DE102006050640A1 - Fastening element has head part with metallic contact surface, and metallic sheet thickness corresponds to axial height between head part and rivet section - Google Patents

Abstract

The fastening element (10) has a head part (14) with a metallic contact surface (12), fastening part (16), and a circular rivet section (18). A square or triangular spacer section (20), rectangular in top view is provided, and the metallic sheet thickness corresponds to axial height between the head part and the rivet section. An independent claim is also included for the assembled component from the fastening element.

Description

The The present invention relates to a fastener with a a sheet metal bearing surface having head portion, a fixing portion and a in Top view annular Rivet section. Furthermore, the present invention relates to an assembly part consisting of such a fastener and a sheet metal part.

A fastener or a sheet metal part of this kind is for example from the EP-A-539793 known both in the form of a nut member and in the form of a bolt element. The nut element is available from the company Profil Verbindungstechnik GmbH & Co. KG under the name RSN nut.

in the Area of joining technology are also known as "cage nuts" that are made a tin cage and a nut member disposed therein, usually one in plan view square nut element, with the cage attached to a sheet metal part welded becomes. The nut member is within the cage in two mutually perpendicular directions slidably disposed parallel to the sheet metal part, and it is in the sheet metal part provided a hole that is sufficiently large that a bolt through the Hole passed through and can be screwed into the nut member, no matter which concrete position occupies the nut member within the cage. In this way, a construction is created by the movable, but non-rotating arrangement of the nut member in Cage a certain Tolerance compensation creates. This construction has long been known is, but is relatively expensive. There are additional ones costs for the production of the cage also for the attachment of the cage on sheet metal part, which attachment by welding a additional Process stage means that the manufacturing process of the sheet metal part also expensive. About that leads out the need for a cage to a construction that is not very compact.

task The present invention is a fastener of the above to create said type, which is suitable for attachment to a sheet metal part is, but opposite the sheet metal part remains displaceable, without the need for a Cage as well to provide a corresponding assembly part.

Around to solve this task is inventively a fastener of the type mentioned above, which is characterized that in plan view rectangular, square or triangular Distance section with a sheet metal thickness corresponding axial height between the head part and the rivet section is located.

According to one alternative solution according to the invention is a fastener of the aforementioned type provided that is characterized in that a distance section with a a sheet metal thickness corresponding axial height between the head part and located in the rivet section and has an outer shape, which in Top view corresponds to a corrugated circular shape, i. a form with rounded peaks and intervening valleys, the in a circular or oval shape, something like a wavy Teigausstechform are arranged.

By Forming of the annular rivet section in a plan view to a folded rivet bead manages the sheet metal part between the sheet metal contact surface and trapped the folded rivet section that the fastener is secured captive on the sheet metal part. By the axial height of the spacer section the arrangement can be readily made so that the sheet metal part not firmly between the sheet support surface and the flanged Rivet section is clamped, but by providing a corresponding big hole in the sheet metal part of the nut member relative to the sheet metal part within certain limits, for example 0.5 to 1 mm, in two perpendicular mutually arranged directions is displaceable, these dimensions are purely exemplary and not restrictive to understand. Furthermore is created by creating a hole in the sheet metal part with a mold and dimensions so that the fastener slidable in the hole, However, only limited rotation, ensures that the necessary Anti-rotation by the interaction of the spacer section is achieved with the limitation of the hole in the sheet metal part.

Of the Spacer portion preferably has an axial height, that of the sheet metal contact surface too the outer boundary edge measured at the free end face of the spacer section is larger as the intended sheet thickness. Such a design ensures that after the assignment or flanging a sufficient freedom of movement of the fastener in Regarding the sheet metal part is ensured, provided that the die used to transfer the rivet section is designed so that the apportionment takes place in such a way that the apportionment by at least substantially 90 °, so that the transferred Rivet portion approximately perpendicular to the central longitudinal axis of the fastener is and the fastener is not immovable ge compared to the Sheet metal part makes, i. the sheet metal part is not fixed between the folded Rivet section and the sheet metal bearing surface jams.

The shape of the head part can be relatively freely ge be chosen. For example, in plan view, the shape of the head part may correspond to or deviate from the spacing section, as long as the head part is larger in its transverse dimensions than the spacer section and thus forms the sheet metal contact surface, which is preferably perpendicular to the central longitudinal axis of the fastening element.

The Fixing element can be realized in the form of a nut element be and then characterized by the fact that the attachment section formed by a smooth or internally threaded bore is, wherein the internal thread at least through the head part and possibly also extends through the spacer section.

alternative For this purpose, the fastening element in the form of a bolt element be realized such that the threaded through a shaft part Fastening portion of the headboard remote from the front side of the spacer portion and through the annular rivet portion extends. In this embodiment is it cheap if the free end of the shaft part with a conical or possibly. rounded tip is provided, as with the attachment of another Component to an assembly part, consisting of a sheet metal part with the attached thereto fastener, the fastener then automatic is aligned by the corresponding hole in the other component.

Of the in plan view annular Rivet section is in one embodiment formed by a rivet cylinder, which in cross section the shape of the Having viewed in plan view spacer section.

alternative For this purpose, the annular rivet section in plan view by a be formed in cross-section polygonal riveting cylinder.

When Another alternative, the annular rivet in plan view by a formed in cross section at least substantially circular rivet cylinder become.

No matter what specific shape of the rivet portion, it is preferably provided on its radially outer and / or inner side with extending in the longitudinal direction of the rivet portion notches or other attenuations or radial notches at its free end face. The flanging of the rivet portion is facilitated by tearing at the locations of the notches or weakenings and subdividing into individual flaps connected at one end to the spacing portion, whereby the individual flaps can then be easily bent or folded over to engage with the rivet Sheet support surface to form a groove which receives the sheet metal part. It is particularly favorable if each flap in the region of the connection to the spacer section is arranged with its broad side parallel to one side of the spacer section. But it is also conceivable that the rivet portion alone by stretching to a Nietbördel, for example, a per se known L-shaped Nietbördel is reshaped, for example according to the U.S. Patent 4,543,701 ,

The For example, division into lobes can be achieved in this way that the notches are located at locations corresponding to the corners of the in Top view of rectangular, square or triangular spacing section correspond.

The Notches can over the entire length of the rivet section or, for example, extending from one Place on or adjacent the free end face of the rivet section via a Part of the length of the rivet section.

A possible variant of the invention Fastening element is characterized in that the spacer section within the rivet cylinder has an axial height which is the axial height of the spacer portion from the sheet metal working surface to the outer boundary edge exceeds by an amount at the free end face of the spacer section, that of the radial wall thickness of the rivet portion at least substantially corresponds and preferably is slightly smaller than this, for example by 0.1 mm. After folding the rivet section, i. the only one From this formed lobes, then lies the free end face of the spacer section in the level of the headboard opposite sides of the folded cloth or ends shortly before, so that they can be screwed with this one contact surface for the further Component forms and at a favorable Screw connection leads.

If said end face ends just before the said plane, so can be ensured that by tightening the bolt or the Mother, who screwed or with the fastener according to the invention is to the other component to that from the sheet metal part and the fastener to fix existing assembly part, the sheet metal part between the sheet metal surface and the folded rivet section is clamped properly. With others Words is the package consisting of the head part of the fastener, the sheet metal part, the folded rivet section or the formed thereof Rag, the spacer section and the other component and possibly one Disc and the bolt head or the mother clamped, creating a high-quality screw connection is created.

It is also favorable if the fastening element according to the invention is characterized in that an annular groove within the Ni eteabschnitt between this and the free end face of the located within the riveting portion of the spacer portion is located. This construction favors the folding of the rivet section or the individual tabs formed therefrom. The outer boundary of the annular groove is then preferably formed by the radially inner wall of the rivet section.

To the attachment of the fastening element according to the invention to a sheet metal part results in an inventive component, which is characterized distinguishes that the sheet metal part a hole with at least substantially has the cross-sectional shape of the spacer portion, but larger than this one is such that the dimension of the hole is chosen that the fastener slidable in the hole, but only limited rotation is, and that the annular Rivet section is folded so far radially outward that the Fastener is held out of the sheet metal part express safe, i. in the axial direction between the sheet support surface and the folded rivet section is caught.

As As expressed above, the rivet portion becomes the transferring operation preferably divided into individual lobes whose number is the page number of the distance section corresponds. The division is made to the Make any notches or weakenings in the rivet section.

The Assembly component can be made so that the sheet metal part opposite sides of the folded rivet section and within the Nietabschnitts located end face of the spacer portion in one Lie flat.

alternative For this purpose, the assembly part can be provided so that the sheet metal part has a bead in the region of the fastening element, in which the Attachment is attached, and that facing away from the sheet metal part Pages of the folded rivet section and possibly within the Nietabschnitts located end face of the spacer portion at least essentially in a plane with the headboard facing away Side of the sheet metal part outside the bead lies or lie.

The The present invention will now be described with reference to exemplary embodiments and the attached Drawing closer explains in which show:

1A a perspective view of a first embodiment according to the invention of a fastener in the form of a nut member,

1B a top view of the element of 1A .

1C a representation of the element of 1B according to the plane of the drawing IC-IC of 1B partly in the form of a sectional drawing to the left of the central longitudinal axis of the element and partly in side view to the right of the central longitudinal axis of the element,

1D a representation according to the 1C , but riveted to a sheet metal part,

1E a representation similar to the 1D but riveted to a sheet metal part with a bead, with the nut element,

2A - 2E a series of drawings corresponding to the series of drawings of 1A - 1E but of a further variant of the fastening element according to the invention,

3A - 3B Representations similar to the 1B and 1C but of a further variant of the nut element according to the invention,

4A - 4B similar to the 3A - 3B but of a further embodiment according to the invention, here in the form of a bolt element,

5 a representation similar to that of 2C but in a reverse arrangement and of another embodiment of the invention.

Referring to 1A Here is a one-piece fastener in the form of a nut member 10 with a sheet metal surface 12 having headboard 14 , a fixing section 16 in the form of an internal thread and a square in plan view annular rivet section 18 shown. A top view square spacer section 20 with an axial height, ie a height that is in the direction of the central longitudinal axis 22 is measured, which corresponds to the intended Blechteildi bridge, is between the annular rivet section 18 and the sheet metal bearing surface 12 arranged.

That the axial height corresponds to the distance portion of the sheet metal thickness, means in In this context, that the axial height of the spacer portion at least is substantially equal to the sheet metal thickness or preferably is a bit bigger, for example, in the range 0 to 0.2 mm, this statement is not as limiting to understand.

Such a dimension ensures, as in 1D shown that the nut element opposite the sheet metal part remains displaceable, even after the flanging or the folding of the rivet, which takes place by means of a suitable die, for example in a press or in a likewise known C-frame. The square rivet section in plan view is at the corners 24 that with the corners 26 of the spacer portion are aligned with extending in the longitudinal direction of the rivet portion notches 28 Mistake. When riveting the nut element 10 with the sheet metal part 30 (please refer 1D ), the rivet section is torn at the weakened sites formed by the notches and into four lobes 32 divided, which are folded radially outwards by 90 ° through the Nietmatrize. That is, the rags 32 lie after the assignment with their subpages 34 in a plane perpendicular to the central longitudinal axis 22 stands.

The presentation of the 1D shows a first possibility, an assembly part consisting of the fastening element according to the invention 10 and the sheet metal part 30 to realize. The sheet metal part has a hole 42 on, which is also square, but larger than the square distance section 20 that in the hole 42 is included. As a result, the nut member is indeed displaceable in two mutually perpendicular Richtun conditions in the sheet metal plane relative to the sheet metal part, but only limited rotation. The transverse dimension of the square hole perpendicular to two opposite sides is to be chosen smaller than the diagonal dimension of the spacer portion between two opposite corners. In this embodiment, another component (not shown), ie, another sheet metal part or another component, from below to the component assembly 24 attached and there by means of a bolt, which in the thread 16 engages (also not shown), attached. It may be advantageous between the other component and the bottom 34 the folded rivet section, ie the flap 32 , in 1D to use a washer to ensure that the clamping forces are sufficiently distributed in the screwed connection. When tightening the bolt, the individual lobes 32 , which are formed from the rivet section, even further in the direction of the head part 14 deformed the element so that the sheet metal part 30 in the aligned position of the nut member between the tops of the individual lobes 32 and the sheet metal bearing surface 12 is clamped.

1E shows an alternative variant for the attachment of the fastener on the sheet metal part. Here is the sheet metal part 30 only with a bead 40 which is perforated in the central area and therefore also a square hole 42 having. The nut member is then, as related to above 2D described riveted to the sheet metal part in the middle of the bead, so that here too the element is displaceable in two directions against the sheet metal part. It would also be conceivable to make the perforation in the sheet metal part, ie the hole shape, so that the nut element can only be displaced in one direction against the sheet metal part.

2A - 2E show a further embodiment according to the invention, the embodiment according to 1A - 1E is very similar. For this reason, the same reference numerals have been used for features having the same shape or function as the corresponding features in FIGS 1A - 1E , and it is understood that the previous description also for these features of 2A - 2E unless otherwise stated. This convention also applies to all other embodiments. The execution according to 2A - 2E is different from that of 1A - 1E only in that the rivet section 18 here in plan view has a circular shape and is not square as in the embodiment according to 1A - 1E , The scores 28 , which ensure the required weakening of the rivet section, are also here in places 24 arranged the corners 26 correspond to the square in this plan view spacer section. The scores 28 extend in this embodiment, over the entire axial height of the rivet portion to ensure that the rivet portion in the riveting operation using a suitable die at these locations breaks, so that four separate lobes 32 are formed after the assignment riveting the fastener with the sheet metal part 30 to ensure. Although here, as well as in 1A - 1E , the notches 28 extend over the entire axial height of the rivet, it is quite conceivable in all embodiments, the notches 28 to provide only over a portion of the rivet section or even to realize as radially extending notches in the free end face of the rivet section (not shown). Furthermore, other variants of the rivet section are quite conceivable, for example, this could have a polygonal shape in plan view, for example, with eight pages instead of four sides as in 1A - 1E ,

3A and 3B show another way to realize a fastener according to the invention. Also the 3A and 3B show a mother element 10 ' However, the spacer portion is not rectangular, square or triangular in plan view, but here comes a distance section 20 ' for use, having an outer shape that corresponds in plan view a corrugated circular shape, ie a shape with rounded tips 50 and intervening valleys 52 , which are arranged in a circular shape, much like a wavy Teigausstechform. The headboard 14 of the fastener 10 ' of the 3A and 3B is executed circular in this embodiment, but could be chosen freely and could for example also have a rectangular, square or triangular shape or be polygonal in plan view or even have a corrugated or star-shaped shape. The round shape of the head part shown here 14 ' could readily be used in other embodiments described in this application, as well as the other modifications which have been explained above.

The drawing of the 3A shows with a dashed line and a sheet metal part 30 ' that with the mother element 10 ' can be used. The extension of the sheet metal part can be chosen arbitrarily. The hole 42 ' in the sheet metal part corresponds in shape to the corrugated shape of the spacer section 20 , However, is sized larger, so that the nut member relative to the sheet metal part is slidable in two directions. Between the peaks and valleys 50 and 52 of the distance section 20 ' the parent element and the corresponding peaks and valleys 54 and 56 the sheet metal part is a radial overlap so that the nut member relative to the sheet metal part is limited rotation. In other words, the interlocking of peaks makes 54 and valleys 56 of the sheet metal part 30 ' with whom 50 . 52 the nut member, the rotation of the nut member relative to the sheet metal part safely.

Otherwise, the description applies in connection with the 1 and 2 as for the embodiment according to 3A and 3B , which is expressed by the use of the same reference numerals. For this reason, the same reference numerals, but here with a dash, have been used for features that have the same shape or function as the corresponding features in the 1A - 1E , and it is understood that the previous description also for these features of 3A and 3B unless otherwise stated.

Although the rivet section 18 ' according to the element 3A and 3B in plan view is circular cylindrical, it could also have any other arbitrary shape, for example, polygonal running. Again, notches are provided to facilitate the division of the cylindrical Nietabschnitts into individual lobes and their assignment.

The present invention is by no means limited only to nut members. The 4A and 4B show an embodiment which is realized as a bolt element. The similarities with the 3A and 3B are easily recognizable. The corresponding parts are therefore provided with the same reference numerals, but with a double line, and it is understood that the previous description of the 3A and 3B same for the 4A and B is, unless it is said otherwise. Basically, the only difference is that instead of a female thread 16 for the embodiment of 3A and 3B here a shaft part 60 with an external thread 62 and with a cone-shaped tip 64 is provided. The shaft part 60 protrudes in this embodiment from the center of the free end face of the spacer portion 20 '' in the direction of the central longitudinal axis 22 '' of the fastener 10 '' from the headboard 14 '' away and ends at its free end in the above-mentioned cone-shaped tip. After riveting the bolt element 10 '' according to 4A and 4B to the sheet metal part, another component 70 with a corresponding circular hole 72 on the bolt element 10 '' be positioned, and then it can be with a mother 74 be secured. If the hole 72 in the further component 70 not with the middle longitudinal axis 22 '' the bolt element is aligned, as in 4B shown, the cone-shaped tip of the bolt member will hit the edge of the hole in another component on one side and this then shifts the bolt member 10 '' opposite the first sheet metal part 30 '' until a sufficient alignment is achieved within the scope of the invention created by the compensation area. The connection can then after folding the rivet in the flanged position by tightening the nut 74 be screwed.

It is understood that all previous embodiments, such as 1A - 1E and 2A - 2E , could also be realized as a bolt elements. Furthermore, it is understood that it is also conceivable not to provide the shank part on the end face of the spacer section facing away from the head part for less critical screw connections, but directly on the head part 14 '' , ie projecting downwards in the illustration according to 4B (not shown) to arrange.

Finally shows 5 another modified embodiment with some special features. This embodiment is also a mother element 10 ''' realized, but could also be realized as a bolt element. The special feature in this embodiment is that the spacer section 20 ''' inside the rivet cylinder 18 ' has an axial height which is the axial height of the spacer portion from the sheet metal bearing surface to the outer boundary edge 80 at the free end face of the spacer section exceeds by an amount h, the radial wall thickness of the rivet section 18 ' at least substantially corresponds. In the specific case exceeds the axial height of the inner portion of the Ab section 20 ''' said axial height by an amount which is slightly less than the radial thickness of the rivet portion 18 because of the reasons given in the introduction to the description. Further shows 5 an annular groove 82 within the rivet portion between the latter and the free end face of the portion of the spacer portion located within the rivet portion 20 ''' , Sense of this groove 82 is, the assignment of the rivet section 18 ' or the example of four lobes formed from this 32 ''' (as in dotted line on the left side of the 5 shown). It can be seen that the outer boundary of the annular groove through the radially inner wall 84 the rivet section is formed. The rivet cylinder 18 ' is here as in 1 square in plan view, but could also be circular or polygonal or have another suitable shape.

at all embodiments can as an example for called the material of the fastener all materials which, in the context of cold working, are the firmness values of Class 8 according to ISO standard or higher reach, for example, a 35B2 alloy according to the old Standard DIN 1654 or a material according to DIN EN 20898 Part 2. The thus formed fasteners are u.a. for all commercial Steel materials for drawable Sheet metal parts as well as for Aluminum or its alloys. Aluminum alloys, especially those with high strength, used for the profile or the functional elements be, e.g. AlMg5. Also coming from profiles or functional elements high strength Magnesium alloys such as AM50 in question.

Claims (21)

Fastening element ( 10 ) with a sheet metal contact surface ( 12 ) having head portion ( 14 ), a fixing section ( 16 . 60 ) and a rivet section annular in plan view ( 18 ), characterized in that in plan view rectangular, square or triangular spacer section ( 20 ) with an axial height corresponding to a sheet-metal thickness between the head part ( 14 ) and the rivet section ( 18 ) is located. Fastening element ( 10 '; 10 '' ) with a sheet metal contact surface ( 12 '; 12 '' ) having head portion ( 14 '; 14 '' ), a fixing section ( 16 '; 60 ) and a rivet section annular in plan view ( 18 '; 18 '' ), characterized in that a spacing section ( 20 '; 20 '' ) with an axial height corresponding to a sheet-metal thickness between the head part ( 14 '; 14 '' ) and the rivet section ( 18 '; 18 '' ) and has an outer shape which corresponds in plan view to a corrugated circular shape, ie a shape with rounded tips ( 50 ; 50 '' ) and in between valleys ( 52 ; 52 '' ), which are arranged in a circular or oval shape, much like a corrugated Teigausstechform. Fastening element according to claim 1 or 2, characterized in that the spacer section ( 20 ) has an axial height which depends on the sheet metal bearing surface ( 12 ) to the outer boundary edge ( 80 ) Measured at the free end face of the spacer portion is greater than the intended sheet thickness. Fastening element according to one of claims 1 to 3, characterized in that the shape of the head part ( 14 ) in plan view of the spacer section ( 20 ) or deviates in its transverse dimensions and is larger than the distance section ( 20 ) and thereby the sheet metal processing surface ( 12 ), which is preferably perpendicular to the central longitudinal axis ( 22 ) of the fastener is. Fastening element according to one of claims 1 to 4 and in the form of a nut element ( 10 ), characterized in that the attachment portion by a smooth or with internal thread ( 16 ) provided bore which at least through the head part ( 14 ) and possibly also by the distance section ( 20 ). Fastening element according to one of claims 1 to 4 and in the form of a bolt element, characterized in that by a shaft part ( 60 ) with thread ( 62 ) provided attachment portion of the headboard ( 14 '' ) facing away from the end portion of the spacer section ( 20 '' ) away and through the annular rivet section ( 18 '' ) extends therethrough. Fastening element according to one of the preceding claims, characterized in that the annular rivet section in plan view ( 18 ) is formed by a rivet cylinder, which in cross-section the shape of the viewed in plan view spacer portion ( 20 ) having. Fastening element according to one of the preceding claims 1 to 6, characterized in that the annular rivet section in plan view ( 18 ) is formed by a polygonal in cross-section rivet cylinder. Fastening element according to one of the preceding claims 1 to 6, characterized in that the annular rivet section in plan view ( 18 ) by a cross-sectionally at least substantially circular rivet cylinder ( 18 ' ) is formed. Fastening element according to one of the preceding claims, characterized in that the rivet cylinder ( 18 ) on its outer and / or inner side with in the longitudinal direction of the rivet cylinder extending notches ( 28 ) or others ren attenuations is provided. Fastening element according to claim 10, characterized in that the notches ( 28 ) are arranged at locations which correspond to the corners ( 24 ) correspond to the rectangular, square or triangular spacing section in plan view. Fastening element according to one of claims 10 or 11, characterized in that the notches ( 28 ) extend over the entire length of the rivet section. Fastening element according to one of claims 10 or 11, characterized in that the notches ( 28 ) extends from a position on or adjacent to the free end face of the rivet section over part of the length of the rivet section ( 18 ). Fastening element according to one of the preceding claims, characterized in that the spacer section ( 20 ''' ) within the rivet section ( 18 ' ) has an axial height which is the axial height of the spacer section (FIG. 20 ''' ) from the sheet metal processing surface ( 12 ) to the outer boundary edge ( 80 ) at the free end face of the spacer section ( 20 ''' ) exceeds by an amount (h), the radial wall thickness of the rivet portion ( 18 ' ) at least substantially corresponds. Fastening element according to one of the preceding claims, characterized in that an annular groove ( 82 ) within the rivet section ( 18 ' ) between the latter and the free end face of the region of the spacer section located inside the rivet section (FIG. 20 ''' ) is located. Fastening element according to claim 15, characterized in that the outer boundary of the annular groove ( 82 ) through the radially inner wall ( 84 ) of the rivet section ( 18 ' ) is formed. Assembly component consisting of a fastening element according to one of the preceding claims and a sheet metal part, characterized in that the sheet metal part ( 30 ) a hole ( 42 ) with at least substantially the cross-sectional shape of the spacer section (FIG. 20 ), but which is greater than this, in such a way that the dimension of the hole ( 42 ) is selected so that the fastening element is displaceable in the hole, but only limited rotation, and that the annular rivet section ( 18 ) so far radially outwardly folded that the fastener ( 10 ) in the sheet metal part ( 30 ) is held expressly, ie in the axial direction between the sheet support surface ( 12 ) and the folded rivet section ( 18 ) is caught. Assembly component according to claim 17, characterized in that the rivet section ( 18 ) by the transfer process into individual lobes ( 32 ) whose number is, for example, the page number of the distance section ( 20 ) corresponds. Assembly component according to claim 18, characterized in that the division at the locations of in the rivet section ( 18 provided notches ( 28 ) or weakening has occurred. Assembly component according to one of the preceding claims 17 to 19, characterized in that the sheet metal part ( 30 ) facing away from ( 34 ) of the folded rivet section ( 18 ) and the inside of the rivet section located end face of the spacer section ( 20 ) are at least substantially in one plane. Assembly component according to one of the preceding claims 17 to 20, characterized in that the sheet metal part ( 30 ) in the region of the fastening element a bead ( 40 ), in which the fastening element ( 10 ) is mounted, and that the sides facing away from the sheet metal part ( 34 ) of the folded rivet section ( 18 ) and possibly the inside of the rivet section located end face of the spacer section ( 20 ) at least substantially in a plane with the side facing away from the head part of the sheet metal part ( 30 ) lies outside the bead or lie.