METHOD AND DEVICE FOR FASTENING A COMPONENT TO A SUBSTRATE

Abstract

In a method for fastening a component, a nail having a nail shank and a nail head is provided, a sleeve is arranged on the nail shank, a driving-in element and a guide channel are provided, the nail head and the sleeve are arranged in the guide channel such that a peripheral gap is formed between the nail head and the guide channel, the driving-in element is driven through the guide channel toward the nail head in order to move the nail in a driving-in direction toward the substrate, the sleeve is compressed between the nail shank, the guide channel and the nail head while the nail moves toward the substrate, and a preload is applied to the sleeve by means of the nail head.

Claims

1. A method for fastening a component to a substrate, the method comprising: providing a nail having a nail shank and a nail head, wherein the nail head has a head diameter which projects beyond the nail shank, arranging a sleeve on the nail shank, providing a driving-in element and a guide channel, wherein the guide channel has an inside diameter which exceeds the head diameter, arranging the nail head and the sleeve in the guide channel such that a peripheral gap is formed between the nail head and the guide channel, driving the driving-in element through the guide channel toward the nail head in order to move the nail in a driving-in direction toward the substrate, compressing the sleeve between the nail shank, the guide channel and the nail head while the nail moves toward the substrate, and applying a preload to the sleeve by the nail head.

2. The method as claimed in claim 1, wherein a diameter of the nail head is larger than an outside diameter of the sleeve.

3. The method as claimed in claim 1, including physically deforming the sleeve plastically during the compression between the nail shank, the guide channel and the nail head.

4. The method as claimed in claim 1, including completely filling the sleeve in a cavity between the nail shank, the guide channel and the nail head during the compression between the nail shank, the guide channel and the nail head.

5. The method as claimed in claim 1, further comprising: providing a fastening element, having a disk for holding the component, a hollow shaft which projects from the disk and which has a shaft bottom, wherein the sleeve projects from the shaft bottom, inserting the guide channel into the hollow shaft until the guide channel bears against the shaft bottom and the sleeve is arranged in the guide channel.

6. The method as claimed in claim 1, further comprising: providing a power-operated setting device, having the guide channel, the driving-in element and a drive for the driving-in element, wherein the guide channel projects beyond the driving-in element in all positions of the driving-in element in the driving-in direction.

7. A device for fastening a component to a substrate, the device comprising: a nail having a nail shank and a nail head, wherein the nail head has a head diameter which projects beyond the nail shank, and wherein the nail shank has a preloading element which is intended for applying a preloading force to the nail shank when the nail is driven into the substrate a fastening element, having a disk for holding the component, a hollow shaft which projects from the disk and which has a shaft bottom which projects from the shaft bottom and is arranged on the nail shank.

8. The device as claimed in claim 7, wherein the preloading element comprises a barb arranged on an outer circumference of the nail shank.

9. The device as claimed in claim 8, wherein the preloading element comprises a multiplicity of barbs arranged on the outer circumference of the nail shank.

10. The device as claimed in claim 9, wherein the multiplicity of barbs is arranged in rows spaced apart by grooves.

11. The device as claimed in claim 10, wherein the grooves are inclined relative to a longitudinal direction of the nail shank by an angle of inclination between 4 and 8.

12. The device as claimed in claim 7, wherein the sleeve consists substantially of plastic.

13. The device as claimed in claim 7, wherein the nail, the driving-in element and/or the guide channel consist substantially of a metal or an alloy.

14. The device as claimed in claim 13, wherein the preloading element comprises a material which has a greater material hardness than a material of the rest of the nail shank.

15. The device as claimed in claim 14, wherein the preloading element comprises an alloy containing zinc and nickel.

16. The method of claim 1, comprising fastening an insulating material to a wall or ceiling of a building.

17. The method of claim 5, wherein the shaft bottom has a passage for the nail shank and the sleeve.

18. The device of claim 7, wherein the shaft bottom has a passage for the nail shank and the sleeve.

19. The device of claim 12, wherein the sleeve consists substantially of thermoplastic.

20. The device of claim 13, wherein the nail, the driving-in element and/or the guide channel consist substantially of steel.

Description

[0014] Exemplary embodiments of the invention will be described in more detail below with reference to the appended drawings, In the drawing:

[0015] FIG. 1 shows a longitudinal section through a fastening device,

[0016] FIG. 2 shows a detail of a fastening device during a fastening process in a longitudinal section,

[0017] FIG. 3 shows the detail of the fastening device from FIG. 2 in a longitudinal section following the completion of the fastening process,

[0018] FIG. 4 shows a detail of a nail in a side view, and

[0019] FIG. 5 shows the detail of the nail from FIG. 4 in a longitudinal section.

[0020] FIG. 1 illustrates a longitudinal section through a fastening device 100 for fastening a component 101, such as, for example, an insulating element, to a metal substrate 102, such as, for example, a steel beam or a frame element of a wall or ceiling of a building. In the exemplary embodiment shown, cladding 103 and a covering film 104 are arranged between the substrate 102 and the component 101. The fastening device 100 comprises a fastening element 110 and a nail 120.

[0021] The fastening element 110 has a disk 111 for holding the component 101 against the substrate 102, a hollow shaft 112, which projects from the disk 111 and which has a shaft bottom 113, and a sleeve 115, which projects from the shaft bottom 113. The shaft bottom 113 has a passage 114 for the nail 120. The sleeve 115, preferably the entire fastening element 110, consists substantially of a thermoplastic.

[0022] The nail 120 comprises a nail shank 121 with a nail point 122, in particular a conical nail point, and a nail head 123 having a head diameter which projects beyond the nail shank 121. The nail 120 is arranged in the passage 114 such that the sleeve 115 rests against the nail shank 121 and surrounds the nail shank 121. A diameter of the nail head 123 is larger than an outside diameter of the sleeve 115. The nail 120 consists substantially of steel.

[0023] FIG. 2 and FIG. 3 show a detail of the fastening device 100 during fastening to the substrate. In order to carry out the fastening method, a guide channel 130 of a power-operated nail setting tool (not shown specifically) is first of all introduced into the hollow shaft 112 of the fastening element 110 until the guide channel 130 rests against the shaft bottom 113 and the sleeve 115 is arranged in the guide channel 130. (FIG. 2). A cavity 132 is formed here between the nail shank 121, the guide channel 130 and the nail head 123, in which cavity the sleeve 115 is situated. An inside diameter of the guide channel 130 exceeds the head diameter, such that the nail 120 is guided in the guide channel 130 when the nail head 123 and the sleeve 115 are arranged in the guide channel 130. A peripheral gap 131 is formed between the nail head 123 and the guide channel 130.

[0024] In a subsequent step (FIG. 3), a driving-in element of the nail setting tool is driven through the guide channel toward the nail head 123 in order to move the nail 120 in a driving-in direction toward the substrate and to drive it into the substrate (to the right in FIGS. 2-3). Here, the driving-in element consists, for example, of a steel plunger having a plunger diameter which is somewhat smaller than the head diameter of the nail head 123.

[0025] While the nail is moving toward the substrate, the sleeve 115 is compressed and, in particular, plastically deformed between the nail shank 121, the guide channel 130 and the nail head 123. During this process, the sleeve 115 completely fills a cavity 132 between the nail shank 121, the guide channel 130 and the nail head 123. A preload is then applied to the sleeve 115 by means of the nail head 123, thus ensuring that the nail head 123 rests firmly against the sleeve 115 and the sleeve 115 rests firmly against the nail shank 121. For this purpose, the nail 120 has a preloading element, as will be explained below. This makes it more difficult for water to penetrate between the nail 120 and the fastening element 110.

[0026] FIG. 4 and FIG. 5 each show a detail of the nail 120. The nail 120 has a multiplicity of preloading elements 124, which are intended to apply a preloading force to the nail shank 121 when the nail 120 is driven into the substrate. For this purpose, the preloading elements 124 are designed as barbs, which are separated from one another by longitudinal grooves 125 and transverse grooves 126. A depth of the longitudinal grooves 125 and/or of the transverse grooves 126 is at least 5% of a shank diameter of the nail shank 121. The preferably at least four longitudinal grooves 125 are inclined helically by an angle of inclination of 6 with respect to a longitudinal direction of the nail shank 121 and extend into the nail tip 122. A distance between in each case two adjacent transverse grooves 126 is preferably less than or equal to a thickness of the substrate.

[0027] Each preloading element 124 has a preferably conical front flank 127, which is directed toward the nail tip 122 (to the right in FIGS. 4-5), and a preferably conical rear flank 128, which is directed toward the nail head (to the left in FIGS. 4-5). A front flank angle between the front flank 127 and the longitudinal direction of the nail shank 121 is smaller (for example between 10 and 30) than a rear flank angle between the rear flank 128 and the longitudinal direction of the nail shank 121 (for example between 60 and 90, preferably between 80 and 90).

[0028] At least on their surface, the preloading elements 124 comprise a material with a high material hardness, which is preferably greater than a material hardness of the rest of the nail shank 121 and/or of the substrate. For this purpose, the preloading elements 124 comprise an alloy containing zinc and nickel, preferably in the form of a coating of the nail shank 121.

[0029] When the nail 120 is driven into the substrate, a material of the substrate is deformed into the longitudinal grooves 125 and the transverse grooves 126 in such a way that it bears against the front flank 127 and the rear flank 128 of the preloading elements 124. Since this deformation of the substrate material is partially elastic, the substrate exerts forces on the preloading elements 124, and these forces differ on account of the different flank angles for the front flank 127 and the rear flank 128. The steeper a flank, the greater the force component in the longitudinal direction of the nail shank 121. This results in a preloading force toward the nail tip 122 along the longitudinal direction of the nail shank 121, exerted on the nail 120 by the substrate. The nail 120 transmits this preloading force to the sleeve 115 by means of the nail head 123 (FIG. 1), and therefore an improved sealing effect of the sleeve 115 can be achieved even in the case of a thermoplastic sleeve material.

[0030] The invention has been described using the example of a method and a device for fastening in particular an insulating material to a wall or ceiling of a building. However, it should be noted that the invention is also suitable for other purposes.