EP0801202A2 - Lattice cross assembly device - Google Patents

Abstract

The connection device is used between glazing bars (101,102) sandwiched between the inner and outer window panes of a double-glazing unit. Each is formed from a similar profile with two broad sides and two narrow sides and has a pin (111) fitting through the main glazing bar (101), received in a clamp element (113) at either side. The clamp elements are fitted into the ends of the abutting secondary glazing bars (102). The ends of the pins are fitted into respective bores provided by the clamp elements which taper in the insertion direction of the pins, so that the clamp element is pushed outwards upon insertion of the pin, to secure it in the end of the secondary glazing bar.

Description

The invention relates to a connecting device for a crossbar construction of the type specified in the preamble of claim 1.

Rungs in double glazing are between two panes of e.g. B. windows arranged. The rungs consist of hollow profile rods, the z. B. are plugged together by means of cross-connectors and are connected to the spacer frame of the double glazing with connecting plugs. The rungs either have the metal color or they are coated with paint, whereby the color of the rungs is usually matched to the color of the window frame.

Connecting devices, for example the connecting device of the type mentioned at the outset, which is known from DE 36 38 355 A1, are used to connect the cross struts to the main strut. In this known connecting device, a clamping piece is used, the pin receiving hole of which is a cylindrical fitting bore for a cylindrical connecting pin, the connecting pin and fitting bore being additionally provided with longitudinal grooves. If the pin is inserted into the hole of the clamping piece inserted in a cross strut, there is a risk that the clamping piece will be pushed into the cross strut, whereby the desired positive connection of the cross strut to the main strut by means of the clamping piece is no longer guaranteed. In addition, the clamping piece with its side edges does not lie over the entire surface of the inner wall of the respective cross strut because laterally projecting lugs are formed on the front end of the clamping piece in the insertion direction, which give rise to one Provide point contact connection between clamping piece and cross strut.

In the utility models DE 89 13 616 Ul and DE 89 00 359 Ul, a connecting piece is described, which is used to hold two cross struts on a continuous, ie uninterrupted strut. The continuous strut has a through hole at a crossing point, through which the connecting piece can be inserted, so that it projects on both sides of the continuous, continuous strut with a projection. One of the two cross struts is placed on each of these two projections, so that the struts are assembled into a right-angled crossbar. The connecting pieces are each formed in two parts, so that they have an expansion joint in their longitudinal center into which an expansion body can be inserted. The expansion body consists either of a barbed expansion wedge (DE 89 13 616 Ul) or of a screw (DE 89 00 359 Ul) which is screwed into the groove of the connecting piece. The expansion wedge (DE 89 13 616 U1) is inserted after one of the two cross struts has been attached. The screw (DE 89 00 359 U1) is inserted after the cross struts have been placed on the projections, so that the expansion element must be operated with a long, narrow element which is passed through one of the cross struts. This is a very cumbersome process, which is why these connectors could not prevail in practice.

From DE 39 41 288 Al a connecting element for connecting hollow rung profiles is known, which is screwed to a cross strut by a screw, so that the cross struts are permanently fixed in position on the connecting element. The screw is inserted from the outside through the cross strut so that the screw head is visible from the outside and disturbs the visual impression of the rung cross.

The invention has for its object to provide a connecting device for a crossbar construction that is easy to use and yet a safe and permanent connection between struts, in particular a torsionally rigid and torsionally rigid connection between the struts formed from hollow profiles is ensured, expediently also preventing the hollow profiles from opening.

This object is achieved by a connecting device with the features of claim 1 and a connecting device with the features of claim 4. Advantageous embodiments of the invention are characterized in the subclaims.

The connecting device according to claim 1 has a clamping piece which rests in a form-fitting manner in the end regions of the cross struts and thus brings about a tensile, torsionally and torsion-resistant connection of the cross struts to a main strut. In addition, the side walls of the clamping pieces are provided with recesses for receiving internal beads formed on the struts, so that the frictional engagement between the clamping piece and the cross struts is increased. Even if the clamping pieces are press-fitted into the end regions of the cross struts, the hollow profiles on the beads, on which preferably a seam holding the hollow profile is preferably provided, are prevented from rising, since the beads are received in the recess in the side walls of the clamping pieces and are held together by the portions of the clamping piece delimiting the recess. The use of thin-walled profiles is thus made considerably easier with clamping pieces according to claim 1, because the clamping pieces stiffen these end regions, since they are fitted in a form-fitting manner into the end regions of the cross struts.

The connecting device according to claim 4 has clamping pieces which are used in cross struts and in each of which a hole is provided for receiving a pin penetrating the main struts. The hole in the clamping pieces is conically tapered in the pin insertion direction, so that the clamping piece transversely to the hole when the pin is inserted into the hole Clamping piece widened transversely to the hole when the pin was inserted into the hole and was thereby wedged against the inner wall of the cross strut. The connection device according to the invention is thus assembled simply by inserting the clamping pieces into the cross struts and inserting the pin passing through the longitudinal strut into the holes of the clamping pieces. Neither screws nor clamping parts have to be adjusted with any actuating means on the clamping pieces. Despite the simple handling due to the special design of the clamping pieces, wedging is achieved in the cross struts, which ensures a firm connection between the struts.

Fig. 1

schematisch ein Fester mit einer Isolierverglasung in Vorderansicht,

Fig. 2

einen Schnitt entlang der Linie II-II in Fig. 1 in vergrößerter Darstellung,

Fig. 3

schematisch die Herstellung des Sprossenhohlprofils aus einem Breitbandcoil in perspektivischer Darstellung,

Fig. 4

einen Ausschnitt aus der erfindungsgemäßen Sprossenkreuzkonstruktion mit rechtwinklig und schräg angesetzten Querstreben,

Fig. 5

eine seitliche Ansicht der Sprossenkreuzkonstruktion von Fig. l,

Fig. 6

die einzelnen Elemente der Konstruktion von Fig. 4 vor deren Verbindung,

Fig. 7

eine Schnittansicht einer Hauptstrebe mit eingestecktem Vierkantstift und einer anzusetzenden Querstrebe mit Klemmstück,

Fig. 8

ein bevorzugtes Ausführungsbeispiel des erfindungsgemäßen Klemmstücks,

Fig. 9

das Klemmstück von Fig. 8 im Querschnitt,

Fig. 10

ein weiteres Ausführungsbeispiel der einzelnen Elemente der Konstruktion aus Fig. 4 vor der Verbindung in derselben Darstellung wie in Fig. 6, und

Fig. 11

eine Schnittansicht entsprechend Fig. 7 unter Verwendung des Klemmstücks gemäß Fig. 10.

The invention is explained in more detail below with reference to the drawings; show it:

Fig. 1

schematically a window with double glazing in front view,

Fig. 2

2 shows a section along the line II-II in FIG. 1 in an enlarged view,

Fig. 3

schematically the production of the hollow rung profile from a broadband coil in a perspective view,

Fig. 4

a section of the crossbar construction according to the invention with cross braces set at right angles and at an angle,

Fig. 5

2 shows a side view of the rung cross construction from FIG. 1,

Fig. 6

the individual elements of the construction of Fig. 4 before their connection,

Fig. 7

2 shows a sectional view of a main strut with inserted square pin and a cross strut to be attached with a clamping piece,

Fig. 8

a preferred embodiment of the clamping piece according to the invention,

Fig. 9

8 in cross section,

Fig. 10

a further embodiment of the individual elements of the construction of FIG. 4 before the connection in the same representation as in Fig. 6, and

Fig. 11

7 shows a sectional view corresponding to FIG. 7 using the clamping piece according to FIG. 10.

In Fig. 1, a window 1 is shown with double glazing and interposed cross bar construction for rung windows. However, the invention relates not only to cross bar constructions for rung windows with double glazing, but also to cross bar constructions for double glazing par excellence.

A window 1 with insulating glazing generally has a window frame 2, at least two glass panes 3 arranged at a distance and stored in the window frame 2, and a spacer frame 4 which holds the glass panes 3 at a distance and is filled with desiccant. Rungs or struts 5 are arranged in the space between the glass panes 3. The rungs 5 consist of hollow profile bars made of metal with a longitudinal weld 12a, which are assembled to form an intersection. At the crossing points, the rungs 5 are assembled in a manner known per se with cross connecting pieces (not shown). Connection plugs take over the mounting of the rungs 5 on the spacer frame 4 in a manner known per se.

The rungs 5 can have different hollow profile cross-sectional shapes. A common profile is shown which has side walls 6 arranged parallel to the glass panes 3 and end walls 7 running transversely to the side walls 6. The end walls 7 are narrower than the side walls 6, which is why a preferably fillet-shaped transition region 6a is provided between the walls 6 and 7.

It is essential that a longitudinal profile indentation 8, Sb or groove-shaped indentations 9 is profiled in both end walls 7, expediently in the longitudinal center thereof.

The profile indentations 8, 8b have the same shape and are arranged in mirror image to one another. The depth of each groove 9 is z. B. 1/8 to 1/10 of the height of the profile (distance between the end walls 7). The width of the groove 9 should be as small as possible, but in any case so small that the bottom of the groove remains invisible from the outside. The side walls 8a of the grooves 9 preferably lie against one another.

The rungs or struts 5 are each cut to the required length by hollow profile rods 11. The hollow profile rods 11 are made of a relatively thin metal strip, e.g. B. formed of aluminum, the longitudinal edges 12 of the metal strip are bent towards each other, so that a closed tube Ila is formed. The butt edges or longitudinal edges 12 are welded together, so that a weld seam 12a is formed. The subsequent profiling produces the groove 9 in such a way that the weld seam 12a is displaced into the interior 5a of the profile and becomes invisible. So that the rung 5 looks the same, it is provided according to an expedient embodiment of the invention that the area of the tube 11a opposite the groove 9 with the weld seam 12 is grooved in the same way and contains the grooving.

As already mentioned, the rung 5 is preferably made of aluminum. The wall thickness of the rung is in particular about 0.4 to 0.6 mm. The outer lateral surface of the rung preferably carries a color layer 6c or is anodized.

A particularly simple method for producing a hollow profile rod 11 results from FIG. 3. The starting material is a relatively wide metal strip 13, which is pulled off from a broadband coil 14. The metal strip 13 consists, for. B. made of aluminum and carries a relatively thin layer of paint 6c on the outside 13a.

The metal strip 13 is first cut longitudinally into a plurality of strips 15 during the pulling process, from which preferably hollow profile rods 11 are z. B. by roll deformation and / or shaped. The strips 15 can also be rolled up and further processed later. The hollow profiles 11 which are formed from the strips 15 can have the same or different cross-sectional shapes. Likewise, the strips 15 can be the same width or different widths.

The division of the metal strip 13 into a plurality of strips 15 by longitudinal cuts 16 takes place at a processing station A which the metal strip 13 passes through when it is pulled off. In the take-off direction, there is a processing station B with shaping tools (not shown) behind the processing station A, in which the strip 15 forms a z. B. in cross section circular tube Ila is formed with abutting longitudinal edges 12. The color layer 6c is located on the outer surface of the tube. At a processing station C downstream of the processing station B with a welding device, the longitudinal edges 12 are welded to the weld seam 12a, preferably by laser welding. Behind the processing station C there is a processing station D with molding tools (not shown), with which the profile indentations 8, 8b are formed and, at the same time or subsequently, the profiles of the side walls 6 and the transition areas 6a and end walls 7 can be formed.

During welding, paint burns in the area of the weld 12a. Due to the inventive profile retraction in the area of the weld, the weld itself and the color areas affected by the heat during welding are hidden in the groove 9, so that they remain invisible from the outside. This unusual measure ensures that hollow profiles formed and welded from a coated metal strip can be used as rungs without the weld seam and the partially burned color areas visually disturbing. But even when using uncoated metal strips, rungs can be formed, the weld seam of which is hidden and does not have a visual effect.

The continuously produced hollow profile rods 11 are cut to suitable commercial lengths and are available to the manufacturer of insulating glazing as an intermediate product. The manufacturer cuts the rungs 5 from the hollow profile rod 11 and forms the desired rung configurations for double glazing.

With regard to the manufacturing process, it follows from the foregoing to provide at least one profile indentation to make a weld invisible and, for optical reasons, suggests arranging at least one further profile indentation in mirror image for the profile indentation with the weld seam. The weld seam does not have to be arranged on one end face. Rather, it can e.g. B. are also on a side wall if the visual requirements for the rung profile allow this.

FIG. 4 shows an exemplary embodiment of a rung cross construction according to the invention, which comprises a hollow profile 101 made of sheet metal serving as the main strut or rung, two vertically attached hollow profile cross struts 102 and an obliquely attached hollow profile cross strut 103. The struts 101, 102 and 103 are manufactured using the rolling method and are of identical design. The rolling of the sheet metal starting material from which the profiles are made is such that an inner bead or fold 104 is formed on both sides of the profile, which contributes to the stability of the profiles. The special cross-sectional shape of the struts 101, 102 and 103 can be seen, for example, from FIG. 5, which shows a side view of the left half of the rung construction in FIG. 4, specifically a view of the narrow side of the two cross struts on the left in FIG. 4 102, which, like the cross strut 103, are cut off at their connecting ends by contour milling such that there are upper and lower sections 105 and 105 'which grip the main strut 101 laterally overlapping. 5 shows a view of the main strut 101 which corresponds to a profile cross section. The two lateral beads 104 are visible, one in the plane of the drawing are arranged vertically extending plane, which represents one of the two mirror symmetry planes of the struts 101, 102 and 103. The second mirror plane of symmetry runs perpendicular to the former through the two broad sides of the profile. The profile broad sides comprise two head surfaces 106 and 106 ′ running parallel to one another as well as two inclined surfaces 107 which adjoin the sides to the narrow profile sides and which are curved concavely. The contour of the narrow profile sides results from the internal bead formation as a rounded transition 108 and 108 'from the inclined surfaces 107 to the beads 104 and 104'.

The contour milling at the connecting ends of the cross struts 102 and the cross strut 103 is selected such that a protruding part 109 of the head surface of these struts abuts the transition edge of its head surface 106 or 106 'to the adjoining inclined surface 107 when the cross strut is attached to the main strut. The front edge of the projecting part 109 therefore runs straight, specifically perpendicular to the longitudinal axis of the strut. The projecting part 109 is followed by lateral, retreating edges 110 which, when the cross struts are attached to the main strut 101, adjoin the convex inclined surfaces 107 with their cut edges. The oblique edges 110 extend at the cross strut connection ends up to their narrow sides, which are trimmed straight so that they abut the narrow sides of the main strut 101.

This results in an essentially U-shaped profile profile in the area of the connection ends of the cross strut profiles when viewed on their narrow sides, the U-legs of the contour milling being correspondingly curved. When monitoring the broad sides of the cross struts, there is essentially a trapezoidal profile in the area of their connecting ends.

The shape of the hollow profile struts described above is intended to give an optical impression that is present in real rungs. However, this shape is not mandatory. Rather you can all possible, essentially rectangular cross-sectional shapes are used.

It is essential to the cross-bar construction in question that a skeleton structure is selected which allows the wall thickness of the hollow-profile struts to be made significantly less than in the case of conventional hollow-profile struts which are used for cross-bar constructions. In particular, the skeleton structure described in more detail below allows profiles with a wall thickness which is up to 10 times less than that of previous rung cross constructions to be used.

An element of the skeleton structure is shown in FIGS. 4 and 5, namely a connecting pin 111. The connecting pin 111 passes through the main strut 101 in the transverse direction, the narrow side walls of which are provided with push-through openings 112, as can be seen, for example, from FIG. 6, which shows an exploded view of the elements 4, wherein the connecting pins 111 are inserted into clamping pieces 113 designed as clamping pieces, which are inserted into the connecting ends of the cross struts in the manner described in more detail below.

As can be seen from FIGS. 6 to 9, the clamping piece is designed as a solid body, the contour of which, as can best be seen from the cross-sectional representation of FIG. 9, is adapted to the inner wall contour of the profiles. For example, the clamping pieces 113 are complementary to the hollow profiles and have two flat, opposing head surfaces 114 and 114 'and laterally adjoining inclined surfaces 115 and 115' which are convexly curved to the inclined surfaces 107 of the hollow profiles. In the exemplary embodiment shown in FIG. 9, the side surfaces 116 are only roughly adapted to the inner contour of the hollow profiles, which have the beads 107 and the rounded surfaces 108 and 108 'at these points, which have a profile in cross section together with the central beads on the bulbous course a B recalls. The side surfaces 116 do not have this contour unit, which is why the width of the clamping piece 113 from side surface 116 to side surface 116 corresponds approximately to the clear distance between the opposing beads 104 in the hollow profiles. As an alternative to this, it can advantageously be provided that the width extension of the clamping piece 113 is chosen so large that it corresponds to the distance between the narrow inside walls of the hollow profiles. In this case, recesses are provided at the points in the side walls 116 of the clamping piece 113, which are adjacent to the beads 104. As a result, all-round surface contact of the clamping piece 113 with the inner wall of the respective hollow profile is achieved.

As can be seen from the cross-sectional representations of the clamping piece 113 from FIG. 9, a bore or a hole 117 is formed in the clamping piece center, which serves to receive the connecting pin 111 and has a cross-sectional shape that is matched exactly to that of the connecting pin. The cross-sectional shape shown in FIG. 9 is preferred, namely a square cross section of the bore 117 and a corresponding square cross section of the connecting pin 111.

In order to ensure a tight fit of the connecting pin 111 in the pin receiving bore 117 of the clamping piece 113, and at the same time a tight fit of the clamping piece 111 in the connecting end section of the cross struts, the clamping piece 113, as best shown in FIG. 8, is designed in the manner of a plastic dowel . For this purpose, the full body clamping piece 113 is provided in the longitudinal direction with a slot 118 which extends in the direction of the central longitudinal axis of the clamping piece 113. The base of the slot 118 lies in the front third of the fitting bore 117 for the pin 111, which bore also extends along the longitudinal center axis of the clamping piece 113, with a longitudinal extent which corresponds to approximately two thirds of the length of the clamping piece 113. In other words, the fitting bore 117 is designed as a blind hole. Starting from his The base in the front part of the fitting bore 117 in the pin insertion direction opens the slot towards the opposite end of the clamping piece 113 with an angle a located in the plane of the drawing, as can be seen from the left half of FIG. 8. The right half of FIG. 8 shows the state of the clamping piece 113 fully inserted into a cross strut, which for the sake of clarity is not shown any more than the pin 111 inserted into the fitting bore 117. It is clear that the in the relaxed spread position according to the left Half of FIG. 8 straight fitting bore 117 in the compressed state of the clamping piece 113 according to the right half of FIG. 8 in the area of the slot 118, the V-shaped spread of which has been completely overcome, has a cross section which is increasingly decreasing in the direction of insertion of the pin 111. When the pin is inserted, this has the effect that the potential spreading force of the clamping piece is supported in the inserted state by the spreading force exerted transversely to the pin insertion direction on the fitting bore 117 in the slot area through the slot on the bore walls, which causes compression of the clamping piece material in the slot area of the fitting bore becomes. The result of this is an excellent press fit of the clamping piece 113 in the respective hollow profile and an equally high-quality press fit of the pin 111 in the fitting bore 117.

As can further be seen from FIG. 8, the clamping piece 113 is tapered at an angle β at its front end in its insertion direction. For this purpose, it has sloping side wall parts 120. These are preferably formed both on the side walls 116 and on the head surfaces 114 and, if appropriate, also on the inclined surfaces 115. This wedge-shaped design of the front clamping piece allows, in particular in view of the spreading design of the clamping piece, a simplified insertion into the connection end of the respective cross strut.

In the area of its rear end face 121 in the direction of insertion, the clamping piece 113 is widened, specifically also by inclined surfaces, namely by the surfaces 122, which are designed to be complementary to the inclined surfaces 120. A particularly intimate press contact of the clamping piece 113 is achieved at its outer end. Also between the inclined surfaces 122 at the rear and the inclined surfaces 120 at the front end of the clamping piece 113 extend obliquely extending wall parts 123 in the region of the side walls 116. These extend at an angle γ which is half the opening angle α of the slot 118, and when the clamping piece 113 is inserted into a cross hollow profile, these wall parts 123 assume a parallel orientation to the profile side walls, analogously to a plastic expansion dowel.

The variant of the clamping piece 113 shown in FIG. 6 corresponds to the design of the clamping piece from FIG. 8 with the difference that the inclined walls 122 located at the rear are not provided in the variant from FIG. 6, and with the difference that the longitudinal slot 118 extends up to close to the pin insertion end wall of the clamping piece 113. The clamping piece 113 is shown in FIG. 6 in the state it is in when it is inserted into the hollow profile 102, that is to say after overcoming the original spread shape of the clamping piece 113, as shown in the left half of FIG. 8. Left and right to the slot 118 run parallel to this in the head surfaces 114 and 114 'of the clamping piece 113 grooves 124 which extend over the entire length of the clamping piece 113 and open into the respective end faces. These grooves cause a certain elasticity of the clamping piece 113 in the transverse direction, that is to say in the direction of its two narrow sides 116, which facilitates the insertion of the clamping piece into the respective hollow profile.

As can be seen from FIG. 7 in connection with FIG. 5, the front end face of the clamping piece 113 is flush with the edges of the recessed narrow sides of the cross struts. This is the basis of the U-shaped profile cross-section when looking at the narrow side of the profile connection end. This makes a large area The front clamping piece end face has reached the opposite narrow side of the main hollow profile. From Fig. 7 it can also be seen that the length of the connecting pin 111 and the depth of the fitting bores 117 are selected so that the pin and clamping pieces form a rigid and highly rigid skeleton when the pin is fully inserted into the clamping pieces, without the hollow profiles 101 and 102 also being used enter into a passport connection. It is rather the case that, when the skeleton elements 111 and 113 are completely connected, the transverse hollow struts 102 overlap the main strut 101 in a visually correct manner, but the hollow profile parts do not exert any force on one another. Rather, the hollow profiles form a kind of skin that serves as a veneer for the skeletal structure and is not exposed to any bending forces. For this reason, the hollow profiles of the rung construction described above can be made much thinner than in the prior art, in which the hollow profiles have a supporting function.

From FIG. 7, but also from the middle part of FIG. 6, it can be seen that the push-through holes 112 in the main strut 101 in the plane of the drawing, this is the crossbar plane, have a dimension which is approximately the same as the strength of the connecting pin 111 in this Level corresponds. This achieves a play-free reception of the pins 111 in the cross bar plane, with the result that the predetermined cross angle is exactly maintained. Perpendicular to the cross bar level, the pin 111, however, is added with play in the push-through openings 112. This is achieved in that the push-through openings extend essentially up to the top surfaces 106 and 106 'of the main hollow profile and over the entire width of the narrow sides of the main hollow profile. This results in the following shape of the push-through openings 112. When viewed on the narrow sides of the main strut 101, the push-through holes have a rectangular shape, the narrow sides of the rectangle running in the longitudinal direction of the main strut 101 and corresponding to the thickness of the pin 111, while the long side of this rectangle exceeds the strength of the pen; when looking at the Broad sides of the main struts 101 have the push-through openings 112 for the pin 111 U-shaped, and the base of this U-shaped shape is set back by a predetermined amount from the outer edge of the hollow strut, preferably up to the head side 106 of the hollow strut 101 or at least to the center of the respective sloping surface 107. In no case does the base of the U-shape extend so far into the main strut that its structure is weakened, or that there is no covering by the projection 105 of the fully attached cross struts 102.

10 and 11 show a modified embodiment of the crossbar construction in the same view and arrangement as the crossbar construction according to FIGS. 6 and 7, only the differences compared to the arrangement according to FIGS. 6 and 7 being discussed.

The main difference of the crossbar construction according to FIGS. 10 and 11 in comparison to the crossbar construction described above consists in a different shape of the clamping pieces 113. Thus, the clamping piece 113 according to FIGS. 6 and 7 is not provided with a longitudinal slot and has a contour with a projection on the front, as will be described in more detail below.

As can be seen from FIGS. 10 and 11, the clamping pieces 113 are shaped in such a way that they fit into the end of the straight or inclined cross strut at the top, bottom and sides with a plurality of, in total, four mating surfaces. The upper and lower mating surfaces 125 are divided by two grooves and extended beyond the end face of the clamping piece 113 to be attached to the main strut 101 to a projecting end section 126 which, because of the division, consists of three individual segments which are similar when connected to the main strut 101 how the overlap sections 105 lay flat on the main strut 101. The segmentation makes it possible, even with less elastic plastics and a greater wall thickness of the segments to achieve a resilient system with a press fit effect on the lateral top and bottom of the main struts.

The sections 126 are somewhat shorter than the overlap sections 105 of the cross struts 102 and 103, so that they are not visible after the profile parts have been connected. The clamping pieces 113, which are made of plastic, for example by injection molding, receive the pins 111 in an exact square recess, as already described, with a press fit.

In order to achieve an even better form-fitting adaptation of the clamping pieces 113, not only grooves for receiving the beads 104 are excluded on their side faces, but a ridge is formed parallel to the clamping piece head sides, which can be seen in FIG Bead 104 formed recess on the outside of the main strut 101 inserts.

Furthermore, friction ribs extending in the direction of insertion are preferably formed for a more tight fit of the clamping pieces 113 on the head sides 114 and 114 'and side walls. This reduces the precision requirements for the manufacture and processing of the hollow profiles as well as the clamping pieces.

The shape of the main and transverse struts and the fitting of the clamping pieces adapted to them are not limited to the solution shown, rather, depending on the requirements, there can also be considerable deviations from this and other types of fitting can be selected as defined in the claims. In principle, it is possible to adapt the shape of the clamping pieces only very roughly to that of the cross struts and to use a hardening plastic compound to firmly fit the former. The same applies to the use of the pin or pins in the clamping pieces. Form or contour cutters are preferably used to form the plastic clamping pieces.

This also applies to the manufacture of sections 104 of FIG Hollow profiles. The length of the clamping pieces 113 depends both on the width and the wall thickness of the cross struts 102 and 103. This also applies to the length of the overlap sections 126. Depending on the size and wall thickness of the cross struts, the fit and the material of the clamping pieces, a wide variety of dimensions are included the advantageous transfer of the connecting forces of the rung cross construction to the clamping piece-pin skeleton possible.

Claims (13)

Connecting device for a crossbar construction with main struts (101) and cross struts (102 or 103) made of the same hollow profiles having two broad side walls and two narrow side walls, wherein - With a main strut (101) two laterally adjacent cross struts (102 or 103) are connected, a pin (111) passes through the main strut (101) in the transverse direction, - The ends of the pin (111) each in a hole (117) of a clamping piece (113), - The clamping pieces (113) are each adapted to the inner wall contour of the cross struts (102 or 103) formed from hollow profiles, - At least the cross struts (102 or 103) each have an inner bead (104, 104 ') on opposite lateral areas, and - The clamping pieces (113) have side walls (116), in which recesses for receiving the beads (104, 104 ') are made. Connection device according to claim 1,
characterized,
that the clamping pieces each have a press fit in the end region of one of the cross struts (102 or 103). Connection device according to claim 1 and / or 2,
characterized,
that the clamping pieces (113) have two flat, opposing head surfaces (114 and 114 ') and laterally adjoining inclined surfaces (115 and 115'). Connecting device for a rung cross construction, in particular according to one or more of claims 1 to 3, with main struts (101) and cross struts (102 or 103) made of the same hollow profiles having two broad side walls and two narrow side walls, wherein - With a main strut (101) two laterally adjacent cross struts (102 or 103) are connected, a pin (111) passes through the main strut (101) in the transverse direction, - The ends of the pin (111) each in a hole (117) of a clamping piece (113), and - The clamping pieces (113) of the inner contour of the cross struts (102 or 103) are adapted,
characterized,
that the hole (117) in the clamping piece (113) is designed as a conically tapered hole in the pin insertion direction such that the clamping piece (113) widens transversely to the hole when the pin (111) is inserted into the hole (117) and thereby against the inner wall of the Cross strut (102 or 103) is wedged. Connection device according to claim 4,
characterized,
that the clamping piece (113) is longitudinally slotted in the manner of an expansion dowel, the slot (118) opening in the direction of insertion of the front end edge of the clamping piece (113), passing through the pin receiving hole (117), ending in front of the rear end edge of the clamping piece (113) and at relaxed, not in the cross strut (102 or 103) inserted clamping piece (113) wedge shape so that two through the slot (118) fixed clamping piece legs with each other parallel side longitudinal edges in the direction of the front clamping piece front edge diverge, whereby the two legs are clamped transversely to the narrow side inner wall of the cross strut (102 or 103) when the clamping piece (117) is inserted into the cross strut under wedge action due to the closed slot (118). Connection device according to claim 1 or 5,
characterized,
that the pin receiving hole (117) in the clamping piece (113) is a blind hole. Connecting device according to one or more of claims 1 to 6,
characterized,
that the pin receiving hole (117) in the clamping piece (113) is a fitting hole for the pin (111). Connecting device according to one or more of claims 1 to 7,
characterized,
that the pin (111) and the pin receiving hole (117) have a square cross section. Connecting device according to one or more of claims 1 to 8,
characterized,
that the clamping pieces (113) are tapered in the region of their front end edges, with inclined guiding surfaces (120). Connecting device according to one or more of claims 1 to 9,
characterized,
that the pin (111) is of equal thickness over its entire length. Connecting device according to one or more of claims 1 to 10,
characterized,
that the pin receiving hole (117) in the clamping pieces (113) extends over approximately two thirds of the length of the clamping pieces (113). Connecting device according to one or more of claims 5 to 11,
characterized,
that the slot (118) in the clamping pieces (113) extends over approximately two thirds of the length of the clamping pieces (113). Connecting device according to one or more of claims 4 to 12,
characterized,
that the clamping pieces (113) each sit with a press fit in the end region of a cross strut (102 or 103).

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