FIELD OF THE INVENTION

This invention relates to self-riveting elements or fasteners, such as screws, bolts, nuts and the like, wherein the rivetable element includes a shaft or barrel portion and an integral head portion having a riveting portion on the underside of the head portion, adjacent the shaft

or barrel portion. The field of this invention also relates to riveting dies having a central

opening which receives the shaft or barrel portion of the riveting element and a riveting portion adjacent the opening which deforms the sheet metal part or panel to which the riveting element is attached into the riveting portion of the fastener head. Finally, the field of this invention relates to methods of attaching riveting elements of the type described to a sheet metal part or plastically deformable panel.

RELATED APPLICATIONS This application claims priority to German patent application P 44 10 475.8 filed March 25, 1994.

BACKGROUND OF THE INVENTION As described, the present invention relates to improved self-riveting elements or fasteners having a shaft or barrel portion and an integral head portion which may be permanently affixed to a sheet metal part or panel by riveting. Elements of this type are previously known, wherein the shaft is generally threaded and introduced in a pre-formed hole in the sheet metal part. The head portion then bears on one side of the metal part. The sheet metal part or panel is then shaped in a setting operation, such that the panel molds physically into a small groove in the shaft of the element, directly adjacent to the bearing

surface on the underside of the head portion, thereby securing the element in a sheet metal part or panel. The underside of the head, adjacent the shaft, may include radial ribs and the panel is deformed over the ribs during installation, preventing relative rotation of the elements on the sheet metal panel. Such assemblies are frequently used in industrial production by the automotive and appliance industries to fasten another component to the assembly, which may consist of a second sheet metal part and fastener, such as a nut. The contact surface of the head portion is thus located on one side of the first panel, opposite the second fastening element, such that the sheet metal part is stressed by compression between the fasteners. In practice, however, the previously known self-riveting elements of this type were not securely attached to the metal part, such that the element commonly loosened in shipping or storage before assembly, particularly where the sheet metal part is relatively thin as now used by the automotive and appliance industries. It is not uncommon for the riveting element to become lost or assume an orientation in the panel which is unacceptable for further processing of the sheet metal part, as described above. The loosening of the prior self-riveting elements of this type also sometimes resulted in inefficiency of the intended anti-rotation means, such that the element will rotate as the nut is assembled on the shaft portion, before the nut is tightened on the bolt. These difficulties are a particular problem in automotive body construction and other applications where the head portion of the riveting elements are located in an enclosed cavity following installation, which is no longer accessible for repair. If the fastening element freely rotates in the panel or is lost under these conditions, the object being manufactured, such as an automobile, can no longer be finished in regular production, but must be repaired at substantial expense. Obviously, these problems should be avoided, if possible.

Another problem, particularly with attaching a riveting fastener to thin sheet metal panels results from the fact that the anti-rotation ribs must have a certain height; that is, the height of the ribs from the contact surface on the underside of the head portion must be sufficient to prevent rotation. Where the sheet metal part is relatively thin, the ribs dent the panel to a degree such that the full strength of the sheet metal part is no longer available, which may lead to further problems.

Another disadvantage of self-riveting male fastener elements of this type is that the

small groove in the shaft portion which receives the panel material to prevent pull-out is

difficult to make and thus unnecessarily increases the cost of the fastener. Further, this radial groove results in an undesirable reduction in the strength of the bolt or screw fastener, including its fatigue properties, resulting from the sharp edges and reduction of the cross-sectional area of the shaft portion of the element. Further, because of the groove dimensions, the element may also be insufficiently secured to the sheet metal part, aggravating the tendency of the element to loosen in the sheet metal part or drop out, as described above.

Thus, a primary object of the present invention is to provide a self-riveting element of this type which can be manufactured and fixed to the sheet metal panel at a relatively low cost and wherein the risk of loosening or loss of the element out of the sheet metal part is reduced and preferably precluded. Another object is to provide a joint between the self-riveting element and panel which is as strong as possible and a self-riveting element or fastener which is suitable for attachment to thin sheet metal parts, including nonferrous sheet metal parts, such as aluminum or its alloys.

SUMMARY OF THE INVENTION The self-riveting element or fastener of this invention includes several inventive features or elements which, in combination, result in an improved element and fastener and panel assembly, and reduces the cost of the assembly. As will be understood, however, the inventive features of this invention may also be used separately, particularly where the function of a particular feature is desired or the function of another feature is not desired. As described above, the self-riveting element or fastener of this invention includes a shaft or barrel portion and an integral head portion which extends generally transverse to the longitudinal axis of the shaft or barrel portion and which provides an annular contact surface on the underside of the head portion adjacent the shaft or barrel portion. In the preferred embodiment, the contact surface includes a plurality of concave pockets or closed fields which are bounded by ribs extending outwardly away from the shaft portion. In the most preferred embodiment, the pockets include a bottom wall which extends radially inwardly toward the shaft portion and the ribs between the pockets extend longitudinally along the shaft portion. In the most preferred embodiment, the shaft portion further includes at least one radial depression or groove which is spaced from the plane of the contact surface of the head portion, preferably a distance equal to approximately the thickness of the sheet metal part or panel to which the riveting element is attached. This depression or groove most preferably extends spirally around the shaft portion and may be the groove of the first thread where the shaft or barrel portion is threaded.

This design makes it possible in riveting the element or fastener to the sheet metal part or panel to plastically deform the material of the sheet metal part by a suitable die arranged concentrically to the shaft into the concave, peripherally closed fields or pockets in the underside of the head portion and radially into the depression or groove in the shaft

portion with essentially no thinning of the sheet metal part. Further, the self-riveting element or fastener of this invention prevents rotation of the fastener in the panel without weakening of the sheet metal part, thus avoiding the problems associated with the projecting radial ribs on conventional self-riveting elements of this type. Further, because the ribs between the concave pockets extend longitudinally along the shaft portion, the anti-rotation is achieved not only through the material driven into the concave fields, but also by the positive connection between the longitudinal ribs on the shaft portion and the sheet metal part. As

a result, the torque resistance of the fastener in the panel is considerably improved. In attaching the element to the panel, the sheet metal part is not unnecessarily reduced in thickness and the depression or groove in the shaft portion may be located further away from the underside of the contact surface of the head than would be possible with the radial groove according to the prior art, such that the depression can be more easily formed. Further, the shape of the depression or groove can be formed more cleanly than where the groove is located immediately adjacent the head as in the prior art, insuring that the sheet metal will be more fully deformed into the depression, thereby generating an improved resistance to push-off of the fastener and loss of the element from the sheet metal part, as described above.

Another advantage of the self-riveting fastener element of this invention is the location of the longitudinal ribs and the radial depression or groove on an enlarged portion of the shaft adjacent the head. Owing to this design, the self-riveting element is weakened less by the depression, allowing a more full utilization of the rated strength of the fastener element and an improvement of the fatigue properties of the element. Further, the torque resistance of the element in the panel is also improved. Of special importance, however, is that the flow performance of the sheet metal part material can be improved in the attachment of the

fastener to the panel. Preferably, the preformed or prefabricated hole in the sheet metal part has a diameter which enables the insertion of the shaft portion without damage. The large diameter portion of the shaft portion preferably has a diameter which is slightly greater than the opening or hole in the panel, such that the diameter of the hole is enlarged during installation of the self-riveting element in the panel, which provides additional material which can be driven into the concave, peripherally closed fields or pockets in the head and into the radial depression in the shaft portion. It is also possible to conically deform the sheet metal part adjacent the hole in accordance with the disclosure of U.S. co-pending application Serial No. 343,724 filed November 22, 1994, the disclosure of which is incorporated herein by reference. The shaft or barrel portion of the self-riveting element is then received through the conical opening, through the apex of the conical-shaped depression and the panel is then pressed flat by driving the head portion against the panel, thereby making additional material available for forming a tight joint between the element and the sheet metal part.

The spiral depression or groove in the shaft portion can be formed by a threaded groove, namely a continuation of a threaded portion on the shaft of the self-riveting element. In this manner, the depression is made in the same operation as when the thread is formed or cut in the shaft portion. This leads to a considerable cost saving in the manufacture of the self-riveting fastener element and also leads to a clean spiral depression. If the longitudinal ribs are formed on the shaft portion, adjacent the head, to the smaller diameter portion of the shaft during the thread rolling operation, which is preferred, the depression or groove can be readily deformed during the thread rolling operation, such that all threads end in the depression. Alternatively, however, it is possible for the ribs to be formed after the thread rolling operation in a separate step, for example, also in a thread rolling operation. In this case, the depression would be divided into several sections by the ribs. Further, the

relieved portion between the ribs extending along the shaft should not extend into the depression to avoid interference with the deformation of the panel into the depression. An exception would apply where the self-riveting elements are used for attachment of an electrical terminal. In that case, the ribs could produce a desirable kerfing effect in the opening of the terminal, which could be beneficial to creating a good electrical contact.

The spiral depression may represent one or two threads and may also be in the form of thread sections, especially where the depression is fashioned as a multiple-start threading, which would be useful for the rivetable element of this invention. The spiral depression or

groove has yet another advantage as compared to a circular radial groove. Following installation after extended use, additional torque may be required to remove the nut from the shank portion of the stud because of contamination or corrosion. Such elevated torque, however, will result in forcing the riveting element against the sheet metal part due to the spiral shape of the depression, such that increased torque resistance is provided. Although a spiral groove is preferred for the reasons set forth above, it is also possible to utilize a circular groove or depression wherein the pitch of the depression is zero degrees. This form may be preferred wherein the shaft portion of the self-riveting element is unthreaded, such as an axle journal. The depression or groove should, however, be spaced from the underside of the head, as described above.

As will be understood, the area of the enclosed fields or pockets relative to the contact area, may be selected for optimal torque resistance. Thus, it is possible to use the self-riveting element of this invention in conjunction with softer metals, including aluminum alloy panels, which are being used increasingly in automotive applications. In such applications, the material of the self-riveting element may be selected to avoid galvanic corrosion, wherein the self-riveting element may be formed of an aluminum alloy.

As described, the die member utilized for assembly of the self-riveting element of this invention includes a bore which receives the shank or banel portion of the fastener and the opening is preferably crowned to deform panel metal into the confined fields or pockets in the head portion of the element. As will be understood, the bottom surface of the groove in the underside of the head portion will depend upon the shape of the die used. Further, the self-riveting element may be a male fastening element, such as a screw or bolt, or a female element, such as a nut, wherein the shaft portion is replaced by an annular barrel portion.

The method of this invention thus includes forming a hole in the sheet metal part by punching, drilling or the like; inserting the shaft or barrel portion of the self-riveting element through the hole in the sheet metal part or panel; then plastically deforming the sheet metal part material in the vicinity of the panel hole to at least partially fill the pockets in the underside of the head and radially inwardly into the groove or depression in the shank or banel portion of the self-fastening element. Other advantages and meritorious features will be more fully understood from the following description of the prefened embodiments, the appended claims and the drawings, a brief description of which follows.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a side elevation of one embodiment of the self-riveting element of this invention, which is partially cross-sectioned for clarity;

Figure 2 is an end view of the self-riveting element shown in Figure 1 ; Figure 3 is an enlarged cross-sectional partial view of the self-riveting fastening element shown in Figure 1;

Figure 4 is a partial cross-sectional end view of Figure 3 in the direction of view arcows 4-4;

Figure 5 is a schematic illustration of an installation apparatus or setting head of this invention illustrating the first step of the method of installation of this invention; Figure 6 is a partial cross-sectional view similar to Figure 5 following installation of the self-riveting fastening element shown in Figure 5;

Figure 7 is a detailed partial cross-sectional side view of the riveting die shown in Figures 5 and 6;

Figure 8 is a side partially cross-sectioned view of the self-riveting fastening element shown in Figures 1 to 4 installed in a sheet metal part;

Figure 9 is an enlarged partial cross-section view of Figure 8 in the area indicated by reference 9;

Figure 10 is a side partially cross-sectioned view similar to Figure 1 of a second embodiment of the self-riveting fastening element shown in Figure 1, wherein the shank portion of the riveting element is unthreaded;

Figure 11 is an end view of the fastening element shown in Figure 10;

Figure 12 is a partial cross-sectional view of the riveting element shown in Figure 10;

Figure 13 is an enlarged partially cross-sectional view of Figure 12;

Figure 14 is a side partially cross-sectioned view of another embodiment of the self-riveting element of this invention in the form of a female element;

Figure 15 is an end view of the self-riveting element shown in Figure 14;

Figure 16 is an enlarged partially cross-sectioned side view of the fastening element shown in Figure 14;

Figure 17 is an end partially cross-sectioned view of Figure 16 in the direction of view arrows 17-17;

Figure 18 is a partially cross-sectioned side view of another embodiment of the self-riveting element of this invention in the form of a threaded female fastening element installed in a panel; and

Figure 19 is an enlarged view of the fastening element shown in Figure 18.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Figure 1 is a side elevation of one embodiment of the rivetable element 10 of the invention in the form of a threaded bolt having a head portion 12 and a shaft portion 16 which is externally threaded at 14. As shown in further detail in Figures 2, 3 and 4, the underside 18 of the head portion 12 has a concave contact surface including peripherally closed fields or pockets 20 which are partly bounded by ribs 22 which extend radially outwardly from the shaft portion 16 as shown in Figures 2 and 4 and which are continuous with rib portions 24 which extend axially along the shaft portion 16 as shown at 24 in Figure 3. As shown, the ribs 24 extend from the head portion to 26 to depression or groove 28 which in the disclosed embodiment is the first spiral groove of the threaded portion 14 of the shaft.

As shown in Figures 2 and 4, the closed fields or pockets 20 are bounded on their radial outer side by sunounding annular peripheral surface 30 of the head, with the ribs 22 defining the radial surface which is continuous with the annular surface 30. The radial inside of the pockets 20 are defined by a cylindrical peripheral surface 32 of the shaft portion. As shown in Figure 3, the rib portions 22 extend obliquely to the plane 31 defined by the underside of the head portion 12 or backed-off from this plane (31) such that the ribs do not protrude from this backed-off plane adjacent the shaft portion of the self-riveting element.

It will be understood, however, that the rib portions 22 may be located in the same plane 31 as the peripheral surface 30. The peripheral surface 30, as well as the surfaces adjacent the shaft 22, form the actual contact surface of the head portion 12. In this embodiment, the closed fields or pockets 20 are generally quadratic or rectangular which, in practice, is a favorable shape. It will be understood, however, that the pockets may be shaped differently within the purview of the present invention. With the embodiment disclosed in Figures 2 and 4, the rib portions 22 in the contact area of the underside 18 of the head portion 20 expand radially outwardly as shown in Figures 2 and 4. Further, the rib portions 22 extend

continuously and without interruption into the outer peripheral surface 30 of the head portion. In the disclosed embodiment, there are eight rib portions 22, with the prefened number of rib portions ranging from between six and eight.

As evident from Figures 1 and 3, the pockets or closed fields 20 have their greatest depth measured axially in the direction of axial line 35 (in Figure 1) adjacent the shaft portion 16. The contact surface on the underside 18 of the head 12 comprises primarily the rib portions 22 and the peripheral outer surface 30. The bottom surfaces of the pockets 20 can be used as a contact surface through deformation of the sheet metal part into the closed fields or pockets. The contact surface is thus relatively large, such that the rivetable element 10 may be used with relatively soft sheet metal parts without concern that a critical surface pressure will result. In the most prefened embodiment, the bottom surfaces of the closed fields are located on a conical shell surface with an inscribed angle of preferably between about 130° to 140°. This taper angle is refened to in Figure 3 as angle . Thus, the rivetable element 10 of the embodiment shown in Figures 1 to 3 features a centering depression which assures a high-quality, valuable guidance of the element. A conical pilot point 36 at the end of the shaft portion 16 not only provides a female fastener or nut received

on the shaft portion with a lead-in, but also guides the self-riveting element in the setting head as it is inserted into the sheet metal part, as described below.

The setting or assembly operation is schematically illustrated in Figures 5 and 6. The installation tool 40 shown in Figure 5 includes a setting or installation head 38 having a press joining punch 42 movable in the direction of anow 43. Anow 42 indicates the feed direction of the self-riveting element 10 in the installation head. The self-riveting elements 10 are fed individually to the installation head 38. The self-riveting element 10 shown in Figure 5 proceeds under gravity, compressed air or the joining punch 42 through bore 44 of the installation head until the head portion 12 of the element contacts the ball 48, which is resiliently biased into the bore 44 by spring 46. In practice, three spring biased balls are provided arranged at intervals of 120° around the longitudinal axis 50 of the installation head 38. In the station of Figure 5, the prepunched sheet metal part 52 into which the element 10 is to be installed is retained between the installation head 38 and a riveting die member 54 of a lower tool 56. The shaft portion 16 of the self-riveting element 10 is provided with a threaded portion 14 which is partially received through the preformed hole in the sheet metal part and through a coaxially aligned cylindrical centering hole 60 in the riveting die 54. The riveting die 54 is releasably retained within a bore 57 of the lower tool 56 and bears against a bolster 59 on a lower press plate 61.

In the subsequent station of the setting operation, the press/joining punch 42 provided in the installation head 38 moves further downwardly, forcing the head portion of the element past the spring loaded balls 48. During this motion, the sunounding crown area 64 shown in Figure 7 of the riveting die is forced into the material of the sheet metal part deforming the sheet metal into the V-shaped groove 23 which includes the enclosed fields or pockets 20 and into the recess 28, thereby creating a secure, riveted joint between the riveting

element 10 and the sheet metal part 52, forming a secure assembly. The prefened embodiment of the riveting die 54 includes a crown area 64 which sunounds the hole 58 as shown in Figure 7. That is, the annular crown-shaped area of the riveting die defines a wavy end face with peaks 72 and valleys 74 extending in axial direction. In the operation, the relief peaks 72 deform and drive the material of the sheet metal part into the concave fields or pockets 20 in the underside 18 of the head portion of the element, while the valleys 74 make contact with the sheet metal part opposite the ribs 22 which extend radially outwardly, such that there is no pronounced thinning of the sheet metal part in the area of the ribs.

Because the sheet metal material is deformed between the riveting die and the underside of the head portion 12 of the element 10, the sheet metal material is also forced to flow into depression 28, thereby forming the desirable positive joint. Unexpectedly, it is not necessary to angularly align the element 10 on the peaks and valleys of the crown portion 64 because the element will rotate to assume a position in which the peaks 72 of the riveting die 54 are aligned with the concave fields or pockets 20. That is, the necessary alignment takes place through a slight automatic twist of the element during the installation operation.

A groove 80 is formed in the sheet metal part 52 by the crowned area 64 of the die member 54 as shown in Figures 8 and 9. This groove 80 may be interrupted, but extends around the shaft portion 16 of the self-riveting fastener on the side of 71 of the sheet metal part away from the head 12 of the fastener as shown in Figures 8 and 9. As will be understood, this groove 80 features a wavy bottom surface; however, the peaks of the wavy bottom surface should not protrude beyond the underside 71 of the sheet metal part in order to provide a clean seating of the nut or other object to be attached to the sheet metal part. An exception is where the object to be attached to the sheet metal part is an electrical terminal. In such case, the peak areas of the wavy bottom surface may protrude beyond the

underside 71 of the sheet metal part to provide a greater contact surface pressure on the terminal, providing a better electrical contact.

As will be understood, the self-riveting element of this invention may be a female fastener, such as a nut, or any other type of element which may be permanently attached to a sheet metal part, such as a metal panel used by the automotive and appliance industries.

Figures 10 through 13, for example, illustrate an element 110 in the form of an axle journal. Because of the similarities of the element 110 with the self-riveting element 110 discussed hereinabove, similar reference numbers are used for the element 110 shown in Figures 11 and 12 and for all further embodiments described hereinbelow to avoid unnecessary duplication of description.

The differences between the axle journal 110 shown in Figures 10 through 13 and the dread bolt 10 are not very significant. Major differences are found in two areas. First, the shaft portion 116 of element 110 includes a cylindrical bearing surface 115, such that the shaft portion is not threaded. It will be understood, however, that the cylindrical bearing surface 115 may include a threaded section in order to tighten the sheet metal part with an appropriate nut or nut and washer arrangement between the head portion 112 and the nut or to secure an interior bushing of the object mounted on the axle journal against axial shifting in a longitudinal direction of the element.

Second, the groove 128 into which the sheet metal is deformed is an annular groove, rather than a spiral groove thread as groove 28 in Figure 3. The annular or circular groove 128 may thus be considered as a spiral groove with an angle of inclination equal to zero degrees. From Figure 12, it can be seen that this sunounding groove 128 is ananged approximately an equal distance to the sheet metal thickness from the contact surface 118 of the head 112 and that this distance is substantially greater than similar grooves provided in

the fastening elements disclosed in the prior art. It is thus easier to form the groove or depression in the shaft portion than where the groove is located immediately adjacent the head portion 112 as disclosed in the prior art. As described above, however, the groove 128 may be formed as a thread groove as shown at 28 in Figures 1 through 4. The groove 128 is formed in this embodiment in the bearing area of the shaft portion adjacent the head portion 112 which may be possible and prefened with the element shown in Figures 1 to 9. The positive joint between the element 110 and a sheet metal part accomplished exactly as described above in regard to Figures 8 and 10 with the threaded bolt 10.

The riveting element of this invention may also be in the form of a female element, such as the bearing bushing 210 shown in Figures 14 to 17 and the nut fastener 310 shown in Figures 18 and 19. The bearing bushing 210 shown in Figures 14 to 16 includes an axial through-bore 282 having a cylindrical center portion 282 which provides the bearing surface. In Figure 14, the upper portion of the bore 282 includes a centering hole 234 having a diameter somewhat larger than the bearing surface 282. The lower portion of the bore 284 includes an enlarged diameter portion 286 which serves to prevent deformation of the shaft portion of the nut due to plastic deformation of the sheet metal part into the fields or pockets 220 and the depression 228, which would result in constriction of the cylindrical bore 282, which would prevent the bearing part from being inserted in the element 210. In this embodiment, the head portion is a radial flange 212 and the shaft portion is an annular barrel portion 216. As set forth above, similar elements are numbered as described above in regard to Figures 1 to 13.

As shown in Figures 18 and 19, the riveting element 310 may be provided with an internal thread 388, such that the element 310 may be used as a nut fastener following installation in a metal part 352, as shown. This embodiment is very similar to the bearing

bushing 210 shown in Figures 14 to 17, except that the bore 388 is threaded. The head portion 312 is in the form of a radial flange portion and the shaft portion 316 is a tubular or annular banel portion which includes a radial depression. It will be understood, however, that the annular banel portion may also be extended and externally threaded. The threaded bore 388 may then receive a threaded screw (not shown) to attach a further object or element to the metal part 352. When using a female element 310 according to Figures 18 and 19, a cup-shaped depression 392 may be prefened in the sheet metal part 352, which allows flush mounting of an object on the underside 371 of the sheet metal part. This cup-shaped depression 392 may be created in the sheet metal part 352 either by a preceding operation as the sheet metal part is being punched or by a special shaping end face of the riveting die shown in Figures 5 and 6 as will be understood by those skilled in the art. The female riveting elements shown in Figures 14 to 19 may be attached to a metal part by the installation apparatus shown in Figures 5 and 6, as described above.

As will now be understood, the self-riveting element and method of installation of this invention may be utilized for a broad range of applications, including male and female elements, fasteners and the like. Further, the several improvements disclosed herein may be used in combination or separately to produce an improved element and fastener assembly. For example, the peripherally closed fields or pockets (20, 120, etc.) provide anti-rotation means for the fastener assembly. Thus, the pockets may not be utilized in a fastener assembly where anti-rotation means is not desired. The method of this invention may then include forming a hole through the panel having a diameter greater than the stud or banel portion of the elements, supporting the panel on a die assembly having an opening coaxially aligned with the panel hole configured to receive the stud or banel portion of the fastening element, but having a diameter less than the head or flange portion of the bearing surface,

wherein the die member includes a projecting annular lip coaxially aligned with the groove in the riveting element. In the prefened embodiment, the groove 23 is generally V-shaped and extends into the flange or head portion of the element adjacent the barrel or stud portion, as shown in Figure 3. The method then includes inserting the stud or barrel portion of the element through the panel hole into the die member opening, receiving the head or flange portion bearing surface against the panel, adjacent the panel opening. The method then includes driving the bearing surface of the element against the panel, causing the die member

annular lip to substantially simultaneously deform the panel metal into the axial groove and

radially into the radial groove of the element. In the most prefened embodiment, the radial groove is the first thread of a threaded portion of the fastener, such as shown in Figure 3; however, the groove may be annular as shown at 128 in Figure 10. The element and metal part or panel assembly thus includes a self-riveting element, as disclosed, and a metal part or panel, wherein the stud or banel portion of the element is received through an opening or hole in the metal part or panel and the panel or metal part is deformed into both the V- shaped annular groove which sunounds the stud or banel portion and into the radial groove in the stud or barrel portion. In the most prefened embodiment, the panel portion is further and simultaneously deformed into the circumferentially spaced confined fields or pockets, forming a very secure assembly which prevents pull-out and rotation of the self-riveting element in the panel. In the most prefened embodiment, the self-riveting element is a fastener which may be utilized to attach a second element to the panel. In the embodiment 10 disclosed in Figures 1 to 4, the fastening element is a male fastening element, such as a screw or bolt 10. In the embodiment 110 shown in Figures 10 to 13, the fastening element 110 is an axle journal, wherein the cylindrical stud portion 15 receives a female member having a cylindrical bore, which is attached to the stud portion of the fastening element. In

the embodiment 210 disclosed in Figures 14 to 17, the fastening element 210 is a bearing bush which receives a male element having a cylindrical surface which is received in the bore 82 of the bushing. Finally, in the embodiment 310 shown in Figures 17 and 18, the fastening element is a nut fastener, which receives a screw or bolt for attachment of an element to the panel. Having described the prefened embodiments of the riveting element, method of attachment and assembly of this invention, it will be understood by those skilled in the art that various modifications may be made to the disclosed embodiments within the purview of the appended claims, which follow.