NL2005660C2 - PEN-SHORT CONFIRMATION. - Google Patents

Description

PEN-SHORT CONFIRMATION

The invention relates to a pin-shaped fastener for remotely fastening a façade wall to a stone, concrete or wooden base, such as a wall, wherein the fastener can be arranged in bores formed in the façade wall and in the base.

The invention is also related to a method for remotely fixing a façade wall to a stone, concrete or wooden base, such as a wall, wherein use is made of pin-shaped fasteners which are formed in bores in the façade wall and in the base. applied.

Such a pin-shaped fastener is generally known. A drawback of the known fixing means is that in practice cold bridges are easily created between the facade wall and the substrate, while in practice the known fixing means is insufficiently capable of transmitting forces. The known fastening means furthermore has the drawback that it comprises a shaft with step-by-step transitions, which can lead to an increased risk of stress peaks in the material, in particular in the case of an inaccurate method of placement on the construction site.

The object of the invention is to improve the state of the art, and for this purpose a pin-shaped fastening means according to the invention has the special feature that the fastening means comprises a shank 2 which, near its one end facing the ground, over at least a part of its length is provided with a helical first edge running along its circumferential surface which extends radially with respect to the shaft to form male threads, and which is provided with at least a part of its length near its other end remote from the substrate its helical second edge running its circumferential surface 10 and extending radially with respect to the shaft to form male screw thread, the pitch of the helical first edge 15 being substantially the same as the pitch of the helical second edge, the diameter of the helical shape of the second edge is greater than or geli j is at the diameter of the helical shape of the first edge. In particular, a part of the shaft that is located between the part of its length where the first edge is arranged and the part of its length where the second edge is arranged is adapted to support (hard or soft) insulating material, without that there is a risk of damage. As a result, thermal bridges are virtually prevented and so-called "thermal leakage" along the fastener is virtually avoided. This also makes it possible for the façade wall to be almost completely suspended, whereby force transfer as a result of the weight of the façade wall and external force influences (for example wind, attached ice or vegetation) via the fastening means on the foundation of a building on which the foundation rests, is passed on. The fastener is preferably made of 3 corrosion-resistant material. In another preferred variant, the fastener has undergone a surface treatment to bring its corrosion resistance to such a level that in practice it can fully perform its function for at least fifty years. Due to very close production tolerances, the pitches of both threads are exactly the same.

In a preferred embodiment of a fastener 10 according to the invention, the diameter of the shaft over the part of its length where the second edge is arranged is greater than or equal to the diameter of the shaft over the part of its length where the first edge is applied.

15

In a further preferred embodiment of a fastening means according to the invention, the one end of the shaft facing the ground rejuvenates. In particular, the other end remote from the substrate 20 comprises a connection for driving the fastening means, such as a screw-bit connection. This makes it possible to generate high torques to drive the fastener in the façade wall and in the substrate. The rejuvenation has a special shape without abrupt transitions or edges, so that no peak stresses occur and a high degree of insensitivity to placement errors is realized.

In a further preferred embodiment of a fastening means according to the invention, sides of the first edge lie close to the apex thereof and the sides of the second edge close to the apex thereof enclose an angle between 25 ° and 40 °.

4

As stated, the invention also relates to a method for remotely fixing a façade wall to a stone, concrete or wooden base, such as a wall, wherein use is made of pin-shaped fixing means which are formed in bores in the façade wall and in the surface are applied. According to the invention, the method has the special feature that each fastening means comprises a shank which, near its one end that faces the substrate, is provided over at least a part of its length with a helical first edge running along its circumferential surface which is relative to the shaft extends radially to form male threads, and which, near its other end remote from the substrate, is provided over at least a part of its length with a helical second edge extending along its circumferential surface 20 and projecting radially relative to the shaft of male screw thread, the pitch of the helical first edge 25 being substantially equal to the pitch of the helical second edge, the diameter of the helical shape of the second edge being greater than or equal to the diameter of the helical shape of the first edge. Preferably, insulating material is supported by a part of the shaft which is located between the part of its length where the first edge is arranged and the part of its length where the second edge is arranged.

5

In a preferred embodiment of a method according to the invention, at least one fixing means is arranged at least substantially perpendicularly in the bores in the facade wall and in the substrate, at least one other fixing means being inclined, i.e. at an angle to the horizontal in the vertical. flat, in the bores in the facade wall and in the substrate. This creates a force triangle that can absorb the own weight of the façade wall to be fitted.

In particular, the fastener is made in the bores in the subsurface using a plug. This plays a role in particular if the fastener is applied in a stony surface.

15

The invention will be further elucidated with reference to a figure shown in a drawing, in which a side view is shown of a facade assembly with fixing means according to the invention.

20

The figure shows a wooden, aluminum or plastic line 1 with a minimum thickness of 38 mm, on which a facade (not shown) can be mounted, as well as a stony surface, for example a wall 2. Between the line 1 and the wall 2 soft or hard insulation material 3 is applied. The rail 1, the wall 2 and the intermediate insulating material 3 are interconnected by various stainless steel fixing pins 4, in each case in pairs, as shown. The one fixing pin 4 is thereby mounted perpendicular to the wall 2 therein, while the other fixing pin 4 is thereby inclined, i.e. at an angle of 30 ° to the horizontal in the vertical plane, with respect to the wall 2 therein 6 mounted. In both cases, use is made of a plug 5 which is not previously provided in bores 6 in the wall 2. Namely, the plug 5 is first placed on the fixing pin 4, whereafter the whole from outside 5 is placed in the wall 2 by the line 1, the insulating material 3. When the pins 4 turn more deeply, the tightening torque increases, so that the "plugs 5" are also turned. Instead of stainless steel, the fixing pins 4 can also be made of another material, which, however, has been treated with sufficient corrosion protection.

As shown, each pin 4 has a shaft 7 which, near its one end facing the wall 2 (over at least a part of its length) is provided with a helical first edge 8 extending along its circumferential surface and which is relative to the shaft 7 extends radially to form an external male thread. In addition to its other end remote from the wall 2, the shaft 7 (over at least a part of its length) is also provided with a helical second edge 9 extending along its circumferential surface and which also protrudes radially with respect to the shaft 7 to form male external thread. The pitch of the helical first edge 8 is equal to the pitch of the helical second edge 9. Furthermore, the diameter of the helical shape of the second edge 9 is greater than or equal to the diameter of the helical shape of the first edge 8. A part 10 of the shaft 7 that lies between the part 30 of its length where the first edge 8 is arranged and the part of its length where the second edge 9 is arranged, has a smooth surface and supports the insulating material 2.

7

As shown, the shaft 7 has gradual (instead of stepwise) transitions, as a result of which the fixing pin 4 is insensitive to any voltage peaks and is also largely insensitive to placement errors in practice. The length of the wire 8 is precisely matched to the length of the plug 5 and placement depth in the wall 2.

The invention is not limited to the drawn embodiment, but also extends to other preferred variants that fall within the scope of the appended claims. Thus, a person skilled in the art will understand that a facade wall can also be mounted directly, that is, without line 1, at a distance from the wall 2, although the use of a line 1 is desirable from the viewpoint of a stable intermediate distance. Furthermore, a person skilled in the art will realize that in practice not every horizontally inserted fixing pin 4 is always combined (applied) with an obliquely inserted fixing pin. The number of force triangles (ie the number of inclined mounting pins 4) is in practice determined as a function of the weight of the facade wall and expected external force factors.

Claims (10)

Claims 1. Pin-shaped fastener for remotely fastening a façade wall to a stone, concrete or wooden base, such as a wall, wherein the fastener can be arranged in bores formed in the façade wall and in the base, characterized in that the fastener is a shaft comprises 10. which, near its one end facing the ground, is provided over at least a part of its length with a helical first edge extending along its circumferential surface and extending radially with respect to the shaft to form male threads, and which, near its other end remote from the ground, is provided over at least a part of its length with a helical second edge extending along its circumferential surface which extends radially with respect to the shaft to form male threads, the pitch of the helical first edge is at least substantially equal to the pitch of the Helical second edge, the diameter of the helical shape of the second edge being greater than or equal to the diameter of the helical shape of the first edge. Fastening means according to claim 1, wherein the diameter of the shaft over the part of its length where the second edge is arranged is greater than or equal to the diameter of the shaft over the part of its length where the first edge is arranged . 3. Fastening means as claimed in claim 1 or 2, wherein the one end of the shaft facing the ground rejuvenates. 4. Fastening means as claimed in claim 1, 2 or 3, wherein the other end remote from the ground comprises a connection for driving the fastening means. 5. Fastening means as claimed in any of the foregoing claims 1-4, wherein a part of the shaft that is situated between the part of its length where the first edge is arranged and the part of its length where the second edge is arranged arranged to carry insulating material. A fastener according to any one of the preceding claims 1 to 5, wherein sides of the first edge near the apex thereof and the sides of the second edge near the apex thereof enclose an angle between 25 ° and 40 °. 25 7. Method for securing a façade wall remotely to a stone, concrete or wooden base, such as a wall, wherein use is made of pin-shaped fasteners which are arranged in bores formed in the façade wall and in the base, characterized in that each fastening means comprises a shank which, near its one end facing the ground, is provided over at least a part of its length with a helical first edge extending along its circumferential surface and extending radially with respect to the shank to form male threads, and which, near its other end remote from the ground, is provided over at least a part of its length with a helical second edge extending along its circumferential surface 10 and protruding radially with respect to the shank to form male threads, the pitch of the helical first edge 15 is at least substantially equal to d the pitch of the helical second edge, the diameter of the helical shape of the second edge being greater than or equal to the diameter of the helical shape of the first edge. 20 8. Method as claimed in claim 7, wherein insulating material is supported by a part of the shaft that lies between the part of its length where the first edge is arranged and the part of its length where the second edge is arranged. 9. Method as claimed in claim 7 or 8, wherein at least one fastening means is arranged at least substantially perpendicularly in the bores in the facade wall and in the substrate, and wherein at least one other fastening means is arranged obliquely in the bores in the facade wall and in the substrate. applied. A method according to claim 7, 8 or 9, wherein the fastener is made in the bores in the subsurface using a plug.