EP3077147A1 - Stud element and welding method for connecting said stud element to a workpiece - Google Patents

Abstract

The present invention relates to a stud element (1) and in particular to a welding stud element which is suitable for connecting to a workpiece (10) by way of a welding method, wherein a welding surface of the head (3) of the stud element has at least one internal protrusion (4) and at least one external protrusion (5, 5a, 5b), said protrusions extending away from the welding surface, wherein the external protrusion (5, 5a, 5b) is arranged circumferentially around the internal protrusion (4). Furthermore, the present invention relates to a welding method and in particular a stud arc-welding method for connecting the abovementioned stud element to a workpiece (10).

Description

 Bolt element and welding method for connecting this bolt element with a workpiece

description

The present invention relates to a bolt element, in particular a

Welding bolt element which is suitable to be connected to a workpiece using a welding process. Furthermore, the invention relates to a welding method, in particular an arc-bolt welding method, for connecting a corresponding bolt element to a workpiece.

The fundamentally known arc stud welding method belongs to the arc pressure welding method and is used for permanent connection of a bolt-shaped element, such as a threaded bolt, a pin, a bush, a hoe or an eyelet with a corresponding larger component, such as a body panel, a housing or a workpiece or similar. When using a light arc bolt welding method, an arc is ignited between an end face of a bolt and the workpiece, whereby both parts are locally melted and then joined using a correspondingly low Anp ressdruckes. Arc stud welding methods can be distinguished, inter alia, in stud firing methods or peak spark plug welding methods, and in the stud firing method, the arc is generated by raising the stud from the component under current flow. In contrast, the arc is fired at a tip of the bolt in the tip ignition bolt welding method, this firing tip explodes explosively and evaporates to a small extent. The induction voltage, which accordingly arises from the opening of the circuit, thus ignites the arc, which then detects the entire pin face. When connecting the bolt or the bolt element with the workpiece surface is to be noted that as little spatter as possible during the welding process, which could permanently damage the workpiece surface, especially if, for example, a post-processing of this workpiece surface is not provided. Furthermore, even when using the arc stud welding method, a welding of the

Bolt element with the workpiece surface with a low voids formation within the weld layer or the weld sought to provide a stable and permanent connection of the bolt element with the workpiece and in particular its surface enable . However, already at the ignition of the arc and its uneven propagation over the surface of the bolt and in particular its end face, which is later connected to the workpiece surface, strong

Spatters occur. In addition, it is conceivable that the arc propagates so unevenly over the pin end face that the material of this pin end surface is unevenly melted up or melted during the pressing or joining operation of the pin with the workpiece, which in turn results in an uneven cohesive connection between the pins individual areas of the bolt and the workpiece arises due to different material melting in the different areas.

It is therefore the object of the present invention, the disadvantages described above in a welding process and in particular a

 At least partially repair arc stud welding process. In particular, it is the object of the present invention to provide a bolt element and a welding method, by means of which in a simple and cost-effective manner an advantageously permanent connection of a bolt element with a workpiece is made possible, in which only a small voids formation, as well as a small one

Spatter formation occurs, wherein the strength of the welded joint compared to known stud elements and welding method is primarily consistent and can be particularly preferably even increased.

The above object is achieved by a bolt element, in particular a

Welding bolt element, with the features of claim 1 and by a welding method, in particular an arc-bolt welding method, with the features of claim 9. Further features and details of the invention will become apparent from the dependent claims, the description and the drawings. In this case, features and details which are described in connection with the bolt element according to the invention are of course also in connection with the welding method according to the invention and in each case vice versa, so that with respect to the disclosure of individual E rfindungsaspekten always reciprocal reference is or may be. In addition, the welding method according to the invention can be carried out with the bolt element according to the invention.

The bolt element, which is in particular a welding bolt element, is suitable to be connected to a workpiece using a welding process. According to the invention, the bolt element has a bolt element head with a welding surface and an arrangement surface facing away from the welding surface, and a Bolt member body extending away from the placement surface of the Boizenelementkopfes on. The bolt element according to the invention is characterized in that the welding surface of the boiler element head has at least one inner projection and at least one outer projection extending away from the welding surface, wherein the outer projection is circumferentially arranged around the inner projection. It is therefore conceivable for the bolt element head to extend from a central axis of the bolt element which extends along a length or longitudinal extent of the bolt element

Bolt member extends, extending away radius, which corresponds to the radius of the bolt member body, so that consequently has the bolt element head corresponding to the bolt element body or advantageously identically large circumference. However, it would also be conceivable that the bolt element head has a larger circumference than the bolt element body. The bolt element head may, for example, be disc-shaped, cylindrical, cube-shaped, tetrahedral or hexagonal or have a comparable shape. The bolt element body which extends away from the bolt element head, for example, likewise has a disc-shaped, cylindrical, cube-shaped, tetrahedral or hexahedral shape or a corresponding or comparable shape. Thus, it is possible that the bolt element head and the bolt element body of a bolt element have a comparable shape and, for example, both are cylindrical. This would be the case in particular if the

Bolt element body and the bolt element head have an identical circumferential size, so that the bolt element head and the bolt element body advantageously represent a monolithic element or component or are. However, it is also conceivable that the

Bolt element head has a shape deviating from the bolt element body and is designed, for example, disk-shaped, while the bolt element body has a cylindrical shape. Furthermore, it is conceivable that the bolt element body has a thread and in particular an external thread, such as a coarse thread, pointed thread or trapezoidal thread, wherein it is also possible that the

Bolt element body is designed in the form of a hollow cylinder and may have a corresponding internal thread. Thus, it is also conceivable that the bolt element body has recesses, depressions or engagement regions. The bolt element body is advantageously the region of the bolt element on which a further workpiece or component is applied in order to be connected to the first workpiece on which the bolt element is fastened or welded. As a bolt element can be used, for example, a Grobflanschbolzen, M6, M8, M10 Grobgewindestahlbolzen or even an existing aluminum bolt. In the context of the invention, the inner projection is arranged concentrically with the outer projection. This means that the outer projection, which advantageously at least partially surrounds or at least partially surrounds the inner projection, has a center which corresponds to the center of the inner projection. As a result, the outer protrusion is advantageously arranged evenly spaced from the inner protrusion in the circumferential direction of the inner protrusion. Advantageously, the outer protrusion circulates around the inner protrusion and thus forms a kind of bead which surrounds the inner protrusion like a wall. It is also possible that not only an outer protrusion but also two or more outer protrusions are arranged circumferentially around the inner protrusion, wherein advantageously the inner protrusion is concentric with the individual outer protrusions and in particular with each of the individual outer protrusions , As a result, each outer protrusion has a different size from the other outer protrusion, and in particular a different diameter, such that the outer protrusions are spaced apart from one another and spaced from the inner protrusion, in particular extending away from the welding surface of the bolt element head.

It is also conceivable that the inner projection is arranged concentrically to the welding surface of the bolt element head. This means that the inner projection and the welding surface of the bolt element head advantageously have a same center, wherein also preferably the outer projection and the inner projection and consequently the outer projection and the welding surface have an identical center. It is therefore possible that the bolt element has a longitudinal axis which extends through the center of the bolt element body, the center of the

Bolt element head and advantageously thus through the center of the inner projection and the at least one outer projection extends, so that the bolt element head, the bolt element body, the inner projection and also advantageously the outer projection are arranged concentrically to each other. By a concentric arrangement of the outer projection in particular to the inner projection, a substantially uniform propagation of the arc, starting from the inner projection to the outer projection, possible. Consequently, it can be advantageously realized by the concentric arrangement of the inner projection to the outer projection and the bolt element head as well as to the bolt element body, a uniform connection of the melted or bolted bolt material with the advantageous molten material of the workpiece along the entire welding surface of the bolt element. Advantageously, characterized by a uniform over the welding surface of the bolt element head considered bende and uniform adhesion of the bolt element on the workpiece and a reduced voids formation within the weld or the weld melt realized.

In the context of the invention, the inner projection has a greater length extending away from the welding surface of the bolt element head than the outer projection. Advantageously, at least the inner projection and particularly advantageously also the outer projection extend substantially at least in sections orthogonally away from the welding surface of the bolt element head. Advantageously, stabilization, and in particular centering of an arc in the region of the inner projection and thus uniform propagation of the arc along the welding surface of the bolt element head and thus inter alia a reduction of welding spatter during the welding process can be made possible by a longer inner projection.

It is furthermore conceivable for the outer projection to be arranged at a distance from an edge region of the bolt element head on the welding surface. This means that the outer projection is not adjacent to the edge region of the bolt element head, so that in a welding process and in particular in a melting of the material layer of the outer projection, this outwardly away, that is along the welding surface of the bolt element head, to the edge region of the

Bolt element head can spread without beneficial to flow beyond this edge region. Accordingly, a Schweißwulst advantageously forms only between the

Bolt element and the workpiece and is therefore arranged in the region of the welding surface of the bolt element head. For this purpose, the assembly of a further workpiece or component on the bolt applied to a workpiece is advantageously not adversely affected or impaired.

In the context of the invention, it is possible that the inner projection is conical or frustoconical or pyramidal or truncated pyramid shaped or designed in a comparable shape. Accordingly, in particular, the inner projection has a green surface disposed on the welding surface of the bolt element head, so that the inner projection thus tapers away from the welding surface. Furthermore, it is conceivable that the inner projection has a pointed, rounded or flat or blunt and in particular frustoconical distal end. The distal end of the inner projection is consequently the end of the inner projection opposite the base. Particularly advantageous is a relatively pointed distal end of the inner projection is considered to center the arc in detail in this area and to be able to stabilize. Furthermore, it is conceivable that the outer projection has a trapezoidal, dreieckför- shaped, square or semicircular cross-section or a cross section with a comparable shape. Again, it is possible that the outer projection may have a pointed, oval or blunt or flattened distal end. The distal end of the outer projection is therefore the end of the outer projection opposite the base side of the cross-section. Furthermore, it is possible that the outer projection, if it has a trapezoidal cross-section, may have an isosceles or symmetrical trapezoidal shape or even a rectangular trapezoidal shape. The outer protrusion is arranged on the welding surface such that, in particular with regard to a cross section of the outer protrusion, the base side of the outer protrusion is arranged on the welding surface, so that the outer protrusion extends in a tapering manner away from the welding surface of the bolt element head. In the context of the invention, it is further conceivable that the inner projection and / or the outer projection is / are arranged on a projection which is arranged on the welding surface of the bolt element head. Such a survey may serve to ensure that in a welding operation, in which in particular the inner projection and / or the outer projection are melted, nevertheless a defined distance between the bolt element head and in particular the welding surface of the bolt element head and the surface of the workpiece and in particular a connecting surface of the Workpiece remains. This is the purpose of the aforementioned survey, which undergoes no or at least only a very small material melting or material melting especially in the arc stud welding. Consequently, the aforementioned elevation advantageously serves as a spacing element between the bolt element head and the workpiece.

Furthermore, a welding method, in particular an arc-bolt welding method, for connecting a bolt element according to one of the preceding claims 1 to 8 and consequently according to the aforementioned type with a workpiece is claimed. The welding method according to the invention comprises the following steps:

 Arranging at least the inner projection on a connecting surface of the workpiece,

 Generating a closed circuit for forming an arc between the bolt element and the workpiece,

Igniting the arc which stabilizes in a region of the inner projection during a duration of a pre-current phase, Increasing electrical current flow in the electrical circuit to initiate a main flow phase, and

 Acting on the bolt element with a compressive force for at least partially compressing the welding surface of the bolt element head of the bolt element with the connecting surface of the workpiece.

In the context of the invention, it is conceivable that the arc is generated in a release of the inner projection of the bolt element head of the bolt element of the connecting surface of the workpiece. Accordingly, the aforesaid welding method is advantageously used in the form of a stud ignition welding method, although it is also conceivable to use it in the form of a tip ignition stud welding method. In a first step of the method according to the invention becomes

Bolt element and in particular the bolt element head is introduced in the region of the workpiece such that at least the inner projection is arranged on a connecting surface of the workpiece, wherein advantageously the inner projection at least partially contacts this connecting surface of the workpiece. The

Bolt element is subsequently applied with an electric current to form a closed circuit with the workpiece. For this purpose, the bolt element and in particular the workpiece is connected to a power source, so that the bolt element advantageously forms a cathode and the workpiece advantageously forms an anode, between which free charge carriers move. Such charge carriers are, for example, electrons emerging from the metal surface and atoms positively charged by ionization. In the welding method according to the invention and in particular in the arc bolt welding method according to the invention, the electric arc serves as a tool and energy source. In order to generate or burn a corresponding arc, free charge carriers must be present between the electrodes. To ignite the arc, the bolt element and especially the inner projection of the

Bolt element head of the bolt element advantageously briefly lifted from the workpiece and in particular its connection surface. This creates an arc, which represents a self-sustaining gas charge between the bolt member and the workpiece, wherein during the gas discharge, an electric current flows through the gas and this ionized ion. The gas discharge itself can cause visible light. The ignition of the arc takes place advantageously during a Vorstromphase, which may be, for example, 35 milliseconds or less. During this time, the arc is stabilized, in particular in the region of the inner projection, that is, the arc is fixed in this region of the inner projection and thus advantageously centric in the region of the weld surface of the bolt element head. Will now be In particular, the electric current flow is increased to a value of, for example, 1000A, thereby initiating the main current phase, in which, in particular, the inner projection is at least partially fused or melted by means of the arc, while the arc itself subsequently follows in the direction of the outer projection. Jump, advantageously evenly from the inner projection, spreads. As a result, during the main flow phase, the arc is fixed to the outer projection, the material of which is melted or melted off. Advantageously, at the same time for the propagation of the arc and in particular for fixing the arc in the region of the outer projection, the bolt element is acted upon by a defined pressure force, by which the bolt element is moved in the direction of the workpiece. Due to the compressive force, the bolt element and in particular the welding surface of the

Bolt element or the material portions of the inner projection and the outer projection of the bolt member pressed or pressed on the connecting surface of the workpiece, so that the material areas of the connecting surface of the workpiece, which have also been melted by means of the arc, with the fused or melted Material regions of the inner projection and advantageously also the outer projection materially connect. Consequently, during the main flow phase not only the material of the inner projection and advantageously also of the outer projection is melted or melted at least in sections, but also material regions of the workpiece become particularly advantageous in the area of the connection surface in which the arc from the workpiece to the pin merges, melted, so that these melted material areas of the bolt element and the workpiece can cohesively connect to each other. By stabilizing and centering and in particular fixing the arc in the region of the inner projection, it is possible that, after a defined melting of the material of the inner projection, the arc advantageously extends uniformly in the circumferential direction around the inner projection towards the outside in the direction of the outer projection spreads, so that the material of the outer projection can advantageously be melted or melted evenly within a defined period of time. Accordingly, during a pressing operation of the bolt on the corresponding connection surface of the workpiece advantageously take place between the molten materials of the workpiece and also the bolt taking place evenly over the welding surface of the bolt member connection. A stabilization and centering as well as a uniform propagation of the arc along the welding surface of the bolt element also leads advantageously to a small bead formation and to a low voids formation in the weld and thus to a high or increased stability of the welded joint between the bolt element and the workpiece , In the described welding method, all the advantages that have already been described for the bolt element according to the first aspect of the invention.

A bolt element according to the invention, which is suitable for being connected to a workpiece using a welding method, as well as a bolt element known from the prior art are explained in more detail below with reference to drawings. Each show schematically:

FIG. 1 shows a longitudinal section of an embodiment of a bolt element according to the invention, arranged on a connecting surface of a workpiece,

FIG. 2 shows a plan view of a welding surface of an embodiment of a bolt element according to the invention,

FIG. 3 shows a plan view of a welding surface of a further embodiment of a bolt element according to the invention,

Figure 4 is a longitudinal sectional view of an embodiment of one of the prior

 Technology known bolt element,

FIG. 5 is a plan view of a welding surface of that shown in FIG

 Bolt element,

Figure 6 is a sectional view of a first embodiment of a

 Bolt element head of a bolt element according to the invention,

Figure 7 is a sectional view of a second embodiment of a

 Bolt element head of a bolt element according to the invention,

9 shows a side view of a longitudinal section of a bolt element head, welded to a workpiece, of a bolt element known from the prior art, FIG. 10 shows a side view of a longitudinal section of an embodiment of a bolt element head of a bolt element according to the invention welded to a workpiece, FIG.

11 shows a side view of a further longitudinal section of the bolt element shown in FIG. 9 welded to a workpiece for illustrating the formation of voids, and FIG. 12 shows a side view of a further longitudinal section of the bolt element shown in FIG. 10 with a workpiece for illustrating the formation of voids.

Elements with the same function and mode of action are each provided with the same reference numerals in FIGS.

FIG. 1 shows a longitudinal section of an embodiment of a bolt element 1 or welding bolt element 1 according to the invention, arranged on a connecting surface 10a of a workpiece 10. The bolt element 1 has a bolt element body 2 and a bolt element head 3. The bolt element 1 shown in FIG. 1 is advantageously a substantially cylindrical connecting element whose bolt element body 2 has a thread 2a. The cylindrical bolt element head 3, which is advantageously designed in the form of a disk, has an inner projection 4 and an outer projection 5 surrounding the inner projection 4. The

Bolt member 1 is shown as a section, so that the shape of the inner projection 4 as well as the outer projection 5 surrounding the inner projection 4 can be illustrated by the view of the cross section of the inner projection 4 and the outer projection 5, respectively. The bolt element 1 has a central axis Z which extends along the length of the bolt element 1. As can be seen in FIG. 1, the

Bolt element body 2 and the bolt element head 3 are arranged concentrically to one another and consequently have a center point lying on the central axis Z. Furthermore, the inner projection 4 is also arranged concentrically with the bolt element head 3 and consequently with the bolt element body 2. Advantageously, the inner projection 4 is also arranged concentrically to the outer projection 5, so that viewed in the circumferential direction around the inner projection 4, the outer projection 5 equally spaced from the inner projection 4 on the welding surface 3a of the bolt element head 3 is arranged. This is also shown in particular in FIG. 2, which will be described below. During the welding operation, the bolt element 1 is arranged in the region of a connecting surface 10 a of the workpiece 0. Advantageously, the inner projection 4 and in particular a distal end 4a of the inner projection 4 contacts the connecting surface 10a of the workpiece 10 at least in sections. Of the

Bolt member body 2 extends from the placement surface 3b of FIG

 Bolt element head 3 away, wherein the arrangement surface 3b facing away from the welding surface 3a and is arranged opposite thereto. This is advantageous

Bolt member 1 integrally formed or monolithic, so that in particular the bolt member body 2 and also the bolt element head 3 are made with the corresponding projections jumps 4 and 5 from a workpiece to form the bolt member 1. The bolt element 1 and the workpiece 0 are each connected via power lines 21 to a power source 20 to be acted upon by electric current. In an arrangement or contacting of the inner projection 4 with the connecting surface 10a of the workpiece 10 then creates a closed circuit through which an arc can be formed et. It is conceivable that the workpiece 10 is a cast workpiece, while the bolt element 1 consists for example of an aluminum material.

FIG. 2 shows a plan view of a welding surface 3a of an embodiment of a bolt element head 3 of a bolt element 1 according to the invention. The

 Welding surface 3a and in particular the bolt element head 3 in this case has a circular and in particular a disk-shaped shape, in the center of which the inner projection 4 is arranged centrally. However, it is also conceivable that the

Bolt element head 3 is formed oval or angular. Advantageously centric, the outer projection 5 surrounds the inner projection 4, wherein the outer projection 5 also advantageously forms a circular elevation or an elevation running on a circular path. As viewed in the circumferential direction around the inner projection 4, the outer projection 5 is therefore equally spaced from the inner projection 4. Furthermore, the outer projection 5 is arranged at a distance from an edge region 3c of the welding surface 3a and in particular of the bolt element head 3 at a distance from the welding surface 3a. Deviating from the embodiment of FIG. 2, however, it is also conceivable that the inner projection 4 is not arranged centrally on the welding surface 3 a of the bolt element head 3. Consequently, it would also be possible for the outer projection 5, which advantageously completely surrounds or at least partially surrounds the inner projection 4, likewise not to be centric to the center of the welding surface 3a of FIG

Bolt element head 3 is arranged. The particular shown in FIGS. 1 and 2 Embodiments of the arrangement of the inner projection 4 and the outer projection 5 are merely exemplary understood and do not justify completeness.

FIG. 3 shows a plan view of a welding surface 3a of a bolt element head 3 of a further embodiment of the bolt element 1 according to the invention, which in particular has two outer projections 5 which have been identified by reference numerals 5a and 5b for better understanding. Both outer projections 5a and 5b completely surround the inner projection 4 according to the embodiment of FIG. 3, wherein the inner projection 4 and the two outer projections 5a, 5b are arranged concentrically with each other. The two outer projections 5a and 5b are advantageously arranged circularly around the inner projection 4, wherein the first outer projection 5a viewed from the center or from the centric center line Z from a smaller radius or diameter than the second outer projection 5b, which not only the inner projection 4, but also the first outer projection 5a surrounds. It is therefore also possible for more than one or two outer projections 5a, 5b to be arranged on the welding surface 3a of the bolt element head 3. Accordingly, it is conceivable that more than two outer projections 5 or 5a and 5b, but advantageously also three and more outer projections 5 are arranged such that they are advantageously arranged concentric with each other and concentric with the inner projection 4 and this inner projection 4 surrounded advantageous surrounding. In an arrangement of a plurality of outer projections 5, therefore, a plurality of material due to the plurality of outer projections 5 is melted during the welding process, which can be materially connected to the melted on the connecting surface 10 a of the workpiece 10 material. As a result, under certain circumstances, an increased solidification of the bolt element 1 with the workpiece 10 (see FIG.

4 is a longitudinal section of a known from the prior art

Bolt element 30 and in FIG. 5 is a plan view of a welding surface 40a of the bolt member 30 shown in FIG. 4, wherein the bolt member 30 has a bolt element head 40 with a single projection 41 arranged thereon, which extends away from a welding surface 40a. The welding surface 40a faces an assembly surface 40b from which a bolt member body 42 may extend. In the known from the prior art bolt member 30, it is difficult to center the arc within a central region Z of the projection 41 to ensure a starting from this central region Z of the projection 41 uniform propagation of the arc along the projection 41 to Consequently, to allow a substantially uniform melting of the material of the projection 41.

In FIGS. 6 to 8, in each case, embodiments of a bolt element head 3 of a bolt element 1 according to the invention are shown in longitudinal section. Thus, for example, Fig. 4 shows an embodiment of a bolt element head 3 of an inventive

Bolt element 1, which has an inner origin 4 as well as an outer projection 5 which surrounds the inner projection 4. The extending away from the welding surface 3a length L2 of the inner projection 4 is greater than the longer of the welding surface 3a extending L longer L1 of the outer projection 5. Thus, for example, it is conceivable that the inner projection 4 has a length L2 of, for example, advantageous 1, 5-2 mm, while the outer projection 5, for example, advantageously a length L1 of 1 -1, 9 mm may have. It should be noted here that the inner projection 4 always has a greater length than the outer projection 5. When considered in section, the outer projection 5 has a trapezoidal and in particular symmetrical trapezoidal shape, while the inner projection 4 is essentially one has a triangular shape with a substantially pointed distal end 4a. However, it is also conceivable that the distal end 4a is rounded or flattened. It is also conceivable that the outer projection 5 may have a triangular shape with a pointed or abgeru-ended distal end 5a.

Compared to this, the embodiment of the bolt element head 3 of FIG. 7 has an outer projection 5 which does not have the same trapezoidal shape but rather a right-angled trapezoidal shape, with the regions or walls of the outer projection 5 projecting in the direction extend the inner projection 4 extend obliquely at a defined angle. The inner projection 4 may taper at an angle α of, for example, 7 ° or more or less away from the welding surface 3a. The inner projection 4 also has a flattened distal end 4a. In an arrangement of a plurality of outer projections 5, as shown in particular in Fig. 8, it is also possible that, for example, a first outer projection 5a has a right angle Trapezgest old, while another and in particular second outer projection 5b an equal klige Has trapezoidal shape. The design of the inner projection 4 may, for example, as shown in FIGS. 6 or 7, be triangular and have a pointed or a rounded or flat distal end 4a. FIG. 9 is a side view of a longitudinal section of a bolt element head 40, welded to a workpiece 10, of a prior art

Bolt element 30, as shown for example in FIGS. 4 and 5 shown. The only one projection 41 having bolt member 30 is so connected to the connecting surface 10a of the workpiece 10 that significant spatter 60 occur, in particular in the illustrated right portion of Figure 9. This is justified, therefore, that the ignited arc could not be ignited exactly centric in the region of the projection 41 and consequently of the welding surface 40a of the bolt element head 40. As a result, the arc has unfavorably spread unevenly along the projection 41, so that it has led to an uneven melting of the material of the projection 41 during the pressing process between the pin member 30 and the workpiece 10.

In contrast, in FIG. 10, a reduced spatter formation 60, which is also distributed substantially uniformly along the region of the welding surface 3a, is shown when using a bolt element 1 according to the invention. Advantageously, for example, in an arc stud welding method, the arc substantially in the region of the inner projection 4, which is arranged concentrically to the outer projection 5 and the Bolzenelementkopf 3, are ignited and consequently lent evenly along the welding surface 3a of the bolt element head 3 in the direction of the outer projection 5 to advantageously a uniform material melting of the outer projection 5 during the pressing process, wherein the

Bolt element 1 is connected to the workpiece 10, to ensure. To illustrate the reduced voids formation when using a bolt element 1 according to the invention, a bolt element 30 known from the prior art is shown in FIG. 11 and in particular in the side view of a longitudinal section of FIG. 11, which was welded to a workpiece 10. As can be clearly seen in FIG. 11, a material layer 50 with a multiplicity of voids 51 enclosed therein has formed between the workpiece 10 and the bolt element 30 and in particular the projection 41 of the bolt element 30 or of the bolt element head 40, which forms a bead, in particular in the edge region of the bolt element head 40 and in particular on the projection 41 thereof. The voids 51 or cavities lead to an opening of the material layer 50, by which in turn the strength of the welded connection can be reduced, which disadvantageously leads to a detachment of the bolt element 30 from the workpiece 10. As shown in FIG. 12, in a welding process using a bolt element 1 according to the invention having a workpiece 10, the melt layer or material layer 50 has a reduced voids formation and consequently a smaller number of voids 51 or cavities in the material layer 50. Furthermore, the formation of a bead, which extends into the intermediate region between the welding surface 3a and the connecting surface 10a of the workpiece 10, is also reduced. As a result, it is possible to increase the strength and, in particular, the welded connection between the bolt element 1 according to the invention and the material 10.

LIST OF REFERENCE NUMBERS

1 bolt element / welding bolt elements t

2 bolt body

 2a thread

 3 bolt element head

 3a welding surface

 3b arrangement surface

 3c edge area

 4 inside lead

 4a distal end

 5 outer projection

 5a first outer projection

 5b second outer Vors tion

 5c distal end

 30 bolt element - state of the art

40 Bolt Element Head - State of the Art

40a welding surface - state of the art

40b arrangement surface - prior art

42 Bolt Element Body - Prior Art

50 material layer

 51 voids

 60 spatters

 Z centric central axis / center

Claims

claims

A stud element (1), in particular a weld stud element (1), which is suitable for being connected to a workpiece (10) using a welding method

 - A Bolzeneiementkopf (3) with a welding surface (3a) and facing away from the welding surface (3a) arrangement surface (3b), and

 a bolt element body (2) extending away from the placement surface (3b) of the bolt element head (3),

 characterized in that

 the welding surface (3a) of the bolt element head (3) has at least one inner projection (4) and at least one outer projection (5, 5a, 5b) extending away from the welding surface (3a), the outer projection (5, 5a , 5b) is arranged circumferentially around the inner projection (4).

2. Bolt element (1) according to claim 1,

 characterized in that

 the inner projection (4) is arranged concentrically with the outer projection (5, 5a, 5b).

3. Bolt element (1) according to one of the preceding claims 1 or 2,

 characterized in that

 the inner projection (4) concentric with the welding surface (3a) of the

 Bolt element head (3) is arranged.

4. bolt element (1) according to one of the preceding claims,

 characterized in that

 the inner projection (4) has a larger length (L2) extending away from the welding surface (3a) of the bolt element head (3) than the outer projection (5, 5a, 5b),

5. bolt element (1) according to one of the preceding claims,

 characterized in that

the outer projection (5, 5a, 5b) is spaced apart from a peripheral region (3c) of the Bolt element head (3) on the welding surface (3a) is arranged.

6. bolt element (1) according to one of the preceding claims,

 characterized in that

 the inner projection (4) is cone-shaped or frusto-conical or pyramid-shaped or truncated pyramid-shaped or designed in a comparable shape.

7. Bolt element (1) according to one of the preceding claims,

 characterized in that

 the outer projection (5, 5a, 5b) has a trapezoidal, triangular, quadrangular, semicircular cross section or a cross section with a comparable shape.

8. bolt element (1) according to one of the preceding claims,

 characterized in that

 the inner projection (4) and / or the outer projection (5, 5a, 5b) is / are arranged on a projection which is located on the welding surface (3a) of the

 Bolt element head (3) is arranged.

9. Welding method, in particular arc stud welding method, for connecting a bolt element (1) according to one of the preceding claims 1 to 8 with a workpiece (10), comprising the steps:

 Arranging at least the inner projection (4) on a connecting surface (10a) of the workpiece (10),

 Generating a closed circuit for forming an arc between the bolt element (1) and the workpiece (10),

 Ignition of the arc, which stabilizes in a region of the inner projection (4) during a duration of a pre-current phase,

 - Increasing the electrical current flow in the circuit for initiating a main flow phase, and

 Pressurizing the bolt element (1) with a pressure force for at least partially compressing the welding surface (3a) of the

Bolt element head (3) of the bolt element (1) with the connecting surface (10a) of the workpiece (10).

10. welding method according to claim 9,

 characterized in that

 the arc in a release of the inner projection (4) of the

 Bolt element head (3) of the bolt element (1) of the connecting surface (10a) of the workpiece (10) is generated.