Weldability Improvements in Advanced High Strength Steel

Cross Reference to Related Applications This application claims the benefit of U.S. Provisional Application Serial No. 62/561,474 filed September 21, 2017 and U.S. Provisional Application Serial No. 62/722,482 filed August 24, 2018.

Field of Invention

This disclosure relates to weldability of steel alloys that provide weld joints which retain hardness values in a heat affected zone adjacent to a fusion zone and which also have improved resistance to liquid metal embrittlement due to the presence of zinc coatings.

Background

Production of steel continues to increase, with a current US production around 100 million tons per year with an estimated value of $75 billion. Steel utilization in vehicles is also high, with advanced high strength steels (AHSS) currently at 17% and forecast to grow by 300% in the coming years [American Iron and Steel Institute, Profile 2013, Washington, D.C.]. With current market trends and governmental regulations pushing towards higher efficiency in vehicles, AHSS are increasingly being pursued for their ability to provide high strength to mass ratio. The high strength of AHSS allows for a designer to reduce the thickness of a finished part while still maintaining comparable or improved mechanical properties. In reducing the thickness of a part, less mass is needed to attain the same or better mechanical properties for the vehicle thereby improving vehicle fuel efficiency. This allows the designer to improve the fuel efficiency of a vehicle while not compromising on safety. The joining and bonding of steel is an important consideration for manufacturing processes.

Materials are commonly joined self-to-self, to metallic materials, and to non-metallic materials through a variety of methods in manufacturing settings. These joining and bonding methods include but are not limited to the use of structural adhesives, soldering, brazing, and various types of welding. Each of these joining and bonding techniques possess a myriad of sub-types, each with its own applications. For steel in particular, welding techniques are commonly used due to low cycle times, cost, and complexity which is enabling for usage in high volume production settings. In particular, resistance spot welding (RSW) is utilized extensively in the manufacturing process for automobile production with the average American mid-sized car estimated to contain greater than 5000 resistance spot welds. The number of resistance spot welds in automobiles is expected to remain constant or increase in the coming years.

Resistance spot welding is typically performed on sheet material and functions by running a current pulse or pulses between two electrodes and through the materials to be welded after clamping pressure is applied. With current passing through the material, the materials' bulk and surface electrical resistance cause the sheet to undergo resistive heating, rapidly melting the sheet at the point of contact between the sheets. The pool of molten metal grows outward from the sheet surface interface and into both sheet materials until the current pulse or pulses are complete. At this time, the liquid melt pool undergoes rapid cooling and solidification. The weld fusion zone forms between the two sheets from metal that was previously the melt pool, providing a metallurgical bond. Schematic illustration of the typical weld is shown in FIG. 1.

During the current pulse, heat is generated in and around the pool of molten metal that will become the weld fusion zone. In the area that surrounds the weld fusion zone, the metal was exposed to heat although not sufficient heat to melt. Metal directly adjacent to the weld fusion zone is exposed to temperatures that are greater than 90% of the alloy's melting temperature in many cases. Material that is further from the weld fusion zone has decreasing amounts of thermal exposure as a function of its distance from the weld fusion zone. Often, this heat exposure at the temperature range from 400°C up to the melting point (Tm) results in a change in the microstructure of the metal, and the area in which the change has occurred is known as the heat affected zone (HAZ). In the HAZ, the microstructure changes are often detrimental to the weld. The HAZ is commonly associated with embrittlement effects, grain growth, martensite formation and other microstructure related effects that degrade the mechanical performance of the metal. For instance, commercial dual phase (DP) steels [i.e. steels which consist mainly of ferrite and martensite phases) exhibit a range of HAZ effects where HAZ hardening is often observed near the weld fusion zone. Commercial Transformation Induced Plasticity (TRIP) steels are also known for a marked increase in the hardness of the HAZ as compared to the base metal. The mechanical properties of the weld are also affected by the nature of the HAZ in any given steel correspondingly. The HAZ may affect the maximum tensile strength, bendability, and fatigue lifetime of a weld. The HAZ will affect steels differently, and different welding configurations will result in different HAZ conditions. HAZ has been observed in steel materials welded by various arc welding methods (GMAW, SMAW, GTAW, etc.), gas welding (oxy- fuel welding), various resistance welding methods (spot welding, laser welding, seam welding, etc.).

The HAZ formed as a consequence of the welding process adds another variable to consider during materials selection for automobile parts designers. If the steel cannot be resistance spot welded without the creation of a detrimental HAZ, the steel will likely only have limited uses in automobile markets. As such, steels with smaller heat affected zones or with heat affected zones that exhibit minimal effects on mechanical properties are desirable.

For many applications, there is a requirement for the steel sheet material to be coated to prevent oxidation and rusting of the material. Zinc is not used as an alloying addition to steel but is used to coat the surface of steel since it is anodic to steel and provides effective corrosion protection in a wide variety of environments. Zinc is applied to a steel surface by several techniques including hot dip galvanization, galvanneal, and electrogalvanization. Coated materials present a unique complication to resistance spot welding in the form of liquid metal embrittlement (LME). The basic mechanism of LME in steel involves the presence of one or more galvanized coatings at the weld joint interface. LME is prevalent during welding and first involves the formation of molten zinc. During welding, in the weld fusion zone, the steel is melted, which typically may occur from 1425 to 1540°C. Pure zinc melts at 420°C and depending on the amount of alloying which occurs during the galvanization process and the specific chemistry of steel which is being coated, the resulting zinc coating has a melting point from 420 to 650°C. Thus, molten zinc will form during the welding process. The second step to LME is zinc penetration into the base steel. This occurs through diffusion and is assisted through high diffusion rate pathways such as grain boundaries, with much higher diffusivity and penetration occurring in larger grained microstructures. The third step of LME is thermal expansion and contraction during cooling which results in initial crack formation, often along the zinc coated grain boundaries and resulting propagation. The presence of the LME cracks causes an embrittlement of the weld leading to early weld failure in service. Summary

A method for joining high strength sheet steel comprising: a. supplying a metal alloy comprising at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu or C and melting said alloy and cooling at a rate of < 250 K/s and solidifying to a thickness of 25 mm up to 500 mm and forming an alloy having a melting point Tm; b. processing said alloy into sheet form with thickness up to 5.0 mm with the sheet exhibiting a total elongation 10.0 to 75.0 %, a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa, and a hardness HI; c. welding said sheet self-to-self by heating and forming: (i) a fusion zone in said sheet at a temperature above the alloy Tm; and (ii) a heat affected zone in said sheet at a temperature T2 that is less than the alloy Tm; and d. cooling said sheet and forming a hardness H2 in said heat affected zone of the sheet wherein H2 = H1 +/- 100 HV.

A method for joining high strength sheet steel with other steel grades comprising: a. supplying a metal alloy comprising at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu or C and melting said alloy and cooling at a rate of < 250 K/s and solidifying to a thickness of 25 mm up to 500 mm and forming an alloy having a melting point Tm; b. processing said alloy into sheet form with thickness up to 5.0 mm with the sheet exhibiting a total elongation 10.0 to 75.0 %, a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa, and a hardness HI; c. welding said sheet to other steels by heating and forming: (i) a fusion zone in said sheet at a temperature above the alloy Tm; and (ii) a heat affected zone in said sheet at a temperature T2 that is less that the alloy Tm; and d. cooling said sheet and forming a hardness H3 in said heat affected zone of said sheet wherein H3 = HI +/- 125 HV. A method for joining a coated high strength sheet steel comprising: a. supplying a metal alloy comprising at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu or C and melting said alloy and cooling at a rate of < 250 K/s and solidifying to a thickness of 25 mm up to 500 mm and forming an alloy having a melting point Tm; b. processing said alloy into sheet form with thickness LI, with the sheet exhibiting a total elongation 10.0 to 75.0 %, a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa; c. applying a zinc containing coating to said alloy sheet and forming a coated sheet; d. welding said coated sheet self-to-self or to other steels by heating and forming a fusion zone, wherein said other steels have uncoated surfaces or surfaces with zinc containing coatings; and e. cooling to form a weld which: (1) is crack free; or (2) contains one or more cracks with the depth of the largest crack at L2, which is < 15% of sheet thickness LI.

Brief Description of the Drawings

The detailed description below may be better understood with reference to the accompanying FIG.s which are provided for illustrative purposes and are not to be considered as limiting any aspect of this invention.

FIG. 1 Schematic illustration of the typical weld nugget formed at spot welding showing base material (sheet), HAZ, and fusion zone.

FIG. 2 Summary of self-to-self welding of alloys herein.

FIG. 3 Summary of mixed metal welding of alloys herein.

FIG. 4 Summary of welding of alloys herein in the presence of a coating. FIG. 5 Schematic illustration of the mid frequency inverter (MFDC) method of spot welding.

FIG 6 Alloy 1 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 2 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 3 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 4 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 5 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 6 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 7 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 8 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 9 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 10 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 11 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 12 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 13 microhardness measurement data as a function of distance from the center of the weld nugget. Alloy 14 microhardness measurement data as a function of distance from the weld nugget center. FIG 20 Alloy 15 microhardness measurement data as a function of distance from the weld nugget center.

FIG 21 Alloy 16 microhardness measurement data as a function of distance from the weld nugget center. FIG 22 Alloy 17 microhardness measurement data as a function of distance from the weld nugget center.

FIG. 23 The weld lobe for single pulse welding of sheet samples from Alloy 8 at 4.2 kN clamping force. Edge points defining the weld lobe area are marked from 1 to 6.

FIG. 24 An image of the spot weld nugget cross section corresponding to Point 1 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 25 An image of the spot weld nugget cross section corresponding to Point 2 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 26 An image of the spot weld nugget cross section corresponding to Point 3 of the weld lobe for Alloy 8 in FIG. 23. FIG. 27 An image of the spot weld nugget cross section corresponding to Point 4 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 28 An image of the spot weld nugget cross section corresponding to Point 5 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 29 An image of the spot weld nugget cross section corresponding to Point 6 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 30 Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 1 of the weld lobe for Alloy 8 in FIG. 23.

FIG. 31 Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 2 of the weld lobe for Alloy 8 in FIG. 23. Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 3 of the weld lobe for Alloy 8 in FIG. 23.

Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 4 of the weld lobe for Alloy 8 in FIG. 23.

Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 5 of the weld lobe for Alloy 8 in FIG. 23.

Microhardness as a function of the distance across the boundary between the fusion zone and the base metal in the sample welded at parameters corresponding to Point 6 of the weld lobe for Alloy 8 in FIG. 23.

A schematic illustration of the lap shear testing.

A SEM micrograph of the recrystallized microstructure in the base metal in the single pulse self-to-self spot welded Alloy 8 sample.

A SEM micrograph of the microstructure at the interface between the fusion zone and the base metal in the single pulse self-to-self spot welded Alloy 8 sample.

A SEM micrograph of the microstructure in the fusion zone in the single pulse self-to- self spot welded Alloy 8 sample before lap shear testing.

Microhardness as a function of the distance across the weld nugget in the single pulse self-to-self spot welded Alloy 8 sample.

A SEM micrograph of the recrystallized microstructure in the base metal in the double pulse self-to-self spot welded Alloy 8 sample.

A SEM micrograph of the microstructure at the interface between the fusion zone and the base metal in the double pulse self-to-self spot welded Alloy 8 sample.

A SEM micrograph of the fusion zone in the double pulse self-to-self spot welded Alloy 8 sample before lap shear testing. FIG. 44 Microhardness as a function of the distance across the weld nugget in the double pulse self-to-self spot welded Alloy 8 sample.

FIG. 45 A SEM micrograph of the recrystalhzed microstructure in the base metal of self-to-self spot welded Alloy 8 sample. FIG. 46 A SEM micrograph of the microstructure in the interface between the fusion zone and the base metal in the triple pulse self-to-self spot welded Alloy 8 sample.

FIG. 47 A SEM micrograph of the microstructure in the fusion zone weld nugget in the triple pulse self-to-self spot welded Alloy 8 sample before lap shear testing.

FIG. 48 Microhardness as a function of the distance across the weld nugget in the triple pulse self-to-self spot welded sample from Alloy 8.

FIG. 49 A micrograph of the cross section of the IF steel self-to-self spot welded sample.

FIG. 50 Microhardness as a function of the distance across the weld nugget in the IF steel self-to- self spot welded sample.

FIG. 51 SEM images of microstructure in the IF steel self-to-self welded sample; a) in the base metal b) at the interface between the base metal and the heat affected zone, c) in the heat affected zone, d) at the interface between the heat affected zone and the fusion zone, and e) in the fusion zone.

FIG. 52 A micrograph of the spot weld nugget cross section of Alloy 8 (top) welded to IF steel

(bottom). FIG. 53 Microhardness as a function of the distance across the Alloy 8 to IF steel spot weld nugget.

FIG. 54 SEM images of microstructure in the Alloy 8 to IF steel weld nugget; a) in the base metal of Alloy 8, b) at the interface between the base metal of Alloy 8 and the fusion zone c) in the fusion zone, d) at the interface between the fusion zone and the heat affected zone in IF steel, e) in the heat affected zone in IF steel, f) at the interface between the heat affected zone and the base metal of IF steel, and g) in the base metal of IF steel. FIG. 55 A micrograph of the spot weld nugget cross section in the DP980 self-to-self spot welded sample.

FIG. 56 Microhardness as a function of the distance across the weld nugget in the DP980 self-to- self spot welded sample. FIG. 57 SEM images of microstructure in the DP980 self-to-self spot welded sample; a) in the base metal, b) at the interface between the base metal and the fusion zone, and c) in the fusion zone.

FIG. 58 A micrograph of the cross section of the Alloy 8 (top) to DP980 (bottom) spot weld nugget. FIG. 59 Microhardness as a function of the distance across the Alloy 8 to DP980 spot weld nugget.

FIG. 60 SEM images of microstructure in the Alloy 8 to DP980 weld nugget; a) in the base metal of Alloy 8, b) at the interface between the base metal of Alloy 8 and the fusion zone c) in the fusion zone, d) at the interface between the fusion zone and the heat affected zone in DP980, e) in the heat affected zone in DP980, f) at the interface between the heat affected zone and the base metal of DP980, and g) in the base metal of DP980.

FIG. 61 A micrograph of the cross section of the spot weld nugget in the TRIP 700 self-to-self welded sample.

FIG. 62 Microhardness as a function of the distance across the spot weld nugget in the TRIP 700 self-to-self welded sample.

FIG. 63 SEM images of microstructure in the TRIP 700 self-to-self welded sample; a) in the base metal b) at the interface between the base metal and the heat affected zone, c) in the heat affected zone, d) at the interface between the heat affected zone and the fusion zone, and e) in the fusion zone. FIG. 64 Micrograph of the cross section of the Alloy 8 (top) to TRIP 700 (bottom) spot weld nugget.

FIG. 65 Microhardness as a function of the distance across the Alloy 8 to TRIP 700 spot weld nugget. FIG. 66 SEM images of micro structure in the Alloy 8 to TRIP 700 weld nugget; a) in the base metal of Alloy 8, b) at the interface between the base metal of Alloy 8 and the fusion zone c) in the fusion zone, d) at the interface between the fusion zone and the heat affected zone in TRIP 700, e) in the heat affected zone in TRP 700, f) at the interface between the heat affected zone and the base metal of TRIP 700, and g) in the base metal of TRIP 700.

FIG. 67 A nugget size as a function of the spot welding current for Alloy 8 sheet material in two conditions welded to coated IF steel.

FIG. 68 Images of the nugget cross section in the first sample of IF steel sheet welded between two sheets from Alloy 8 in the annealed condition with the nugget size of 4- t; a) General view and b) Enlarged view of the area marked by a box in a).

FIG. 69 Images of the nugget cross section in the second sample of IF steel sheet welded between two sheets from Alloy 8 in the annealed condition with the nugget size of 4- t; a) General view and b) Enlarged view of the area marked by a box in a).

FIG. 70 Images of the nugget cross section in the first sample of IF steel sheet welded between two sheets from Alloy 8 in the annealed condition with the nugget size of 5.5Vt; a) General view and b) Enlarged view of the area marked by a box in a).

FIG. 71 Images of the nugget cross section in the second sample of IF steel sheet welded between two sheets from Alloy 8 in the annealed condition with the nugget size of 5.5Vt; a) General view and b) Enlarged view of the area marked by a box in a).

FIG. 72 Images of the nugget cross section in the first sample of IF steel sheet welded between two sheets from Alloy 8 in the hardened condition with the nugget size of 4 t; a) General view, b) Enlarged view of the area marked by a box in a).

FIG. 73 Images of the nugget cross section in the second sample of IF steel sheet welded between two sheets from Alloy 8 in the hardened condition with the nugget size of 4-Vt; a) General view and b) Enlarged view of the area marked by a box in a). Images of the nugget cross section in the first sample of IF steel sheet welded between two sheets from Alloy 8 in the hardened condition with the nugget size of 5.5 t; a) General view and b) Enlarged view of the area marked by a box in a).

Images of the nugget cross section in the second sample of IF steel sheet welded between two sheets from Alloy 8 in the hardened condition with the nugget size of 5.5 t; a) General view and b) Enlarged view of the area marked by a box in a).

Detailed Description

Alloys herein can be produced in a sheet form by different methods of continuous casting including but not limited to belt casting, thin strip / twin roll casting, thin slab casting, and thick slab casting with achievement of advanced property combinations by subsequent post-processing. After processing into a sheet form as a hot band or cold rolled sheet with or without annealing with thickness up to 5.0 mm, preferably in the range of 0.1 mm to 5.0 mm, the alloys herein have a total elongation 10.0 to 75.0 , a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa, and a Vickers hardness in a range from 150 to 650 HV. The alloys are also such that they have a Tm from 1250 °C to 1650 °C and a hardness value (HI) from 150 HV to 650 HV.

Welding Without Formation Of Deleterious Heat Affected Zone (HAZ)

FIG. 2 summarizes the welding of alloys herein to themselves involving material melting and re-solidification with the identified retention of hardness values. In Step 1 in FIG. 2, the starting condition is to supply a metal alloy. This metal alloy comprises at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu, or C. The alloy chemistry is melted, cooled at a rate of < 250 K/s, and solidified to a thickness of 25 mm and up to 500 mm. The casting process can be done in a wide variety of processes including ingot casting, bloom casting, continuous casting, thin slab casting, thick slab casting, belt casting etc. Preferred methods would be continuous casting in sheet form by thin slab casting or thick slab casting.

To produce alloys herein in a sheet form, the cast processes can vary widely depending on specific manufacturing routes and specific targeted goals. As an example, consider thick slab casting as one process route to get to sheet product. The alloy would be cast going through a water cooled mold typically in a thickness range of 150 to 350 mm in thickness that typically processed through a roughing mill hot roller into a transfer bar slab of 15 to 150 mm in thickness and through the finishing mill into a hot band with thickness of 1.5 to 5.0 mm. Another example would be to preferably process the cast material through a thin slab casting process. In this case, after casting typically forms 25 to 150 mm in thickness by going through a water cooled mold, the newly formed slab goes directly to hot rolling without cooling down and the strip is rolled into hot band coils with typical thickness from 1.5 to 5.0 mm in thickness. Note that ingot casting would be similar to the examples above but higher thickness might be cast typically from 200 to 500 mm thick followed by hot rolling using roughing mills such as Steckel mills where the ingot can be continuously reduced in thickness followed by final rolling through finishing hot rolling mills. Step 2 in FIG. 2 corresponds to sheet production from alloys herein with thickness up to 5.0 mm, preferably 0.1 mm to 5.0 mm. The processing of the cast material in Step 1 into one or a plurality of sheet forms can be preferably done by hot rolling forming a hot band. Produced hot band can be further processed towards smaller gauges by cold rolling that can be applied at various reductions per pass, variable number of passes and in different mills including tandem mills, Z-mills, and reversing mills. Preferably cold rolled thickness would be 0.5 mm to 5.0 mm thick. Preferably, the cold rolled material is annealed to restore the ductility lost from the cold rolling process either partially or completely. Preferably, sheet material from alloys herein, at a thickness of up to 5.0 mm, or preferably has a total elongation 10.0 to 75.0 %, yield strength 250 to 1200 MPa, tensile strength 700 to 1700 MPa, and Vickers hardness (HI) ranging from 150 to 650 HV. Alloys herein in a sheet form from Step 2 are welded and joined self-to-self by heating to a temperature Tl that is above the Tm of the alloy with formation of the fusion zone. Tl may preferably have a value of > 1250 °C and less than 2500 °C. The sheet material adjacent to the fusion zone is exposed to a temperature T2 which is less than Tm (Step 3, FIG. 2) which defines the Heat Affected Zone (HAZ). Reference to welding self-to-self should be understood as welding and joining two portions of the same identified alloy together (i.e. a metal alloy comprising at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu or C and exhibiting a total elongation 10.0 to 75.0 %, a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa). Accordingly, self-to-self may include welding one portion of an alloy sheet to another portion of the same sheet, or welding two alloy sheets having the aforementioned characteristics. In addition, the HAZ is therefore reference to that portion of sheet material which experiences a temperature rise T2 up to but not including the Tm of the alloy. Such temperature rise T2 in the HAZ can be > 400 °C and less than the melting temperature Tm of the alloy. The alloy in the HAZ upon cooling is now still capable of indicating a hardness value H2 that is within +/- 100 HV of the alloy's original hardness HI. Step 4, FIG. 2). H2 itself may preferably have a value from 50 HV to 750 HV. Case Examples 1 through 4 herein show the control of the hardness herein (i.e. H2 = HI +/-

100 HV after resistance spot welding involving alloy melting, fusion zone formation and temperature exposure of the material adjacent to fusion zone. Without being bound by any particular theory, this is believed to be due to the chemistry and phase stability of the alloys herein, which result in microstructures where austenite is the dominant phase (i.e. > 50 volume ) in the initial sheet material and also the dominant phase (i.e. > 50 volume %) in the weld fusion zone and HAZ.

FIG. 3 summarizes the welding of the alloys herein to other steels involving material melting and re-solidification. Step 1 and Step 2 are identical to that described above in relation to FIG. 2. The sheet is first formed with thickness of up to 5.0 mm, more preferably 0.1 mm to 5.0 mm, and having a total elongation 10.0 to 75.0 %, yield strength 250 to 1200 MPa, tensile strength 700 to 1700 MPa, and Vickers hardness HI ranging from 150 to 650 HV. The alloys in sheet form from Step 2 (FIG. 3) are then joined to other steels by heating to a temperature above Tm with formation of fusion zone. The sheet material adjacent to the fusion zone is exposed to a temperature T2 which is less than Tm (Step 3, FIG. 3) which again defines the Heat Affected Zone (HAZ). Reference to other steels should be understood as welding and joining the sheet material to a metal alloy that does not comprise a metal alloy comprising at least 70 atomic % iron and at least four or more elements selected from Si, Mn, Cr, Ni, Cu or C and exhibiting a total elongation 10.0 to 75.0 %, a yield strength 250 to 1200 MPa, a tensile strength 700 to 1700 MPa. As above, the HAZ is therefore reference to that portion of sheet material which experiences a temperature rise T2 up to but not including the Tm of the alloy. Such temperature rise T2 in the HAZ is > 400 °C and less than the melting temperature Tm of the alloy. Preferably T2 has a value of < 400 °C and <1250 °C. The alloy in the HAZ upon cooling is now still capable of indicating a hardness value H3 that is within +/- 120 HV of the alloy's original hardness HI. HI is again contemplated to preferably fall in the range of 150 HV to 650 HV and H3 is contemplated to have a value from 25 HV to 775 HV.

Case Examples 5 through 7 show such control of the hardness herein (i.e. H3 = HI +/- 125 HV. when the alloys are welded. Without being bound by any particular theory, it is well known that diffusivity increases as a function of temperature and is even higher in the liquid phase. Thus, during welding, diffusion is likely to occur in the weld HAZ and weld fusion zone. In conventional steels, this may result in the formation of brittle phases which are often harder creating high thickness HAZ which may be revealed by microhardness traverses. However, in the alloys herein, the austenite stability achieved means that during the weld process, austenite remains the dominant phase.

Welding Without Formation Of Deleterious Liquid Metal Embrittlement (LME)

The alloys herein based on LME welding trials, indicate improved resistance to LME crack formation (Case Example 8). The welding of the alloys herein with resistance to LME are illustrated in FIG. 4. Step 1 and Step 2 are similar to that described above in relation to FIG. 2 and FIG. 3. Once the sheet is formed with thickness LI (up to 5.0 mm or more preferably 0.1 mm to 5.0 mm) having a total elongation 10.0 to 75.0 %, yield strength 250 to 1200 MPa, and tensile strength 700 to 1700 MPa, a zinc containing coating can be applied. The coating may be preferably applied to the alloy sheet herein by galv annealing, galvanizing, metallizing, or electrogalvanizing forming a coated sheet (Step 3, FIG. 4). The zinc containing coating may have a thickness of 1.0 μιη to 50.0 μιη and contain 50% by weight or more of Zn. The coated sheets from alloys herein with one or both coated surfaces can then be welded and joined self-to-self or to other steels with zinc containing coatings or uncoated surfaces by heating to a temperature above Tm with formation of fusion zone (Step 4, FIG. 4) followed by cooling to form a weld which: (a) is crack free; or (b) contains one or more cracks with the depth of the largest crack at L2, which is < 15% of sheet thickness LI (Step 5, FIG. 4). L2 itself may preferably have a value of 75 μηι to 1500 μιη.

As liquid zinc is formed during welding, it penetrates into the base metal to ultimately cause LME cracking. However, LME welding results indicate that only relatively shallow penetration of zinc is found when welding the alloys herein. The depth of penetration of the crack is typically found to be less than 15% of the base metal thickness adjacent the weld. Without being bound by any particular theory this relatively low penetration may be a consequence of the relatively fine grain size (< 10 μιη) of the alloys herein which resist coarsening in the HAZ leading to reduced diffusivity pathways and suppressing a liquid zinc penetration into the base metal. Furthermore, after penetration of liquid zinc occurs in the grain boundaries, LME cracking may occur due to thermal expansion and contraction. There are two main components to this which both create localized stresses and can contribute to cracking. The first component of this is the thermal expansion and contraction due to changes in temperature only. This thermal factor is present in all steels including the alloys herein with variations due to their specific thermal expansion coefficients resulting from specific chemistries. The other factor creating localized stresses is the formation of new phases. In conventional steels, which are generally ferritic, increase in temperature will result in the formation of the high temperature austenite phase. Then during cooling, since the cooling rate in the weld zone is very rapid (> 10 ⁴ K/s), the austenite transforms to martensite. Martensite formed during cooling is a brittle phase which can lead to failure of the weld independent of LME. More importantly, the austenite (i.e. face centered cubic) to martensite (i.e. body centered tetragonal) phase transformation creates additional residual stresses due to the localized volume change as a result of phase transformation, which might be in the range of 5 to 10% depending on the specific steel chemistry. This volume change results in additional residual stress which when combined with the residual stress from the temperature gradient can then initiate crack formation and propagation in the already zinc penetrated weakened grain boundary regions. In the alloys herein, the austenite phase is relatively stable in a wide range of conditions and during solidification, even in the rapidly solidified region of a weld, martensite phase and alpha formation is either avoided or present at sufficiently small amounts, e.g. the level the martensite phase and/or alpha iron (ferrite iron) is < 10.0%, more preferably < 7.5 %, or < 5.0%, or < 2.5% or < 1.0%. Thus, this deleterious contribution to residual stresses is reduced and the LME cracking effect is minimized.

Cracks once formed will often propagate due to the concentration of stresses at the crack tip. Whether a crack propagates or not, it will depend on the plastic zone in front of the crack tip which blunts the crack tip when the stress is below that needed for crack propagation. Due to high ductility found in the alloys herein, as reflected by the elongation falling in the range of 5.0 to 80.0 %, it is believed that the plastic zone in front of the crack tip is very favorable to minimize propagation of LME cracks if they do form. This is consistent with the observations that LME in the alloys herein is limited and even when a crack does form its depth is less than 15% of the base metal thickness. This level of maximum crack propagation is also contemplated to be sufficient to provide high integrity spot welds for commercial services.

Thus, welds are shown to be achieved in the alloys herein without deleterious HAZ when welded self-to-self or to other steels and with relatively high resistance to LME in a case of welding of coated sheet materials in a presence of Zn. Welding can be done by various methods including but not limited to resistance spot welding, resistance seam welding, upset welding, laser beam welding, electron beam welding, etc.

Main Body The chemical composition of the alloys herein is shown in Table 1 which provides the preferred atomic ratios utilized.

Table 1 Chemical Composition of Alloys (Atomic %)

As can be seen from the Table 1, the alloys herein are iron based metal alloys, having greater than 70 at.% Fe. In addition, it can be appreciated that the alloys herein are such that they comprise Fe and at least four or more, or five or more or all six elements selected from Si, Mn, Cr, Ni, Cu, or C. Most preferably, the alloys herein are such that they comprise, consist essentially of, or consist of Fe at a level of 70 at.% or greater along with Si, Mn, Cr, Ni, Cu, and C, wherein the level of impurities of all other elements is in the range from 0 to 5000 ppm.

For example, in the case of the alloys containing Fe at a level of greater than 70 at.%, and four elements selected from Si, Mn, Cr, Ni, Cu, or C, the selected amounts of the four elements from Si, Mn, Cr, Ni, Cu, or C are such that the at.% of Fe and the selected elements adds up to 100 at .%, subject to the level of impurities noted above and the maximum amounts of the elements identified. The same analysis would apply if five elements are selected from Si, Mn, Cr, Ni, Cu, or C or if all six of such elements are selected. When an element is selected, the minimum amount is contemplated to be in at.% as follows; Si 0.7, Mn 0.8, Cr, 0.4, Ni 0.4, Cu 0.4, C 0.4. When an element is not present, the level would be zero atomic percent. Accordingly, in a given alloy, the levels of elements other than Fe may be as follows in at.%: Si (0-6.5); Mn (0-16.0), Cr. (0-8.8), Ni (0-11.6), Cu (0-2.8) and C (0-3.8). The alloys herein were processed into a laboratory sheet by processing of laboratory slabs. Laboratory alloy processing is developed to mimic closely the commercial sheet production by continuous casting and include hot rolling and cold rolling. Annealing might be applied depending on targeted properties. Produced sheet can be used in hot rolled (hot band), cold rolled, annealed or partially annealed states. Laboratory Slab Casting

Alloys were weighed out into 3,000 to 3,500 gram charges according to the atomic ratios in Table 1 using commercially available ferroadditive powders and a base steel feedstock with known chemistry. As eluded to above, impurities can be present at various levels depending on the feedstock used. Impurity elements would commonly include the following elements; Al, Co, N, P, Ti, Mo, W, Ga, Ge, Sb, Nb, Zr, O, Sn, Ca, B and S which if present would be in the range from 0 to 5000 ppm (parts per million) with preferred ranges of 0 to 500 ppm.

Charges were loaded into a zirconia coated silica crucible which was placed into an Indutherm VTC800V vacuum tilt casting machine. The machine then evacuated the casting and melting chambers and flushed with argon to atmospheric pressure twice prior to casting to prevent oxidation of the melt. The melt was heated with a 14 kHz RF induction coil until fully molten, approximately from 5 to 7 minutes depending on the alloy composition and charge mass. After the last solids were observed to melt it was allowed to heat for an additional 30 to 45 seconds to provide superheat and ensure melt homogeneity. The casting machine then evacuated the chamber and tilted the crucible and poured the melt into a water cooled copper die. The melt was allowed to cool under vacuum for 200 seconds before the chamber was filled with argon to atmospheric pressure.

Laboratory casting corresponds to Step 1 in FIG. 2, FIG. 3 and FIG. 4 provides slabs with thickness of 50 mm. Depending on equipment capability, slab thickness in Step 1 can vary from 25 to 500 mm.

Density Measurements

The density of the alloys was measured on arc-melt ingots using the Archimedes method in a specially constructed balance allowing weighing in both air and distilled water. The density of each alloy is tabulated in Table 2 and was found to be in a range from 7.77 to 8.01 g/cm ³ . Experimental results have revealed that the accuracy of this technique is +0.01 g/cm ³ .

Table 2 Density of Alloys

Thermal Analysis

A sample of between 50 and 150 mg from each alloy herein was taken in the as-cast condition. Differential Scanning Calorimetry (DSC) measurements were taken using a Netzsch Pegasus 404 DSC through all four stages of the experiment, and this data was used to determine the solidus and liquidus temperatures of each alloy. This sample was heated to an initial ramp temperature between 900°C and 1300°C depending on alloy chemistry, at a rate of 40°C/min. Temperature was then increased at 10°C/min to a max temperature between 1425°C and 1500°C (maximum temperature limit for the used DSC equipment) depending on alloy chemistry. Once this maximum temperature was achieved, the sample was cooled at a rate of 10°C/min back to the initial ramp temperature before being reheated at 10°C/min to the maximum temperature. Solidus temperatures varies from 1294 to 1472°C (Table 3), with liquidus temperatures from 1432 to 1500°C. Liquidus-solidus gap is in a range from 26 to 138°C. Thermal analysis provides information on melting behavior of the alloys herein that varies depending on alloy chemistry. Note that once the solidus temperature is exceeded, the liquid is present and this is the melting temperature. It is therefore contemplated that the alloys herein will have a Tm value in the range of 1250 °C to 1650 °C.

Table 3 Thermal Analysis of Selected Alloys

Solidus Liquidus Melting Gap

Alloy

(°C) (°C) (°C)

Alloy 12 1471 1498 27

Alloy 13 1464 1490 26

Alloy 14 1419 1458 39

Alloy 15 1392 1450 58

Alloy 16 1460 1489 29

Alloy 17 1472 1500 28

Laboratory Hot Rolling

The alloys herein were preferably processed into a laboratory hot band by hot rolling of laboratory slabs at high temperatures. Laboratory alloy processing is developed to simulate the hot band production from slabs produced by continuous casting. Industrial hot rolling is performed by heating a slab in a tunnel furnace to a target temperature, then passing it through either a reversing mill or a multi-stand mill or a combination of both to reach the target gauge. During rolling on either mill type, the temperature of the slab is steadily decreasing due to heat loss to the air and to the work rolls so the final hot band is formed at a reduced temperature. This is simulated in the laboratory by heating in a tunnel furnace to between 1100°C and 1250°C, then hot rolling. The laboratory mill is slower than industrial mills causing greater loss of heat during each hot rolling pass so the slab is reheated for 4 minutes between passes to reduce the drop in temperature, the final temperature at target gauge when exiting the laboratory mill commonly is in the range from 800°C to 1000°C, depending on furnace temperature and final thickness.

Prior to hot rolling, laboratory slabs were preheated in a Lucifer EHS3GT-B 18 furnace. The furnace set point varies between 1100°C to 1250°C, depending on alloy melting point and point in the hot rolling process, with the initial temperatures set higher to facilitate higher reductions, and later temperatures set lower to minimize surface oxidation on the hot band. The slabs were allowed to soak for 40 minutes prior to hot rolling to ensure they reach the target temperature and then pushed out of the tunnel furnace into a Fenn Model 061 2 high rolling mill. The 50 mm casts are hot rolled for 5 to 10 passes though the mill before being allowed to air cool. Final thickness ranges after hot rolling are up to 5.0 mm, preferably 0.1 mm to 5.0 mm, and even more preferably from 1.8 mm to 5.0 mm, with variable reduction per pass ranging from 20% to 50%. The relative amount of magnetic content in the hot band from alloys herein was measured by Feritscope as shown in Table 4. The magnetic phases volume percent ranging from 0.3 to 74.7 Fe% depending on alloy chemistry.

Table 4 Feritscope Measurement Data in Hot Band from Alloys Herein

Tensile properties were measured on an Instron mechanical testing frame (Model 3369), utilizing Instron' s Bluehill control and analysis software. All tests were run at ambient temperature in displacement control at a constant displacement rate of 0.036 mm/s. Tensile properties of the alloys in the hot rolled condition are listed in Table 5. The ultimate tensile strength of the alloys herein varies from 912 to 1687 MPa with tensile elongation from 15.3 to 65.9%. The yield strength is in a range from 284 to 712 MPa. Hardness values are in a range from 13.3 to 47.5 HRC (205 to 478 HV). Note that the Table 5 properties correspond to Step 2 in FIG. 2, FIG. 3 and FIG. 4. Further processing of the hot band can additionally occur through cold rolling and annealing as shown below.

Table 5 Tensile Properties of Hot Band from Alloys Herein

Ultimate Yield

Tensile

Alloy Tensile Strength Average Hardness

Elongation

Strength (0.2% offset)

(%) (MPa) (MPa) (HRC) (HV*)

62.8 1156 464

61.8 1141 463

63.6 1142 493

47.9 1374 330

Alloy 6 48.8 1336 317 20.8 242

41.5 1362 321

53.4 1248 307

Alloy 7 51.4 1248 284 17.7 227

49.2 1253 310

57.6 1175 313

Alloy 8 58.6 1209 294 17.1 224

56.6 1167 307

65.9 963 515

58.7 954 485

Alloy 9 24.2 261

56.6 963 529

62.1 970 545

61.6 1079 340

Alloy 10 16.2 219

61.6 1082 320

55.9 912 481

57.6 927 493

Alloy 11 19.5 236

54.7 912 470

58.3 928 487

45.0 1150 289

Alloy 12 14.7 212

44.2 1152 296 Ultimate Yield

Tensile

Alloy Tensile Strength Average Hardness

Elongation

Strength (0.2% offset)

(%) (MPa) (MPa) (HRC) (HV*)

45.4 1147 302

42.8 1149 284

45.8 1014 332

44.8 1006 321

Alloy 13 13.3 205

48.0 1029 326

47.1 1005 344

42.8 1215 357

42.1 1231 347

Alloy 14 18.4 230

42.5 1202 352

42.5 1222 351

46.2 1107 397

50.4 1099 376

Alloy 15 26.2 273

46.7 1104 386

43.9 1115 384

25.8 1480 480

23.2 1383 446

Alloy 16 18.3 230

30.3 1492 468

31.8 1534 485

15.6 1649 676

16.2 1679 693

Alloy 17 47.5 478

15.3 1682 712

15.3 1687 690

Converted from Rockwell C hardness Laboratory Cold Rolling

Hot band material was media blasted prior to cold rolling to remove surface oxides which could become embedded during the rolling process. The resultant cleaned sheet material was rolled using a Fenn Model 061 2 high rolling mill down to 1.2 mm thickness using multiple passes. Reductions were in a range ranged from 10% to 40% until the final gauge thickness was achieved. If the cold rolled sheets were not at the desired thickness an annealing is preferably applied to restore ductility and lower material's strength in order to perform additional cold rolling. This anneal was conducted with a hydrogen anneal to reduce oxidation; samples were loaded at room temperature, heated to 850°C at a rate of 40°C/minute, allowed to stay at temperature for 15 minutes then the furnace was shut off and samples were allowed to cool to room temperature over -60 minutes before being cold rolled again until the final gauge thickness was achieved.

Laboratory Annealing

Once the final gauge thickness of 1.2 mm was reached, tensile samples were cut from the laboratory sheet by wire-EDM. The samples were annealed under conditions intended to simulate the thermal exposure expected during an industrial continuous annealing process representing final treatment of sheet material in Step 2 in FIG. 2, FIG. 3 and FIG. 4. Samples were wrapped in stainless steel foil to prevent oxidation and loaded into a preheated furnace at 850°C. Samples were left in the furnace for 10 minutes while the furnace purged with argon before being removed and allowed to air cool. The relative magnetic phase content in sheet from alloys herein after cold rolling and annealing was measured by Feritscope as shown in Table 6. The magnetic phases volume percent ranging from 0.3 to 68.5 Fe% depending on alloy chemistry.

Table 6 Feritscope Measurement Data in Sheet from Alloys Herein after Annealing

Magnetic Phases

Alloy Volume Percent

[Fe%]

Alloy 1 0.9

Alloy 2 0.6

Alloy 3 0.5 Magnetic Phases

Alloy Volume Percent

[Fe%]

Alloy 4 1.2

Alloy 5 0.8

Alloy 6 0.6

Alloy 7 1.1

Alloy 8 1.1

Alloy 9 0.3

Alloy 10 1.1

Alloy 11 1.1

Alloy 12 2.0

Alloy 13 2.1

Alloy 14 1.6

Alloy 15 1.7

Alloy 16 22.8

Alloy 17 68.5

Tensile properties were measured on an Instron mechanical testing frame (Model 3369), utilizing Instron' s Bluehill control and analysis software. All tests were run at ambient temperature in displacement control at a constant displacement rate of 0.036 mm/s. Tensile properties of 1.2 mm thick sheet from alloys herein after annealing are listed in Table 7. The ultimate tensile strength values of the annealed sheet from alloys herein are in a range from 759 to 1683 MPa; yield strength varies from 273 to 720 MPa and tensile elongation is recorded in the range from 13.8 to 74.3%. Hardness values are in a range from 3.1 to 47.9 HRC (154 to 483 HV). Anticipated properties are listed in Claim lb. Note that the Table 7 properties correspond to Step 2 in FIG. 2, FIG. 3 and FIG. 4.

Table 7 Tensile Properties of 1.2 mm Thick Sheet from the Alloys Herein after Annealing Ultimate 0.2% Offset

Tensile

Alloy Tensile Yield Average Hardness

Elongation

Strength Strength

(%) (MPa) (MPa) (HRC) (HV*)

50.1 1175 483

Alloy 1 50.9 1161 472 20.3 240

50.8 1190 471

28.5 1021 416

25.6 954 412

Alloy 2 20.9 243

28.0 1033 415

28.1 1005 430

60.3 1134 499

58.2 1141 500

Alloy 3 21.9 248

60.4 1139 500

64.2 1138 490

72.9 1035 413

70.2 1016 407

Alloy 4 16.8 222

73.7 1056 429

74.3 1032 406

56.8 1165 386

67.5 1129 440

Alloy 5 14.4 210

58.5 1136 396

62.2 1137 389

15.6 759 379

17.9 888 420

Alloy 6 15.7 217

17.0 839 368

18.0 849 431

Alloy 7 55.7 1267 469 20.1 239 Ultimate 0.2% Offset

Tensile

Alloy Tensile Yield Average Hardness

Elongation

Strength Strength

(%) (MPa) (MPa) (HRC) (HV*)

52.0 1242 456

56.0 1248 470

57.7 1277 464

65.4 1162 491

59.4 1179 469

Alloy 8 19.7 237

61.8 1193 477

62.6 1172 531

64.7 993 484

66.1 997 491

Alloy 9 19.0 233

66.2 994 481

66.3 994 491

63.9 1102 463

63.5 1118 465

Alloy 10 65.3 1127 478 18.2 229

70.8 1108 475

62.6 1112 473

66.4 892 326

61.6 876 319

Alloy 11 3.1 154

64.2 889 322

67.5 886 321

42.5 1170 273

40.5 1164 295

Alloy 12 12.4 200

43.3 1164 283

41.9 1175 296 Ultimate 0.2% Offset

Tensile

Alloy Tensile Yield Average Hardness

Elongation

Strength Strength

(%) (MPa) (MPa) (HRC) (HV*)

49.5 987 388

48.7 988 381

Alloy 13 12.4 200

49.0 991 358

44.2 999 377

39.5 1196 366

39.6 1196 377

Alloy 14 14.7 212

38.4 1213 377

39.3 1187 355

51.1 1070 402

51.8 1073 405

Alloy 15 18.2 229

54.3 1060 381

57.9 1067 395

36.6 1659 292

31.0 1683 317

Alloy 16 8.0 178

34.7 1683 292

37.3 1655 286

13.8 1663 701

14.0 1657 675

Alloy 17 47.9 483

13.8 1641 713

14.0 1665 720

Converted from Rockwell C hardness

Based upon the data in Tables 5 and 7 and the tensile properties of Case Example 8, it is contemplated that the alloys disclosed herein may therefore have a hardness HI of 150 HV to 650 HV, a yield strength of 250 MPa to 1200 MPa, a tensile strength of 700 MPa to 1700 MPa and a total tensile elongation of 10.0 to 75.0%.

Laboratory Welding The laboratory produced 1.2 mm thick sheet material from alloys herein in cold rolled and annealed state with properties listed in Table 7 was joined self-to-self by melting and re- solidification process using spot welding method. Steel sheets were cleaned with a nylon mesh abrasive pad after heat treatment and prior to welding to reduce the quantity of surface oxide. H&H programmable spot welder with a P10 controller was used. A single pulse weld was used. The spot welding procedure started with the material being clamped for 1/6 of a second prior to welding. The welding time and power level were varied with the 5 parameter sets listed in Table 8. After welding, the sample was remained clamped for 1/6 of a second to cool. The electrode diameter was 0.125 inches and the clamping force was approximately 850 lbs. The result of the spot welding was the formation of weld nuggets schematically shown in FIG. 1. The melted and re-solidified area of the joint sheets formed a fusion zone. Sheet material adjacent to the fusion zone was affected by heat during welding forming a heat affected zone (HAZ).

Table 8 Weld Schedule

The welded samples were cut by EDM across the weld nuggets for micro structural and microhardness analysis. After micro structural examination, the spot welds formed using Weld Schedule #2 (Table 8) were selected for microhardness measurements. Microhardness measurements as a function of distance across the interface between the fusion zone and the base metal were made for each alloy herein. The load used for the microhardness measurements was 500 g. The results of the microhardness measurement as a function of distance are listed in Table 9 through Table 17 for alloys herein and plotted in FIG. 6 through FIG. 22. In cases when the HAZ is detectable by observation in the microscope, it marked correspondingly on the plots. The hardness difference between base metal and the fusion zone of the self-to-self welds of the alloys herein is summarized in Table 18. As shown by the avg hardness changes, the maximum hardness change in the heat affected zone was 76 HV compared to the value in the sheet before welding. As individual measurements can vary as shown, it is anticipated that the hardness change in the heat affected zone would be within (i.e. +/-) 100 HV from the base metal hardness for the self to self welding of the alloys here-in.

Table 9 Microhardness Across the Weld Nugget in Alloy 1 & Alloy 2

Table 10 Microhardness Across the Weld Nugget in Alloy 3 & Alloy 4

Table 11 Microhardness Across the Weld Nugget in Alloy 5 & Alloy 6 Area of the Alloy 5 Alloy 6

Weld Distance HV Distance HV

(mm) (kg/mm ² ) (mm) (kg/mm ² )

0.68 259 1.07 255

0.90 259 1.27 257

1.13 260 1.54 277

1.36 269 1.78 280

1.58 274 2.00 259

1.80 281 2.23 261

Base Metal 2.03 276 2.45 263

2.25 282 2.67 275

2.47 278 2.89 272

2.70 276

Table 12 Microhardness Across the Weld Nugget in Alloy 7 & Alloy 8

Area of the Alloy 7 Alloy 8

Weld Distance HV Distance HV

(mm) (kg/mm ² ) (mm) (kg/mm ² )

0 235

0.22 161

0.45 197

0.77 198

Fusion Zone

1.00 236 0 260

1.22 249 0.22 264

1.44 245 0.44 266

1.68 235 0.66 275

1.93 225 0.89 247

Base Metal 2.14 247 1.11 248

2.37 254 1.34 275 Area of the Alloy 7 Alloy 8

Weld Distance HV Distance HV

(mm) (kg/mm ² ) (mm) (kg/mm ² )

2.59 262 1.56 280

2.81 254 1.78 274

3.03 253 1.99 260

Table 13 Microhardness Across the Weld Nugget in Alloy 9 & Alloy 10

Table 14 Microhardness Across the Weld Nugget in Alloy 11 & Alloy 12

Area of the Alloy 11 Alloy 12

Weld Distance HV Distance HV

(mm) (kg/mm ² ) (mm) (kg/mm ² )

0.23 147 0.22 260

0.50 215 0.45 336

0.75 211 0.67 274

1.00 209 0.90 258

1.25 216 1.13 288

1.50 204 1.41 249

1.75 216 1.63 243

Base Metal 2.01 216 1.86 247

2.26 222 2.09 251

2.32 249

Table 15 Microhardness Across the Weld Nugget in Alloy 13 & Alloy 14

Area of the Alloy 13 Alloy 14

Weld Distance HV Distance HV

(mm) (kg/mm ² ) (mm) (kg/mm ² )

2.51 249 1.82 247

2.75 255 2.04 254

2.27 250

2.49 245

Table 16 Microhardness Across the Weld Nugget in Alloy 15 & Alloy 16

Table 17 Microhardness Across the Weld Nugget in Alloy 17

Table 18 A Summary on Microhardness of the Base Metal and the Heat Affected Zone Average Average Microhardness (HV)

Microhardness Microhardness (HV) of Base Metal of the Weld

Alloy (HV) Difference of Alloys (Table 7) (Tables 9 through 17)

(kg/mm ² ) (kg/mm ² ) (kg/mm ² )

Alloy 7 239 249 10

Alloy 8 237 264 27

Alloy 9 233 285 52

Alloy 10 229 268 39

Alloy 11 154 215 61

Alloy 12 200 248 48

Alloy 13 200 257 57

Alloy 14 212 248 36

Alloy 15 229 305 76

Alloy 16 178 223 45

Alloy 17 483 470 -13

Case Examples

Case Example # 1: Weld Lobe of Alloy 8 for Self- To-Self Resistance Spot Welding

Alloy 8 sheet with a thickness of -1.4 mm was used for welding trials. Chemical composition of the alloy is listed in Table 1. Sheet material for welding was used in the annealed condition and tested in tension for property evaluation. Ultimate tensile strength varied from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The Vickers hardness of the sheet material used for welding was converted from Rockwell C (HRC) hardness measurements with values from 186 to 247 HV and average value of 222 HV.

Sheet samples were sheared off in 610 mm increments. Fourteen sheared sheet samples were used for resistance spot welding trials. The spot welding system used for the study is schematically diagrammed in FIG. 5 utilizing the MFDC method. It consisted of a Miyachi MFDC IS A-500 inverter power supply with controller that provided power to the primary coil to a RoMan 9.0 V DC transformer. The secondary coil power from the transformer was reduced in voltage thus increasing the current in order to do the actual spot welding through B nose electrodes that were dressed with a face diameter of 5.5 mm. The weld current was measured using a Miyachi mm-326B weld checker system for feedback control. Sheet samples were joined self-to-self by single pulse spot welds.

The weld parameters used to determine the weld lobe are listed in Table 19. The weld lobe is defined as the spot welding window based on the spot welding process parameters of weld current and cycle time at fixed force. The welding window is the range of current at fixed cycle time and force between expulsion and minimum nugget size, which is considered to be optimal at 5.0 mm in diameter and on the high current side when expulsion occurs. Thus at any combination of weld parameters inside the weld lobe the result of spot welding should be a good weld nugget. The weld lobe of the Alloy 8 is shown in FIG. 23 and parameters determined at weld testing corresponding to marked points in FIG. 23 are listed in Table 20. The spot weld parameters of the Alloy 8 are determined to be in a range of parameters that are commonly used in industrial spot welding applications.

Cross section samples for microstructural evaluation were cut by EDM from the spot welded sheets mounted in epoxy. The samples were polished progressively with 9 μιη, 6 μιη, and 1 μιη diamond suspension solution then finally with 0.02 μιη silica solution. After polishing the cross section was etched with 2% Nital solution. Images of the spot weld nugget cross sections corresponding to the six points defining the weld lobe of the Alloy 8 (FIG. 23) are shown in FIG. 24 through FIG. 29. In each image, the fusion zone is clearly visible due to its difference with the Alloy 8 base metal structure.

Table 19 Spot Welding Parameters

Table 20 Weld Lobe Parameters

Microhardness measurements as a function of distance across the interface between the fusion zone and base metal were made on each weld lobe sample. Note, the measurements are done on one side of the weld nugget only since the welding was done self-to self. The load used for the microhardness measurements was 500 g. The results are listed in Table 21 and plotted in FIG. 30 through FIG. 35 for each sample welded at parameters corresponding to the six points defining the weld lobe of the Alloy 8 (FIG. 23). The measured microhardness of the base sheet material in the areas adjacent to the fusion zone varies from 244 to 292 HV with an average at 258 HV.

Three lap shear specimens were spot welded self-to-self from Alloy 8 sheet using the weld parameters corresponding to each of the six points defining the weld lobe of the alloy (FIG. 23) and then tested until rupture. A schematic illustration of the lap shear testing is shown in FIG. 36. The width of the sheet samples was 24 mm with a length of 125 mm. The shear area was 30 mm. The test results for the lap shear testing are listed in Table 22 with rupture force ranging from 6.8 kN to 13.5 kN.

Table 21 Microhardness Measurement Data Across Fusion Zone Interface With Base Metal

Table 22 Lap Shear Results

This Case Example demonstrates a weld lobe for sheet Alloy 8 with ultimate tensile strength higher than 1000 MPa (from 1141 to 1199 MPa) determined by using conventional spot welding technology. The weld lobe shows a range of welding parameters for joining Alloy 8 sheet self-to- self by resistance spot welding with good weld nuggets demonstrating high rupture force during lap shear testing. The microhardness measurements across the interface between the fusion zone and the base metal showed no evidence of deleterious HAZ with microhardness value in sheet material adjacent to fusion zone slightly higher (from 244 to 292 HV) than the average value for the sheet material used (222 HV). Case Example # 2: Single Pulse Self-to-Self Resistance Spot Welding of Alloy 8

Alloy 8 sheet with a thickness of -1.4 mm was used for welding trials. Chemical composition of the alloy is listed in Table 1. Sheet material for welding was used in the annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated at 222 HV.

Five lap shear specimens were joined by single pulse self-to-self spot welds with the parameters listed in Table 23 and then tested until rupture. A schematic illustration of the lap shear testing is shown in FIG. 36. The width of the sheet samples was 24 mm with a length of 125 mm. The shear area was 30 mm. The test results for the lap shear testing are listed in Table 24. The lap shear rupture force ranged from 14.6 kN to 15.6 kN.

Table 23 Spot Welding Parameters

Table 24 Lap Shear Testing Results

Cross section specimens of the weld nuggets were cut by EDM from the spot welded samples for microstructural evaluation, which were mounted in epoxy. The cross section samples were polished progressively with 9 μιη, 6 μιη and 1 μιη diamond suspension solution then finally with 0.02 μιη silica solution. After polishing the cross section was etched with 2% Nital solution. The cross section microstructure was examined in a Zeiss EVO MA- 10 scanning electron microscope.

A SEM image of the microstructure of the base metal of Alloy 8 is provided in FIG. 37 showing typical recrystallized structure with equiaxed austenite grains. FIG. 38 shows a SEM image of the microstructure at the interface between the fusion zone and the base metal of Alloy 8 with a gradual transition from columnar dendritic structure in the fusion zone to the Alloy 8 sheet microstructure. FIG. 39 shows a SEM image of the microstructure in the fusion zone of the weld nugget. The microstructure contains long columnar dendrites with periodic spaced dendritic branches. Microhardness measurements were made on the self-to-self welded sample from Alloy 8 sheet across the weld nugget starting from the base metal of Alloy 8 through the fusion zone and back to the base metal. The results are plotted as a function of distance across the weld nugget in FIG. 40 and listed in Table 25. The measured microhardness of the base metal (Alloy 8 sheet) in the areas adjacent to the fusion zone varies from 243 to 260 HV with an average at 253 HV.

Table 25 Microhardness Measurement Data Across the Weld Nugget after Singe Pulse Self-to-Self Spot Welding of Alloy 8 Sheet

Area of Distance HV

the Weld (mm) (kg/mm ² )

-1.02 236

-0.50 253

0.00 213

0.52 245

1.02 259

1.53 261

2.05 247

2.57 270

3.08 260

Base Metal 3.60 259

4.10 254

This Case Example demonstrates that in a case of single pulse self-to-self spot welding of alloys herein, no evidence of deleterious HAZ was found with microhardness value in sheet material adjacent to the fusion zone slightly higher (from 243 to 260 HV) than the average value for the sheet material used (222 HV).

Case Example # 3: Double Pulse Self- to-Self Resistance Spot Welding of Alloy 8

Alloy 8 sheet with a thickness of -1.4 mm was used for welding trials. Chemical composition of the alloy is listed in Table 1. Sheet material for welding was used in the annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated at 222 HV.

Five lap shear specimens were joined by double pulse self-to-self spot welds with the parameters listed in Table 26 and then tested until rupture. A schematic illustration of the lap shear testing is shown in FIG. 36. The width of the sheet samples was 24 mm with a length of 125 mm. The shear area was 30 mm. The test results for the lap shear testing are listed in Table 27. The lap shear rupture load ranged from 14.4 kN to 15.4 kN.

Table 26 Spot Welding Parameters (Repeated Two Times)

Table 27 Lap Shear Testing Results

Cross section specimens of the weld nuggets were cut by EDM from the spot welded samples for micro structural evaluation, which were mounted in epoxy. The cross section samples were polished progressively with 9 μιιι, 6 μιη and 1 μηι diamond suspension solution then finally with 0.02 μιη silica solution. After polishing the cross section was etched with 2% Nital solution. The cross section micro structure was examined in a Zeiss EVO MA- 10 scanning electron microscope.

A SEM image of the microstructure of the base metal of Alloy 8 is provided in FIG. 41 showing typical recrystallized structure with equiaxed austenite grains. FIG. 42 shows a SEM image of the micro structure at the interface between the fusion zone and the base metal of Alloy 8. There is a gradual transition from columnar dendritic structure in the fusion zone of the weld nugget to the Alloy 8 sheet micro structure. A SEM image of the micro structure in the fusion zone is shown in FIG. 43. The microstructure contains long columnar dendrites with periodic spaced dendritic branches. Microhardness measurements were made on the self-to-self welded sample across the weld nugget starting from the base metal of Alloy 8 through the fusion zone and back to the base metal. The results are plotted as a function of distance across the weld nugget in FIG. 44 and listed in Table 28. The measured microhardness of the base metal (Alloy 8 sheet) in the areas adjacent to the fusion zone varies from 230 to 284 HV with an average at 256 HV.

Table 28 Microhardness Measurement Data Across the Weld Nugget after Double Pulse Self-to-Self Spot Welding of Alloy 8 Sheet

Area of Distance HV

the Weld (mm) (kg/mm ² )

2.59 248

3.10 230

4.14 252

4.66 264

This Case Example demonstrates that in a case of double pulse self-to-self spot welding of alloys herein, no evidence of deleterious HAZ was found with microhardness value in sheet material adjacent to fusion zone slightly higher (from 230 to 284 HV) than the average value for the sheet material used (222 HV).

Case Example # 4: Triple Pulse Resistance Spot Welding of Alloy 8

Alloy 8 sheet with a thickness of -1.4 mm was used for welding trials. Chemical composition of the alloy is listed in Table 1. Sheet material for welding was used in the annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated to be 222 HV.

Five lap shear specimens were joined by triple pulse self-to-self spot welding with the parameters listed in Table 29 and then tested until rupture. A schematic illustration of the lap shear testing is shown in FIG. 36. The width of the sheet samples was 24 mm with a length of 125 mm.

The shear area was 30 mm. The test results for the lap shear testing are listed in Table 30. The lap shear rupture load ranged from 15.7 kN to 16.5 kN.

Table 29 Spot Welding Parameters (Repeated Three Times)

Table 30 Lap Shear Testing Results

Cross section specimens of the weld nuggets were cut by EDM from the spot welded samples for microstructural evaluation, which were mounted in epoxy. The cross section samples were polished progressively with 9 μιη, 6 μιη and 1 μιη diamond suspension solution then finally with 0.02 μιη silica solution. After polishing the cross section was etched with 2% Nital solution. The cross section microstructure was examined in a Zeiss EVO MA- 10 scanning electron microscope.

FIG. 45 presents a SEM image of the microstructure of the base metal of Alloy 8 sheet showing typical recrystallized structure with equiaxed austenite grains. A SEM image of the microstructure at the interface between the base metal and the fusion zone of the weld nugget is shown in FIG. 46. There is a gradual transition from columnar dendritic structure of the fusion zone to the Alloy 8 sheet microstructure. A SEM image of the dendritic microstructure in the fusion zone is shown in FIG. 47. The microstructure contains long columnar dendrites with periodic spaced dendritic branches similar to that observed in cases of single and double pulse spot welding. Microhardness measurements were made on the self-to-self welded sample across the weld nugget starting from the base metal of Alloy 8 through the fusion zone and back to the base metal. The results are plotted as a function of distance across the weld nugget in FIG. 48 and listed in Table 31. The measured microhardness of the base metal (Alloy 8 sheet) in the areas adjacent to the fusion zone varies from 258 to 276 HV with an average at 269 HV.

Table 31 Microhardness Measurement Data Across the Weld Nugget After Triple Pulse Self-to-Self Spot Welding of Alloy 8 Sheet

This Case Example demonstrates that in a case of triple pulse self-to-self spot welding of the alloys herein, no evidence of deleterious HAZ was found with microhardness value in sheet material adjacent to fusion zone slightly higher (from 258 to 276 HV) than the average value for the sheet material used (222 HV). Case Example # 5: Resistance Spot Welding - Alloy 8 to IF Steel

Alloy 8 sheet with a thickness of -1.4 mm and commercial sheet from IF steel were used for welding trials. Alloy 8 sheet for welding was used in the annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated to be 222 HV.

The spot welding system used for the study is schematically diagrammed in FIG. 5 utilizing the MFDC method. It consisted of a Miyachi MFDC ISA-500 inverter power supply with controller that provided power to the primary coil to a RoMan 9.0 V DC transformer. The secondary coil power from the transformer was reduced in voltage thus increasing the current in order to do the actual spot welding through B nose electrodes that were dressed with a face diameter of 5.5 mm. The weld current was measured using a Miyachi mm-326B weld checker system for feedback control. Sheet samples were joined by single pulse spot welds.

An optimized self-to-self spot welding of IF steel was performed and analyzed. The weld parameters used to form the IF steel to IF steel spot weld join are listed in Table 32. A micrograph of the spot weld is shown in FIG. 49. Microhardness measurements were made across the weld nugget starting from the HAZ through the fusion zone and HAZ on another side of the nugget to the base metal of IF steel. The results are listed in Table 33 and plotted in FIG. 50. The microhardness measurements showed that the fusion zone of the weld had higher hardness than the base metal with its gradual decrease in HAZ down to the values of microhardness for utilized IF steel sheet. Examination of the cross section of the weld nugget in a Zeiss MA- 10 Scanning Electron Microscope (SEM) revealed distinct micro structural zones that are identified in the microhardness plot in FIG. 50. The base metal microstructure of IF steel is shown in FIG. 51a. The interface of the base metal with heat affected zone is shown in FIG. 51b. The microstructure in the heat affected zone is shown in FIG. 51c. FIG. 5 Id shows the interface between the heat affected zone and the fusion zone. The fusion zone microstructure is shown in FIG. 51e. Table 32 IF Steel Self-to-Self Spot Welding Parameters

Table 33 Microhardness Measurement Data Across the Weld Nugget

After Self-to-Self Spot Welding of IF Steel

The weld parameters used to form the Alloy 8 to IF steel spot weld are listed in Table 34. A micrograph of the spot weld is shown in FIG. 52. Microhardness measurements were made across the weld nugget from the base metal of Alloy 8 through the fusion zone to the base metal of IF steel. The results are listed in Table 35 and plotted in FIG. 53. Structural analysis was performed using a Zeiss MA- 10 Scanning Electron Microscope (SEM). The microstructure of the Alloy 8 base metal is shown in FIG. 54a. The base metal of Alloy 8 interface with the fusion zone of the weld nugget is shown in FIG. 54b. There is a gradual transition of the fusion zone microstructure to Alloy 8 base metal microstructure with no micro structural evidence of the HAZ. The fusion zone microstructure of the weld is shown in FIG. 54c. The fusion zone interface with the heat affected zone in the IF steel is shown in FIG. 54d. The heat affected zone microstructure in the IF steel is shown in FIG. 54e. The heat affected zone interface with the base metal of IF steel is shown in FIG. 54f . The IF steel base metal microstructure is shown in FIG. 54g, which is significantly different from that in the HAZ in FIG. 54e.

Table 34 Alloy 8 to IF Steel Spot Welding Parameters

Table 35 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 8 to IF Steel

Alloy 8 to IF Steel

Area of the Weld Distance HV

(mm) (kg/mm ² )

-1.27 335

-1.02 319

-0.76 307

-0.51 313

-0.25 327

0.00 367

0.51 369

0.76 285

HAZ

1.02 281

1.27 274

1.52 248

1.78 230

Base Metal 2.03 178

(IF Steel) 2.28 143

This Case Example shows that Alloy 8 can be spot welded to commercially produced IF steel using conventional spot welding technology. The resulting spot weld did not show a deleterious heat affected zone at the Alloy 8 interface with the fusion zone with microhardness value in sheet material adjacent to fusion zone slightly higher (from 278 to 283 HV) than the average value for the sheet material used (222 HV).

Case Example # 6: Resistance Spot Welding - Alloy 8 to DP980

Alloy 8 sheet with a thickness of -1.4 mm and commercial sheet from DP980 steel were used for welding trial. Alloy 8 sheet for welding was used in the annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated to be 222 HV.

The spot welding system is schematically diagrammed in FIG. 5, which was by the MFDC method. It consisted of a Miyachi MFDC IS A-500 inverter power supply with controller that provided power to the primary coil to a RoMan 9.0 V DC transformer. The secondary coil power from the transformer was reduced in voltage thus increasing the current in order to do the actual spot welding through B nose electrodes that were dressed with a face diameter of 5.5 mm. The weld current was measured using a Miyachi mm-326B weld checker system for feedback control.

An optimized self-to-self spot welding of DP980 steel was first examined as a control in order to compare to the case when Alloy 8 was spot welded to DP980. The weld parameters used to form self-to-self spot weld of DP980 are listed in Table 36. A micrograph of the spot weld is shown in FIG. 55. Microhardness measurements were made across the weld nugget from HAZ on one side to HAZ on another side. The results are listed in Table 37 and plotted in FIG. 56. Structural analysis was performed using a Zeiss MA- 10 Scanning Electron Microscope (SEM). The base metal micro structure of DP980 is shown in FIG. 57a. The interface between the base metal and the fusion zone is presented in FIG. 57b at lower magnification clearly showing the presence of the HAZ with different contrast along the interface. The fusion zone microstructure is shown in FIG. 57c.

Table 36 DP980 Self-to-Self Spot Welding Parameters

Table 37 Microhardness Measurement Data Across the Weld Nugget

After Self-to-Self Spot Welding of DP980 Steel

DP980 to DP980

Area of the Weld Distance HV

(mm) (kg/mm ² )

-3.22 459

-2.69 449

-2.15 467

-1.62 469

-1.07 460

-0.53 457

0.00 463

0.55 471

1.08 463

1.62 467

2.15 463

2.69 480

3.23 486

HAZ 3.76 303

The weld parameters used to form the Alloy 8 to DP980 spot weld are listed in Table 38. A micrograph of the spot weld is shown in FIG. 58. Microhardness measurements were made across the weld nugget for which the results are listed in Table 39 and plotted in FIG. 59. Structural analysis was performed using a Zeiss MA- 10 Scanning Electron Microscope (SEM). The microstructure of the Alloy 8 base metal is shown in FIG. 60a. The base metal of Alloy 8 interface with the fusion zone of the weld nugget is shown in FIG. 60b. There is a gradual transition of the fusion zone microstructure to Alloy 8 base metal microstructure with no microstructural evidence of the HAZ. The fusion zone microstructure of the weld is shown in FIG. 60c. The fusion zone interface with the heat affected zone in the DP980 steel is shown in FIG. 60d. The heat affected zone microstructure in the DP980 steel is shown in FIG. 60e. The heat affected zone interface with the base metal of DP980 steel is shown in FIG. 60f. The DP980 steel base metal microstructure is shown in FIG. 60g. Table 38 Alloy 8 to DP980 Weld Lobe Parameters

Table 39 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 8 to DP980 Steel

Alloy 8 to DP980

Area of the Weld Distance HV

(mm) (kg/mm ² )

-0.27 364

0.00 358

0.26 391

0.52 370

0.77 371

1.04 374

1.30 386

1.56 393

1.82 398

2.08 407

2.33 326

HAZ

2.60 289

2.86 292

3.11 286

Base Metal 3.37 285

(DP980) 3.63 265

3.89 269

4.15 260

This Case Example shows that Alloy 8 can be spot welded to commercially produced DP980 using conventional spot welding technology. The resulting spot weld did not show a deleterious heat affected zone on the Alloy 8 interface with the fusion zone with microhardness value in sheet material adjacent to fusion zone slightly higher (from 314 to 365 HV) than the average value for the sheet material used (222 HV).

Case Example # 7: Resistance Spot Welding - Alloy 8 to TRIP 700 Alloy 8 sheet with a thickness of ~ 1.4 mm and commercial sheet from TRIP 700 steel were used for welding trials. Alloy 8 sheet material for welding was used in annealed condition with ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and tensile elongation from 44.2 to 61.8%. The average value of Vickers hardness of the sheet material used for welding was estimated to be 222 HV.

The spot welding system is schematically diagrammed in FIG. 5, which was by the MFDC method. It consisted of a Miyachi MFDC IS A-500 inverter power supply with controller that provided power to the primary coil to a RoMan 9.0 V DC transformer. The secondary coil power from the transformer was reduced in voltage thus increasing the current in order to do the actual spot welding through B nose electrodes that were dressed with a face diameter of 5.5 mm. The weld current was measured using a Miyachi mm-326B weld checker system for feedback control.

An optimized self-to-self spot weld of TRIP 700 was first examined. The weld parameters used are listed in Table 40. A micrograph of the spot weld is shown in FIG. 61. Microhardness measurements were made across the weld nugget starting from the base metal through the HAZ and the fusion zone to the HAZ on another side of the nugget. The results are listed in Table 41 and plotted in FIG. 62. Examination of the cross section in a Zeiss MA-10 Scanning Electron Microscope (SEM) revealed distinct microstructural zones that are identified from the microhardness plot in FIG. 62. The base metal microstructure of TRIP 700 is shown in FIG. 63a. The interface of the base metal with heat affected zone is shown in FIG. 63b. The microstructure in the heat affected zone is shown in FIG. 63c. FIG. 63d shows the interface between the heat affected zone and the fusion zone. The fusion zone microstructure is shown in FIG. 63e.

Table 40 TRIP 700 Self-to-Self Spot Welding Parameters

Table 41 Microhardness Measurement Data Across the Weld Nugget

After Self-To-Self Spot Welding of TRIP 700

The weld parameters used to form the Alloy 8 to TRIP 700 spot weld are listed in Table 42. A micrograph of the spot weld is shown in FIG. 64. Microhardness measurements were made across the cross section of the weld nugget from the base metal of Alloy 8 through the fusion zone to the base metal of TRIP 700 steel. The results are listed in Table 43 and plotted in FIG. 65. Structural analysis was performed using a Zeiss MA-10 Scanning Electron Microscope (SEM). The microstructure of the Alloy 8 base metal is shown in FIG. 66a. The base metal of Alloy 8 interface with the fusion zone of the weld nugget is shown in FIG. 66b. There is a gradual transition of the fusion zone microstructure to Alloy 8 base metal microstructure with no micro structural evidence of the HAZ. The fusion zone microstructure of the weld is shown in FIG. 66c. The fusion zone interface with the heat affected zone in the TRIP 700 steel is shown in FIG. 66d. The heat affected zone microstructure in the TRIP 700 steel is shown in FIG. 66e. The heat affected zone interface with the base metal of TRIP 700 steel is shown in FIG. 66f. The TRIP 700 steel base metal micro structure shown in FIG. 66g.

Table 42 Alloy 8 to TRIP 700 Spot Welding Parameters

Table 43 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 8 to TRIP 700 Steel

Alloy 8 to TRIP 700

Area of the Weld Distance HV

(mm) (kg/mm ² )

-1.05 310

-0.78 307

-0.52 300

-0.26 309

0.00 287

0.53 285

0.79 315

1.05 330

1.31 312

1.57 356

1.83 447

2.09 486

2.35 498

2.61 478

2.87 473

HAZ 3.13 471

3.38 461

3.65 467

3.90 489

4.15 476

4.41 498

4.67 498

5.18 275

TRIP700

5.44 247 This Case Example shows that Alloy 8 can be spot welded to commercially produced TRIP 700 using conventional spot welding technology. The resulting spot weld did not show a heat affected zone on the Alloy 8 interface. The microhardness measurements showed that value in sheet material adjacent to fusion zone slightly higher (from 259 to 280 HV) than the average value for the sheet material used (222 HV).

Case Example # 8: Resistance Spot Welding - IF Steel between Two Alloy 8 Sheets

Alloy 8 sheet at 1.4 mm gauge and commercial sheet from IF steel were used for welding trial. Sheet material from Alloy 8 was used in two conditions, cold rolled and annealed and cold rolled and annealed and warm rolled. The cold rolled and annealed condition was achieved through annealing from 900 to 1100°C. Warm rolling was an additional step which then occurred at a temperature range from 150 °C to 250 °C and a rolling reduction range from 20 to 30% is called the hardened condition. Note that by either applying a cold rolling reduction or a warm rolling reduction such as the above, the yield strength properties of the alloys herein can be increased to achieve a hardened condition. The annealed Alloy 8 sheet with a thickness of -1.4 mm had the following tensile properties; ultimate tensile strength from 1141 to 1199 MPa, yield strength from 381 to 411 MPa, and a tensile elongation from 44.2 to 61.8%. The hardened Alloy 8 sheet with a thickness of ~1.2 mm had the following tensile properties; ultimate tensile strength from 1566 to 1574 MPa, yield strength from 1025 to 1071 MPa, and a tensile elongation from 17.6 to 24.9%.

Sheet samples from the coil were used for three sheet thickness (3-t) testing to aggravate conditions that may produce liquid metal embrittlement (LME). A 1.0 mm thick sheet sample of IF galvannealed steel with Zn coating was welded between two sheet samples from Alloy 8 sheet in both conditions (annealed and hardened). The welds were done using b-nose electrode with 6-mm face under ~5 kN (1100-lbs) weld force with 5-degrees of planar tilt with respect to the electrode face to increase the tensile stress in weld joint. Welding was done to achieve a weld nugget size of 4Vt and 5.5Vt to assess LME susceptibility across the nugget size range. The samples were welded with the same current range. The nugget size as a function of welding current is shown in FIG. 67 for welded samples from Alloy 8 in both conditions.

Samples of cross section of the welds were examined for the presence of LME by optical microscopy in un-etched conditions and photographs were taken with polarized light to reveal grain size. The results for each experimental condition are listed in Table 44. Sample identification includes nugget size (4Vt or 5.5Vt); A or B refers to first and second sample from each material; L corresponds to annealed condition and H corresponds to hardened condition.

Table 44 Metallographic Analysis Results

A general view of the nugget in the A4L sample is shown in FIG. 68a. Shallow cracks of LME were found in this sample as shown in FIG. 68b. A general view of the nugget in the B4L sample is shown in FIG. 69a. Enlarged image of the area marked in FIG. 69a is shown in FIG. 69b. No LME observed in any corners of the weld in this sample. A general view of the nugget in the A5.5L sample is shown in FIG. 70a. Enlarged image of the area marked in FIG. 70a is shown in FIG. 70b. No cracks observed in any corners of the weld in this sample. A general view of the nugget in the B5.5L sample is shown in FIG. 71a. Enlarged image of the area marked in FIG. 71a is shown in FIG. 71b. No cracks observed in any corners of the weld in this sample.

Similar analysis was performed on the weld samples which utilized the hardened version of the Alloy 8 sheet. A general view of the nugget in the A4H sample is shown in FIG. 72a. Enlarged image of the area marked in FIG. 72a is shown in FIG. 72b. No cracks observed in any corners of the weld in this sample. A general view of the nugget in the B4H sample is shown in FIG. 73a. A very shallow LME crack was observed in this sample as shown in FIG. 73b. A general view of the nugget in the A5.5H sample is shown in FIG. 74a. A LME crack was observed in this sample at the edge of the area with grain growth in Alloy 8 sheet as shown in FIG. 74b. A general view of the nugget in the B5.5H sample is shown in FIG. 75a. A pore appears to form at the edge of the fusion zone that was backfilled with Zn as shown in FIG. 75b.

This Case Example demonstrates that Alloy 8 sheet material in annealed and hardened conditions during initial welding trial in a presence of Zn coating and without optimization produced welds showing high resistance to LME. In three out of eight samples, very shallow cracks of LME were found with penetration less than 15% of the material thickness. Case Example #9: Resistance Spot Welding of Selected Alloys to DP980

Alloy 1, Alloy 3, Alloy 6, Alloy 9, and Alloy 15 sheet with a thickness of 1.2 mm were laboratory produced by casting of 50 mm thick slab and processing by hot rolling, cold rolling and annealing as described in the Main Body section of this application. The sheet material from alloys herein was joined to DP980 by melting and re-solidification process using spot welding method. Steel sheets were cleaned with a nylon mesh abrasive pad after heat treatment and prior to welding to reduce the quantity of surface oxide. H&H programmable spot welder with a P10 controller was used. The spot welding procedure started with two materials being clamped together for 1/6 of a second prior to welding. The welding was done using a single pulse weld with 40 cycles of 1/60 sec at 40% power level. After welding the sample remained clamped for 1/6 of a second to cool. The electrode diameter was 0.125 inches and the clamping force is approximately 850 lbs. The melted and re-solidified area of the joined sheets formed a fusion zone. Sheet material adjacent to the fusion zone that was affected by heat during welding corresponds to a heat affected zone (HAZ).

The welded samples were cut by EDM across the weld nuggets for microhardness measurements. Cross section samples were mounted in epoxy. The samples were polished progressively with 9 μηι, 6 μιη and 1 μιη diamond suspension solution then finally with 0.02 μιη silica solution. After polishing the cross section was etched with 2% Nital solution. Microhardness measurements as a function of distance across the weld nugget from the base metal of DP980 through the fusion zone to the base metal of alloys herein were done with the load of 500 g. The results of the microhardness measurement as a function of distance are listed in Table 45 through Table 49 for each alloy herein. The hardness difference between base metal of the alloys herein and the heat affected zone in the mixed metal welds is summarized in Table 50.

Table 45 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 1 to DP980 Steel

Distance HV

Area of the Weld

(mm) (kg/mm ² )

5.15 325

Table 46 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 3 to DP980 Steel

Distance HV

Area of the Weld

(mm) (kg/mm ² )

0 291

DP980 (Base)

0.20 191

Heat Affected Zone 0.40 252

0.60 254

0.80 265

1.01 269

1.21 250

1.42 246

Fusion Zone

1.61 260

1.81 238

2.01 263

2.21 258

2.41 254

2.62 366

2.83 372

3.04 365

Heat Affected Zone

3.25 389

3.46 404

3.67 363

Alloy 3 (Base) 3.87 321 Distance HV

Area of the Weld

(mm) (kg/mm ² )

4.07 258

4.27 274

4.48 291

4.69 310

Table 47 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 6 to DP980 Steel

Distance HV

Area of the Weld

(mm) (kg/mm ² )

3.47 400

3.69 386

3.89 281

Alloy 6 (Base) 4.09 274

4.29 294

Table 48 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 9 to DP980 Steel

Distance HV

Area of the Weld

(mm) (kg/mm ² )

Alloy 9 (Base) 3.51 336

Table 49 Microhardness Measurement Data Across the Weld Nugget

After Spot Welding of Alloy 15 to DP980 Steel

Distance HV

Area of the Weld

(mm) (kg/mm ² )

0 305

DP980 (Base) 0.21 307

0.41 297

Heat Affected Zone 0.62 313

0.83 298

1.03 387

1.23 399

1.43 369

1.63 372

1.83 372

Fusion Zone

2.00 363

2.21 376

2.41 366

2.61 370

2.81 379

3.01 425

3.22 392

3.44 384

Heat Affected Zone

3.65 395

3.86 404 Distance HV

Area of the Weld

(mm) (kg/mm ² )

4.07 402

4.28 407

4.49 317

Alloy 15 (Base) 4.70 255

4.92 271

Table 50 A Summary on Microhardness of the Base Metal and the Heat Affected Zone

This Case Example shows that alloys herein can be spot welded to commercially produced DP980 using conventional spot welding technology. The resulting spot welds did not show a deleterious heat affected zone on the alloy interface with the fusion zone. Microhardness values in the sheet material adjacent to the fusion zone corresponding to HAZ slightly higher than the average value for the sheet material used (from +61 to +116 HV).