NL1001949C2 - Fixing assembly for plates. - Google Patents

Description

Fastening assembly for plates

The invention relates to a mounting assembly for arranging plates, in particular glass or panel plates, on an extension of a substructure, preferably for a facade of a building, as described in claim 1.

DE-A1 ~ 3,927 * 653 discloses a holder for glass plates, which provides a support free of bending moments with tolerance compensation. A glass plate is herein clamped between two support plates by means of a retaining screw passing through the glass plate and the support plates fastening together. One of the fifth wheels is connected via a ball joint to a holder, which is attached to the substructure. Between the substructure and the glass plate, a tolerance equalization takes place in the area of the glass bore through which the retaining screw 15 passes, compensating movements for the tolerance equalizing as relative movement of the glass plate relative to the holder. It is not possible to form a flat glass surface over a larger area of the glass plate. The glass plates are fitted on the construction site in such a way that the holders with one of the support plates are first attached to the substructure in the correct place and then the glass plate is placed on the associated holders and by screwing on the second support plate to the holder secured. In this case, each glass plate must be separately mounted on the holders provided for this purpose on the construction site.

EP-B1-0.201.212 discloses a support for glass plates, which comprises a ball element spherically rotatable in a sleeve element, wherein the sleeve element is fixed in a bore of the plate. The pivot point of the spherical movement lies mainly in the central plane of the plate. The ball element is connected to a substructure. Here, too, the supports must first be attached to the substructure, so that the glass plates can subsequently be placed on the associated supports and attached to them.

It is the object of the present invention to provide a mounting assembly of the type mentioned at the outset, which reduces the construction work on the construction site and the associated costs.

This object is achieved by the features indicated in claim 1.

2

Due to the design of the mounting assembly according to the invention, it is possible to provide the plates with mounting parts already outside the construction site, for instance at the manufacturer of facade cladding, so that these pre-assembled units on the construction site are still attached only by means of the mounting bolt. the supporters for the substructure need to be fitted. This fixing of the plates on the construction site is done very quickly, since screw connections in the area of the plate, which, in order not to damage the plate, require the observance of predetermined torques, are no longer required on the construction site. This makes it possible, for example, to significantly reduce the time for applying a facade cladding to a building, so that the total construction time also decreases.

It is advantageous when the mounting bolt goes through an opening in the rear segment of the mounting part, engages an opening in the spacer and is lockable therein. This enables fast and trouble-free installation on the construction site.

In a further advantageous embodiment, the fastening bolt, which can in principle also be manufactured as a threaded bolt, is formed as a plug bolt, which can be attached to the interpreter by means of a securing pin passing through the bore bolt and by the interpreter. This reduces the installation time even further, since the mounting only requires the insertion and securing of one plug bolt per mounting assembly.

If the fastening part is rigidly attached to the spacer, then forces can be absorbed in all three main directions via this fastening part.

If the fixing part can be fixed in axial direction and in radial direction relative to the longitudinal axis of the interpreter, while retaining pivotability around the longitudinal axis or around an axis running substantially parallel thereto, this provides a semi-fixed bearing, which allows for the absorption of forces in two spatial directions, while a freedom of movement is provided in the third spatial direction. This allows, for example, sheet expansion to be equalized in one direction.

In addition, it is particularly advantageous if the rear section of the fastening part comprises a one-surface swivel hinge.

With respect to the longitudinal centerline of the spacer, the fastening part can be attached to the spacer 10 8 3 in the axial direction and in the radial direction, while retaining pivotability around the longitudinal centerline or around a substantially parallel centerline and retaining pivotability around centerlines which extend in a plane substantially perpendicular to the longitudinal axis and intersect the longitudinal axis or the parallel axis running parallel thereto at substantially the same point as the longitudinal axis of the fastening part, a loose bearing is provided, which allows freedom of movement in two of the three spatial directions, so that expansions can be accommodated in both these spatial directions.

In addition, it is particularly advantageous if the rear segment of the fastening part comprises a two-plane swivel hinge.

It is furthermore advantageous if the front segment can be pivotally connected to the plate mounting. In this way, in connection with the semi-solid bearing or the loose bearing, a fixing assembly is provided, which in each case can take up particularly effective movements of the plate in the plate face, since these fixing assemblies are each formed as double-hinge assemblies due to the pivotability at both ends. the mounting part.

It is particularly advantageous if the front segment is formed as a front pivot part and forms part of a pivot bearing, which further comprises a counter bearing connected to the plate attachment and a bearing part holding the pivot part and the counter bearing together. A compact pivot bearing is hereby provided in the area of the plate mounting and of the front segment of the mounting part.

Preferably, the front pivoting part and the counter bearing on the one hand, as well as the front pivoting part and the bearing part, on the other hand have concentrically curved surfaces which touch each other.

In a preferred embodiment, the front segment and the rear segment of the fastening part are formed by two separate parts, which are joined together by means of a connection. As a result, a simple mounting of the fastening part on the plate can take place, in particular when a pivot bearing is arranged in the region of the front end of the fastening part.

In a further preferred embodiment, the spacer, the fixing part and / or the plate holder or at least parts thereof consist of a material that does not conduct heat or only little heat. This ensures that optimal heat insulation takes place while avoiding cold bridges.

The invention is explained in more detail below with reference to exemplary embodiments. Herein: figure 1 shows a first embodiment of the mounting assembly, which is designed as a fixed bearing; figure 2 shows a second embodiment of the mounting assembly as semi-solid bearing; figure 3 shows a third embodiment of the mounting assembly as a lower bearing; and Figure 4 shows the support of a plate by means of the fastening assemblies according to the invention.

Figure 1 shows a mounting assembly, in which an interpreter 1 is provided, that an element is a substructure of a facade 15 of a building. The spacer 1 is arranged at one end on a post 1 ', for example a vertical post (see figure 4), so that its longitudinal centerline 10 runs substantially perpendicular to the longitudinal direction of the post 1'. The spacer 1 is provided at its free end with an axial bore 12 and in the vicinity of its free end has a transverse bore 14 passing through the axial bore 12, which runs substantially perpendicular to the longitudinal axis 10.

The axial bore 12 is designed to receive a mounting bolt 2, which in the vicinity of its front end also has a transverse bore adapted to the bore 14 in the spacer 1. The fastening bolt 2 is provided at its free end with a cross-section round front segment 20 adapted to the axial bore 12 in the spacer 1, which for the purpose of inserting the fastening bolt 2 in the axial bore 12 in the spacer for substantially dimensional accuracy. 1 is formed. At its other end, the mounting bolt 2 is provided with a head section 22, the diameter of which is greater than that of the front section 20. Between the head section 22 and the front section 20, a central section 24 extends, which is substantially square in cross section formed, the length of the edges of the square segment substantially corresponding to the diameter of the front segment 20.

A fastening part 3 consists of a rear segment 32 and a front segment 34. The longitudinal axis 30 of the fastening part 3 or 5 extends transversely but not necessarily perpendicular to the longitudinal axis 10 of the strut 1. In its rear segment 32, the fastening part 3 comprises a passage opening 31 »which is adapted in cross-section to the cross section of the middle segment 24 of the mounting bolt 2, so that this middle segment can be arranged substantially dimensionally in the passage opening 31.

At its front free end, the rear segment 32 is provided with an axial bore 37 * which includes an internal screw thread 37 '.

The front segment of the fastening part 3 is formed as a pivot bearing 4. For this purpose, an axial bore 37 of the rear section 32 of the rearwardly located shaft journal 4l of a front pivot 40 provided with an external screw thread 41, is screwed into the front axial bore 37 provided with the screw thread 37. The front pivot 40 is formed at its free end in the form of a ball-shell segment, which includes a face 45 curved at the front and an annular backward curved surface 47.

A union nut 52 with an internal thread 53 is provided in its rear region with a rear axial bore 54, the internal diameter of which is smaller than that of the internal thread 53 · The rear axial bore 54 opens conically to the rear end face of the union nut 52. The union nut 52 is provided with a spherical curved face 48, 25 at the transition from the internal thread 53 to the rear axial bore 54, which the rearward curved surface 47 of the pivoting part 40 comes into contact. The union nut 52 formed as a bearing part is inserted from behind over the rear area of the front pivot part 40 and screwed with its internal screw thread 53 onto the external screw thread 42 'of a counter bearing 42. Thereby, the rear region of the front pivot 40 passes through the rear axial bore 54 of the union nut 52. The counter bearing 42 has a spherically curved surface 46 on its rear side facing the front pivot 40, which engages the spherically curved surface 45 of the front pivot 40. The front end face of the counter bearing 42 substantially closes with the front annular end face of the union nut 52.

By screwing the union nut 52 onto the counter bearing 42

a

6, the ball-jacketed segment of the front pivot 40 is clamped between the swivel nut 52 and the counter bearing 42. The spherically curved surfaces 45, 46, 47, 48 all have the same center of curvature. The dimensions of the spherically curved surfaces 45, 46, 47, 48 in the circumferential direction are dimensioned such that the surfaces 45 and 47 of the front pivot 40 in the circumferential direction are smaller than the surfaces 48 of the bearing part formed by the union nut 52 and the curved face 46 of the counter bearing 42, so that the front pivot 40 is pivotable about the common center of the concentrically curved faces 45, 46, 47, 48, these being convex and concave curved, respectively.

A plate mounting 5, preferably of stainless steel, penetrating the plate 6, is screwed into an axial threaded bore 42 "of the counter bearing 42 15 by means of the screw 50 engaging the plate mounting 5 and in this way fastened to the counter bearing 42. plate mounting 5 and the plate 6 is provided with a plastic interior 3 ** At its internal screw thread 53 surrounding annular end face at the front free end, the swivel nut 52 is provided with a ring groove 5 &, in which a sealing ring 58 is arranged. 52 is screwed substantially completely onto the counter bearing 42, then the sealing ring 58 comes into contact with the rear face side of the plate 6, so that a seal of the space behind the plate 6 with respect to the opening of the plate mounting 5 receiving plate 6 is reached, plate 6 is thus connected via plate mounting 5, screw 50 and counter bearing 42 on the one hand and via union nut 52 e n the sealing ring 58, on the other hand, is attached to the front pivot part 40.

The fastening part 3 fixedly and sealingly connected to the plate 6 in this way is attached to the spacer 1, while the fastening bolt 2 is passed through the opening 31 in the rear segment 32 of the fastening part 3, the middle part 24 of the fastening bolt 2 comes into positive engagement with the opening 31. The front segment 20 of the fastening bolt 2 is inserted into the axial bore 12 of the spacer 1, the cross bore in the fastening bolt 2 being aligned with the transverse bore 14 in the spacer 1 and a securing pin 15 through the two transverse drilling is made. The securing pin 15 can be formed by a spring pin or by another conventional securing pin. In this way, 10 01 949. " 7 the fastening part 3 on the spacer 1 is secured both in the axial direction and in the radial direction with respect to the longitudinal axis 10 of the spacer 1.

Moreover, due to the square cross-section of the opening 31 of the fastening part 3 and of the middle segment 24 of the fastening bolt 2 as well as the securing pin 15 engaging through the opening 14, the fastening of the fastening part 3 around the longitudinal axis 10 of the spacer 1 is excluded. . Thus, a fixed bearing for the plate is formed by the interpreter 1, the fixing bolt 2, the fixing part 3 and the plate mounting 5.

Figure 2 shows a further embodiment of a fastening device according to the invention. The embodiment of the pivot bearing 4 corresponds to that of figure 1. In this embodiment, the rear segment 32 'of the fixing part 3' is provided with an opening 31 'passing transversely through the rear segment 32', which is formed as a round bore. The mid-section 24 'of the mounting bolt 2' has a cylindrical cross-section, the outside diameter of which is matched to the inside diameter of the bore 31 * Although the mounting bolt 2 'is by means of the crossbore 14 14 in the spacer 1 and the transverse bore in the mounting bolt 2 ', the securing pin 15 is secured against twisting relative to the spacer 1, the mounting part 3' in this embodiment of the mounting assembly can be pivoted around the longitudinal axis 10 of the spacer 1.

The rotatability of the fastening part 3 'around the longitudinal axis 10 of the spacer 1 and the provision of the pivot bearing 4 in the front segment of the fastening part 3' make a freedom of movement of the plate 6 in a circumferential direction around the longitudinal axis 10 of the interpreter 1, so that the embodiment shown in figure 2 shows a semi-fixed bearing with a one-plane pivot hinge 33.

Figure 3 shows a third embodiment of the mounting assembly according to the invention, wherein the pivot bearing 4 again corresponds to that in figure 1.

The rear segment 32 "of the fastening part 3" has a spherical circumferential shape, only at the front end of which a pin segment 30 "pointing towards the front pivoting part 40 projects in the direction of the longitudinal axis 30 of the fastening part 3". The 10 010 «».

8 external diameter of the pin segment 30 "is smaller than that of the ball segment 30 '. The passage opening 31" passing through the securing part 3 "narrows each time from the mouth of the passage opening 31" in the region of the ball surface towards the center-5 plane of the fastening part 3 ", so that the diameter of the passage opening 31" in the region of the central plane of the fastening part 3 "is smaller than in the region of the mouths of the passage opening 31" diameter of the passage opening 31 "in the region of the median plane of the fastening part 3" substantially corresponds to the external diameter of the shaft 20 "of the fastening bolt 2".

The spacer 1 "is spherically concave on its front end face 11", into which the axial bore 12 "opens, the radius of curvature corresponding to the radius of curvature of the ball section 15 30 '. Also the head section 22" of the fixing bolt 2 "on the side of the shaft around the shaft 20" is provided with a spherical concave cylindrical ring surface 21 ", the radius of curvature of which also corresponds to that of the ball segment 30 '.

To fix the fastening part 3 "to the spacer 1" 20, the fastening bolt 2 "is inserted through the opening 31" of the fastening part 3 "and into the axial bore 12" of the spacer 1 ”. By turning the mounting bolt 2 "into the axial bore 12", the cross bore 14 in the spacer 1 "is aligned with the respective cross bore in the mounting bolt 2", and a securing pin 15 is inserted through the cross bore 1 * 4 into the spacer 1 "and inserted through the fixing bolt 2", securing the fixing bolt 2 "in the spacer 1" in the axial direction and against twisting. Since the spherically shaped surfaces 21 "on the fixing bolt 2" and 11 "on the spacer 1" having the same center of curvature as the ball segment 30 'of the fastening part 3 ", the fastening part 3" is pivotable both about the longitudinal axis 10 of the spacer 1 "and pivotable about axes 16, which are substantially perpendicular to the longitudinal axis 10 horizontal plane 17 and which intersect the longitudinal axis 10 at the same point as the longitudinal axis 30 of the fastening part 3 "·

In this manner, a two-plane swivel hinge 35 is provided, which in connection with the swivel bearing 4 forms a loose bearing.

Figure 4 shows the attachment of a plate 6 to two vertical 10 0 1 9 posts 1 '. The distance of the vertical uprights to each other may be slightly less than the width of the plate 6. The upright 1 "may lie flush with the glass edge or lie on it, preferably centrally, protruding. In the region of its vertical longitudinal sides, the plate 6 is provided with four passage holes at a distance from the edge thereof, in which in each case a plate attachment 5 for holding the plate 6 is arranged. The eight fixing points of the plate 6 shown in this example consist of a fixed bearing F (top left in figure 4) and a semi-fixed bearing HF 10 (bottom left in figure 4) as well as six loose bearings L. This installation ensures on the one hand excellent fixation of the plate 6 to the vertical post 1 'and on the other hand provides a free freedom of movement of the plate 6, for instance caused by heat expansion of the plate 6. If desired, the plate 6 can also be attached to only one vertical post 1', the strut shown on the left in figure 4 are attached, provided that the fixed and the semi-fixed bearing are fitted to this stile.

The mounting assemblies shown in Figures 1 to 3 are largely mounted outside the construction site, where the 20 plates, for example facade panels of a building, must be fitted, the plate 6 with the respective mounting part 3. 3 ' , 3 "is provided outside the construction site and this prefabricated unit is delivered to the construction site. There it is then only provided by the respective fastening bolts 2, 2 ', 2" through the associated fastening parts 3. 3'. 3 ”in the relevant interpreter 1, 1” and attaching the securing pin 15 to the substructure. This fastening process can be carried out very quickly, so that the installation time of facade panels on the construction site is substantially reduced.

By applying a plate 6 to the substructure via a fixed bearing, a semi-fixed bearing and several loose bearings, all compensating movements take place without relative movements between the mounting assembly and the plate. However, if necessary, for example, plate attachments can also be used, which allow translation equalization between the plate and the mounting assembly, without direct relative movement between the plate and the plate fixing elements clamping the plate. The fastening assembly according to the invention can be both tired.

Include 10 bends as well as twists and is particularly useful for a polygonal facade.

The fastening of the plate 6 can be formed either by the flat sealing plate 5 shown in Figures 1 to 3, which engages in a countersunk bore of the plate, as well as by an applied pressure plate. Instead of the fixing of the rear segment 32 of the fastening part 3 on the fastening bolt 2 shown in Figure 1 by means of the respective square cross-section, another fuse against rotation can also be provided, for example an internal toothing in the bore 31 as well as a external serrations on a then cross-sectional round center segment of the mounting bolt are formed. Also in this area a fuse against twisting is possible by means of a securing pin, as it is arranged between the interpreter 1 and the fixing bolt 2.

10 01. '·.

Claims (13)

1. Fixing assembly for applying plates, in particular glass or panel plates, to a joist (1; 1 ") of a substructure, preferably for a facade of a building, with a fixing part (3; 3 *» 3 ") * that can be attached to a rear segment (32; 32 '; 32") by means of a mounting bolt (2; 2'; 2 ") on the spacer (1; 1") and that with a front segment (40) communicates with a plate mounting (5) for holding a plate (6). Fixing assembly according to claim 1, wherein the fixing bolt (2; 2 '; 2 ") through an opening (31; 31'; 31") in the rear segment (32; 32 '; 32 ") of the fixing part (3; 3 '; 3 ”), grips an opening in the interpreter (1; 1") and is secured herein. 15 Fixing assembly according to claim 2, wherein the fixing bolt (2; 2 '; 2 ") is formed as a plug bolt, which is secured by means of a securing pin penetrating through a bore (14) through this and the spacer (1; 1"). (15) is attachable to the interpreter (1; 1 "). Fastening assembly according to claim 1, 2 or 3. wherein the fastening part (3) can be fixedly attached to the spacer (1). Fixing assembly according to claim 1, 2 or 3. wherein the fixing part (3 ') can be fixed to the spacer (1) with respect to the longitudinal axis (10) of the spacer in the axial direction and in the radial direction while retaining pivotability around the longitudinal centerline (10) or around a centerline extending substantially parallel thereto. Fastening assembly according to claim 5. wherein the rear segment (32 ') of the fastening part (3') comprises a one-plane pivot hinge (33). 30 Fixing assembly according to claim 1, 2 or 3. wherein the fixing part (3 ") can be fixed to the spacer (1") with respect to the longitudinal axis (10) of the spacer in the axial direction and in the radial direction of pivotability about the longitudinal axis (10) or about a center axis extending substantially parallel thereto, and while retaining pivotability about axis (16) which is in a plane substantially perpendicular to the longitudinal axis (10) and the longitudinal centerline (10) and the parallel axis extending parallel thereto substantially in the same point 10 01 9 4 9 '. cut as the longitudinal centerline (30) of the mounting part (3 "). Fixing assembly according to claim 7, wherein the rear segment (32 ") of the fixing part (3") comprises a two-plane pivot hinge (35). 5 Fixing assembly according to any one of claims 1 to 8, wherein the front segment (40) is pivotally connectable to the plate fixing (5) Fastening assembly according to claim 9> wherein the front segment of the fastening part is formed as front swiveling part (40) and part of a swivel bearing (4), which furthermore comprises a counter bearing (42) connected to the plate fastening (5) and a swivel part (40) and counter bearing (42) together hold bearing part (52). Fixing assembly according to claim 10, wherein the front pivoting part (40) and the counter bearing (42) on the one hand, as well as the front pivoting part (40) and the bearing part (52) on the other, each contacting concentrically curved surfaces (45, 46, 47, 48). Fastening assembly according to any of the preceding claims, wherein the front segment (40) and the rear segment (32; 20 '; 32 ”) of the fastening part (3; 3'; 3") are formed by two separate parts, which can be joined together by means of a connection (4l). Fixing assembly according to any of the preceding claims, wherein the spacer (1; 1 "), the fixing part (3; 3 '; 3") and / or the plate holder (5) or at least parts thereof consist of a staple or only little heat-conducting material. 1 ö 01 Q · ;: "