SELF-FASTENING THREADED INSERT AND PROCESS FOR ASSEMBLING SUCH THREADED INSERT

Abstract

A self-fastening threaded insert is described, with respect to a slab of building material, comprising a bearing element with respect to the slab, a deformation element adapted to interact with the slab, and a supporting element cooperating with the bearing element. The deformation element is deformed due to the effect of an external load transmitted by the supporting element, and is adapted to transmit to the slab forces which are perpendicular to an application force of the external load to be able to fasten the threaded insert to the slab. A process for assembling such threaded insert is also described.

Claims

1. A self-fastening threaded insert with respect to a slab of building material, comprising a bearing element with respect to said slab, at least one deformation element adapted to interact with said slab, and a supporting element cooperating with said bearing element, wherein said at least one deformation element is deformed due to the effect of an external load transmitted by said supporting element, said at least one deformation element being adapted to transmit to said slab forces which are perpendicular to an application force of said external load to be able to fasten said threaded insert to said slab.

2. The threaded insert of claim 1, wherein said bearing element adapted to contain said supporting element is housed in a recess of said slab to allow said threaded insert to abut onto an internal surface of said recess without projecting from an external face of said slab.

3. The threaded insert of claim 1, wherein said bearing element adapted to contain said supporting element comprises an abutment flange with respect to an external face of said slab to allow said threaded insert to abut against at least said external face of said slab.

4. The threaded insert according to any one of claims 1 to 3, wherein said at least one deformation element comprises an elastic toothed crown adapted to be housed with interference in a cylindrical recess of said slab.

5. The threaded insert according to any one of claims 1 to 3, wherein said at least one deformation element comprises a cup spring adapted to be housed with interference in a cylindrical recess of said slab.

6. The threaded insert according to claim 4, wherein said at least one deformation element is connected to at least one spacer ring.

7. The threaded insert according to claim 1, wherein said supporting element comprises abutting means adapted to block a connection element screwed onto said threaded insert to prevent said threaded insert from being extracted from the recess of said slab.

8. The threaded insert according to claim 1, wherein it operates alternatively as connection element through an internal threading and an external threading.

9. The threaded insert according to claim 1, wherein said bearing element is made of plastic or metallic material and said supporting element is made of metal to allow supporting loads with a high force.

10. A process for assembling a self-fastening threaded insert with respect to a slab of building material according to claim 1, comprising the steps of: performing an excavation of the slab to obtain a receiving recess; inserting said threaded insert into the receiving recess to allow fastening said bearing element onto the slab and housing with interference said at least one deformation element with respect to an internal wall of the recess of the slab, and connecting an external element through a connection element screwed onto said threaded insert.

11. The threaded insert according to claim 5, wherein said at least one deformation element is connected to at least one spacer ring.

Description

[0012] The present invention will be better described by some preferred embodiments thereof, provided as a non-limiting example, with reference to the enclosed drawings, in which:

[0013] FIG. 1 shows a perspective View of an embodiment of the self-fastening threaded insert according to the present invention;

[0014] FIGS. 2 to 5 show partially sectioned side views along the axis of symmetry respectively of various embodiments of the self-fastening threaded insert according to the present invention;

[0015] FIG. 6 shows a perspective view of a sectioned portion of a slab adapted to house the self-fastening threaded insert, according to the present invention;

[0016] FIG. 7 shows a perspective view of the slab of FIG. 6 coupled with an embodiment of the self-fastening threaded insert according to the present invention; and

[0017] FIG. 8 shows a partial and enlarged side sectional view of an embodiment of the self-fastening threaded insert equipped with an external connection element screwed according to the present invention.

[0018] With reference to FIGS. 1, 2 and 3, it is possible to note that a threaded insert 1 with automatic fastening with respect to a slab of building material comprises a bearing element 10 with respect to the slab, at least one deformation element 20 adapted to interact with the slab, and a supporting element 30 cooperating with the bearing element 10.

[0019] Advantageously, such at least one deformation element 20 is deformed due to the effect of an external load transmitted by the supporting element 30. In this way, such at least one deformation element 20 can transmit to the slab forces which are perpendicular to an application force of the external load, to allow the threaded insert 1 to get fastened to the slab.

[0020] Advantageously, the supporting element 30 can support a battery of deformation elements 20, preferably in a number ranging from 1 to 4 elements connected. in series or more, depending on applications.

[0021] With reference to FIGS. 2, 4, 6 and 7, it is possible to note that the bearing element 10 adapted to contain the supporting element 30 is housed in a recess of the slab to allow the threaded insert 1 to abut against an internal surface RF of the recess without projecting from an external face SF of the slab.

[0022] With reference to FIGS. 3, 5 and 6, it is possible to note that the bearing element 10 adapted to contain the supporting element 30 comprises an abutment flange 11 with respect to an external face SF of the slab to allow the threaded insert 1 to abut at least against the external face SE of the slab.

[0023] At least one of such deformation elements 20 can comprise an elastic toothed crown, adapted to be housed with interference in a cylindrical recess of the slab.

[0024] Alternatively, each deformation element 20 can comprise a smooth or toothed cup spring, adapted to be housed with interference in a cylindrical recess of the slab (not shown).

[0025] According to a preferred configuration, each deformation element 20 can be connected to at least one spacer ring 21, as shown in FIG. 1.

[0026] With reference to FIG. 8, it is possible to note that the supporting element 30 comprises abutting means adapted to block a connection element T screwed to the threaded insert 1 to prevent the threaded insert 1 from going out of the recess of the slab.

[0027] Preferably, the abutting means can comprise a blind threaded hole or a partially threaded through-hole or prevent a screw T from pressing onto the bottom of the recess of the slab.

[0028] With reference to FIGS. 2 to 5, the threaded insert 1 can alternatively operate as connection element through an internal threading 31 and an external threading 32.

[0029] The bearing element 10 made of plastic or metallic material, depending on the application, and the supporting element 30 made of metal allow supporting loads with a high force.

[0030] A process for assembling a self-fastening threaded insert 1 with respect to a slab of building material comprises the steps of: [0031] performing an excavation of the slab to obtain a receiving recess; [0032] applying the threaded insert 1 into the receiving recess to allow fastening the bearing element 10 to the slab and housing with interference, with respect to an internal wall RF of the recess of the slab, each deformation element 20 belonging to the threaded insert 1; [0033] connecting an external element through a connection element T screwed onto the threaded insert 1.

[0034] The threaded insert 1 allows obtaining the objects of the invention, with the advantages of allowing an assembling after having performed a simple hole on the slab, even when working, with the use of standard tools, being able to quickly insert the threaded insert into such hole through a simple pressure, without having to add adhesives and gluing agents.

[0035] Moreover, the threaded insert of the invention allows performing an assembling of the threaded insert with disappearing, without external encumbrances, facilitating handling and storage of the slabs.

[0036] A further advantage is given by the absence of stresses on the receiving material when the threaded insert is not stressed, while during its use the elastic washers are stressed by an axial traction force, radially acting against the walls due to flexure and pressure, preventing the insert from going out of the slab.

[0037] The threading of the supporting element made as non-through ensures the fastening of the threaded insert onto the slab, avoiding the extraction effect generated by the possible inappropriate length of the screw.