DE102014114335A1 - ALUMINUM ALLOY ON STEEL WELDING - Google Patents

Abstract

A resistance spot welding method may include spot welding a workpiece stack that includes a steel workpiece and an aluminum alloy workpiece that overlap one another to provide a butting interface. A pair of opposed welding electrodes are pressed against opposite sides of the workpiece stack with one welding electrode in contact with the aluminum alloy workpiece and the other welding electrode in contact with the steel workpiece. The welding electrodes are constructed so that when an electric current is passed between the electrodes and through the workpiece stack, the electric current in the steel workpiece has a higher current density than in the aluminum alloy workpiece to thereby heat within a smaller zone in the steel workpiece to concentrate. It is believed that concentrating heat within a smaller zone in the steel workpiece will alter the solidification behavior of the resulting aluminum alloy weld pool in a desirable manner.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Patent Application No. 61 / 886,752 filed Oct. 4, 2013, the entire contents of which are hereby incorporated by reference.

TECHNICAL AREA

The technical field of this disclosure relates generally to resistance spot welding, and more particularly to resistance spot welding a steel workpiece to an aluminum alloy workpiece.

BACKGROUND

Resistance spot welding is a process used in a number of industries to join two or more metal workpieces together. For example, the automotive industry often uses resistance spot welding to abut prefabricated metal workpieces during the manufacture of, inter alia, a vehicle door, hood, trunk lid or tailgate. Typically, multiple spot welds are formed along a peripheral area of the metal workpieces or other bonding area to ensure that the part is structurally sound. While spot welding has typically been practiced to produce certain, similarly assembled metal workpieces - e.g. For example, to join steel to steel and aluminum alloy to aluminum alloy, the desire to incorporate lighter weight materials into a vehicle platform has created interest in joining steel workpieces to aluminum alloy workpieces by resistance spot welding. Moreover, the possibility of resistance spot welding of workpiece stacks containing different workpiece combinations (eg aluminum alloy / aluminum alloy, steel / steel and aluminum alloy / steel) with one piece of equipment would increase production flexibility and reduce manufacturing costs.

Resistance spot welding generally relies on resistance to the flow of electrical current through overlapping stationary metal workpieces and across their impact interface to generate heat. To perform such a welding process, a pair of opposed spot welding electrodes are typically clamped at diametrically aligned points on opposite sides of the workpieces at a predetermined weld. Then, an electric current is passed through the metal workpieces from one electrode to the other. The resistance to the flow of this electrical current generates heat within the metal workpieces and at their impact interface. When the metal workpieces that are spot-welded are a steel workpiece and an aluminum alloy workpiece, the heat generated at the impact interface initiates a weld pool extending into the aluminum alloy workpiece from the impact interface. The aluminum alloy weld pool wets the adjacent surface of the steel workpiece and, upon completion of the flow of current, solidifies into a weld nugget that forms all or part of a weld between the two workpieces.

In practice, however, spot welding a steel workpiece to an aluminum alloy workpiece presents a challenge because a number of properties of these two metals can adversely affect the strength, particularly peel strength, of the weld. First, the aluminum alloy workpiece typically includes one or more refractory oxide layers (hereinafter collectively referred to as "oxide layer") on its surface. The oxide layer, which is mainly composed of aluminum oxides, but also other oxides such. B. magnesium oxides, is electrically insulating and mechanically robust. The surface oxide layer therefore increases the electrical contact resistance of an aluminum alloy workpiece, particularly at its abutment surface and at its electrode contact point, making it difficult to effectively control and concentrate the heat within the aluminum alloy workpiece, thus tending to increase the ability of the aluminum alloy workpiece Hampering molten weld, to wet the steel workpiece. And while efforts have been made in the past to attempt to remove the oxide layer from the aluminum alloy workpiece prior to spot welding, such approaches may be impractical because the oxide layer has the ability to react in the presence of oxygen, particularly with the use of Heat from spot welding applications, to regenerate.

The steel workpiece and the aluminum alloy workpiece also have various properties that tend to complicate the spot welding process. In particular, steel has a relatively high melting point (~ 1500 ° C) and a relatively high thermal and electrical resistance, while the aluminum alloy has a relatively low melting point (~ 600 ° C) and a relatively low thermal and electrical resistance. As a result of this physical Differences are generated during the electrical current flow of most of the heat in the steel workpiece. This heat imbalance establishes a temperature gradient between the steel workpiece (higher temperature) and the aluminum alloy workpiece (lower temperature), which initiates rapid melting of the aluminum alloy workpiece. The combination of the temperature gradient generated during the current flow and the high thermal conductivity of the aluminum alloy workpiece means that immediately after the electric current has ceased, a situation arises in which heat is not distributed symmetrically from the weld. Rather, heat from the hotter steel workpiece is directed through the aluminum alloy workpiece toward the welding electrode in contact with the aluminum alloy workpiece, producing steep thermal gradients in that direction.

It is believed that the development of steep thermal gradients between the steel workpiece and the welding electrode in contact with the aluminum alloy workpiece weakens the integrity of the resulting weld joint in two primary ways. First, since the steel workpiece retains heat for a longer duration than the aluminum alloy workpiece after the electric current has ceased, the molten weld pool initiated and grown in the aluminum alloy workpiece solidifies directionally, starting from the area closest to the colder welding electrode (often water cooled) associated with the aluminum alloy workpiece and propagating toward the impact interface. A solidification front of this kind tends to errors - z. Gaseous porosity, shrinkage voids, microcracking, and oxide residues - in the direction and along the impact interface within the aluminum alloy weld nugget. Second, the persistently elevated temperature in the steel workpiece favors the growth of brittle Fe-Al intermetallic compounds at and along the impact interface. The intermetallic compounds tend to form thin reaction layers between the weld nugget and the steel workpiece. These intermetallic layers are generally considered to be part of the weld joint, if any, in addition to the weld nugget. It is believed that the presence of a distribution of weld lens flaws, along with excessive growth of Fe-Al intermetallic compounds along the impact interface, reduces the peel strength of the finished weld joint.

In the light of the aforementioned challenges, previous efforts to spot weld a steel workpiece and aluminum alloy workpiece have used a weld schedule that determines higher currents, longer weld times, or both (compared to spot welding of steel to steel) to attempt and provide an adequate weld bonding surface obtain. These efforts have been largely unsuccessful in a production environment and tend to damage the welding electrodes. Assuming that the previous efforts for spot welding were not particularly successful, mainly mechanical methods such. B. impact rivets and flow-drill screws used. Both impact rivets and flow-drill screws are much slower compared to spot welding and are associated with high utility costs. They also add weight to the vehicle body structure, which at some point may begin to counteract the weight savings achieved by the principal use of aluminum alloy workpieces. Thus, in the technical field, advances in spot welding would be welcome, which would better enable the process to add steel and aluminum alloy workpieces.

SUMMARY

A method of resistance spot welding a stack comprising a steel workpiece and an aluminum alloy workpiece includes contacting opposite sides of the stack at a predetermined weld with opposite welding electrodes. One welding electrode is in contact with and pressed against the steel workpiece, and the other welding electrode contacts and is pressed against the aluminum alloy workpiece. Then, an electric current is passed between the welding electrodes and through the stack to initiate and grow an aluminum alloy weld pool within the aluminum alloy workpiece and at a butting interface of the workpieces. The welding electrodes form a footprint in their respective workpieces, and upon completion of the current flow, the footprint formed on the aluminum alloy workpiece has a larger surface area than the footprint formed on the steel workpiece. The difference in footprint sizes results in a passage of electrical current through the steel workpiece at a higher current density than in the aluminum alloy workpiece.

The difference in current density between the steel and the aluminum alloy workpiece (higher current density in the steel workpiece) concentrates heat within a smaller zone in the steel workpiece as compared to the aluminum alloy workpiece. The welding current plan can if desired, to initiate a weld pool within the steel workpiece in addition to initiating the aluminum alloy weld pool within the aluminum alloy workpiece and at the impact interface. The process of concentrating heat within a smaller zone in the steel workpiece - possibly to the extent of initiating a steel weld pool - alters the temperature gradients and thereby the solidification behavior of the aluminum alloy weld pool. It is believed that these thermally-induced effects can result in a butt joint weld joint having improved peel strength and better overall structural integrity.

Specifically, it is believed that concentrating heat within a smaller zone in the steel workpiece as compared to the aluminum alloy workpiece causes temperature gradients to be formed within and around the aluminum alloy weld pool, thereby allowing the weld pool of its outer periphery solidifies toward its center. A solidification front that moves inwardly from the periphery of the weld pool towards the center of the weld pool, in turn, drives welding defects toward the center of the weld where they are less prone to affect the mechanical properties of the weld. Concentrating heat such that a steel weld pool is initiated may also help propel faults into the center of the weld by causing the steel workpiece to thicken toward the impact interface. Such a thickening of the steel workpiece helps to keep the center of the aluminum alloy weld pool heated so that it finally solidifies. The non-planar impact interface created by the thickening of the steel workpiece may also help to resist cracking in the ultimately formed weld joint.

There are a variety of welding electrode designs and combinations that can be used to spot weld the steel and aluminum alloy workpieces of the stack so that greater electrical current density is achieved in the steel workpiece as compared to the aluminum alloy workpiece. The welding electrode on the steel side can z. B. have a flat or relatively flat welding surface with a small diameter, while the welding electrode on the aluminum alloy side may have a flat or more rounded welding surface with a larger diameter. The two welding electrodes may also be multifunctional electrodes of similar construction designed to form footprints with asymmetric surfaces on the steel and aluminum alloy workpieces. Besides being more spot weldable to the steel workpiece and the aluminum alloy workpiece, such welding electrodes can also be used to spot weld stacks of steel workpieces and stacks of aluminum alloy workpieces when spot welding process flexibility is desired.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Figure 11 is a side elevation view of a workpiece stack including a steel workpiece and an aluminum alloy workpiece assembled in an overlapping manner for resistance spot welding at a predetermined weld location using a welding gun;

2 is a partial, enlarged view of the stack and opposed welding electrodes incorporated in FIG 1 are shown;

3 is a partial, exploded side view of the stack and opposed welding electrodes incorporated in FIG 2 are shown;

4 is a side elevational view of the in 3 illustrated steel welding electrode;

5 is a side elevational view of the in 3 pictured aluminum alloy welding electrode;

6 FIG. 12 is a partial cross-sectional view (the stack is shown in cross-section) of the stack during spot welding in which the steel welding electrode is in contact with an electrode contact surface of the steel workpiece and an aluminum alloy welding electrode contacts an electrode contact surface of the aluminum alloy workpiece stands;

7 Fig. 12 is a partial cross-sectional view (the stack is shown in cross-section) of the stack after the cessation of electrical current in which a weld joint has formed at the impact interface and a steel weld nugget has formed within the steel workpiece;

8th is a side elevational view of a multi-function welding electrode during the spot welding of the in 1 - 3 mapped stack as the steel welding electrode, the aluminum alloy welding electrode or both welding electrodes can be used;

9 is a partial cross-sectional view (the stack is shown in cross-section) of the stack during spot welding, in which the in 8th shown multi-function welding electrode is used as both the steel welding electrode and the aluminum alloy welding electrode;

10 is a side elevational view of another multifunction welding electrode, during the spot welding of the in the 1 - 3 mapped stack as the steel welding electrode, the aluminum alloy welding electrode or both welding electrodes can be used;

11 is a partial cross-sectional view (the stack is shown in cross-section) of the stack during spot welding, in which the in 10 shown multifunctional welding electrode in contact with an electrode contact surface of the steel workpiece and the in 5 an aluminum alloy welding electrode shown in contact with an electrode contact surface of the aluminum alloy workpiece;

12 FIG. 12 is a photomicrograph of an aluminum alloy workpiece (upper substrate) and a steel workpiece (lower substrate) resistance welded together using a pair of welding electrodes which have passed electrical current of a higher current density through the steel workpiece as compared to the aluminum alloy workpiece ;

13 is a micrograph of in 12 after being etched to better show the steel weld nugget formed in the steel workpiece;

14 Fig. 11 is a micrograph of an aluminum alloy workpiece (upper substrate) and a steel workpiece (lower substrate) which have been resistance-point welded together in a conventional manner;

15 FIG. 15 is a partial cross-sectional view of a stack comprising a pair of aluminum alloy workpieces after being molded using the in-mold 8th shown multi-function welding electrode on each side of the stack resistance welded together; and

16 FIG. 15 is a partial cross-sectional view of a stack comprising a pair of steel workpieces after being broken down using the in-mold 8th The multi-function welding electrodes shown on each side of the stack were resistance-point welded together.

DETAILED DESCRIPTION

The 1 - 3 generally show a stack of workpieces 10 , which is a steel workpiece 12 and an aluminum alloy workpiece 14 in overlapping manner for resistance spot welding at a predetermined weld 16 using a welding gun 18 are compiled. The steel workpiece 12 is preferably a galvanized or galvanized low carbon steel. It can of course other types of steel workpieces, including z. For example, a low-carbon, bare steel or a galvanized, modern, high-strength unalloyed steel (AHSS) can be used. Some specific types of steel used in the steel workpiece 12 can be used include "interstitial-free" (IF) steel, dual-phase (DP) steel, "transformation-induced plasticity" (TRIP) steel and press-hardened steel (PHS). What the aluminum alloy workpiece 14 For example, it may be an aluminum-magnesium alloy, an aluminum-silicon alloy, an aluminum-magnesium-silicon alloy, or an aluminum-zinc alloy, or it may be coated with zinc or a conversion coating to increase its adhesiveness improve if desired. Some specific aluminum alloys used in the aluminum alloy workpiece 14 can be used are the aluminum-magnesium alloy 5754, the aluminum-magnesium-silicon alloy 6022 and the aluminum-zinc alloy 7003. The term "workpiece" and its steel and aluminum variants are widely used in the present disclosure, to refer to a sheet metal layer, casting, continuous casting, or any other part that is resistance point weldable, including any surface layers or layers, if any.

When stacked for spot welding, the steel workpiece includes 12 an impact surface 20 and an electrode pad 22 , Likewise, the aluminum alloy workpiece comprises 14 an impact surface 24 and an electrode pad 26 , The abutment surfaces 20 . 24 of the two workpieces 12 . 14 are in contact with each other to create a shock interface 28 at the weld 16 provided. The electrode pads 22 . 26 of steel and aluminum alloy workpiece 12 . 14 On the other hand, they generally face away from each other in opposite directions to make them accessible to a pair of opposed spot welding electrodes. Each of the steel and aluminum alloy workpiece 12 . 14 preferably has a thickness 120 . 140 in the range of from about 0.3 mm to about 6.0 mm, and more preferably from about 0.5 mm to about 4.0 mm, at least at the weld 16 lies.

The welding gun 18 is usually part of a larger automated welding process and includes a first gun arm 30 and a second gun arm 32 which are mechanically and electrically configured to repeatedly form spot welds according to a defined weld schedule. The first gun arm 30 has a first electrode holder 34 on which a steel welding electrode 36 holds, and the second gun arm 32 has a second electrode holder 38 on which an aluminum alloy welding electrode 40 holds. The welding gun arms 30 . 32 are operated during spot welding to their respective welding electrodes 36 . 40 against the oppositely facing electrode pads 22 . 26 the overlapping steel and aluminum alloy workpieces 12 . 14 to squeeze. The first and second welding electrodes 36 . 40 are usually in diametrical alignment with each other at the intended weld 16 against their respective electrode pads 22 . 26 pressed.

The steel welding electrode 36 and the aluminum alloy welding electrode 40 are each made of an electrically conductive material such. B. a copper alloy formed. The two welding electrodes 36 . 40 as further explained below, are built to cease the passage of electrical current between the electrodes 36 . 40 a footprint on the electrode pad 26 Aluminum Alloy Workpiece 14 to provide a larger surface than a footprint on the electrode pad 22 of the steel workpiece 12 , The aluminum alloy footprint preferably has a surface which is greater than a surface area of the steel at a rate of from about 1.5: 1 to about 16: 1, and more preferably from about 2: 1 to about 6: 1 at this time. footprint. The difference in footprint sizes has a higher current density in the steel workpiece 12 as in the aluminum alloy workpiece 14 result.

The difference in current density between the steel and the aluminum alloy workpiece 12 . 14 concentrates heat within a smaller zone in the steel workpiece 12 compared with the aluminum alloy workpiece 14 , The weld stream schedule can be regulated evenly, if desired, around a steel weld pool within the steel workpiece 12 in addition to initiating an aluminum alloy weld pool within the aluminum alloy workpiece 14 and at the impact interface 28 is initiated. The act of concentrating heat within a smaller zone in the steel workpiece 12 Possibly to the extent of initiating a steel weld pool, the temperature gradients, particularly the radial temperature gradients, change the solidification behavior of the aluminum alloy weld pool located at the impact interface 28 is to change, so that errors in the ultimately formed welded joint are forced to a more desirable location. In some cases, especially if a steel weld pool in the steel workpiece 12 Initially, the concentration of heat in the steel workpiece and the resulting thermal gradients can drive weld failures at or near the center of the weld joint at the impact interface 28 aggregate, which promotes better weld joint integrity and peel strength.

The aluminum alloy welding electrode 40 includes a body 42 and a welding area 44 , The body 42 how best in 5 shown defines an accessible hollow recess 46 at one end 48 for inserting and securing with the second electrode holder 38 in a known manner.

A transition nose 50 may be from an opposite end 52 of the body 42 up to the welding surface 44 but it does not have to stretch as the weld area expands 44 directly from the body 42 may extend to provide what is commonly referred to as a "full-area electrode". The body 42 preferably has a cylindrical shape with a diameter 420 which ranges from about 12 mm to about 22 mm or narrower from about 16 mm to about 20 mm. The transition nose 50 is preferably frusto-conical, although other alternative forms such. B. a spherical and elliptical shape may also be suitable.

The welding surface 44 is the section of the aluminum alloy welding electrode 40 which makes contact with the electrode pad during spot welding 26 Aluminum Alloy Workpiece 26 is produced and pressed into this to produce a footprint. The welding surface 44 has a diameter 440 and a radius of curvature that are sufficient together to prevent excessive indentation in the aluminum alloy weld pool and the softened workpiece region surrounding the weld pool. Excessive indentation is usually defined as an indentation that is 50% or more of the thickness 140 Aluminum Alloy Workpiece 14 equivalent. Such impressions can be avoided by, for. B. the welding surface 44 with a diameter 440 from about 6 mm to about 20 mm and a radius of curvature of about 15 mm until flat. In a preferred embodiment, the diameter is 440 the welding surface 44 about 8 mm to about 12 mm, and the radius of curvature is about 50 mm to about 250 mm. If desired, the welding surface 44 also be textured or have surface features such as those used in the U.S. Pat. Nos. 6,861,609 . 8,222,560 . 8,274,010 . 8,436,269 and 8,525,066 and the U.S. Patent Publication No. 2009/0255908 are described.

The steel welding electrode 36 has the same basic components as the aluminum alloy welding electrode 40 - namely a body 54 , the one accessible hollow recess 56 at one end 58 defines a welding surface 60 and an optional transition nose 62 that are different from the body 54 at an opposite end 64 up to the welding surface 60 extends, as in 4 shown. The body 54 preferably has a cylindrical shape with a diameter 540 which ranges from about 12 mm to about 22 mm or narrower from about 16 mm to about 20 mm. The transition nose 62 is preferably spherical, although other alternative forms such. B. elliptical and frustoconical may also be suitable. While some or all sections of the aluminum alloy and steel welding electrode 40 . 36 they may be the same - but not necessarily - it is the interaction of their perspiration surfaces 44 . 60 with their respective electrode pads 26 . 22 What the current density within the workpieces 12 . 14 makes different.

The welding surface 60 is as before the section of the steel welding electrode 36 which makes contact with the electrode pad during spot welding 22 of the steel workpiece 12 is produced and pressed into this to produce a footprint. Here is the welding area 60 designed so that their footprint (ie, which at the electrode contact surface 22 of the steel workpiece 12 made) is smaller than that through the welding surface 44 the aluminum alloy welding electrode 40 at the electrode contact surface 26 Aluminum Alloy Workpiece 14 prepared footprint. In the embodiment which is in 4 is shown has the welding surface 60 the steel welding electrode 36 a diameter 600 which is in a range from about 4 mm to about 16 mm, and more preferably from about 5 mm to about 8 mm, and is flat or has a radius of curvature greater than about 20 mm.

The 1 - 3 and 6 - 7 illustrate a spot welding process in which the stack 10 at the weld 16 using the welding electrodes described above 36 . 40 is spot-welded. The welding gun 18 (partially shown) is designed to provide the electrical current and contact pressure needed to spot-weld the steel workpiece 12 to the aluminum alloy workpiece 14 necessary. The pistol arms 30 . 32 the welding gun 18 may be fixed (pedestal welder) or robotically movable, as is conventional in the art, and operated during spot welding, around the welding electrodes 36 . 40 at the weld 16 with the electrode contact surfaces facing in opposite directions 22 . 26 of steel and aluminum alloy workpiece 12 . 14 in diametral contact with each other and to press against it. The through the pistol arms 30 . 32 fixed clamping force helps to ensure good mechanical and electrical contact between the welding electrodes 36 . 40 and their respective electrode pads 22 . 26 manufacture.

The resistance spot welding process starts with the stack 10 between the steel and the aluminum alloy welding electrode 36 . 40 is arranged so that the weld 16 generally with the opposite welding surfaces 60 . 44 is aligned. The workpiece stack 10 can be brought to such a location as is often the case when the pistol arms 30 . 32 Are part of a fixed pedestal welder, or the gun arms 30 . 32 can be robotically moved to the electrodes 36 . 40 in relation to the weld 16 to arrange. Once the pile 10 correctly arranged, become the first and the second gun arm 30 . 32 merged to the welding surfaces 60 . 44 the steel welding electrode 36 and the aluminum alloy welding electrode 40 at the weld 16 with the electrode contact surfaces facing in opposite directions 22 . 26 of steel and aluminum alloy workpiece 12 . 14 to contact and press against, as in 6 is shown. The through the welding electrodes 36 . 40 transmitted contact pressure causes the welding surface 60 the steel welding electrode 36 starts a footprint 66 at the electrode contact surface 22 of the steel workpiece 12 to form, and equally the welding surface 44 the aluminum alloy welding electrode 40 starts a footprint 68 at the electrode contact surface 26 Aluminum Alloy Workpiece 14 to build.

Then, according to a corresponding welding schedule, an electric current - usually a DC between about 5 kA and about 50 kA - at the weld 16 between the welding surfaces 60 . 44 the steel and aluminum alloy welding electrode 36 . 40 and through the pile 10 passed through. The resistance to the flow of electric current through the workpieces 12 . 14 initially causes the steel workpiece 12 warmed faster than the aluminum alloy workpiece 14 because it has a higher thermal and electrical resistance. This heat imbalance causes a temperature gradient from the steel workpiece 12 to the aluminum alloy workpiece 14 arises. The flow of heat down the temperature gradient towards the water-cooled aluminum alloy welding electrode 40 in conjunction with the heat generated by the resistance to the flow of electric current across the impact interface 28 results finally brings the aluminum alloy workpiece 14 to melt and form an aluminum alloy weld pool 70 that the abutting surface 20 of the steel workpiece 12 wetted.

During this time, when electrical power is passed, which can take anywhere from about 40 milliseconds to about 1000 milliseconds, the steel footprint grows 66 very little while the aluminum alloy footprint 68 significantly more grows, as the weld area 44 the aluminum alloy welding electrode 40 into the softened aluminum alloy workpiece 14 presses. As in this embodiment, the welding surface 44 the aluminum alloy welding electrode 40 larger than the welding surface 60 the steel welding electrode 36 , At the time when the passage of electrical current ceases, the aluminum alloy footprint 68 a larger surface than the steel footprint 66 , This difference in footprint sizes results in the flow of electrical current within the steel workpiece 12 a higher current density is present than in the aluminum alloy workpiece 14 , The increase in the current density in the steel workpiece 12 during the electric current flow has a more concentrated heat zone within the steel workpiece 12 as a result, which may improve the integrity and peel strength of the finished weld joint, as discussed in more detail below. The concentrated heat zone can - but need not necessarily - be a molten steel molten bath 72 within the steel workpiece 12 initiate.

After stopping the electric current, the aluminum alloy weld pool solidifies 70 to a welded joint 74 at the impact interface 28 to form, as in 7 generally illustrated. The steel weld pool 72 if it is formed, solidifies at this time also to a steel weld nugget 76 within the steel workpiece 12 although it preferably does not extend to either the impact surface 20 or the electrode pad 22 of the workpiece 12 extends. The welded joint 74 includes an aluminum alloy weld nugget 78 and usually an Fe-Al intermetallic layer 80 , The aluminum alloy weld nugget 78 extends to a distance in the aluminum alloy workpiece 14 which often ranges from about 20% to about 80% of the thickness 140 Aluminum Alloy Workpiece 14 lies, although the weld nugget 78 occasionally all the way to the electrode pad 26 (ie, 100% or full penetration). The intermetallic Fe-Al layer 80 is located between the aluminum alloy weld nugget 78 and the steel workpiece 12 at the impact interface 28 , This layer generally becomes due to a reaction between the aluminum alloy weld pool 70 and the steel workpiece 12 during a current flow and for a short time after the current flow is formed when the steel workpiece is still hot. It may include FeAl ₃ , Fe ₂ Al ₅ and other compounds. When measured in the direction of electric current flow, the Fe-Al intermetallic layer is 80 typically about 1 μm to about 5 μm thick.

The formation of a concentrated heat zone in the steel workpiece 12 - whether by initiating and growing the steel welding bath 72 or not - improves the strength and integrity of the welded joint 74 in at least two ways. First, the concentrated heat changes the temperature distribution through the weld 16 by changing and generating radial temperature gradients, which in turn cause the aluminum alloy weld pool 70 froze from its outer periphery towards its center. This solidification behavior drives welding defects in the direction of the center of the welded joint 74 where they are less prone to weaken their mechanical properties. Second, in those cases where the steel weld pool tends 72 initiated and brought to growth, the impact surface 20 of the steel workpiece 12 to get away from the electrode pad 22 to turn away. Such a rotation may be the steel workpiece 12 at the weld 16 make up to 50% thicker. Increasing the thickness of the steel workpiece 12 this helps in the center of the aluminum alloy weld pool 70 keeping it hot so that it cools and solidifies last, which can further increase the radial temperature gradients and cause weld failure, at or near the center of the weld joint 74 agglomerate. The bulging of the impact surface 20 of the steel workpiece 12 can also crack along the impact interface 28 Disturb by breaking cracks along a non-preferred path in the weld joint 74 distracts into it.

The 12 - 14 show an example of the influence that initiate and grow the steel welding pool 72 on the between the steel workpiece 12 and the aluminum alloy workpiece 14 formed weld joint 74 may have. Starting with 14 this shows the microstructure of a welded joint 82 by a conventional Resistance spot welding process was formed in which no concentrated heat zone in the steel workpiece (the lower substrate) was generated. Here in this example, errors D were observed at and along the impact interface 84 discovered. These defects D may include, but are not limited to, shrink pore, gas porosity, oxide residue formation, and microcracking. It was found that the error D, when present and along the impact interface 84 accumulated, the peel strength of the welded joint 82 and more generally the overall integrity of the welded joint 82 can negatively influence and weaken. Moreover, in addition to the defects D, one or more Al-Fe intermetallic layers (too small to be shown) may be interposed between the steel (lower) and aluminum alloy (upper) workpiece 12 . 14 and at and along the impact interface 84 to grow.

Without being bound by theory, it is believed that the accumulation of the errors D at and along the impact interface 84 at least partly due to the solidification behavior of the aluminum alloy weld pool. In particular, due to the unequal physical properties of the two materials - the much higher thermal and electrical resistance of the steel - there may be a heat imbalance between the much hotter steel workpiece (the lower substrate) and the aluminum alloy workpiece 14 (the upper substrate). Thus, the steel workpiece acts as a heat source, while the aluminum alloy workpiece acts as a heat conductor that produces a high temperature gradient in the vertical direction that causes the aluminum alloy weld pool to close to the region near the cooler (eg, water cooled). Welding electrode in contact with the aluminum alloy workpiece in the direction of the impact interface 84 cools and solidifies. The way and the direction of the solidification front are in 14 generally indicated by dashed arrows P, and a boundary of the welded joint 82 is shown generally by dashed lines B. As the solidification front progresses along the path P, the errors D become toward the impact interface 84 driven and can along the shock interface 84 distributed as shown. The oblique boundary B is the result of solidification in the direction of the impact interface 84 ,

The 12 - 13 show the microstructure of a welded joint 86 formed by a resistance spot welding process in which the current density in the steel workpiece (the lower substrate) was higher so that the molten steel molten bath inside the workpiece was initiated and made to grow. Here, it is believed that the initiation and growth of the steel weld pool was caused by the additional heat generated within the steel workpiece by concentrating the stream in a smaller area than would otherwise have been the case. Because the heat has been concentrated at a localized region within the steel workpiece (the lower substrate), more heat removal capabilities and larger radial temperature gradients are provided at the weld. In particular, heat from the aluminum alloy weld pool may be dissipated laterally into adjacent colder portions of the aluminum alloy workpiece. Heat from the steel weld pool may also migrate up into the aluminum alloy weld pool and then through the aluminum alloy workpiece as it cools and to the steel weld nugget 88 ( 13 ), which helps keep the center of the aluminum alloy weld pool at elevated temperatures for a long time.

The altered temperature gradients at the weld change the cooling effect of the aluminum alloy weld pool when it solidifies to weld 86 within the aluminum alloy workpiece (upper substrate) and at the impact interface 90 stiffens. Instead of the solidification front towards the impact interface 90 progresses, as in 14 As shown, the aluminum alloy weld pool cools radially and solidifies from its outer periphery towards its center. The way and the direction of the solidification front are in 12 generally indicated by dashed arrows P, and a boundary of the welded joint 86 is shown by dashed lines B. The path P points towards the central region and the boundary B is due to the changed solidification path (compared with the in 14 shown) orthogonal to the impact interface 90 , The solidification of the aluminum alloy weld pool in this way tends to cause the defects D toward the center of the joint 86 to press as shown. The steel weld nugget formed in the steel workpiece (the lower substrate) 88 is best in 13 (in which the photographed material was etched to show the steel weld nugget).

It can be seen that the initiation and growth of the steel weld pool has forced the abutting surface of the steel workpiece (lower substrate) outwardly into the aluminum alloy workpiece (the upper substrate). The steel workpiece has thus become thicker at the weld. The thicker section of the steel workpiece provides a larger, high temperature, thermally effective mass at the center of the aluminum alloy weld pool which helping to keep the center of the aluminum alloy weld pool hot so that it solidifies last. As a result, the welding defects D in this example have not only been driven to the center of the welded joint, but have additionally been at the center of the welded joint 86 adjacent to the impact interface 90 collected. Placing the defects at this point is more conducive to good peel strength and joint integrity than if the defects were along the impact interface 90 are scattered, as in 14 is shown.

Referring again to the 6 - 7 become the steel and the aluminum alloy welding electrode 36 . 40 withdrawn from their clamping positions soon after the passage of electrical current between the welding electrodes 36 . 40 stopped and leave footprints 66 . 68 with an asymmetric surface on the electrode pads 22 . 26 of steel and aluminum workpiece 12 . 14 back. The stack 10 then again between the steel and the aluminum alloy welding electrode 36 . 40 at another weld 16 is placed or moved away so that another pile 10 can be arranged for spot welding. Then, further spot welds are formed in the same manner.

The 8th - 9 illustrate another spot welding process in which the stack 10 at the weld 16 is spot-welded to basically achieve the same effects as before, but in this embodiment, similarly constructed multi-function welding electrodes 104 on each side of the pile 10 instead of in the 4 and 5 shown welding electrodes 36 . 40 used. As in 8th shown points each of the welding electrodes 104 the same basic components as those in 5 shown aluminum alloy welding electrode 40 with the exception of one major difference - and that includes each welding electrode 104 a welding surface 106 and a plateau 108 that is around a central axis 110 the welding surface 106 rises around. The welding surface 106 has a diameter 1060 from about 6 mm to 12 mm and a radius of curvature of about 20 mm to about 100 mm. The plateau 108 has a plateau surface 112 on, by the welding surface 106 is forcibly displaced by about 0.1 mm to about 0.5 mm. The plateau area 112 has a diameter 1120 from about 3 mm to about 7 mm and is shallower than the weld area 106 - the plateau area 112 is preferably flat or has a radius of curvature of about 40 mm or more. In addition, the plateau area can / can 112 and / or the welding surface 106 the two welding electrodes 104 if desired, be patterned or comprise surface intrusions or protrusions, as in U.S. Pat U.S. Patent No. 5,525,066 described.

In the 8th shown welding electrode 104 is multifunctional due to its ability to act differently when used with the steel workpiece 12 is in contact as if with the aluminum alloy workpiece 14 is in contact, as in 9 is illustrated. Specifically, when used on the steel side, the plateau surface 112 of the centrally located plateau 108 a contact with the electrode pad 22 of the steel workpiece 12 here and push into it. During a current flow prevents the relative hardness of the steel workpiece 12 that the surrounding welding surface 106 a contact with the electrode pad 22 produces and impresses them to a large extent. On the other hand, when used on the aluminum alloy side, the entire plateau is present 108 and the surrounding weld area 106 with the electrode contact surface 26 of the softened aluminum alloy workpiece 14 in contact and press into it. The same welding electrode design thus forms a footprint 114 in the electrode contact area 26 Aluminum Alloy Workpiece 14 that has a larger surface area than a footprint 116 put them in the electrode contact area 22 of the steel workpiece 12 during spot welding. After completion of the electric current, the in the electrode contact surface 26 Aluminum Alloy Workpiece 14 formed footprint 114 as before, by a ratio of about 1.5: 1 to about 16: 1, and more preferably from about 2: 1 to about 6: 1, greater surface area than that in the electrode pad 22 of the steel workpiece 12 formed footprint 16 ,

The footprints 114 . 116 passing through the welding electrodes 104 at the electrode pads 22 . 26 of steel and aluminum alloy workpiece 12 . 14 are formed, have the same effect as before. That is, the current density is at the weld 16 in the steel workpiece 12 higher than in the aluminum alloy workpiece 14 what causes it to be compared with the aluminum alloy workpiece 14 Heat in a smaller zone within the steel work piece 12 concentrated. The concentrated heat can also be used to make a steel weld pool 118 within the steel workpiece 12 to initiate and to grow. The concentrated heat zone may again be the aluminum alloy weld pool 120 in the same way as discussed earlier. Furthermore, it has the use of similarly constructed welding electrodes 104 on each side of the pile 10 the added benefit of having the stack 10 does not have to be oriented so that the workpieces 12 . 14 with a special welding electrode match. It can thus many stacks 10 be spot welded successively without it being necessary to stack 10 if necessary, turn or reorient to achieve a specific electrode / workpiece mating.

After spot welding the stack 10 - the steel workpiece 12 and the aluminum alloy workpiece 14 - it is possible to change the process and the two similarly built welding electrodes 104 for spot welding a stack 130 to use two or more aluminum alloy workpieces 132 includes, as in 15 is shown. During the spot welding process, the welding electrodes become 104 at a weld 136 in contact with opposite electrode pads 134 brought and an electric current is passed between them. Initially, only the plateau surface 112 each of the welding electrodes 104 with their respective electrode contact area 134 in contact. The plateau areas 112 soon press into the electrode pads 134 and finally the surrounding welds do that 106 when the aluminum alloy workpieces 132 soften up to footprints 138 to form with approximately the same size and shape. The resistance to the flow of electric current flowing through the workpieces 132 through and over a shock interface 140 is passed, generates heat and initiates an aluminum alloy weld pool (in 15 not shown) at the impact interface 140 , This weld pool penetrates into the overlapping aluminum alloy workpieces 132 one and after the cessation of electric current cools and solidifies to an aluminum alloy weld nugget 142 ,

Similarly, it is as in 16 shown, possible, the two similarly built welding electrodes 104 for spot welding a stack 150 to use two or more steel workpieces 152 includes. During the spot welding process, the welding electrodes become 104 at a weld 156 in contact with opposite electrode pads 154 brought. Then an electric current between the two electrodes 104 directed. Here is the plateau surface because of the relative hardness of steel 112 each welding electrode mainly with their respective electrode pad 154 in contact and press into it, to footprints 158 to form with approximately the same size and shape. The resistance to the flow of electric current flowing through the workpieces 152 through and over a shock interface 160 is passed, generates heat and initiates a molten steel molten bath (in 16 not shown) at the impact interface 160 , This weld pool penetrates into the overlapping steel workpieces 154 one and after the cessation of the electric current, it cools down and solidifies to a steel weld nugget 162 ,

The 10 - 11 illustrate another spot welding process in which the stack 10 at the weld 16 is spot-welded, in principle to achieve the same effects as before, but with a different multi-function welding electrode 92 as the one in 8th is shown. The multi-function spot welding electrode used here 92 is in 10 shown and has the same basic components as those in 4 shown steel welding electrode 36 , with the exception of one essential difference. That is, the multifunction welding electrode 92 includes a rounded welding surface 94 and a rounded ledge 96 , which is around a central axis 98 the welding surface 94 increases. The welding surface 94 has a diameter 940 from about 6 mm to 12 mm and a radius of curvature of about 20 mm to about 100 mm. The rounded projection 96 is preferably spherical with a diameter at the welding surface 94 which ranges from about 3 mm to about 7 mm, and a radius of curvature ranging from about 5 mm to about 20 mm.

In the 9 shown welding electrode 92 is how the in 8th shown welding electrode 104 , multifunctional due to their ability to act differently when used with the steel workpiece 12 is in contact as if with the aluminum alloy workpiece 14 in contact. For this reason, the multi-function welding electrode could 104 on each side of the pile 10 instead of in the 4 and 5 shown welding electrodes 36 . 40 in a similar way to those in 8th shown multifunction welding electrode 104 be used. If the multi-function welding electrode shown here 92 on both sides of the workpiece stack 10 used is the rounded projection 96 with the steel workpiece 12 in contact and push into it, and the surrounding weld area 94 generally does not do this while both the rounded ledge 96 as well as the surrounding welding area 94 with the aluminum alloy workpiece 14 be in contact and push into it. The same welding electrode configuration thus forms a contact area in the electrode contact area 26 Aluminum Alloy Workpiece 14 , which has a larger surface area than a footprint, in the electrode pad 22 of the steel workpiece 12 during spot welding to the same extent as previously stated.

The in the 8th and 10 pictured multifunction spot welding electrodes 104 . 92 do not necessarily work together on each side of the workpiece stack 10 as they both Welding electrodes are used. Each of the multifunction welding electrodes 104 . 92 can through the steel welding electrode 36 from 4 replaced and in conjunction with the aluminum alloy welding electrode 40 from 5 be used. Similarly, any of the multifunction welding electrodes 104 . 92 through the aluminum alloy welding electrode 40 from 5 replaced and in conjunction with the steel welding electrode 36 from 4 be used. To demonstrate this, the in 11 illustrated embodiment, the in 10 illustrated multifunction welding electrode 92 on the steel side of the workpiece stack 10 used, the above in 5 described aluminum alloy welding electrode 40 is used on the aluminum alloy side.

If you go through the in 4 shown steel welding electrode 36 as part of the spot welding process described above ( 1 - 3 and 6 - 7 ), the rounded protrusion pushes 96 into the electrode contact area 22 of the steel workpiece 12 to a footprint 100 which can be sharper than that through the steel welding electrode 36 from 4 formed footprint 66 , After termination of the conducted electric current, that in the electrode contact surface 26 Aluminum Alloy Workpiece 14 formed footprint 68 as before, by a ratio of about 1.5: 1 to about 16: 1, and more preferably from about 2: 1 to about 6: 1, greater surface area than that in the electrode pad 22 of the steel workpiece 12 formed footprint 100 , The spot welding process, which involves the formation of the welded joint and the concentrated heat zone within the steel workpiece 12 is basically the same. Here it is possible, however, that on the rounded ledge 96 attributable footprint 100 the current density within the steel workpiece 12 increase and steeper radial temperature gradients with respect to the flatter welding surface 60 the steel welding electrode described above 36 can generate. The rounded projection and its heat-concentrating effect can thus provide a smaller zone of heat concentration within the steel workpiece 12 and consequently a smaller steel weld pool 102 initiate if initiation occurs first.

The above description of preferred exemplary embodiments and specific examples is purely descriptive in nature; these are not intended to limit the scope of the following claims. Each of the terms used in the appended claims is intended to have its usual and conventional meaning unless expressly and unambiguously stated otherwise in the specification.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6861609 [0036]
• US 8222560 [0036]
• US 8274010 [0036]
• US 8436269 [0036]
• US 8525066 [0036, 0051]
• US 2009/0255908 [0036]

Claims (10)

A method of spot welding a steel workpiece to an aluminum alloy workpiece, the method comprising: providing a stack comprising a steel workpiece and an aluminum alloy workpiece, wherein the steel workpiece and the aluminum alloy workpiece overlap to provide an impact interface; bringing an electrode contact surface of the steel workpiece into contact with a steel welding electrode; bringing an electrode contact surface of the aluminum alloy workpiece into contact with an aluminum alloy welding electrode; passing an electrical current between the steel and aluminum alloy welding electrodes and through the stack to initiate an aluminum alloy weld pool within the aluminum alloy workpiece and at the bump interface, wherein the electrical current in the steel workpiece has a higher current density as in the aluminum alloy workpiece; and the passage of the electric current is stopped at a time when a footprint formed by the aluminum alloy welding electrode at the electrode contact surface of the aluminum alloy workpiece has a larger surface area than a footprint formed by the steel welding electrode at the electrode contact surface of the steel workpiece wherein the footprint formed by the aluminum alloy welding electrode has a surface area greater than the footprint formed by the steel welding electrode by a ratio of 1.5: 1 to 16: 1. The method of claim 1, wherein the aluminum alloy welding electrode comprises a welding surface having a diameter between 6 mm and 20 mm and a radius of curvature between 15 mm and flat, and wherein the steel welding electrode comprises a welding surface having a diameter between 4 mm and 16 mm and a radius of curvature of 20 mm or more. The method of claim 1, wherein at least one of the aluminum alloy welding electrode or the steel welding electrode has a welding surface and a rounded protrusion rising above a central axis of the welding surface, the welding surface having a diameter of 6 mm to 12 mm and a radius of curvature of 20 mm to 100 mm and the rounded projection has a diameter of 3 mm to 7 mm at the welding surface and a radius of curvature of 5 mm to 20 mm. The method of claim 1, wherein at least one of the aluminum alloy welding electrode or the steel welding electrode has a welding surface and a plateau forcibly displaced from the welding surface and rising above a central axis of the welding surface, the welding surface having a diameter of 6 mm to 12 mm and a radius of curvature of 20 mm to 100 mm, and wherein the plateau surface of the plateau has a diameter of 3 mm to 7 mm and a radius of curvature of 40 mm or more on the welding surface, while being shallower than the welding surface. The method of claim 1, wherein the act of passing an electrical current between the steel and aluminum alloy welding electrodes and through the stack initiates a molten steel molten bath within the steel workpiece. The method of claim 5, wherein the molten steel molten bath twists an abutting surface of the steel workpiece away from the electrode contact surface of the steel workpiece to thicken the steel workpiece at the weld. The method of claim 5, wherein after completing the passage of the electrical current, the aluminum alloy weld pool melts to a weld joint comprising an aluminum alloy weld nugget, and the molten steel weld pool solidifies to a steel weld nugget, wherein the steel weld nugget does not rise extends to a shock interface of the steel workpiece. The method of claim 1, wherein after the completion of the passage of electrical current, the aluminum alloy weld pool melts to a weld joint comprising an aluminum alloy weld nugget and an Fe-Al intermetallic layer. A method of spot welding comprising: providing a first workpiece stack comprising a steel workpiece and an aluminum alloy workpiece, wherein the steel workpiece and the aluminum alloy workpiece overlap to provide an impact interface; contacting an electrode contact surface of the steel workpiece with a first welding electrode and bringing an electrode contact surface of the aluminum alloy workpiece into contact with a second welding electrode, the first and second welding electrodes being diametrically opposed to their respective workpiece surfaces Welding point are pressed, each of the first and the second welding electrode having the same structure; passing an electrical current between the first and second welding electrodes and through the first workpiece stack at the weld to initiate and grow an aluminum alloy weld pool in the aluminum alloy workpiece which wets an adjacent abutting surface of the steel workpiece; electric current in the steel workpiece has a higher current density than in the aluminum alloy workpiece; the passage of the electric current is stopped and the first and second welding electrodes are withdrawn from the steel and aluminum alloy workpieces; a second stack of workpieces is provided, comprising either (1) a steel workpiece and another steel workpiece overlapping to provide a butting interface between the steel workpieces, or (2) an aluminum alloy workpiece and another aluminum alloy workpiece which is overlap to provide an impact interface between the aluminum alloy workpieces; opposite sides of the second workpiece stack are brought into contact with the first and second welding electrodes, and an electric current is passed between the first and second welding electrodes and through the second workpiece piece stack, the electric current being an aluminum alloy molten weld pool at a butting interface initiating and growing overlapping aluminum alloy workpieces when the second workpiece stack comprises aluminum alloy workpieces, or initiating a steel weld pool at a butting interface of the overlapping steel workpieces and causing them to grow when the workpiece stack comprises steel workpieces. The method of claim 9, wherein during the passing of the electrical current between the first and second welding electrodes and through the first workpiece stack, the first welding electrode is pressed into the aluminum alloy workpiece to form a footprint on the electrode contact surface of the aluminum alloy workpiece and the second welding electrode is pressed into the steel workpiece to form a footprint on the electrode contact surface of the steel workpiece, and at the time when the passage of the electric current is terminated, the footprint formed by the first welding electrode is one Ratio of 1.5: 1 to 16: 1 has greater surface area than the footprint formed by the second welding electrode.

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