The field of the invention relates generally to friction stir welding and more particularly to friction stir welding of dissimilar metals and to workpiece assemblies formed by friction stir welding dissimilar metals together.
Recent surveys conducted by the Joining and Welding Research Institute (JWRT) of Japan and the Edison Welding Institute (EWI) of the U.S. have identified welding of dissimilar metals as a top priority in materials joining technologies. For instance, being able to weld aluminum-to-copper would be advantageous in many industries where electric connections are made during the manufacturing process. In another instance, being able to weld aluminum-to-steel or aluminum-to-magnesium would result in significant weight reduction in some applications, which would be advantageous in many industries, e.g., the aircraft, locomotive, shipbuilding, and automotive manufacturing industries. Being able to efficiently and effectively weld aluminum-to-magnesium is of particular interest because magnesium has a specific strength (i.e., strength to density ratio) that is 14 percent higher than aluminum and 68 percent higher than iron making it one of the lightest metallic structural materials. Although aluminum and magnesium alloys are typically soft materials and often have relatively similar melting points, they tend to react with each other when heated such as during friction stir welding. The more they are heated up, that is, the more heat input during friction stir welding, the more they react with each other to weaken the resultant weld.
As illustrated in
With reference to
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The pieces P1, P2 can be welded together along a single joint line using conventional single-pass lap welding or can be welded together along two joint lines using conventional double-pass lap welding. When conventional double-pass lap welding is used, the pieces P1, P2 of materials are flipped over after they have been welded on one side and are then welded on the opposite side using the same process. When dissimilar metals (e.g., aluminum alloy and magnesium alloy) are lap welded together using friction stir welding, brittle intermetallic compounds (e.g., Al12Mg17, Al3Mg2) are often formed, which severely degrades the strength of the weld. As a result, prior efforts to lap pieces of dissimilar materials have been relatively unsuccessful.
In one aspect, a process for friction stir welding pieces of dissimilar metals together generally comprises overlying a first piece of a second metal onto a first piece of a first metal that is dissimilar from the second metal such that at least a portion of the first piece of second metal overlaps a portion of the first piece of first metal. The first piece of second metal has a plurality of holes therein and the holes are disposed in overlapping relationship with the portion of the first piece of first metal. Each of the holes are filled with a plug formed from the first metal. The first piece of first metal is friction stir welded to the first piece of second metal at each of the plug locations.
In another aspect, a workpiece assembly generally comprises a first piece of a first metal and a first piece of a second metal overlying at least a portion of the first piece of first metal. The first piece of second metal has a plurality of holes therein and each of the holes is filled with a plug formed from the first metal. A discontinuous weld seam securely joins the first piece of first metal and the first piece of second metal. The weld seam is defined by a plurality of weld spots comprising a stirred mixture of the first metal and the second metal. Each of the weld spots correspond to one of the plugs filling the holes in the first piece of second metal.
This patent or patent application publication contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
With reference now to the drawings,
As seen in the embodiment illustrated in
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In one suitable embodiment, the pin 52 is tilted forward in the direction of movement of the tool 50 between about 2 degrees and about 4 degrees. More suitably, the pin 52 is tilted forward about 3 degrees. A plurality of clamps 60 can be used to secure the pieces 10, 20, 30 during the welding process. It is contemplated that other means for securing the pieces 10, 20, 30 during the welding process can be used besides the illustrated clamps 60 and that more or fewer clamps can be used.
During the welding process, the tool 50 and thereby the pin 52 is moved along the joint line 40 to weld the three pieces 10, 20, 30 together to form a workpiece assembly, indicated generally at 62 in
As discussed above, the tool 50 and the pin 52 generate a sufficient amount of heat during the welding process to plasticize portions of the pieces 10, 20, 30 adjacent the joint line 40 as they are moved along the joint line. The pin 52 mixes the plasticized material together to form a weld seam 64 (
With reference now to
With reference now to
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In one suitable embodiment, the pin 52 is tilted forward in the direction of movement of the tool between about 2 degrees and about 4 degrees, and more suitable, the pin 52 is tilted forward about 3 degrees. As in the previous process, the plurality of clamps 60 can be used to secure the pieces 110, 120, 130 during the welding process.
During the welding process, the tool 50 and thereby the pin 52 is moved along the joint line 140 to weld the three pieces 110, 120, 130 together. After the three pieces 110, 120, 130 are welded together along joint line 140, the flash is removed. Then, the pieces are flipped over such that the first piece of magnesium alloy 110 overlies the first piece of aluminum alloy 120 (
With reference now to
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With reference now to
The tool 50 and pin 52 are used to spot friction stir weld together the plugs 230, the first piece of magnesium alloy 210, and the first piece of aluminum alloy 220. The tool 50 and pin 52 can be rotated either counterclockwise, as indicated by arrow 54 in
In another suitable embodiment, each of the plugs 230 has a diameter that is 50 to 100 percent larger than the diameter of the pin 52. Thus, if the pin 52 has a diameter of about 4 mm then each of the plugs would suitably have a diameter between about 6 mm and about 8 mm. It is understood that the pin 52 and plugs 230 can have other diameters without departing from the scope of this invention.
A plurality of clamps 60 can be used to secure the pieces 210, 220 in place during the welding process. It is contemplated that other means for securing the pieces 210, 220 during the welding process can be used besides the illustrated clamps 60 and that more or fewer clamps can be used.
As illustrated in
In one experiment, pieces of an aluminum alloy (6061 Al) were welded to pieces of a magnesium alloy (AZ31B Mg) using different welding techniques including conventional butt welding, conventional single-pass lap welding, conventional dual-pass lap welding, the modified single-pass friction stir welding process described above and illustrated in
A 2.2 kW (3 HP) Lagun FTV-1 milling machine equipped with a H13 steel tool was used to friction stir weld the pieces of material together. The tool had a concave shoulder with a 10 mm diameter. A 4 mm diameter threaded pin depended from the tool. For butt welding, the pin length was 1.3 mm and, for lap welding (both conventional and modified) the pin length was 1.5 mm. Additional conventional lap welding was also conducted with using a pin having a length of 2.3 mm.
During the friction stir welding process, the tool was rotated counterclockwise, and tilted forward (i.e., in the direction of movement of the tool) 3 degrees. Each of the pieces was clamped down tight using two, opposing steel fingers located about 10 mm away from the weld line. The tool and pin were cleaned after each welding pass by plunging it into a fresh piece of 6061 Al. This removed any material potentially stuck on the tool and/or pin from the previous weld. Two different rotation speeds 1,400 rpm and 800 rpm were initially used. Besides one exception, the joint strength was significantly lower when the rotation speed was set at 800 rpm. As a result, the rotation speed was fixed at 1,400 rpm after several welds were made at 800 rpm. The travel speed (i.e., the speed at which the tool and thereby the pin is moved along the weld line) was set at 38 mm/minute
Conventional Butt Welding
Eleven conventional butt welds were made during this experiment and the weld conditions and results are listed in Table 2. As seen in Table 2, the conventional butt welds formed between two pieces of 6061 Al or two pieces of AZ31 Mg were relatively strong (e.g., over 2,000 Newtons). The other nine conventional butt welds were made to weld AZ31 Mg to 6061 Al. AZ31 Mg was either on the advancing or retreating side of the tool. The tool axis was positioned along the joint (no offset) or shifted 1.5 mm (1 5 mm offset) toward either 6061 Al or AZ31 Mg. Three of the nine welds were relatively weak, three were relatively strong and the other three were moderate. Thus, the strength of butt welds joining the pieces of 6061 Al and AZ31 Mg was inconsistent and therefore unpredictable.
Conventional Single-Pass Lap Welding
Six conventional single-pass lap welds were made during this experiment and the conditions and results are listed in Table 3. Each of the lap welds were was positioned along a centerline of a 38 mm overlap. That is, the overlap between the welded pieces was 38 mm and the weld was made along the centerline of the overlap (i.e., 19 mm from either edge of the overlap).
As seen in Table 3, the conventional lap welds formed between two pieces of 6061 Al or two pieces of AZ31 Mg were relatively strong (e.g., over 2,000 Newtons). The other four conventional lap welds were used to weld AZ31 Mg to 6061 Al. Three of the four welds were relatively weak while one was moderate. Thus, the overall strength of butt welds joining the pieces of 6061 Al and AZ31 Mg was relatively low, inconsistent, and unpredictable.
Conventional Dual-Pass Lap Welding
One conventional dual-pass lap welding was formed to determine how much the joint strength could be increased by making a second pass. The welding conditions of the dual-pass lap welding are listed in Table 4. The strength of the weld was more than double that of the single pass weld (see CL-2 and CL-4).
Modified Single-Pass Lap Welding
The welding conditions of the single-pass modified friction stir welding are provided in Table 5. A small piece of the bottom-sheet material, 76 mm long, 19 mm wide, and 1.6 mm thick, was butt welded to the top sheet with pin penetration into the bottom sheet. The 19 mm width of the small piece was mainly for the space required for clamping. If the clamps permitted, the width of the small piece could have been less. When AZ31 Mg was on the top, whether it was the top sheet or the small piece, was placed on the advancing side of the tool. This was because, as will be shown subsequently, butt welds were significantly weaker with 6061 Al on the advancing side.
Modified Dual-Pass Lap Welding
Modified dual-pass friction stir welding was similar in material positions except a second pass was made from the opposite side, with its centerline 10 mm away from that of the first pass. The welding conditions of the modified dual-pass lap welds are listed in Table 6.
Tensile Testing
The joint strength, which is provided in the above tables, was determined by tensile testing normal to the weld. Welded coupons were cut in the direction normal to the weld into to 12 mm-wide tensile specimens. The edges of the tensile specimens were polished smooth with 320-grit grinding paper. For lap welds, a 1.6 mm-thick sheet was placed at each end of the tensile specimen to initially align the specimen with the loading direction. A Sintech tensile testing machine was used, and the speed of the crosshead movement was 1 mm/min. Two to four specimens from welds made under the same condition were tested.
Temperature Measurements
A computer-based data acquisition system was used along with K-type thermocouples for temperature measurements at 100 Hz during the friction stir welding process of each of the samples. The thermocouple, with a stainless steel sheath of 0.5 mm outer diameter, was placed in a 0.5 mm×0.5 mm groove at the workpiece surface that ended 3 mm away from the path of the tool axis. In both conventional and modified lap friction stir welding the grooves were at the top surface of the lower sheet. In butt friction stir welding, on the other hand, they were at the bottom surface of the workpiece.
Weld Microstructure
Transverse weld cross-sections were prepared by polishing and etching in three steps. The first step was to etch the samples with a solution consisting of 10 ml acetic acid, 10 ml distilled water and 6-gram picric acid in 100 ml ethanol for 10 s (to reveal the AZ31 part of the microstructure). The second step was to etch them with a solution consisting of 20-gram NaOH in 100 ml distilled water for 40 s (to reveal the grain structure in 6061 Al). The final step was to dip them in a solution consisting of 4-gram KMnO4 and 2-gram NaOH in 100 ml distilled water for 10 s (to make Al colorful). The 3-step etching procedure showed Al, Mg, Al3Mg2 and Al12Mg17 all in different colors.
A JEOL JSM-6100 scanning electron microscope with energy dispersive spectroscopy (EDS) was used for chemical composition measurements. A Hi-Star 2-D x-ray diffractometer with an area detector was used to identify the intermetallic compounds.
Al—Mg Phase Diagram
A binary Al—Mg phase diagram is shown in
Heat Input in Friction Stir Welding
Liquation in the weld during friction stir welding increases when the heat input is increased. The increase in liquation may result in more liquid films forming along grain boundaries and, in the case of Al-to-Mg friction stir welding, the Al/Mg interface. Since the liquid films weaken the Al/Mg interface under shearing force caused by the tool, cracking may occur along the interface.
For a lower conductivity material such as 304 stainless steel, the temperature on the advancing side can be as much as 100° C. higher than that on the retreating side. For a higher conductivity material such as an Al or Mg alloy, the difference is often smaller. However, the liquation (eutectic) temperatures are rather low (437° C. and 450° C.). Furthermore, a relatively small temperature increase can significantly increase the fraction of liquid, that is, the extent of liquation. For instance, according to the Al—Mg phase diagram (
In similar-metal butt friction stir welding, more heating occurs in 6xxx Al alloys than in AZ (Mg—Al—Zn) or AM (Mg—Al—Mn) Mg alloys. In similar-metal butt friction stir welding, higher peak temperatures (100° C. higher on the advancing side and 80° C. on the retreating side, both at 10 mm from the joint line) have been observed in 6040 Al than in AZ31 Mg. Similar trends have been observed in studies on similar-metal friction stir spot welding where heat is generated by a rotating but stationary tool. The stir zone at the tool shoulder has been observed to have a higher peak temperature (about 80° C. higher) in 6111 Al than in AZ91 Mg. A higher torque and heat input (almost three times higher heat input) have been observed in 6061 Al than in AM60 Mg. A higher torque and heat input (twice higher heat input) have been observed in 6061 Al than in AZ91 Mg.
With respect to fact 2, it has been observed in similar-metal friction stir spot welding that AZ and AM Mg can liquate much more easily than 6xxx Al. In AZ and AM Mg (and most other Mg alloys because Al is the most widely used alloying element in Mg alloys) Al12Mg17 is present to react with the surrounding Mg-rich matrix to form liquid at 437° C. (
Based on the two facts, two hypotheses can be made regarding dissimilar-metal friction stir welding of 6xxx Al to AZ or AM Mg with the same tool at the same rotation speed and travel speed. Hypothesis 1 is that a higher heat input can be expected in butt friction stir welding with Al on the advancing side. Hypothesis 2 is that a higher heat input can be expected with a larger Al/tool contact area. A larger Al/tool contact area can exist in the following two cases: first, with tool offset to Al in butt friction stir welding and, second, with Al on the top in lap friction stir welding. Regarding the first case, the difference can be expected to be more significant with Al on the advancing side in view of Hypothesis 1.
These hypotheses will be used below to explain the effect of material positions on the heat input in Al-to-Mg friction stir welding of this experiment.
Butt Welding
The effect of material positions on the joint strength in butt friction stir welding is shown in
Based on the two hypotheses mentioned previously, with the same tool at the same rotation speed and travel speed, the effect of material positions on the heat input in Al-to-Mg butt friction stir welding can be predicted as shown by the arrow indicating the direction of decreasing heat input in
As shown in
As shown in
Although
Single-Pass Conventional Lap Welding
The effect of material positions on the heat input in conventional lap friction stir welding of 6xxx Al to AZ or AM Mg is predicted in
To verify that the heat input is higher with Al on the top and with a longer pin, temperature measurements were conducted. The thermocouples were located 3 mm away from the path of the tool axis and 0.25 mm below the top surface of the lower sheet. As shown in
EDX (energy-dispersive x-ray) analysis showed the lighter layer next to 6061 Al (inset on right) contained about 39 wt % Mg, which is close to the 37 wt % Mg for Al3Mg2. The darker layer next to AZ31 Mg contained about 63 wt % Mg, which is reasonably close to the 57 wt % Mg for Al12Mg17. EPMA (electron probe microanalysis) confirmed the compositions. X-ray diffraction (XRD) also confirmed the presence of Al12Mg17 and Al3Mg2.
The intermetallic layers in weld CL-1 (
EDX showed the particle inside the crack at the interface (inset on left in
In weld CL-2 (
Single-Pass Modified Lap Welding
In order to improve the strength of Al-to-Mg lap welds, conventional lap friction stir welding was modified.
The effect of material positions on the joint strength in single-pass modified lap friction stir welding is shown in
The effect of material positions on the heat input in modified lap friction stir welding is predicted in
As shown in
A weld such as ML-1 can be prepared as follows. 6061 Al sheets, AZ31 Mg sheets, and small AZ31 Mg sheets can be sheared with parallel edges to the predetermined width. With 6061 Al on top of AZ31 Mg and positioned, both can be clamped down simultaneously from one side. After putting the small AZ31 Mg next to 6061 Al and clamping down from the opposite side, the lateral position of the joint line relative to the pin can be fine adjusted just like in butt welding. Since the small AZ31 Mg is free to move, its close fit-up with 6061 Al is guaranteed regardless how precise the dimensions of the sheets are. The small AZ31 Mg can then be butt welded to 6061 Al with pin penetration into the backing plate. This, in fact, can be easier to do than ordinary butt friction stir welding because pin penetration into the backing plate (i.e., support surface) does not have to be avoided.
Dual-Pass Lap Welding
Weld ML-6 is stronger than the dual-pass conventional lap weld CL-7 by a factor of about two (
Modified Friction Stir Spot Welding
A zero disc diameter, also indicated by “no plug” on
How the material positions affect the joint strength of the resultant weld depends significantly on how they affect the heat input and material flow during friction stir welding, both of which affect the formation of defects and hence the joint strength. At lower travel speeds and higher rotation speeds, more heat is generated to cause liquation and hence cracking and intermetallic compounds to weaken the resultant weld. So, the heat input is likely to play a bigger role than materials flow. At higher travel speeds and lower rotation speeds, on the other hand, less heat is generated to cause liquation. However, the materials may not be warm enough for sufficient plastic flow to keep channels from forming and weakening the resultant weld. So, material flow is likely play a bigger role than the heat input. In the present study, the travel speed was set to 38 mm/min, which is low, and the rotation speed was set to 1,400 rpm, which is intermediate. The results indicate that the heat input plays a bigger role than material flow in most cases.
Within the range of experimental conditions in the present study, the following conclusions, which can be useful for structure design in friction stir welding of dissimilar metals can be drawn:
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
This application is a divisional application of U.S. patent application Ser. No. 12/589,948, filed Oct. 30, 2009, which is incorporated herein by reference.
This invention was made with government support under Grant Award No. 0605622 awarded by the National Science Foundation (NSF). The government may have certain rights in the invention.
Number | Date | Country | |
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Parent | 12589948 | Oct 2009 | US |
Child | 13860155 | US |