 5 and 6 run

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parallel to the circumferential groove 4 and lie on the bisector between the plane 8 and the axis 3 (Figure 3). Since the two additional circumferential grooves 5 and 6 are designed in the same way, only parts that form the upper circumferential groove 5 are provided with reference symbols. It can be seen that in the outer area of the circumferential groove there are circumferential projections 16, 18, the dimensions of which correspond to the projections 21, 22 and the projection 13. In this case, the radially extending free end surfaces of the projections 16 and 18 form side wall areas of the circumferential groove 15, and the wall section 17 of the sub-element 9 adjoining the projection 16 and the wall area 19 of the sub-element 10 adjoining the projection 18 form the groove base of the circumferential groove 5.

As can be readily seen, the head 37 of a hammer bolt 36 can be inserted into the circumferential groove 5 and correspondingly also the circumferential groove 6 in the manner described in connection with the circumferential groove 4 and brought into a position engaging behind the edges 16 and 18 by rotation, whereby the rod element supported on the outer surface of the projections 16 and 18 is then aligned at an angle of 45° with respect to the axis 3 and with respect to the plane 8.

As the above explanations show, using the node element shown, rod elements can be attached to any point on the circumference of the circumferential groove 4, so that they then extend perpendicular to the axis 3, while rod elements attached in the anchoring openings 1 and 2 run in the direction of this axis. Rod elements attached to any point on the circumference of the additional circumferential grooves 5 and 6, on the other hand, run at an angle of 45° with respect to the

2J5 Circumferential groove 4 and in the anchoring holes 1 and 2

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attached rod elements, so that there is a large possibility of variation with regard to the alignment of the rod elements, especially because they can be mounted at any point on the circumference of the respective circumferential groove 4, 5, 6, i.e. in a range of 360°.

As already mentioned, the connection between the node element shown and the rod element is made by means of known hammer bolts. ^In Figure 3, a tubular rod element 30 is indicated for this purpose, which has a circular cross-section and a front end surface 31. At a distance from the

; front end face 31 is a cross hole in the rod element 30

There is a recess 32 into which a fastening bushing 33 is inserted, which has a through hole that runs coaxially to the longitudinal axis of the rod element 30 when inserted. A hammer bolt 36 is inserted into the rod element 30 from the front end so that its rear end extends through the through hole in the fastening bushing 33.

The hammer bolt has a guide collar 38 with which it is in sliding engagement in the front end area of the rod element 33 and between which and the fastening bushing 33 a coil spring 39 is arranged, which exerts a force on the guide collar 38 and thus on the hammer bolt 36 as a result of support on the fastening bushing 33 in the direction of a movement of the hammer bolt 36 out of the front end of the rod element 30. At a distance from the outer end of the guide collar 38 is the head 37 of the hammer bolt 36 which, as already mentioned above, has an elongated shape which corresponds approximately to that of the opening area of the anchoring opening 1 shown in Figure 2, but is of course somewhat smaller.

3S When inserted into the support element 30, the hammer head 36 is secured by means of a bushing

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33 recessed/ externally accessible screw

34/ which extends with its inner edge into a recess provided in the shaft of the hammer bolt 36 and thus prevents the hammer bolt 36 from twisting about its longitudinal axis and from being pulled out of the rod element 30* The recess is designed so that the hammer bolt 36 can be slightly displaced out of the rod element 30 under the force of the spring 39 when the Allen screw 34 is slightly loosened, but that when the Allen screw 34 is tightened it is pulled further into the rod element 30 again by the shape of the recess.

In order to attach the rod element 30 to the node element shown, for example in the area of the circumferential groove 5, the Allen screw 34 is loosened slightly so that the spring 39 pushes the hammer bolt 36 slightly out of the rod element 30. In this position, the anchoring bolt 36, which is still held non-rotatably by the Allen screw 34, is inserted into the circumferential groove 5 at the desired location with its head 37 aligned accordingly by turning the rod element 30. In this inserted position, the rod element 30 is then rotated so that the elongated head 37 of the hammer bolt 36 engages behind the protruding edges 16 and 18 of the circumferential groove 5. Then the Allen screw 34 is screwed as far as possible into the fastening bush 33 using the key ?5, which leads to a displacement of the hammer bolt 36 into the rod element 30, so that the head 37 of the hammer bolt 36 is firmly against the inner sides of the projections 16 and 18 of the circumferential groove 5 and the end surface 31 of the rod element 30 and the outer surfaces te

I of the projections 16 and 18 are pressed so that a | firm connection between the node element and the rod element ! 30 is created. |

Claims (7)

&bull;-no l· Claims 1. Node element for connecting rod elements (30) to a lattice or framework structure or the like, with at least two anchoring openings (1, 2) for connecting rod element ends, characterized by a substantially spherical peripheral shape with anchoring openings (1; 2) at diametrically opposite locations for receiving a hammer bolt (36, 37) fastened to the rod element (30) and by at least one circumferential groove (4) with its center plane (8) normal to the diametrical line (3) for anchoring receiving hammer bolts (36, 37) fastened to rod elements (30). 2. Knot liner according to claim 1, characterized in that that the circumferential groove (4) lies on a great circle. 3. Node element according to claim 2, characterized by two additional circumferential grooves (5; 6) running parallel to the circumferential groove (4) and receiving hammer bolts (36, 37), each of which lies at the level of the bisector between the center plane (8) of the circumferential groove (4) and the diametrical line (3). 4. Bone element according to one of claims 1 to 3, characterized by at least two node components (9, 10; 11, 12) lying flat against one another in the central plane (8) of the circumferential groove (4) and connected by a screw bolt (7) running coaxially to the diametrical line (3). 5. Node element according to claim 4, characterized in that each of the node components consists of two through the screw ·· 1 δ *■ bolt (7) connected partial elements (9, 10; 11, 12), one of which forms one side wall (13, 14) and half the groove base (15) of the peripheral groove (4) and the other forms the anchoring opening (1). 6. Node element according to claim 5, characterized in: that one part element (e.g. 9) forms one side wall (16) and a groove base surface (17) and the other sub-element (10) the other side wall (18' and a groove base surface (19) of an additional circumferential groove (5) forms. 7. Node element according to claim 6, characterized in that the two groove base surfaces (17; 19) of the additional -] ₅ len circumferential groove (5) run perpendicular to each other. 44 « * · 4