DE20103427U1 - Insulation holder - Google Patents

Abstract

The invention relates to a fixing element (1) for insulation material for fastening insulation elements on a support. Said fixing element comprises a dowel (10) with a dowel shaft (11) having an axial passage (12) on whose one end a expansible zone (S) is configured and onto whose other end a flange-type pressure plate (13) is formed. An extended shaft section (14) is configured in the transition section from the flange-type pressure plate to the dowel shaft. Said shaft section has a receiving chamber that is coaxial to the longitudinal axis (X) of the dowel and has a diameter that is larger than the axial passage, thereby forming an annular support surface (142) enclosing the axial passage. A pin (2) can be inserted in the dowel to expand the expansible zone. Said pin has a pin shaft (22) and a head (21), said head being insertable in the receiving chamber of the dowel and being provided with a plastic cap (3) so as to fill out the receiving chamber. The cap of the pin is configured on both its ends with one cylindrical shoulder (37, 38, 21, 218) each, having identical outer diameter for guiding the pin when it is inserted in the receiving chamber of the dowel and has at least one interposed recess (33, 213). The cap of the pin, on the front face (39, 219) configured by the shoulder (38, 218) facing the pin shaft has a counter-bearing for receiving axial forces once the pin is inserted in the receiving chamber of the dowel and guarantees that the pin rests against the bearing surface of the shaft element of the dowel.

Description

Insulation holder

The invention relates to an insulation holder for fastening insulation and damping elements to a substrate such as masonry. It can be used wherever reliable protection of a metal expansion element, in particular a nail head, against the effects of weather and moisture is required.

The insulation holders and fastening elements known from practice are manufactured using complex, ostensibly cost-intensive technologies. These fastening systems for insulation materials with a pressure or holding plate, a dowel and a metal nail that is inserted into the hollow shaft of the dowel are based on the basic problem of cold or thermal bridges. Furthermore, there is the possibility of condensation settling on the unprotected steel pin, which can lead to corrosion. Another disadvantage of the insulation holders on the market is the complex dowel assembly. Another disadvantage is the insufficient transverse force absorption of the fastening system.

DE OS 196 48 823 describes an insulation holder for fastening an insulation board, which comprises a holding plate, a hollow shaft for the expansion nail to be inserted and a striking bolt. The striking bolt is inserted into the hollow shaft in a clamping manner with a corresponding projection over the holding plate. The disadvantage of the invention is that it is more complex to assemble and does not adequately absorb the transverse forces acting on the insulation holder and that there is no direct force redirection from the dowel to the nail. EP 042 573 describes an insulation holder with a plastic shackle to be inserted into the hollow shaft. The use of a plastic nail to anchor the insulation holder has the disadvantage that it is only suitable for subordinate fastenings, since the plastic nail only allows for lower expansion forces or can absorb lower transverse forces.

EP 0 074 469 is based on a fastening element for fastening heat-insulating materials, whereby the head of the expansion pin is provided with a plastic jacket, i.e. covered, to protect it from corrosion and prevent a thermal bridge to the plaster. The disadvantage of the solution according to the invention is the high technical complexity, since special and expensive injection molding tools and peripheral devices or equipment are required for the injection molding of the nail head. DE 295 21 698 describes an insulating panel dowel that consists of a dowel sleeve with a plate, a metal pin and a plastic driving pin. The disadvantage of this arrangement is that it requires complex pre-assembly. Insufficient transverse force absorption and the possibility of tilting when driving in the nail also have a disadvantageous effect. DE 195 36 171 contains a fastening element for fastening heat-insulating panels with a pin with a metal base body and a head that is formed with a plastic jacket. By arranging an insulation zone over the sleeve for the pin shaft, the formation of a thermal-cold bridge can be suppressed. The disadvantage here is the complex manufacturing process, due to the overmolding of the
Spreader pin.

The invention specified in claim 1 is based on the problem of creating an insulation holder that is simple to handle, easy to install and inexpensive to manufacture, which protects the metal nail head from moisture after it has been driven into the dowel and, above all, improves the absorption of the weakened transverse forces. Furthermore, an insulation holder is to be made available with which thermal bridges between the nail head and the external plaster can be avoided.

This problem is solved with the features specified in claim 1 in that the insulation holder 1 for fastening insulation and insulating elements to a substrate, such as masonry, comprises a dowel 10 with a dowel shaft 11 with an axial passage 12, at one end of which a spreading area S is formed and at the other end of which a flange-like

Pressure plate 13 is formed and a nail 2 with a head 21 that can be inserted into the dowel 10 to widen the expansion area S and a drive-in cap 3 that can be plugged onto the head 21 of the nail 2.

The invention achieves an insulation holder with a high insulating effect in the application, which better absorbs the transverse forces acting on the holder and in which the nail head is effectively protected from the effects of the weather, e.g. suction effects in strong winds, moisture. Furthermore, thermal bridges are avoided.

Further advantageous details of the invention can be taken from the characterizing features of subclaims 1 to 5, the exemplary embodiment and the drawings.

In a particularly advantageous embodiment in claim 2, the impact cap has a cylindrical cap body with an adjoining cylindrical cap shaft and a lateral insertion slot with a receiving area for the nail head extending transversely to the longitudinal axis, whereby a central seat of the nail head in the X axis and a straight driving in of the nail can be achieved. A longitudinal slot is provided on the cap shaft for inserting the nail shaft parallel to the axis.

According to a proposal of the invention in claim 3, the cap body has lateral recesses and webs, wherein the webs separate the lateral recesses, resulting in additional air chambers with a high insulating effect.

In a further advantageous embodiment in claim 4, the longitudinal slot in the cap shaft of the impact cap can be expanded.

The invention will be explained in more detail using an embodiment and the drawings:

Show it.

Figure 1 a view of the insulation holder with partially inserted expansion nail

with impact cap

Figure 2 is a longitudinal section A-A of Figure 1

Figure 3 is a perspective view of the insulation holder according to Figure 1
Figure 4 is a view of the insulation holder according to Figure 1 with fully

the nail hammered into the dowel
Figure 5 a longitudinal section BB according to Figure 4
Figure 6 a perspective view of the insulation holder according to Figure 4
Figure 7 a perspective view of the impact cap in enlarged view
Figure 8 is a perspective view of the impact cap and nail for

the assembly

Figure 9a is a perspective view of the assembly of the impact cap,
Figure 9b of the nail and dowel to the insulation holder in three stages
Figure 9c

Figures 1 to 9 show the parts connected to one another according to the invention.

The insulation holder for fastening insulation and soundproofing elements to a substrate, for example masonry, is preferably made of plastic with sufficient elasticity. According to Figures 1 to 7, it comprises a dowel 10 with a dowel shaft 11, a nail 2 with a head 21 that can be inserted into the dowel 10, and a drive-in cap 3 that can be plugged onto the head 21 of the nail 2. The dowel shaft 11 has an axial passage 12 through the dowel 10. At one end of the dowel 10 there is a circumferential expansion area S that can be expanded by the nail 2, and at the other end there is a flange-like pressure plate 13. Instead of this pressure plate, a pot-shaped, widened head can also be formed as a holding element. The impact cap 3 consists, as can be clearly seen from Figure 7, of a cap body 31 with a cylindrical cap top and an adjoining cylindrical cap shaft 32, i.e. an extended shaft part. The cap body 31 has a lateral insertion slot (35a) with a

Receiving area 35. The receiving area 35 is arranged coaxially to the longitudinal axis X so that the nail head 21 inserted laterally is centrally located and is driven in straight when driven in by a setting tool or hammered into the top of the impact cap 3, as indicated by the arrow "P", i.e. in the longitudinal axis X. Furthermore, as can be seen from Figure 7, a longitudinal slot 36 running in the axial direction is provided on the cap shaft 32, which serves to insert the nail shaft 22 parallel to the axis, i.e. the nail can be inserted laterally by the radial movement "R". The cylindrical cap shaft 32 of the impact cap 3 is designed as an expansion element and can be expanded by the longitudinal slot 36 so that the nail can be inserted, as can be seen from Figure 8. The nail head 21 is also introduced into the receiving area 35 by the movement in the radial direction according to arrow "R". In the area of the longitudinal edges 36a of the longitudinal slot (insertion slot) 36 on the cap shaft 32 (see Figure 7) there is a chamfer so that the nail shaft 22 can be inserted or pressed in more easily. The cap body 31 is provided with recesses 33 (openings) on the head of the impact cap 3, which serve to save material and increase the insulation effect by air inclusions in the additional air chambers formed. The head plate 37 (see Figure 8) is continuous and has a corresponding thickness for introducing impact forces via the core or the remaining webs 34. A receiving space 141 formed transversely to the longitudinal axis X adjoins the pressure plate 13 of the dowel 10. The outer diameter "a" of the cylindrical cap upper part of the cap body 31 is slightly smaller than the inner diameter "b" of the cylindrical receiving space 141 formed by the receiving part 14 and ensures the precise fit of the cap body 31. The outer diameter "c" of the cap shaft 32 is slightly smaller or at least equal to the inner diameter "d" of the dowel shaft 11, i.e. corresponds to the axial passage 12 through the dowel 10. This provides additional sealing of the axial passage 12 against the ingress of moisture. Figures 9a-9c show the assembly of the impact cap 3, the nail 2 and the dowel 10 to the insulation holder in three stages.

Be2xigszeichen:

1 = Insulation holder

10 = Dowel, preferably made of plastic

11 = Dowel shaft

12 = axial passage through the anchor

13 = flange-like pressure plate

131 = Breakthroughs in

132 = Recesses on the underside of the pressure plate

14 = receiving part, cylindrically extended shaft part in the transition from

to 13

141 = Receiving space in the receiving part 14, cylindrical

2 = Nail (spread nail)

21 = Head of the nail (nail head)

22 = Shaft of the nail (nail shaft)

3 = Impact cap

31 = Cap body, cylindrical cap top

32 = Cap shaft

33 = side recesses in

34 = webs 31, which separate the recesses

35 = Recording area

35a = side slot in

36 = Longitudinal slot 36a = Chamfered edge S = Spreading area

X = Longitudinal axis of the insulation holder, dowel, nail and

Impact cap

a = outer diameter of the cap top

b = inner diameter of the receiving space

c = outer diameter of the cap shaft

Claims (5)

1. Insulation holder ( 1 ) for fastening insulation and insulating elements to a substrate, such as masonry, comprising a dowel ( 10 ) with a dowel shaft ( 11 ) with an axial passage ( 12 ), at one end of which an expansion region (S) is formed and at the other end of which a flange-like pressure plate ( 13 ) is formed, and a nail ( 2 ) with a head ( 21 ) that can be inserted into the dowel ( 10 ) to widen the expansion region (S), characterized in that a drive-in cap ( 3 ) that can be plugged onto the head ( 21 ) of the nail ( 2 ) is provided. 2. Insulation holder according to claim 1, characterized in that the impact cap ( 3 ) has a cylindrical cap body ( 31 ) with an adjoining cap shaft ( 32 ), the cap body ( 31 ) having a lateral insertion slot ( 35a ) with a receiving area ( 35 ) extending transversely to the longitudinal axis X for the lateral insertion of the head ( 21 ) of the nail ( 2 ), and that a longitudinal slot ( 36 ) running in the axial direction, which is connected to the insertion slot ( 35a ), is provided on the cap shaft (32) for receiving the shaft ( 22 ) of the nail ( 2 ). 3. Insulation holder according to claim 1 or 2, characterized in that the cap body ( 31 ) has lateral recesses ( 33 ) which are separated by webs ( 31 ). 4. Insulation holder according to one of claims 1 to 3, characterized in that the longitudinal slot ( 36 ) in the cap shaft ( 32 ) of the impact cap ( 3 ) can be expanded. 5. Insulation holder according to one of claims 1 to 4, characterized in that the flange-like pressure plate ( 13 ) of the dowel ( 10 ) has a receiving space ( 141 ) which is formed coaxially to the longitudinal axis X and which is formed as an extended shaft part ( 14 ) in the transition to the dowel shaft ( 11 ), and that the receiving space ( 141 ) serves to receive the impact cap ( 3 ).