ES2928127T3 - Support profile with tilt element - Google Patents

Abstract

A support profile (30) is proposed with a first profile foot (24) and a second profile foot (32) and a support profile base (38) to hold a plate element (36), the profile having support (30) at least one tilting element (10) which is arranged on at least one profile leg (24, 32). (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Support profile with tilt element

The invention relates to a support profile comprising an inclination element for adjusting the inclination of plate elements.

prior art

Balustrade plates are known, in particular for glass balustrades, which are predominantly free-standing and are fastened only in the region of the feet, that is to say at the lower edge thereof, in an anchored U-shaped retaining profile. to a building component and also fastened on it. The heavy glass plates are securely anchored in the U-shaped retaining profile in such a way that they can reliably absorb the loads acting on the glass plates and transmit these loads to the building, thus meeting the requirements, eg also as fall protection.

In particular, when mounting the individual balustrade plates that are to be placed next to each other, these plates must be aligned in such a way that, in the balustrade that extends over a long distance, the individual balustrade plates of the same They are arranged side by side to produce a flat surface when joined. The problem is that the building components on which the U-shaped retaining profiles are intended to be arranged may have a variably vertically inclined or undulating surface along their length, which makes assembly difficult.

Document EP 1277894 A2 describes an attached handrail where a lower edge part of a disc-shaped filler is attached to a U-shaped supporting body, wherein a pair of wedge-shaped bodies having adjacent adjustable inclinations they are arranged between the inside of a sidebar and the disk-shaped filling. The disc-shaped filler is held pressed between the pair of wedge-shaped bodies and both the bar and a second additional bar. The clamping force with which the disc-shaped filler is clamped can be adjusted by moving the two wedge-shaped bodies against each other. The clamping force is defined by an adjustment screw by means of which one of the wedge-shaped bodies is adjusted against the other.

A drawback of the cited prior art is that the wedge combination described in EP 1277894 reveals clamping force adjustment, but not angular adjustment of the disc-shaped padding. Furthermore, the described wedges move towards the bottom of the support body during insertion and slide further and further down. The further these wedges descend into the support body, the more unstable the grip for the disc-shaped filler becomes.

US 2016/298337 A1 describes a hinged glass handrail threshold. The invention relates to a double hinged threshold for adjustably fixing the panels of a handrail system to a floor, the threshold having a U-shaped channel. A pair of hinge plates is rotatably mounted within the channel . A cylindrical hinge element is provided at the lower end of each of the hinge plates and extends the length of the hinge plate. A slot is provided at the bottom of the sill to receive the cylindrical hinge element. The pair of hinge plates is aligned within the sill in a mirror image. A series of adjusting and locking screws are provided along the sill, which screws extend from the top of the sill or from the sides of the sill to that point and are adapted to selectively press against the pair of hinge plates in para movably adjusting the plates inward against a glass panel or outward away from a glass panel to vertically align and lock the glass panel.

The hinge thresholds described in US 2016/298337 A1 are arranged on the U-shaped profile leg and act at the foot of the U-shaped profile on a sealing device inside which the glass panel is arranged, so they only act indirectly on the glass panel. The effect at this point is minimal and makes it difficult to achieve the desired fit, since the angle of inclination of the upper glass panel at this point is not sufficient.

Document WO 2016/024299 A1 refers to a fixing system for glass panels with bilateral adjustment with respect to a vertical axis. The fixing system for glass panels with bilateral adjustment with respect to a vertical axis is made up of an external aluminum profile and a box-shaped body that is housed in the profile on opposite sides of the panel and is equipped with two independent fixing devices. each one arranged on opposite sides of the panel, in such a way that it is possible both for the panel to rotate with respect to the vertical axis as a consequence of acting on only one of the fastening devices and for the plate to be locked in the position of use as consequence of acting on both clamping devices.

The problem faced by the invention is therefore that of providing angular adjustment for a plate, in particular a balustrade plate.

Description of the invention

According to the invention, this problem is solved by a support profile comprising a tilting element for adjusting the tilting of the plate elements according to claim 1. Advantageous embodiments, details and features of the invention are to be found in the dependent claims and in the following description of the embodiments according to the invention, together with the drawings of the solution according to the invention. A support profile is disclosed comprising a first profile leg and a second profile leg and a support profile sole for holding a plate element, wherein the support profile comprises at least one tilting element which is arranged on at minus one profile leg.

The inclination element is designed for arranging a plate element on the support profile for angular adjustment of the plate element. This tilting element is arranged on at least one profile leg of a support profile at its upper end on the inside of the profile leg. Within the support profile a plate element is arranged between the camber element and the other profile leg, which can also comprise a camber element. The plate element can be a glass panel or it can also be made of other materials such as wood, plastic material, metal or the like. This plate element is intended to be held by the profile legs of the support profile. Therefore, the tilt element is arranged between the profile leg and the plate element. As a result, the inclination can be adjusted and the plate element can be fixed. The tilt element has an end where a force can be applied to tilt and a pivot point where the tilt element is attached to the profile leg or a mounting means. The free end can be locked into latching devices until the force of a screw element acts on it and tilts the tilt element out of its original position.

The plate element for an all-glass balustrade of a balustrade or façade structure or the like is inserted into the support profile and is therefore initially oriented, for mounting purposes, obliquely to deviate from the perpendicular. After alignment, the plate element must be clamped between the two profile legs of the support profile in the region of the feet of the support profile in an approximately perpendicular angular position or in an angular position deviating from it as desired . At least in regions between the support profile and the plate element, a profiled footing made of a flexible material is arranged. This profile shoe can also be arranged, for example, only in a lower region of the support profile. The tilting element can have different shapes. It is wedge-shaped and may have a trapezoidal shape, a rounded teardrop shape, or a thicker or thinner shape that points toward the region of pressure on the plate element, and may have straight or inclined surfaces to support the screw elements. . Narrow shapes for the tilt element can be selected so that the space required within the support profile between the relevant leg and the plate element is not very large. The wedge tip of the tilting element can point towards the support profile downwards towards the base of the profile or upwards towards the opening. The tilt element has no edges that can cause problems when the plate element is inserted. If long shapes are selected, fine adjustment and precisely defined adjustment of the plate elements is possible, in particular for very tall plate elements to be clamped.

The inclination element can be arranged on one or both profile legs, in each case inside it. If the tilt element is arranged on only one profile leg, the other profile leg comprises a fixed pressure element. The tilting element is arranged in a region of the profile foot that points downwards towards the profile sole of the support profile, for example in a recess of the profile foot, so that it can perform a swivel or tilt movement. away from the profile leg and towards the plate element and is therefore movably or tilt-mounted. The inclination element thus has, at its lower support, a pivot point around which the inclination element can be tilted when force is applied by one of the screw elements which are engaged from above. Therefore, the pivot point is arranged on at least one leg or on at least one mounting element. By arranging the tilting element on the bottom support, the hooking point, ie the region of pressure on the plate element, is precisely defined. Therefore, the pressure region remains in the upper region. This means that there is no reduction in hold.

The tilt element can be hooked on or on to be able to perform its tilt movement. As a result of the inclination movement of the inclination element, the desired position with the desired inclination of the plate element can be secured and the plate element can be clamped. The tilt element can also be inserted from the side after the plate element has been inserted and then tilted. Therefore, a way of creating adjustability is described, by making openings or holes for screw elements in the support profile in both profile legs, in each case at the upper edge thereof, the screw elements serving to tilt tilt elements. Holes can be drilled from the upper tip thereof and from the outside from the corresponding side. These drilled holes can be straight or oblique. This depends on the geometric shape of the tilt element and the surface with which the screw element inserted in the drilled hole must engage. Thus, a point of engagement of the screw element on the tilting element is possible on straight and inclined surfaces.

Profile legs can have different shapes, that is, they can be designed to have the same thickness everywhere or to be thicker in the lower region and thinner in the upper region, for example. The openings, in particular the drilled holes, are preferably threaded. The screw element can be arranged therein. As a result of the screw element and the application of force by said screw element to the tilt element, the desired angular adjustability can be achieved. The screw element is designed in particular as a grub screw. This screw element acts on the inclination element to be arranged to adjust the inclination of the glass panel, which inclination element is actuated to different degrees as a result of the arrangement of the screw element and particularly the depth of insertion or screwing of the screw element. Depending on the screwing-in depth of the screw element, the inclination element moves towards the plate element and thus presses against the plate element, so that the vertical inclination thereof can be adjusted.

The screw element can engage the profile legs of the support profile from above and/or from the side. The tilting element is designed in such a way that it is arranged in a mounting element and a mounting element, and the entire mounting element can be inserted into the corresponding profile leg of the support profile. Depending on the arrangement of the support profile, it is possible to perform the angular adjustment of the vertical or horizontal inclination of the plate element.

The tilting element according to the invention therefore has the advantage that by applying the force caused by screwing on the threaded element together with the lever effect of the tilting element, a fine adjustment of the plate element is possible. This allows for greater ease of assembly due to the suitable design of the screw-on support profile in combination with the effect of the tilting element and enables considerable time savings during assembly.

Other advantages and advantageous embodiments of the invention can be found in the following description of the figures, the drawings and the claims.

An embodiment of the solution according to the invention is explained in more detail below on the basis of the attached schematic drawings, in which: The description and illustrations of Figures 2 to 6 are given as a supplement; they are merely illustrative and do not form part of the present invention.

Figure 1 shows a profile leg with an attached mounting element and a tiltable camber element,

Figure 2 shows a tilt element inserted into a profile leg, Figures 3 to 13 represent different embodiments of the tilt element;

Figure 3 to 6 show camber elements inserted directly into a profile leg, and

Figure 7 to 13 show tilt elements integrated into mounting elements, for installation on profile legs,

Figure 14 shows a mounting element installed on a profile leg on one side, with a tilt element on a support profile,

Figure 15 shows the support profile with an inserted profile shoe,

Figure 16 shows the support profile with a plate element inserted into the profile footing,

Figure 17 shows the tilting of the tilting element caused by screwing in a screw element,

Figure 18 shows the arrangement of the sealing devices,

Figure 19 shows the arrangement of tilting elements on both sides of two profile legs of a support profile,

Figure 20 shows the insertion of a screw element,

Figure 21 shows screw elements inserted into two sides, Figure 22 shows a plate element inserted into a profile footing,

Figure 23 shows the screwing of the two screw elements and the camber of the camber element, and Figure 24 shows the angular adjustability due to additional screwing of a screw element and changing the pressure region of the camber element. inclination. All drawings are shown in a cross section.

Figure 1 shows a tilt element 10. The tilt element 10 is embedded in a mounting element 12 and has a trapezoidal shape. To engage said tilt element, the mounting element 12 comprises a hook projection 14 and the tilt element 10 has a tongue 16. The tongue 16 is supported by the hook projection 14. The tilt element 10 is held in a pivot point 18 in the mounting element. A screw element 20 is arranged in an upper projection of the mounting element 12. The screw element 20 is inserted into a straight drilled hole 26. The screw element 20 can be brought up to the oblique surface 22 of the tilt element 10. The mounting element 12, with the tilting element 10 arranged therein, is arranged on a first profile leg 24 of a support profile, which is partly shown here.

Figure 2 shows the tilt element 10 in elongated form, with a rounded, teardrop-shaped part in the region of the pivot point 18. The tilt element 10 is also hooked or hooked by means of its tongue 16' on a projection hook 14' of the correspondingly configured first profiled arm 24. In this embodiment, the tilt element 10 is arranged directly on the first profile leg 24.

Figure 3 shows a part of a first profile leg 24 with a straight drilled hole 26 into which the screw element 20 is inserted. The screw element 20 bears against the oblique surface 22 in the region of the head of the screw element. slope 10. The slope element 10 tapers from bottom to top.

Figure 4 shows a different design of the tilt element 10. It has a straight shape below the oblique surface 22.

Figure 5 shows a shape of the inclination element 10 that tapers from the bottom towards a sole of the profile.

Figure 6 shows a pointed shape in the lower region of the tilt element 10.

Figure 7 shows the tilt element 10 arranged in a mounting element 12.

The tilt element 10 has a completely straight surface towards the screw element.

Figure 8 shows a shape of the tilt element 10 that extends directly downwards below the surface 22.

Figure 9 shows a downwardly tapering shape of the inclination element 10 below the surface 22.

Figure 10 shows an embodiment of the tilt element 10 that is pointed in the lower region.

Figure 11 shows an oblique drilled hole 28 through which the screw element 20 is guided obliquely towards the straight tilt element 10.

Figure 12 shows a tilting element 10 that tapers conically downwards.

Figure 13 shows a tilt element 10 which is in the shape of a round teardrop at the bottom.

Figure 14 shows a support profile 30 comprising the first profile leg 24 and the second profile leg 32. The support profile 30 is U-shaped. On the first profile leg 24 a mounting element 12 with a tilt element 10. A screw element 20 is screwed on top of the mounting element 12 and points towards the tilt element 10.

Figure 15 shows a profile shoe 34 inserted into the support profile 30. The profile shoe is formed over the entire surface of the second profile leg 32 towards the top of the support profile 30.

Figure 16 shows an inserted plate element 36 which, on the side of the second profile leg 32, abuts directly against the profile shoe 34 over its entire longitudinal extent and rests in the lower region of the support profile 30, that is that is, the supporting profile sole 38. The tilt element 10 is also hooked into the mounting element 12. The screw element 20 is still spaced at a particular distance from the tilt element 10.

Figure 17 shows a screw element 20 which is also screwed. The screw element 20 presses on the surface 22 of the tilt element 10, which is thus pushed out or released from its upper attachment. As a result, the tilt element 10 tilts around its pivot point 18 and approaches the plate element 36. Here it comes into contact with the plate element 36 in the pressure region 40. When screwing the screw element 20 force can be applied to the tilt element 10 and therefore force can also be generated against the plate element 36.

In Figure 18, the desired vertical positioning of the plate element 36 is achieved. Due to the screw-in depth of the screw element 20, the tilt element 10 is in the tilt position desired and therefore holds the plate element 36 in this position. The sealing elements 42 are arranged in the upper region.

Figure 19 shows an F-shaped support profile 30 comprising the first profile leg 24 and the second profile leg 32. A mounting element 12 is fitted to each of the two profile legs 24, 32. A Tilt element 10 is hooked on each mounting element 12. Tilt element 10 is arranged on the first profile leg 24 and tilt element 10' with corresponding mounting element 12 is arranged on the second profile leg 32 An oblique drilled hole 28 is made in each mounting element 12.

Figure 20 shows the screw element 20 which is intended to be inserted into the oblique drilled hole 28. In Figure 21, two screw elements 20 are each screwed into its corresponding oblique drilled hole 28 and rest against the surfaces 22 of the respective tilting elements 10, 10'.

Figure 22 shows how the plate element 36 is inserted into the first profile leg 24 and the second profile leg 32 and the two tilt elements 10. The plate element 36 sits on the support profile shoe 34 in the region of the support profile sole 38. In this embodiment, the profile shoe 34 is configured as a small support profile shoe 34, which surrounds the lower region of the plate element 36.

In Figure 23, the two screw elements 20 are screwed further and thus press against the surfaces 22 of the tilt elements 10, 10', so that these are released as a result of the application of force and are they incline around their pivot point so that they abut against the plate element 36 and thus a force is applied on both sides to the plate elements 36, as a result of which the inclination of the element can be changed of plate 36.

Figure 24 shows how the trapezoidal tilt element 10 is further tilted around its pivot point 18 by the pressure of the screw element 20 and presses against the plate element 36. Since the screw element 20 on the first leg The profile leg 24 is screwed further than the screw element 20 on the second profile leg 32, the force applied to the plate element 36 in the pressure region 40 on the first profile leg 24 side is greater than that on the side opposite. Therefore, the inclination of the plate element 36 is adjusted in its angular range towards the second profile leg 32.

List of reference signs

10 Tilt element

12 Mounting element

14 Hook Projection

14' Hitch Projection

16 Tab

16' Tab

18 pivot point

20 Screw element

22 oblique surface

24 First leg in profile

26 Straight Drilled Hole

28 Oblique drilled hole

30 Support profile

32 Second leg in profile

34 Profile footing

36 Plate element

38 Support profile sole

40 Pressure Region

42 Sealing element

Claims (11)

1. Support profile (30) comprising a first profile leg (24) and a second profile leg (32) and a support profile sole (38) for retaining a plate element (36), wherein the support profile (30) comprises at least one tilt element (10) to be arranged between the profile leg and the plate element (36), which is arranged on at least one profile leg (24, 32), characterized because the tilting element (10) is arranged in a mounting element (12) which can be inserted into the profile leg and is clipped onto the mounting element (12), and that the mounting element (12) It comprises a lower support having a pivot point (18) around which the tilting element (10) can be tilted in the direction of the plate element (36), by means of an application of force, wherein the application of force is achieved, in the inclination element, by means of a screw element (20) ^{that is attached from above, in such a way that the pivot point (} 18 ^{) is thus arranged in the mounting element} (12), where As a result of the arrangement of the inclination element (10) in the lower support, the end of the inclination element (10) opposite the pivot point (18) defines a hooking point that is designed as a pressure region (40) in the plate element (10), so that the pressure region (40) remains and n an upper region above the lower support and therefore no reduction in the clamping of the plate element (36) occurs. Support profile (30) according to claim 1, characterized in that the mounting element (12) is releasably held on the first profile leg (24) and/or on the second profile leg (32). Support profile (30) according to claim 2, characterized in that there is a straight drilled hole (26) or an oblique drilled hole (28) in the mounting element (12). Support profile (30) according to claim 3, characterized in that it is screwed into a screw element (20) in each case via the straight bore hole (26) and/or the oblique bore hole (28). Support profile (30) according to claim 4, characterized in that the screw element (20) engages at one end of the tilting element (10). Support profile (30) according to claim 5, characterized in that the inclination element (10) can be tilted around a pivot point (18) in the direction of the support profile sole (38) in a remote region. from the tip of the profile leg (24, 32). Support profile (30) according to any of the preceding claims 4-6, characterized in that the magnitude of the pressure applied to the tilting element (10), on the plate element (36), can be adjusted depending on the depth of the screw element (20). Support profile (30) according to one of the preceding claims 4-7, characterized in that the screw element (20) is screwed from the outside, from the direction of the profile leg (24, 32) or the transverse direction to the profile legs (24, 32). Support profile (30) according to any one of the preceding claims, characterized in that the tilting element (10) is designed in the form of a wedge. Support profile (30) according to claim 9, characterized in that a tip of the tilting element (10) faces in the direction of a support profile sole (38) or in the direction of an opening between the profile legs ( 24) and (32). Support profile (30) according to any one of the preceding claims, characterized in that the inclination of the plate element (36) is variable depending on the flow of the material of the profile leg (32) and/or of a profile footing. (3. 4).