EDGE FORMABILITY IN METALLIC ALLOYS
20210238703 · 2021-08-05
Inventors
- Daniel James Branagan (Idaho Falls, ID)
- Andrew E. Frerichs (Idaho Falls, ID)
- Brian E. Meacham (Idaho Falls, ID)
- Grant G. Justice (Idaho Falls, ID)
- Andrew T. Ball (Reno, NV, US)
- Jason K. Walleser (Idaho Falls, ID)
- Kurtis Clark (Idaho Falls, ID)
- Logan J. Tew (Idaho Falls, ID)
- Scott T. Anderson (Idaho Falls, ID)
- Scott Larish (Idaho Falls, ID)
- Sheng Cheng (Idaho Falls, ID)
- Taylor L. Giddens (Idaho Falls, ID)
- Alla V. Sergueeva (Idaho Falls, ID)
Cpc classification
B23H7/00
PERFORMING OPERATIONS; TRANSPORTING
B21D28/00
PERFORMING OPERATIONS; TRANSPORTING
C21D9/0068
CHEMISTRY; METALLURGY
C22C38/002
CHEMISTRY; METALLURGY
C21D8/021
CHEMISTRY; METALLURGY
International classification
C21D9/00
CHEMISTRY; METALLURGY
B22D11/00
PERFORMING OPERATIONS; TRANSPORTING
B23H7/00
PERFORMING OPERATIONS; TRANSPORTING
B26F3/00
PERFORMING OPERATIONS; TRANSPORTING
C21D8/00
CHEMISTRY; METALLURGY
Abstract
This disclosure is directed at mechanical property improvement in a metallic alloy that has undergone one or more mechanical property losses as a consequence of forming an edge, such as in the formation of an internal hole or an external edge. Methods are disclosed that provide the ability to improve mechanical properties of metallic alloys that have been formed with one or more edges placed in the metallic alloy by a variety of methods which may otherwise serve as a limiting factor for industrial applications.
Claims
1. A cold rolled steel sheet product comprising Fe and at least four alloying elements selected from Si, Mn, B, Cr, Ni, Cu and C, wherein the steel sheet product includes a sheared edge, has an ultimate tensile strength of at least 799 MPa, a total elongation of at least 6.6 percent, and a hole expansion ratio greater than 20.
2. The steel sheet product of claim 1, wherein the steel sheet product comprises at least five of the elements selected from Si, Mn, B, Cr, Bi, Cu and C.
3. The steel sheet product of claim 1, wherein the steel sheet product comprises at least six of the elements selected from Si, Mn, B, Cr, Ni, Cu and C.
4. The steel sheet product of claim 1, wherein the steel sheet product comprises Fe, Si, Mn, B, Cr, Ni, Cu and C.
5. The steel sheet product of claim 1, wherein the steel sheet product has a yield strength of at least 400 MPa.
6. The steel sheet product of claim 1, wherein the sheared edge comprises an internal hole and/or an external edge.
7. The steel sheet product of claim 1, wherein the sheared edge is formed by punching, piercing, perforating, cutting, cropping, EDM cutting, waterjet cutting, laser cutting, or milling.
8. The steel sheet product of claim 1, wherein the steel sheet product is annealed.
9. The steel sheet product of claim 8, wherein the sheared edge has been subjected to annealing after formation of the sheared edge.
10. The steel sheet product of claim 8, wherein the steel sheet product has been subjected to annealing prior to formation of the sheared edge.
11. The steel sheet product of claim 1, wherein the sheared edge is formed in a progressive die stamping operation.
12. The steel sheet product of claim 1, wherein the sheared edge of the steel sheet product is positioned in a vehicle.
13. The steel sheet product of claim 1, wherein the sheared edge of the steel sheet product is part of a vehicular frame, vehicular chassis, or vehicular panel.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] The detailed description below may be better understood with reference to the accompanying FIGS. which are provided for illustrative purposes and are not to be considered as limiting any aspect of this invention.
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[0111] Alloy 1 with holes prepared by different methods; a) Punched hole, b) EDM cut hole, c) Milled hole, and d) Laser cut hole.
DETAILED DESCRIPTION
Structures And Mechanisms
[0112] The steel alloys herein undergo a unique pathway of structural formation through specific mechanisms as illustrated in
[0113] Steel alloys herein with the Modal Structure (Structure #1,
[0114] The Nanomodal Structure (Structure #2,
[0115] When steel alloys herein with the Nanomodal Structure (Structure #2,
[0116] The High Strength Nanomodal Structure (Structure #3,
[0117] Steel alloys herein with the Recrystallized Modal Structure (Structure #4,
[0118] Steel alloys herein with the Refined High Strength Nanomodal Structure (Structure #5,
Mechanisms During Sheet Production Through Slab Casting
[0119] The structures and enabling mechanisms for the steel alloys herein are applicable to commercial production using existing process flows. See
[0120] The formation of Modal Structure (Structure #1) in steel alloys herein occurs during alloy solidification. The Modal Structure may be preferably formed by heating the alloys herein at temperatures in the range of above their melting point and in a range of 1100° C. to 2000° C. and cooling below the melting temperature of the alloy, which corresponds to preferably cooling in the range of 1×10.sup.3 to 1×10.sup.−3 K/s. The as-cast thickness will be dependent on the production method with Thin Slab Casting typically in the range of 20 to 150 mm in thickness and Thick Slab Casting typically in the range of 150 to 500 mm in thickness. Accordingly, as cast thickness may fall in the range of 20 to 500 mm, and at all values therein, in 1 nun increments. Accordingly, as cast thickness may be 21 mm, 22 mm, 23 mm, etc., up to 500 mm.
[0121] Hot rolling of solidified slabs from the alloys is the next processing step with production either of transfer bars in the case of Thick Slab Casting or coils in the case of Thin Slab Casting. During this process, the Modal Structure transforms in a continuous fashion into a partial and then fully Homogenized Modal Structure (Structure #1a) through Nanophase Refinement (Mechanism #1). Once homogenization and resulting refinement is completed, the Nanomodal Structure (Structure #2) forms. The resulting hot band coils which are a product of the hot rolling process is typically in the range of 1 to 20 mm in thickness.
[0122] Cold rolling is a widely used method for sheet production that is utilized to achieve targeted thickness for particular applications. For AHSS, thinner gauges are usually targeted in the range of 0.4 to 2 mm. To achieve the finer gauge thicknesses, cold rolling can be applied through multiple passes with or without intermediate annealing between passes. Typical reduction per pass is 5 to 70% depending on the material properties and equipment capability. The number of passes before the intermediate annealing also depends on materials properties and level of strain hardening during cold deformation. For the steel alloys herein, the cold rolling will trigger Dynamic Nanophase Strengthening (Mechanism #2) leading to extensive strain hardening of the resultant sheet and to the formation of the High Strength Nanomodal Structure (Structure #3). The properties of the cold rolled sheet from alloys herein will depend on the alloy chemistry and can be controlled by the cold rolling reduction to yield a fully cold rolled (i.e. hard) product or can be done to yield a range of properties (i.e. ¼, ½, ¾ hard etc.). Depending on the specific process flow, especially starting thickness and the amount of hot rolling gauge reduction, often annealing is needed to recover the ductility of the material to allow for additional cold rolling gauge reduction. Intermediate coils can be annealed by utilizing conventional methods such as batch annealing or continuous annealing lines. The cold deformed High Strength Nanomodal Structure (Structure #3) for the steel alloys herein will undergo Recrystallization (Mechanism #3) during annealing leading to the formation of the Recrystallized Modal Structure (Structure #4). At this stage, the recrystallized coils can be a final product with advanced property combination depending on the alloy chemistry and targeted markets. In a case when even thinner gauges of the sheet are required, recrystallized coils can be subjected to further cold rolling to achieve targeted thickness that can be realized by one or multiple cycles of cold rolling/annealing. Additional cold deformation of the sheet from alloys herein with Recrystallized Modal Structure (Structure 44) leads to structural transformation into Refined High Strength Nanomodal Structure (Structure #5) through Nanophase Refinement and Strengthening (Mechanism #4). As a result, fully hard coils with final gauge and Refined High Strength Nanomodal Structure (Structure #5) can be formed or, in the case of annealing as a last step in the cycle, coils of the sheet with final gauge and Recrystallized Modal Structure (Structure #4) can also be produced. When coils of recrystallized sheet from alloys herein utilized for finished part production by any type of cold deformation such as cold stamping, hydroforming, roll forming etc., Refined High Strength Nanomodal Structure (Structure #5) will be present in the final product/parts. The final products may be in many different forms including sheet, plate, strips, pipes, and tubes and a myriad of complex parts made through various metalworking processes.
Mechanisms for Edge Formability
[0123] The cyclic nature of these phase transformations going from Recrystallized Modal Structure (Structure #4) to Refined High Strength Nanomodal Structure (Structure #5) and then back to Recrystallized Modal Structure (Structure #4) is one of the unique phenomenon and features of steel alloys herein. As described earlier, this cyclic feature is applicable during commercial manufacturing of the sheet, especially for AHSS where thinner gauge thicknesses are required (e.g. thickness in the range of 0.2 to 25 mm). Furthermore, these reversibility mechanisms are applicable for the widespread industrial usage of the steel alloys herein. While exhibiting exceptional combinations of bulk sheet formability as is demonstrated by the tensile and bend properties in this application for the steel alloys herein, the unique cycle feature of the phase transformations is enabling for edge formability, which can be a significant limiting factor for other AHSS. Table 1 below provides a summary of the structure and performance features through stressing and heating cycles available through Nanophase Refinement and Strengthening (Mechanism #4). How these structures and mechanisms can be harnessed to produce exceptional combinations of both bulk sheet and edge formability will be subsequently described herein.
TABLE-US-00001 TABLE 1 Structures and Performance Through Stressing/Heating Cycles Structure #5 Refined High Strength Structure #4 Nanomodal Structure Recrystallized Transformed Property/Mechanism Modal Structure Untransformed “pockets” Structure Recrystallization Retained austenitic Nanophase Formation occurring at elevated grains Refinement & temperatures in cold Strengthening worked material mechanism occurring through application of mechanical stress in distributed microstructural “pockets” Transformations Recrystallization of cold Precipitation Stress induced deformed iron matrix optional austenite transformation into ferrite and precipitates Enabling Phases Austenite, optionally Austenite, Ferrite, optionally ferrite, precipitates optionally austenite, precipitates precipitates Matrix Grain Size 0.5 to 50 μm 0.5 to 50 μm 50 to 2000 nm Precipitate Size 1 to 200 nm 1 to 200 nm 1 to 200 nm Tensile Actual with properties Actual with properties achieved based on Response achieved based on formation of the structure and fraction of formation of the transformation structure and fraction of transformation Yield Strength 197 to 1372 MPa 718 to 1645 MPa Ultimate Tensile 799 to 1683 MPa 1356 to 1831 MPa Strength Total Elongation 6.6 to 86.7% 1.6 to 32.8%
Main Body
[0124] The chemical composition of the alloys herein is shown in Table 2 which provides the preferred atomic ratios utilized.
TABLE-US-00002 TABLE 2 Alloy Chemical Composition Alloy Fe Cr Ni Mn Cu B Si C Alloy 1 75.75 2.63 1.19 13.86 0.65 0.00 5.13 0.79 Alloy 2 73.99 2.63 1.19 13.18 1.55 1.54 5.13 0.79 Alloy 3 77.03 2.63 3.79 9.98 0.65 0.00 5.13 0.79 Alloy 4 78.03 2.63 5.79 6.98 0.65 0.00 5.13 0.79 Alloy 5 79.03 2.63 7.79 3.98 0.65 0.00 5.13 0.79 Alloy 6 78.53 2.63 3.79 8.48 0.65 0.00 5.13 0.79 Alloy 7 79.53 2.63 5.79 5.48 0.65 0.00 5.13 0.79 Alloy 8 80.53 2.63 7.79 2.48 0.65 0.00 5.13 0.79 Alloy 9 74.75 2.63 1.19 14.86 0.65 0.00 5.13 0.79 Alloy 10 75.25 2.63 1.69 13.86 0.65 0.00 5.13 0.79 Alloy 11 74.25 2.63 1.69 14.86 0.65 0.00 5.13 0.79 Alloy 12 73.75 2.63 1.19 15.86 0.65 0.00 5.13 0.79 Alloy 13 77.75 2.63 1.19 11.86 0.65 0.00 5.13 0.79 Alloy 14 74.75 2.63 2.19 13.86 0.65 0.00 5.13 0.79 Alloy 15 73.75 2.63 3.19 13.86 0.65 0.00 5.13 0.79 Alloy 16 74.11 2.63 2.19 13.86 1.29 0.00 5.13 0.79 Alloy 17 72.11 2.63 2.19 15.86 1.29 0.00 5.13 0.79 Alloy 18 78.25 2.63 0.69 11.86 0.65 0.00 5.13 0.79 Alloy 19 74.25 2.63 1.19 14.86 1.15 0.00 5.13 0.79 Alloy 20 74.82 2.63 1.50 14.17 0.96 0.00 5.13 0.79 Alloy 21 75.75 1.63 1.19 14.86 0.65 0.00 5.13 0.79 Alloy 22 77.75 2.63 1.19 13.86 0.65 0.00 3.13 0.79 Alloy 23 76.54 2.63 1.19 13.86 0.65 0.00 5.13 0.00 Alloy 24 67.36 10.70 1.25 10.56 1.00 5.00 4.13 0.00 Alloy 25 71.92 5.45 2.10 8.92 1.50 6.09 4.02 0.00 Alloy 26 61.30 18.90 6.80 0.90 0.00 5.50 6.60 0.00 Alloy 27 71.62 4.95 4.10 6.55 2.00 3.76 7.02 0.00 Alloy 28 62.88 16.00 3.19 11.36 0.65 0.00 5.13 0.79 Alloy 29 72.50 2.63 0.00 15.86 1.55 1.54 5.13 0.79 Alloy 30 80.19 0.00 0.95 13.28 1.66 2.25 0.88 0.79 Alloy 31 77.65 0.67 0.08 13.09 1.09 0.97 2.73 3.72 Alloy 32 78.54 2.63 1.19 13.86 0.65 0.00 3.13 0.00 Alloy 33 83.14 1.63 8.68 0.00 1.00 4.76 0.00 0.79 Alloy 34 75.30 2.63 1.34 14.01 0.80 0.00 5.13 0.79 Alloy 35 74.85 2.63 1.49 14.16 0.95 0.00 5.13 0.79
[0125] As can be seen from the above, the alloys herein are iron based metal alloys, having greater than or equal to 50 at. % Fe. More preferably, the alloys herein can be described as comprising, consisting essentially of, or consisting of the following elements at the indicated atomic percent: Fe (61.30 to 83.14 at. %); Si (0 to 7.02 at. %); Mn (0 to 15.86 at. %); B (0 to 6.09 at. %); Cr (0 to 18.90 at. %); Ni (0 to 8.68 at. %); Cu (0 to 2.00 at. %); C (0 to 3.72 at. %). 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 six or more elements selected from Si, Mn, B, 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 50 at. % or greater along with Si, Mn, B, Cr, Ni, Cu and C.
Alloy Laboratory Processing
[0126] Laboratory processing of the alloys in Table 2 was done to model each step of industrial production but on a much smaller scale. Key steps in this process include the following: casting, tunnel furnace heating, hot rolling, cold rolling, and annealing.
Casting
[0127] Alloys were weighed out into charges ranging from 3,000 to 3,400 grams using commercially available ferroadditive powders with known chemistry and impurity content according to the atomic ratios in Table 2. Charges were loaded into a zirconia coated silica crucibles which was placed into an Indutherm VTC800V vacuum tilt casting machine. The machine then evacuated the casting and melting chambers and backfilled with argon to atmospheric pressure several times prior to casting to prevent oxidation of the melt. The melt was heated with a 14 kHz RF induction coil until fully molten, approximately 5.25 to 6.5 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 melting and casting chambers, tilted the crucible and poured the melt into a 50 mm thick, 75 to 80 mm wide, and 125 mm deep channel in 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. Example pictures of laboratory cast slabs from two different alloys are shown in
Tunnel Furnace Heating
[0128] Prior to hot rolling, laboratory slabs were loaded into a Lucifer EHS3GT-B18 furnace to heat. The furnace set point varies between 1100° C. to 1250° C. depending on alloy melting point. The slabs were allowed to soak for 40 minutes prior to hot rolling to ensure they reach the target temperature. Between hot rolling passes the slabs are returned to the furnace for 4 minutes to allow the slabs to reheat.
Hot Rolling
[0129] Pre-heated slabs were pushed out of the tunnel furnace into a Fenn Model 061 2 high rolling mill. The 50 mm slabs were preferably hot rolled for 5 to 8 passes though the mill before being allowed to air cool. After the initial passes each slab had been reduced between 80 to 85% to a final thickness of between 7.5 and 10 mm. After cooling each resultant sheet was sectioned and the bottom 190 mm was hot rolled for an additional 3 to 4 passes through the mill, further reducing the plate between 72 to 84% to a final thickness of between 1.6 and 2.1 mm. Example pictures of laboratory cast slabs from two different alloys after hot rolling are shown in
Cold Rolling
[0130] After hot rolling resultant sheets were media blasted with aluminum oxide to remove the mill scale and were then cold rolled on a Fenn Model 061 2 high rolling mill. Cold rolling takes multiple passes to reduce the thickness of the sheet to a targeted thickness of typically 1.2 mm. Hot rolled sheets were fed into the mill at steadily decreasing roll gaps until the minimum gap is reached. If the material has not yet hit the gauge target, additional passes at the minimum gap were used until 1.2 mm thickness was achieved. A large number of passes were applied due to limitations of laboratory mill capability. Example pictures of cold rolled sheets from two different alloys are shown in
Annealing
[0131] After cold rolling, tensile specimens were cut from the cold rolled sheet via wire electrical discharge machining (EDM). These specimens were then annealed with different parameters listed in Table 3. Annealing 1a, 1b, 2b were conducted in a Lucifer 7HT-K12 box furnace. Annealing 2a and 3 was conducted in a Camco Model G-ATM-12FL furnace. Specimens which were air normalized were removed from the furnace at the end of the cycle and allowed to cool to room temperature in air. For the furnace cooled specimens, at the end of the annealing the furnace was shut off to allow the sample to cool with the furnace. Note that the heat treatments were selected for demonstration but were not intended to be limiting in scope. High temperature treatments up to just below the melting points for each alloy are possible.
TABLE-US-00003 TABLE 3 Annealing Parameters Anneal- ing Heating Temperature Dwell Cooling Atmosphere 1a Preheated 850° C. 5 min Air Air + Argon Furnace Normalized 1b Preheated 850° C. 10 min Air Air + Argon Furnace Normalized 2a 20° C./hr 850° C. 360 min 45° C./hr to Hydrogen + 500° C. then Argon Furnace Cool 2b 20° C./hr 850° C. 360 min 45° C./hr to Air + Argon 500° C. then Air Normalized 3 20° C./hr 1200° C. 120 min Furnace Cool Hydrogen + Argon
Alloy Properties
[0132] Thermal analysis of the alloys herein was performed on as-solidified cast slabs using a Netzsch Pegasus 404 Differential Scanning calorimeter (DSC). Samples of alloys were loaded into alumina crucibles which were then loaded into the DSC. The DSC then evacuated the chamber and backfilled with argon to atmospheric pressure. A constant purge of argon was then started, and a zirconium getter was installed in the gas flow path to further reduce the amount of oxygen in the system. The samples were heated until completely molten, cooled until completely solidified, then reheated at 10° C./min through melting. Measurements of the solidus, liquidus, and peak temperatures were taken from the second melting in order to ensure a representative measurement of the material in an equilibrium state. In the alloys listed in Table 2, melting occurs in one or multiple stages with initial melting from ˜1111° C. depending on alloy chemistry and final melting temperature up to ˜1476° C. (Table 4). Variations in melting behavior reflect complex phase formation at solidification of the alloys depending on their chemistry.
TABLE-US-00004 TABLE 4 Differential Thermal Analysis Data for Melting Behavior Solidus Liquidus Melting Melting Melting Temperature Temperature Peak #1 Peak #2 Peak #3 Alloy (° C.) (° C.) (° C.) (° C.) (° C.) Alloy 1 1390 1448 1439 Alloy 2 1157 1410 1177 1401 Alloy 3 1411 1454 1451 Alloy 4 1400 1460 1455 Alloy 5 1415 1467 1464 Alloy 6 1416 1462 1458 Alloy 7 1421 1467 1464 Alloy 8 1417 1469 1467 Alloy 9 1385 1446 1441 Alloy 10 1383 1442 1437 Alloy 11 1384 1445 1442 Alloy 12 1385 1443 1435 Alloy 13 1401 1459 1451 Alloy 14 1385 1445 1442 Alloy 15 1386 1448 1441 Alloy 16 1384 1439 1435 Alloy 17 1376 1442 1435 Alloy 18 1395 1456 1431 1449 1453 Alloy 19 1385 1437 1432 Alloy 20 1374 1439 1436 Alloy 21 1391 1442 1438 Alloy 22 1408 1461 1458 Alloy 23 1403 1452 1434 1448 Alloy 24 1219 1349 1246 1314 1336 Alloy 25 1186 1335 1212 1319 Alloy 26 1246 1327 1268 1317 Alloy 27 1179 1355 1202 1344 Alloy 28 1158 1402 1176 1396 Alloy 29 1159 1448 1168 1439 Alloy 30 1111 1403 1120 1397 Alloy 31 1436 1475 1464 Alloy 32 1436 1476 1464 Alloy 33 1153 1418 1178 1411 Alloy 34 1397 1448 1445 Alloy 35 1394 1444 1441
[0133] The density of the alloys was measured on 9 mm thick sections of hot rolled material 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 5 and was found to be in the range from 7.57 to 7.89 g/cm.sup.3. The accuracy of this technique is ±0.01 g/cm.sup.3.
TABLE-US-00005 TABLE 5 Density of Alloys Density Alloy (g/cm.sup.3) Alloy 1 7.78 Alloy 2 7.74 Alloy 3 7.82 Alloy 4 7.84 Alloy 5 7.76 Alloy 6 7.83 Alloy 7 7.79 Alloy 8 7.71 Alloy 9 7.77 Alloy 10 7.78 Alloy 11 7.77 Alloy 12 7.77 Alloy 13 7.80 Alloy 14 7.78 Alloy 15 7.79 Alloy 16 7.79 Alloy 17 7.77 Alloy 18 7.79 Alloy 19 7.77 Alloy 20 7.78 Alloy 21 7.78 Alloy 22 7.87 Alloy 23 7.81 Alloy 24 7.67 Alloy 25 7.71 Alloy 26 7.57 Alloy 27 7.67 Alloy 28 7.73 Alloy 29 7.89 Alloy 30 7.78 Alloy 31 7.89 Alloy 32 7.89 Alloy 33 7.78 Alloy 34 7.77 Alloy 35 7.78
[0134] Tensile properties were measured on an Instron 3369 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s. Strain data was collected using Instron's Advanced Video Extensometer. Tensile properties of the alloys listed in Table 2 after annealing with parameters listed in Table 3 are shown below in Table 6 to Table 10. The ultimate tensile strength values may vary from 799 to 1683 MPa with tensile elongation from 6.6 to 86.7%. The yield strength is in a range from 197 to 978 MPa. The mechanical characteristic values in the steel alloys herein will depend on alloy chemistry and processing conditions. The variation in heat treatment additionally illustrates the property variations possible through processing a particular alloy chemistry.
TABLE-US-00006 TABLE 6 Tensile Data for Selected Alloys after Heat Treatment 1a Ultimate Yield Tensile Tensile Strength Strength Elongation Alloy (MPa) (MPa) (%) Alloy 1 443 1212 51.1 458 1231 57.9 422 1200 51.9 Alloy 2 484 1278 48.3 485 1264 45.5 479 1261 48.7 Alloy 3 458 1359 43.9 428 1358 43.7 462 1373 44.0 Alloy 4 367 1389 36.4 374 1403 39.1 364 1396 32.1 Alloy 5 510 1550 16.5 786 1547 18.1 555 1552 16.2 Alloy 6 418 1486 34.3 419 1475 35.2 430 1490 37.3 Alloy 7 468 1548 20.2 481 1567 20.3 482 1545 19.3 Alloy 8 851 1664 13.6 848 1683 14.0 859 1652 12.9 Alloy 9 490 1184 58.0 496 1166 59.1 493 1144 56.6 Alloy 10 472 1216 60.5 481 1242 58.7 470 1203 55.9 Alloy 11 496 1158 65.7 498 1155 58.2 509 1154 68.3 Alloy 12 504 1084 48.3 515 1105 70.8 518 1106 66.9 Alloy 13 478 1440 41.4 486 1441 40.7 455 1424 42.0 Alloy 22 455 1239 48.1 466 1227 55.4 460 1237 57.9 Alloy 23 419 1019 48.4 434 1071 48.7 439 1084 47.5 Alloy 28 583 932 61.5 594 937 60.8 577 930 61.0 Alloy 29 481 1116 60.0 481 1132 55.4 486 1122 56.8 Alloy 30 349 1271 42.7 346 1240 36.2 340 1246 42.6 Alloy 31 467 1003 36.0 473 996 29.9 459 988 29.5 Alloy 32 402 1087 44.2 409 1061 46.1 420 1101 44.1
TABLE-US-00007 TABLE 7 Tensile Data for Selected Alloys after Heat Treatment 1b Yield Ultimate Tensile Tensile Strength Strength Elongation Alloy (MPa) (MPa) (%) Alloy 1 487 1239 57.5 466 1269 52.5 488 1260 55.8 Alloy 2 438 1232 49.7 431 1228 49.8 431 1231 49.4 Alloy 9 522 1172 62.6 466 1170 61.9 462 1168 61.3 Alloy 12 471 1115 63.3 458 1102 69.3 454 1118 69.1 Alloy 13 452 1408 40.5 435 1416 42.5 432 1396 46.0 Alloy 14 448 1132 64.4 443 1151 60.7 436 1180 54.3 Alloy 15 444 1077 66.9 438 1072 65.3 423 1075 70.5 Alloy 16 433 1084 67.5 432 1072 66.8 423 1071 67.8 Alloy 17 420 946 74.6 421 939 77.0 425 961 74.9 Alloy 19 496 1124 67.4 434 1118 64.8 435 1117 67.4 Alloy 20 434 1154 58.3 457 1188 54.9 448 1187 60.5 Alloy 21 421 1201 54.3 427 1185 59.9 431 1191 47.8 Alloy 24 554 1151 23.5 538 1142 24.3 562 1151 24.3 Alloy 25 500 1274 16.0 502 1271 15.8 483 1280 16.3 Alloy 26 697 1215 20.6 723 1187 21.3 719 1197 21.5 Alloy 27 538 1385 20.6 574 1397 20.9 544 1388 21.8 Alloy 33 978 1592 6.6 896 1596 7.2 953 1619 7.5 Alloy 34 467 1227 56.7 476 1232 52.7 462 1217 51.6 Alloy 35 439 1166 56.3 438 1166 59.0 440 1177 58.3
TABLE-US-00008 TABLE 8 Tensile Data for Selected Alloys after Heat Treatment 2a Yield Ultimate Tensile Tensile Strength Strength Elongation Alloy (MPa) (MPa) (%) Alloy 2 367 1174 46.2 369 1193 45.1 367 1179 50.2 Alloy 30 391 1118 55.7 389 1116 60.5 401 1113 59.5 Alloy 32 413 878 17.6 399 925 20.5 384 962 21.0 Alloy 31 301 1133 37.4 281 1125 38.7 287 1122 39.0
TABLE-US-00009 TABLE 9 Tensile Data for Selected Alloys after Heat Treatment 2b Yield Ultimate Tensile Tensile Strength Strength Elongation Alloy (MPa) (MPa) (%) Alloy 1 396 1093 31.2 383 1070 30.4 393 1145 34.7 Alloy 2 378 1233 49.4 381 1227 48.3 366 1242 47.7 Alloy 3 388 1371 41.3 389 1388 42.6 Alloy 4 335 1338 21.7 342 1432 30.1 342 1150 17.3 Alloy 5 568 1593 15.2 595 1596 13.1 735 1605 14.6 Alloy 6 399 1283 17.5 355 1483 24.8 386 1471 23.8 Alloy 7 605 1622 16.3 639 1586 15.2 Alloy 8 595 1585 13.6 743 1623 14.1 791 1554 13.9 Alloy 9 381 1125 53.3 430 1111 44.8 369 1144 51.1 Alloy 10 362 1104 37.8 369 1156 43.5 Alloy 11 397 1103 52.4 390 1086 50.9 402 1115 50.4 Alloy 12 358 1055 64.7 360 1067 64.4 354 1060 62.9 Alloy 13 362 982 17.3 368 961 16.3 370 989 17.0 Alloy 14 385 1165 59.0 396 1156 55.5 437 1155 57.9 Alloy 15 357 1056 70.3 354 1046 68.2 358 1060 70.7 Alloy 16 375 1094 67.6 384 1080 63.4 326 1054 65.2 Alloy 17 368 960 77.2 370 955 77.9 358 951 75.9 Alloy 18 326 1136 17.3 338 1192 19.1 327 1202 18.5 Alloy 19 386 1134 64.5 378 1100 60.5 438 1093 52.5 Alloy 20 386 1172 56.2 392 1129 42.0 397 1186 57.8 Alloy 21 363 1141 49.0 Alloy 22 335 1191 45.7 322 1189 41.5 348 1168 34.5 Alloy 23 398 1077 44.3 367 1068 44.8 Alloy 24 476 1149 28.0 482 1154 25.9 495 1145 26.2 Alloy 25 452 1299 16.0 454 1287 15.8 441 1278 15.1 Alloy 26 619 1196 26.6 615 1189 26.2 647 1193 26.1 Alloy 27 459 1417 17.3 461 1410 16.8 457 1410 17.1 Alloy 28 507 879 52.3 498 874 42.5 493 880 44.7 Alloy 32 256 1035 42.3 257 1004 42.1 257 1049 34.8 Alloy 33 830 1494 8.4 862 1521 8.1 877 1519 8.8 Alloy 34 388 1178 59.8 384 1197 57.7 370 1177 59.1 Alloy 35 367 1167 58.5 369 1167 58.4 375 1161 59.7
TABLE-US-00010 TABLE 10 Tensile Data for Selected Alloys after Heat Treatment 3 Yield Ultimate Tensile Tensile Strength Strength Elongation Alloy (MPa) (MPa) (%) Alloy 1 238 1142 47.6 233 1117 46.3 239 1145 53.0 Alloy 3 266 1338 38.5 N/A 1301 37.7 N/A 1291 35.6 Alloy 4 N/A 1353 27.7 N/A 1337 26.1 N/A 1369 29.0 Alloy 5 511 1462 12.5 558 1399 10.6 Alloy 6 311 1465 24.6 308 1467 21.8 308 1460 25.0 Alloy 7 727 1502 12.5 639 1474 11.3 685 1520 12.4 Alloy 8 700 1384 12.3 750 1431 13.3 Alloy 9 234 1087 55.0 240 1070 56.4 242 1049 58.3 Alloy 10 229 1073 50.6 228 1082 56.5 229 1077 54.2 Alloy 11 232 1038 63.8 232 1009 62.4 228 999 66.1 Alloy 12 229 979 65.6 228 992 57.5 222 963 66.2 Alloy 13 277 1338 37.3 261 1352 35.9 272 1353 34.9 Alloy 14 228 1074 58.5 239 1077 54.1 230 1068 49.1 Alloy 15 206 991 60.9 208 1024 58.9 Alloy 16 199 1006 57.7 242 987 53.4 208 995 57.0 Alloy 17 222 844 72.6 197 867 64.9 213 869 66.5 Alloy 18 288 1415 32.6 300 1415 32.1 297 1421 29.6 Alloy 19 225 1032 58.5 213 1019 61.1 214 1017 58.4 Alloy 20 233 1111 57.3 227 1071 53.0 230 1091 49.4 Alloy 21 238 1073 50.6 228 1069 56.5 246 1110 52.0 Alloy 22 217 1157 47.0 236 1154 46.8 218 1154 47.7 Alloy 23 208 979 45.4 204 984 43.4 204 972 38.9 Alloy 28 277 811 86.7 279 802 86.0 277 799 82.0 Alloy 32 203 958 33.3 206 966 39.5 210 979 36.3 Alloy 34 216 1109 52.8 230 1144 55.9 231 1123 52.3 Alloy 35 230 1104 51.7 231 1087 59.0 220 1084 54.4
CASE EXAMPLES
Case Example #1
Structural Development Pathway in Alloy 1
[0135] A laboratory slab with thickness of 50 mm was cast from Alloy 1 that was then laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 5 min as described in Main Body section of current application. Microstructure of the alloy was examined at each step of processing by SEM, TEM and x-ray analysis.
[0136] For SEM study, the cross section of the slab samples was ground on SiC abrasive papers with reduced grit size, and then polished progressively with diamond media paste down to 1 μm. The final polishing was done with 0.02 gm grit SiO.sub.2 solution. Microstructures were examined by SEM using an EVO-MA10 scanning electron microscope manufactured by Carl Zeiss SMT Inc. To prepare TEM specimens, the samples were first cut by EDM, and then thinned by grinding with pads of reduced grit size every time. Further thinning to make foils of 60 to 70 μm thickness was done by polishing with 9 μm, 3 μm and 1 μm diamond suspension solution respectively. Discs of 3 mm in diameter were punched from the foils and the final polishing was completed with electropolishing using a twin-jet polisher. The chemical solution used was a 30% nitric acid mixed in methanol base. In case of insufficient thin area for TEM observation, the TEM specimens may be ion-milled using a Gatan Precision Ion Polishing System (PIPS). The ion-milling usually is done at 4.5 keV, and the inclination angle is reduced from 4° to 2° to open up the thin area. The TEM studies were done using a JEOL 2100 high-resolution microscope operated at 200 kV. X-ray diffraction was done using a PANalytical X'Pert MPD difftactometer with a Cu Kα x-ray tube and operated at 45 kV with a filament current of 40 mA. Scans were run with a step size of 0.01° and from 25° to 95° two-theta with silicon incorporated to adjust for instrument zero angle shift. The resulting scans were then subsequently analyzed using Rietveld analysis using Siroquant software.
[0137] Modal Structure was formed in the Alloy 1 slab with 50 mm thickness after solidification. The Modal Structure (Structure #1) is represented by a dendritic structure that is composed of several phases. In
TABLE-US-00011 TABLE 11 X-ray Diffraction Data for Alloy 1 After Solidification (Modal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.583 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.876 Å Martensite Structure: Tetragonal Space group #: 139 (I4/mmm) LP: a = 2.898 Å c = 3.018 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.093 Å
[0138] Deformation of the Alloy 1 with the Modal Structure (Structure #1,
TABLE-US-00012 TABLE 12 X-ray Diffraction Data for Alloy 1 After Hot Rolling (Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.595 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.896 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.113 Å
[0139] Further deformation at ambient temperature (i.e., cold deformation) of the Alloy 1 with the Nanomodal Structure causes transformation into High Strength Nanomodal Structure (Structure #3,
TABLE-US-00013 TABLE 13 X-ray Diffraction Data for Alloy 1 after Cold Rolling (High Strength Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.588 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.871 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.102 Å
[0140] Recrystallization occurs upon heat treatment of the cold deformed Alloy 1 with High Strength Nanomodal Structure (Structure #3,
TABLE-US-00014 TABLE 14 X-ray Diffraction Data for Alloy 1 After Annealing (Recrystallized Modal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.597 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.884 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.103 Å
[0141] When the Alloy 1 with Recrystallized Modal Structure (Structure #4,
TABLE-US-00015 TABLE 15 X-ray Diffraction Data for Alloy 1 After Tensile Deformation (Refined High Strength Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.586 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.873 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.159 Å Hexagonal phase 1 Structure: Hexagonal Space group #: 186 (P6.sub.3mc) LP: a = 3.013 Å, c = 6.183 Å
[0142] This Case Example demonstrates that alloys listed in Table 2 including Alloy 1 exhibit a structural development pathway with novel enabling mechanisms illustrated in
Case Example #2
Structural Development Pathway in Alloy 2
[0143] Laboratory slab with thickness of 50 mm was cast from Alloy 2 that was then laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described in Main Body section of current application. Microstructure of the alloy was examined at each step of processing by SEM, TEM and x-ray analysis.
[0144] For SEM study, the cross section of the slab samples was ground on SiC abrasive papers with reduced grit size, and then polished progressively with diamond media paste down to 1 μm. The final polishing was done with 0.02 μm grit SiO.sub.2 solution. Microstructures were examined by SEM using an EVO-MA10 scanning electron microscope manufactured by Carl Zeiss SMT Inc. To prepare TEM specimens, the samples were first cut with EDM, and then thinned by grinding with pads of reduced grit size every time. Further thinning to make foils to ˜60 μm thickness was done by polishing with 9 μm, 3 μm and 1 μm diamond suspension solution respectively. Discs of 3 mm in diameter were punched from the foils and the final polishing was fulfilled with electropolishing using a twin-jet polisher. The chemical solution used was a 30% nitric acid mixed in methanol base. In case of insufficient thin area for TEM observation, the TEM specimens may be ion-milled using a Gatan Precision Ion Polishing System (PIPS). The ion-milling usually is done at 4.5 keV, and the inclination angle is reduced from 4° to 2° to open up the thin area. The TEM studies were done using a JEOL 2100 high-resolution microscope operated at 200 kV. X-ray diffraction was done using a Panalytical X'Pert MPD diffractometer with a Cu Kα x-ray tube and operated at 45 kV with a filament current of 40 mA. Scans were run with a step size of 0.01° and from 25° to 95° two-theta with silicon incorporated to adjust for instrument zero angle shift. The resulting scans were then subsequently analyzed using Rietveld analysis using Siroquant software.
[0145] Modal Structure (Structure #1,
TABLE-US-00016 TABLE 16 X-ray Diffraction Data for Alloy 2 After Solidification (Modal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.577 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.850 Å M.sub.2B Structure: Tetragonal Space group #: 140 (I4/mcm) LP: a = 5.115 Å, c = 4.226 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.116 Å
[0146] Following the flowchart in
TABLE-US-00017 TABLE 17 X-ray Diffraction Data for Alloy 2 After Hot Rolling (Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.598 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.853 Å M.sub.2B Structure: Tetragonal Space group #: 140 (I4/mcm) LP: a = 5.123 Å, c = 4.182 Å Iron manganese Structure: Cubic compound Space group #: 225 (Fm3m) LP: a = 4.180 Å
[0147] Deformation of the Alloy 2 with the Nanomodal Structure but at ambient temperature (i.e., cold deformation) leads to formation of High Strength Nanomodal Structure (Structure #3,
TABLE-US-00018 TABLE 18 X-ray Diffraction Data for Alloy 2 After Cold Rolling (High Strength Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.551 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.874 Å M.sub.2B Structure: Tetragonal Space group #: 140 (I4/mcm) LP: a = 5.125 Å, c = 4.203 Å Hexagonal phase Structure: Hexagonal Space group #: 186 (P6.sub.3mc) LP: a = 2.962 Å, c = 6.272 Å
[0148] Recrystallization occurs upon annealing of the cold deformed Alloy 2 with High Strength Nanomodal Structure (Structure #3,
TABLE-US-00019 TABLE 19 X-ray Diffraction Data for Alloy 2 After Annealing (Recrystallized Modal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.597 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.878 Å M.sub.2B Structure: Tetragonal Space group #: 140 (I4/mcm) LP: a = 5.153 Å, c = 4.170 Å Hexagonal phase Structure: Hexagonal Space group #: 186 (P6.sub.3mc) LP: a = 2.965 Å, c = 6.270 Å
[0149] Deformation of Recrystallized Modal Structure (Structure #4,
TABLE-US-00020 TABLE 20 X-ray Diffraction Data for Alloy 2 After Tensile Deformation (Refined High Strength Nanomodal Structure) Phases Identified Phase Details γ-Fe Structure: Cubic Space group #: 225 (Fm3m) LP: a = 3.597 Å α-Fe Structure: Cubic Space group #: 229 (Im3m) LP: a = 2.898 Å M.sub.2B Structure: Tetragonal Space group #: 140 (14/mcm) LP: a = 5.149 Å, c = 4.181 Å Hexagonal phase Structure: Hexagonal Space group #: 186 (P6.sub.3mc) LP: a = 2.961 Å, c = 6.271 Å
[0150] This Case Example demonstrates that alloys listed in Table 2 including Alloy 2 exhibit a structural development pathway with the mechanisms illustrated in
Case Example #3
Tensile Properties at Each Step of Processing
[0151] Slabs with thickness of 50 mm were laboratory cast from the alloys listed in Table 21 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described in Main Body section of current application. Tensile properties were measured at each step of processing on an Instron 3369 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s. Strain data was collected using Instron's Advanced Video Extensometer.
[0152] Alloys were weighed out into charges ranging from 3,000 to 3,400 grams using commercially available ferroadditive powders with known chemistry and impurity content according to the atomic ratios in Table 2. Charges were loaded into zirconia coated silica crucibles which were placed into an Indutherm VTC800V vacuum tilt casting machine. The machine then evacuated the casting and melting chambers and backfilled with argon to atmospheric pressure several times prior to casting to prevent oxidation of the melt. The melt was heated with a 14 kHz RF induction coil until fully molten, approximately 5.25 to 6.5 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 melting and casting chambers and tilted the crucible and poured the melt into a 50 mm thick, 75 to 80 mm wide, and 125 mm deep channel in 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. Tensile specimens were cut from as-cast slabs by wire EDM and tested in tension. Results of tensile testing are shown in Table 21. As it can be seen, ultimate tensile strength of the alloys herein in as-cast condition varies from 411 to 907 MPa. The tensile elongation varies from 3.7 to 24.4%. Yield strength is measured in a range from 144 to 514 MPa.
[0153] Prior to hot rolling, laboratory cast slabs were loaded into a Lucifer EHS3GT-B18 furnace to heat. The furnace set point varies between 1000° C. to 1250° C. depending on alloy melting point. The slabs were allowed to soak for 40 minutes prior to hot rolling to ensure they reach the target temperature. Between hot rolling passes the slabs are returned to the furnace for 4 minutes to allow the slabs to reheat. Pre-heated slabs were 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 8 passes through the mill before being allowed to air cool defined as first campaign of hot rolling. After this campaign the slab thickness was reduced between 80.4 to 87.4%. After cooling, the resultant sheet samples were sectioned to 190 mm in length. These sections were hot rolled for an additional 3 passes through the mill with reduction between 73.1 to 79.9% to a final thickness of between 2.1 and 1.6 mm. Detailed information on hot rolling conditions for each alloy herein is provided in Table 22. Tensile specimens were cut from hot rolled sheets by wire EDM and tested in tension. Results of tensile testing are shown in Table 22. After hot rolling, ultimate tensile strength of the alloys herein varies from 921 to 1413 MPa. The tensile elongation varies from 12.0 to 77.7%. Yield strength is measured in a range from 264 to 574 MPa. See, Structure 2 in
[0154] After hot rolling, resultant sheets were media blasted with aluminum oxide to remove the mill scale and were then cold roiled on a Fenn Model 061 2 high rolling mill. Cold rolling takes multiple passes to reduce the thickness of the sheet to targeted thickness, generally 1.2 mm. Hot rolled sheets were fed into the mill at steadily decreasing roll gaps until the minimum gap is reached. If the material has not yet hit the gauge target, additional passes at the minimum gap were used until the targeted thickness was reached. Cold rolling conditions with the number of passes for each alloy herein are listed in Table 23. Tensile specimens were cut from cold rolled sheets by wire EDM and tested in tension. Results of tensile testing are shown in Table 23. Cold rolling leads to significant strengthening with ultimate tensile strength in the range from 1356 to 1831 MPa. The tensile elongation of the alloys herein in cold rolled state varies from 1.6 to 32.1%. Yield strength is measured in a range from 793 to 1645 MPa. It is anticipated that higher ultimate tensile strength and yield strength can be achieved in alloys herein by larger cold rolling reduction (>40%) that in our case is limited by laboratory mill capability. With more rolling force, it is anticipated that ultimate tensile strength could be increased to at least 2000 MPa and yield strength to at least 1800 MPa.
[0155] Tensile specimens were cut from cold rolled sheet samples by wire EDM and annealed at 850° C. for 10 min in a Lucifer 7HT-K12 box furnace. Samples were removed from the furnace at the end of the cycle and allowed to cool to room temperature in air. Results of tensile testing are shown in Table 24. As it can be seen, recrystallization during annealing of the alloys herein results in property combinations with ultimate tensile strength in the range from 939 to 1424 MPa and tensile elongation from 15.8 to 77.0%. Yield strength is measured in a range from 420 to 574 MPa.
TABLE-US-00021 TABLE 21 Tensile Properties of Alloys in As-Cast State Yield Strength Ultimate Tensile Tensile Elongation Alloy (MPa) Strength (MPa) (%) Alloy 1 289 527 10.4 288 548 9.3 260 494 8.4 Alloy 2 244 539 10.4 251 592 11.6 249 602 13.1 Alloy 13 144 459 4.6 156 411 4.5 163 471 5.7 Alloy 17 223 562 24.4 234 554 20.7 235 585 23.3 Alloy 24 396 765 8.3 362 662 5.7 404 704 7.0 Alloy 25 282 668 5.1 329 753 5.0 288 731 5.5 Alloy 25 471 788 4.1 514 907 6.0 483 815 3.7 Alloy 27 277 771 3.7 278 900 4.9 267 798 4.5 Alloy 34 152 572 11.1 168 519 11.6 187 545 12.9 Alloy 35 164 566 15.9 172 618 16.6 162 569 16.4
TABLE-US-00022 TABLE 22 Tensile Properties of Alloys in Hot Rolled State First Second Yield Ultimate Tensile Campaign Campaign Strength Tensile Elongation Alloy Condition Reduction Reduction (MPa) Strength (MPa) (%) Alloy Hot Rolled 80.5%, 75.1%, 273 1217 50.0 1 95.2% 6 Passes 3 Passes 264 1216 52.1 285 1238 52.7 Alloy Hot Rolled 87.4%, 73.1%, 480 1236 45.3 2 96.6% 7 Passes 3 Passes 454 1277 41.9 459 1219 48.2 Alloy Hot Rolled 81.1%, 79.8%, 287 1116 18.8 13 96.0% 6 Passes 3 Passes 274 921 15.3 293 1081 19.3 Alloy Hot Rolled 81.2%, 79.1%, 392 947 73.3 17 96.1% 6 Passes 3 Passes 363 949 74.8 383 944 77.7 Alloy Hot Rolled, 81.1%, 79.9%, 519 1176 21.4 24 96.2% 6 Passes 3 Passes 521 1088 18.2 508 1086 17.9 Alloy Hot Rolled 81.0%, 79.4%, 502 1105 12.4 25 96.1% 6 Passes 3 Passes 524 1100 12.3 574 1077 12.0 Alloy Hot Rolled, 80.4%, 78.9%, 508 1401 20.9 27 95.9% 6 Passes 3 Passes 534 1405 22.4 529 1413 19.7 Alloy Hot Rolled, 80.7%, 80.1%, 346 1188 56.5 34 96.2% 6 Passes 3 Passes 323 1248 58.7 303 1230 53.4 Alloy Hot Rolled, 80.8%, 79.9%, 327 1178 63.3 35 96.1% 6 Passes 3 Passes 317 1170 61.2 305 1215 59.6
TABLE-US-00023 TABLE 23 Tensile Properties of Alloys in Cold Rolled State Ultimate Yield Tensile Tensile Strength Strength Elongation Alloy Condition (MPa) (MPa) (%) Alloy 1 Cold Rolled 798 1492 28.5 20.3%, 793 1482 32.1 4 Passes Cold Rolled 1109 1712 21.4 39.6%, 1142 1726 23.0 29 Passes 1203 1729 21.2 Alloy 2 Cold Rolled 966 1613 13.4 28.5%, 998 1615 15.4 5 Passes 1053 1611 20.6 Cold Rolled 1122 1735 20.3 39.1%, 1270 1744 18.3 19 passes Alloy 13 Cold Rolled 1511 1824 9.5 36.0%, 1424 1803 7.7 24 Passes 1361 1763 5.1 Alloy 17 Cold Rolled 1020 1357 24.2 38.5%, 1007 1356 24.9 8 Passes 1071 1357 24.9 Alloy 24 Cold Rolled 1363 1584 1.9 38.2%, 1295 1601 2.5 23 Passes 1299 1599 3.0 Alloy 25 Cold Rolled 1619 1761 1.9 38.0%, 1634 1741 1.7 42 Passes 1540 1749 1.6 Alloy 27 Cold Rolled 1632 1802 2.7 39.4%, 1431 1804 4.1 40 Passes 1645 1831 4.1 Alloy 34 Cold Rolled 1099 1640 14.7 35.%, 840 1636 17.5 14 Passes 1021 1661 18.5 Alloy 35 Cold Rolled 996 1617 23.8 35.5%, 1012 1614 24.5 12 Passes 1020 1616 23.3
TABLE-US-00024 TABLE 24 Tensile Properties of Alloys in Annealed State Yield Strength Ultimate Tensile Tensile Elongation Alloy (MPa) Strength (MPa) (%) Alloy 1 436 1221 54.9 443 1217 56.0 431 1216 59.7 Alloy 2 438 1232 49.7 431 1228 49.8 431 1231 49.4 484 1278 48.3 485 1264 45.5 479 1261 48.7 Alloy 13 441 1424 41.7 440 1412 41.4 429 1417 42.7 Alloy 17 420 946 74.6 421 939 77.0 425 961 74.9 Alloy 24 554 1151 23.5 538 1142 24.3 562 1151 24.3 Alloy 25 500 1274 16.0 502 1271 15.8 483 1280 16.3 Alloy 27 538 1385 20.6 574 1397 20.9 544 1388 21.8 Alloy 27 467 1227 56.7 476 1232 52.7 462 1217 51.6 Alloy 27 439 1166 56.3 438 1166 59.0 440 1177 58.3
[0156] This Case Example demonstrates that due to the unique mechanisms and structural pathway shown in
Case Example #4
Cyclic Reversibility During Cold Rolling and Recrystallization
[0157] Slabs with thickness of 50 mm were laboratory cast from Alloy 1 and Alloy 2 according to the atomic ratios provided in Table 2 and hot rolled into sheets with final thickness of 2.31 mm for Alloy 1 sheet and 2.35 mm for Alloy 2 sheet. Casting and hot rolling procedures are described in Main Body section of current application. Resultant hot rolled sheet from each alloy was used for demonstration of cyclic structure/property reversibility through cold rolling/annealing cycles.
[0158] Hot rolled sheet from each alloy was subjected to three cycles of cold rolling and annealing. Sheet thicknesses before and after hot rolling and cold rolling reduction at each cycle are listed in Table 25. Annealing at 850° C. for 10 min was applied after each cold rolling. Tensile specimens were cut from the sheet in the initial hot rolled state and at each step of the cycling. Tensile properties were measured on an Instron 3369 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s Strain data was collected using Instron's Advanced Video Extensometer.
[0159] The results of tensile testing are plotted in
[0160] Tensile properties for each tested sample are listed in Table 26 and Table 27 for Alloy 1 and Alloy 2, respectively. As it can be seen, Alloy 1 has ultimate tensile strength from 1216 to 1238 MPa in hot rolled state with ductility from 50.0 to 52.7% and yield strength from 264 to 285 MPa. In cold rolled state, the ultimate tensile strength was measured in the range from 1482 to 1517 MPa at each cycle. Ductility was found consistently in the range from 28.5 to 32.8% with significantly higher yield strength of 718 to 830 MPa as compared to that in hot rolled condition. Annealing at each cycle resulted in restoration of the ductility to the range from 47.7 to 59.7% with ultimate tensile strength from 1216 to 1270 MPa. Yield strength after cold rolling and annealing is lower than that after cold rolling and was measured in the range from 431 to 515 MPa that is however higher than that in initial hot rolled condition.
[0161] Similar results with property reversibility between cold rolled and annealed material through cycling were observed for Alloy 2 (
TABLE-US-00025 TABLE 25 Sample Thickness and Cycle Reduction at Cold Rolling Steps Rolling Initial Thickness Final Thickness Cycle Reduction Alloy Cycle (mm) (mm) (%) Alloy 1 1 2.35 1.74 26.0 2 1.74 1.32 24.1 3 1.32 1.02 22.7 Alloy 2 1 2.31 1.85 19.9 2 1.85 1.51 18.4 3 1.51 1.22 19.2
TABLE-US-00026 TABLE 26 Tensile Properties of Alloy 1 Through Cold Rolling/Annealing Cycles 1st Cycle 2nd Cycle 3rd Cycle Cold Cold Cold Property Hot Rolled Rolled Annealed Rolled Annealed Rolled Annealed Ultimate 1217 1492 1221 1497 1239 1517 1270 Tensile 1216 1482 1217 1507 1269 1507 1262 Strength 1238 * 1216 1503 1260 1507 1253 (MPa) Yield 273 798 436 775 487 820 508 Strength 264 793 443 718 466 796 501 (MPa) 285 * 431 830 488 809 515 Tensile 50.0 28.5 54.9 32.8 57.5 32.1 50.5 Elongation 52.1 32.1 56.0 29.4 52.5 30.2 47.7 (%) 52.7 * 59.7 30.9 55.8 30.5 55.5 * Specimens slipped in the grips/data is not available
TABLE-US-00027 TABLE 27 Tensile Properties of Alloy 2 Through Cold Rolling/Annealing Cycles 1st Cycle 2nd Cycle 3rd Cycle Cold Cold Cold Property Hot Rolled Rolled Annealed Rolled Annealed Rolled Annealed Ultimate 1236 1579 1250 1553 1243 1596 1231 Tensile 1277 * 1270 1568 1255 1589 1281 Strength 1219 * 1240 1566 1242 1598 1269 (MPa) Yield 480 1126 466 983 481 1006 475 Strength 454 * 468 969 521 978 507 (MPa) 459 * 454 912 497 1011 518 Tensile 45.3 20.3 53.0 24.1 51.1 22.3 46.9 Elongation 41.9 * 51.2 23.1 52.3 23.2 53.5 (%) 48.2 * 51.1 21.6 49.9 21.0 47.9 * Specimens slipped in the grips/data is not available
[0162] This Case Example demonstrates that the High Strength Nanomodal Structure (Structure #3,
Case Example #5
Bending Ability
[0163] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 28 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described in Main Body section of current application. Resultant sheet from each alloy with final thickness of ˜1.2 mm and Recrystallized Modal Structure (Structure #4,
[0164] Bend tests were performed using an Instron 5984 tensile test platform with an Instron W-6810 guided bend test fixture according to specifications outlined in the ISO 7438 International Standard Metallic materials—Bend test (International Organization for Standardization, 2005). Test specimens were cut by wire EDM to a dimension of 20 mm×55 mm×sheet thickness. No special edge preparation was done to the samples. Bend tests were performed using an Instron 5984 tensile test platform with an Instron W-6810 guided bend test fixture. Bend tests were performed according to specifications outlined in the ISO 7438 International Standard Metallic materials—Bend test (International Organization for Standardization, 2005).
[0165] The test was performed by placing the test specimen on the fixture supports and pushing with a former as shown in
[0166] The distance between supports, l, was fixed according to ISO 7438 during the test at:
Prior to bending, the specimens were lubricated on both sides with 3 in 1 oil to reduce friction with the test fixture. This test was performed with a 1 mm diameter former. The former was pushed downward in the middle of the supports to different angles up to 180° or until a crack appeared. The bending force was applied slowly to permit free plastic flow of the material. The displacement rate was calculated based on the span gap of each test in order to have a constant angular rate and applied accordingly.
[0167] Absence of cracks visible without the use of magnifying aids was considered evidence that the test piece withstood the bend test. If a crack was detected, the bend angle was measured manually with a digital protractor at the bottom of the bend. The test specimen was then removed from the fixture and examined for cracking on the outside of the bend radius. The onset of cracking could not be conclusively determined from the force-displacement curves and was instead easily determined by direct observation with illumination from a flashlight.
[0168] Results of the bending response of the alloys herein are listed in Table 28 including initial sheet thickness, former radius to sheet thickness ratio WO and maximum bend angle before cracking. All alloys listed in the Table 28 did not show cracks at 90° bend angle. The majority of the alloys herein have capability to be bent at 180° angle without cracking. Example of the samples from Alloy 1 after bend testing to 180° is shown in
TABLE-US-00028 TABLE 7 Bend Test Results for Selected Alloys Former Diameter Thickness Maximum Bend Alloy (mm) (mm) r/t Angle (°) Alloy 1 0.95 1.185 0.401 180 1.200 0.396 180 1.213 0.392 180 1.223 0.388 180 1.181 0.402 180 1.187 0.400 180 1.189 0.399 180 1.206 0.394 180 Alloy 2 0.95 1.225 0.388 180 1.230 0.386 180 1.215 0.391 180 1.215 0.391 180 1.215 0.391 180 1.224 0.388 180 1.208 0.393 180 1.208 0.393 180 Alloy 3 0.95 1.212 0.392 180 1.186 0.401 180 1.201 0.396 180 Alloy 4 0.95 1.227 0.387 180 1.185 0.401 180 1.187 0.400 180 Alloy 5 0.95 1.199 0.396 110 1.196 0.397 90 Alloy 6 0.95 1.259 0.377 160 1.202 0.395 165 1.206 0.394 142 Ahoy 7 0.95 1.237 0.384 104 1.236 0.384 90 Alloy 9 0.95 1.278 0.372 180 1.197 0.397 180 1.191 0.399 180 Alloy 10 0.95 1.226 0.387 180 1.208 0.393 100 1.208 0.393 180 1.205 0.394 180 Alloy 11 0.95 1.240 0.383 180 1.214 0.391 180 1.205 0.394 180 Alloy 12 0.95 1.244 0.382 180 1.215 0.391 180 1.205 0.394 180 Alloy 13 0.95 1.222 0.389 180 1.191 0.399 180 1.188 0.400 180 Alloy 14 0.95 1.239 0.383 180 1.220 0.389 180 1.214 0.391 180 Alloy 15 0.95 1.247 0.381 180 1.224 0.388 180 1.224 0.388 180 Alloy 16 0.95 1.244 0.382 180 1.224 0.388 180 1.199 0.396 180 Alloy 17 0.95 1.233 0.385 180 1.213 0.392 180 1.203 0.395 180 Alloy 18 0.95 1.222 0.389 160 1.218 0.390 135 Alloy 19 0.95 1.266 0.375 180 1.243 0.382 180 1.242 0.382 180 Alloy 20 0.95 1.242 0.382 180 1.222 0.389 180 1.220 0.389 180 Alloy 21 0.95 1.255 0.378 180 1.228 0.387 180 1.229 0.386 180 Alloy 22 0.95 1.240 0.383 180 1.190 0.399 180 1.190 0.399 180 Alloy 23 0.95 1.190 0.399 180 1.199 0.396 180 1.193 0.398 180 Alloy 28 0.95 1.222 0.389 180 1.206 0.394 180 1.204 0.395 180 Alloy 29 0.95 1.219 0.390 180 1.217 0.390 180 1.206 0.394 180 Alloy 30 0.95 1.215 0.391 180 1.212 0.392 175 1.200 0.396 180 Alloy 31 0.95 1.211 0.392 150 1.209 0.393 131 Alloy 32 0.95 1.222 0.389 180 1.221 0.389 180 1.210 0.393 180
[0169] In order to be made into complex parts for automobile and other uses, an AHSS needs to exhibit both bulk sheet formability and edge sheet formability. This Case Example demonstrates good bulk sheet formability of the alloys in Table 2 through bend testing.
Case Example #6
Punched Edge vs EDM Cut Tensile Properties
[0170] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 2according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0171] Tensile specimens in the ASTM E8 geometry were prepared using both wire EDM cutting and punching. Tensile properties were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s. Strain data was collected using Instron's Advanced Video Extensometer. Tensile data is shown in Table 29 and illustrated in
TABLE-US-00029 TABLE 8 Tensile Properties of Punched vs EDM Cut Specimens from Selected Alloys Cutting Yield Strength Ultimate Tensile Tensile Alloy Method (MPa) Strength (MPa) Elongation (%) Alloy 1 EDM Cut 392 1310 46.7 397 1318 45.1 400 1304 49.7 Punched 431 699 9.3 430 680 8.1 422 656 6.9 Alloy 2 EDM Cut 434 1213 46.4 452 1207 46.8 444 1199 49.1 Punched 491 823 14.4 518 792 11.3 508 796 11.9 Alloy 9 EDM Cut 468 1166 56.1 480 1177 52.4 475 1169 56.9 Punched 508 1018 29.2 507 1007 28.6 490 945 23.3 Alloy 11 EDM Cut 474 1115 64.4 464 1165 62.5 495 1127 62.7 Punched 503 924 24.6 508 964 28.0 490 921 25.7 Alloy 12 EDM Cut 481 1094 54.4 479 1128 64.7 495 1126 62.4 Punched 521 954 27.1 468 978 30.7 506 975 31.2 Alloy 13 EDM Cut 454 1444 39.5 450 1455 38.7 Punched 486 620 5.0 469 599 6.3 483 616 4.5 Alloy 14 EDM Cut 484 1170 58.7 489 1182 61.2 468 1188 59.0 Punched 536 846 17.0 480 816 18.4 563 870 17.5 Alloy 18 EDM Cut 445 1505 37.8 422 1494 37.5 Punched 478 579 2.4 469 561 2.6 463 582 2.9 Alloy 21 EDM Cut 464 1210 57.6 499 1244 49.0 516 1220 54.5 Punched 527 801 11.3 511 806 12.6 545 860 15.2 Alloy 24 EDM Cut 440 1166 31.0 443 1167 32.0 455 1176 31.0 Punched 496 696 5.0 463 688 5.0 440 684 4.0 Alloy 25 EDM Cut 474 1183 15.8 470 1204 17.0 485 1223 17.4 Punched 503 589 2.1 517 579 0.8 497 583 2.1 Alloy 26 EDM Cut 735 1133 20.8 742 1109 19.0 Punched 722 898 3.4 747 894 2.9 764 894 3.1 Alloy 27 EDM Cut 537 1329 19.3 513 1323 21.4 480 1341 20.8 Punched 563 624 4.3 568 614 3.3 539 637 4.3 Alloy 34 EDM Cut 460 1209 54.7 441 1199 54.1 475 1216 52.9 Punched 489 828 15.4 486 811 14.6 499 813 14.8 Alloy 35 EDM Cut 431 1196 50.6 437 1186 52.0 420 1172 54.7 Punched 471 826 19.9 452 828 19.7 482 854 19.7
TABLE-US-00030 TABLE 9 Tensile Elongation in Specimens with Different Cutting Methods Loss In Tensile Elongation Average Tensile Elongation (%) (E2/E1) Alloy EDM Cut (E1) Punched (E2) Min Max Alloy 1 47.2 8.1 0.14 0.21 Alloy 2 47.4 12.5 0.23 0.31 Alloy 9 55.1 27.0 0.41 0.56 Alloy 11 63.2 26.1 0.38 0.45 Alloy 12 60.5 29.7 0.42 0.57 Alloy 13 39.1 5.2 0.11 0.16 Alloy 14 59.7 17.7 0.28 0.31 Alloy 18 37.6 2.6 0.06 0.08 Alloy 21 53.7 13.0 0.20 0.31 Alloy 24 31.3 4.7 0.13 0.16 Alloy 25 16.7 1.7 0.05 0.13 Alloy 26 31.3 4.7 0.14 0.18 Alloy 27 20.5 4.0 0.15 0.22 Alloy 34 53.9 14.9 0.27 0.29 Alloy 35 52.4 19.8 0.36 0.39
[0172] As can be seen from Table 30, EDM cutting is considered to be representative of the optimal mechanical properties of the identified alloys, without a sheared edge, and which were processed to the point of assuming Structure #4 (Recrystallized Modal Structure). Accordingly, samples having a sheared edge due to punching indicate a significant drop in ductility as reflected by tensile elongation measurements of the punched samples having the ASTM E8 geometry. For Alloy 1, tensile elongation is initially 47.2% and then drops to 8.1%, a drop itself of 82.8%%. The drop in ductility from the punched to the EDM cut (E2/E1) varies from 0.57 to 0.05.
[0173] The edge status after punching and EDM cutting was analyzed by SEM using an EVO-MA10 scanning electron microscope manufactured by Carl Zeiss SMT Inc. The typical appearance of the specimen edge after EDM cutting is shown for Alloy 1 in
[0174] This Case Example demonstrates that in a case of wire-EDM cutting tensile properties are measured at relative higher level as compared to that after punching. In contrast to EDM cutting, punching of the tensile specimens creates a significant edge damage which results in tensile property decrease. Relative excessive plastic deformation of the sheet alloys herein during punching leads to structural transformation to a Refined High Strength Nanomodal Structure (Structure #5,
Case Example #7
Punched Edge vs EDM Cut Tensile Properties and Recovery
[0175] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 31 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0176] Tensile specimens in the ASTM E8 geometry were prepared using both wire EDM cutting and punching. Part of punched tensile specimens was then put through a recovery anneal of 850° C. for 10 minutes, followed by an air cool, to confirm the ability to recover properties lost by punching and shearing damage. Tensile properties were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 min/s. Strain data was collected using Instron's Advanced Video Extensometer. Tensile testing results are provided in Table 31 and illustrated in
[0177] For example, in the case of Alloy 1 indicated, when EDM cut into a tensile testing sample, a tensile elongation average value is about 47.2%. As noted above, when punched and therefore containing a sheared edge, the tensile testing of the sample with such edge indicated a significant drop in such elongation values, i.e. an average value of only about 8.1% due to Mechanism #4 and formation of Refined High Strength Nanomodal Structure (Structure 45
TABLE-US-00031 TABLE 10 Tensile Properties of Punched and Annealed Specimens from Selected Alloys Ultimate Yield Tensile Tensile Cutting Strength Strength Elongation Alloy Method (MPa) (MPa) (%) Alloy 1 EDM Cut 392 1310 46.7 397 1318 45.1 400 1304 49.7 Punched 431 699 9.3 430 680 8.1 422 656 6.9 Punched & 364 1305 43.6 Annealed 364 1315 47.6 370 1305 47.3 Alloy 2 EDM Cut 434 1213 46.4 452 1207 46.8 444 1199 49.1 Punched 491 823 14.4 518 792 11.3 508 796 11.9 Punched & 432 1205 50.4 Annealed 426 1191 50.7 438 1188 49.3 Alloy 9 EDM Cut 468 1166 56.1 480 1177 52.4 475 1169 56.9 Punched 508 1018 29.2 507 1007 28.6 490 945 23.3 Punched & 411 1166 59.0 Annealed 409 1174 52.7 418 1181 55.6 Alloy 11 EDM Cut 474 1115 64.4 464 1165 62.5 495 1127 62.7 Punched 503 924 24.6 508 964 28.0 490 921 25.7 Punched & 425 1128 64.5 Annealed 429 1117 57.1 423 1140 54.3 Alloy 12 EDM Cut 481 1094 54.4 479 1128 64.7 495 1126 62.4 Punched 521 954 27.1 468 978 30.7 506 975 31.2 Punched & 419 1086 65.7 Annealed 423 1085 63.0 415 1100 53.8 Alloy 13 EDM Cut 454 1444 39.5 450 1455 38.7 Punched 486 620 5.0 469 599 6.3 483 616 4.5 Punched & 397 1432 41.4 Annealed 397 1437 37.4 404 1439 40.3 Alloy 14 EDM Cut 484 1170 58.7 489 1182 61.2 468 1188 59.0 Punched 536 846 17.0 480 816 18.4 563 870 17.5 Punched & 423 1163 58.3 Annealed 412 1168 55.9 415 1177 51.5 Alloy 18 EDM Cut 445 1505 37.8 422 1494 37.5 Punched 478 579 2.4 469 561 2.6 463 582 2.9 Punched & 398 1506 36.3 Annealed 400 1502 40.3 392 1518 35.4 Alloy 21 EDM Cut 464 1210 57.6 499 1244 49.0 516 1220 54.5 Punched 527 801 11.3 511 806 12.6 545 860 15.2 Punched & 409 1195 47.7 Annealed 418 1214 53.8 403 1194 51.8 Alloy 24 EDM Cut 440 1166 31.0 443 1167 32.0 455 1176 31.0 Punched 496 696 5.0 463 688 5.0 440 684 4.0 Punched & 559 1100 22.3 Annealed 581 1113 22.0 561 1100 22.3 Alloy 25 EDM Cut 474 1183 15.8 470 1204 17.0 485 1223 17.4 Punched 503 589 2.1 517 579 0.8 497 583 2.1 Punched & 457 1143 15.4 Annealed 477 1159 14.6 423 1178 16.3 Alloy 26 EDM Cut 735 1133 20.8 742 1109 19.0 Punched 722 898 3.4 747 894 2.9 764 894 3.1 Punched & 715 1112 18.8 Annealed 713 1098 17.8 709 931 10.0 Alloy 27 EDM Cut 537 1329 19.3 513 1323 21.4 480 1341 20.8 Punched 563 624 4.3 568 614 3.3 539 637 4.3 Punched & 505 1324 19.7 Annealed 514 1325 20.0 539 1325 19.4 Alloy 29 EDM Cut 460 1209 54.7 441 1199 54.1 475 1216 52.9 Punched 489 828 15.4 486 811 14.6 499 813 14.8 Punched & 410 1204 53.9 Annealed 410 1220 53.2 408 1214 52.3 Alloy 32 EDM Cut 431 1196 50.6 437 1186 52.0 420 1172 54.7 Punched 471 826 19.9 452 828 19.7 482 854 19.7 Punched & 406 1169 58.1 Annealed 403 1170 51.4 405 1176 57.7
TABLE-US-00032 TABLE 32 Summary of Tensile Properties; Loss (E2/E1) and Gain (E3/E1) Loss In Tensile Elongation Gain in Tensile Elongation (E2/E1) (E3/E1) Alloy Min Max Min Max Alloy 1 0.14 0.21 0.88 1.06 Alloy 2 0.23 0.31 1.00 1.09 Alloy 9 0.41 0.56 0.93 1.13 Alloy 11 0.38 0.45 0.84 1.03 Alloy 12 0.42 0.57 0.83 1.21 Alloy 13 0.11 0.16 0.95 1.07 Alloy 14 0.28 0.31 0.84 0.99 Alloy 18 0.06 0.08 0.94 1.07 Alloy 21 0.20 0.31 0.83 1.10 Alloy 24 0.13 0.16 0.69 0.72 Alloy 25 0.05 0.13 0.89 1.03 Alloy 26 0.14 0.18 0.48 0.99 Alloy 27 0.15 0.22 0.91 1.04 Alloy 29 0.27 0.29 0.97 1.02 Alloy 32 0.36 0.39 0.94 1.15
[0178] Punching of tensile specimens results in edge damage and lowering the tensile properties of the material. Plastic deformation of the sheet alloys herein during punching leads to structural transformation to a Refined High Strength Nanomodal Structure (Structure #5,
Case Example #8
Temperature Effect on Recovery and Recrystallization
[0179] Slabs with thickness of 50 mm were laboratory cast from Alloy 1 and laboratory processed by hot rolling down to thickness of 2 mm and cold rolling with reduction of approximately 40%. Tensile specimens in the ASTM E8 geometry were prepared by wire EDM cut from cold rolled sheet. Part of tensile specimens was annealed for 10 minutes at different temperatures in a range from 450 to 850° C., followed by an air cool. Tensile properties were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s. Strain data was collected using Instron's Advanced Video Extensometer. Tensile testing results are shown in
[0180] To show the microstructural recovery in accordance to the tensile property upon annealing, TEM studies were conducted on selected samples that were annealed at different temperatures. For comparison, cold rolled sheet was included as a baseline herein. Laboratory cast Alloy 1 slab of 50 mm thick was used, and the slab was hot rolled at 1250° C. by two-step of 80.8% and 78.3% to approx. 2 mm thick, then cold rolled by 37% to sheet of 1.2 mm thick. The cold rolled sheet was annealed at 450° C., 600° C., 650° C. and 700° C. respectively for 10 minutes.
[0181] One reason behind the difference in recovery and transition in deformation behavior is illustrated by the model TTT diagram in
[0182] In other words, in the broad context of the present invention, the effect of shearing and formation of a sheared edge, and its associated negative influence on mechanical properties, can be at least partially recovered at temperatures of 450° C. up to 650° C. as shown in
[0183] Accordingly, this Case Example demonstrates that upon deformation during cold rolling, concurrent processes occur involving dynamic strain hardening and phase transformation through unique Mechanisms #2 or #3 (
Case Example #9
Temperature Effect of Punched Edge Recovery
[0184] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 33 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described in Main Body section of current application. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0185] Tensile specimens in the ASTM E8 geometry were prepared by punching. A part of punched tensile specimens from selected alloys was then put through a recovery anneal for 10 minutes at different temperatures in a range from 450 to 850° C., followed by an air cool. Tensile properties were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 mm/s. Strain data was collected using Instron's Advanced Video Extensometer.
[0186] Tensile testing results are shown in Table 32 and in
[0187] Microstructural changes in Alloy 1 at the shear edge as a result of the punching and annealing at different temperatures were examined by SEM. Cross section samples were cut from ASTM E8 punched tensile specimens near the sheared edge in as-punched condition and after annealing at 650° C. and 700° C. as shown in
[0188] For SEM study, the cross section samples were ground on SiC abrasive papers with reduced grit size, and then polished progressively with diamond media paste down to 1 μm. The final polishing was done with 0.02 μm grit SiO2 solution. Microstructures were examined by SEM using an EVO-MA10 scanning electron microscope manufactured by Carl Zeiss SMT Inc.
[0189]
[0190] Punching of tensile specimens result in edge damage lowering the tensile properties of the material. Plastic deformation of the sheet alloys herein during punching leads to structural transformation to a Refined High Strength Nanomodal Structure (Structure #5,
TABLE-US-00033 TABLE 33 Tensile Properties after Punching and Annealing at Different Temperatures Ultimate Anneal Yield Tensile Tensile Temperature Strength Strength Elongation Alloy (° C.) (MPa) (MPa) (%) Alloy 1 As Punched 494 798 12.6 487 829 14.3 474 792 15.3 450 481 937 21.5 469 934 20.9 485 852 19.3 600 464 1055 27.3 472 1103 30.5 453 984 23.7 650 442 1281 51.5 454 1270 45.4 445 1264 51.1 700 436 1255 50.1 442 1277 52.1 462 1298 51.6 850 407 1248 52.0 406 1260 47.8 412 1258 48.5 Alloy 9 As Punched 508 1018 29.2 507 1007 28.6 490 945 23.3 600 461 992 28.5 462 942 24.8 471 968 25.6 650 460 1055 33.0 470 1166 48.3 473 1177 49.3 700 457 1208 57.5 455 1169 50.3 454 1171 61.6 850 411 1166 59.0 409 1174 52.7 418 1181 55.6 Alloy 12 As Punched 521 954 27.1 468 978 30.7 506 975 31.2 600 462 1067 44.9 446 1013 41.3 471 1053 41.1 650 452 1093 61.5 449 1126 57.8 505 1123 55.4 700 480 1112 59.6 460 1117 61.8 468 1096 61.5 850 419 1086 65.7 423 1085 63.0 415 1100 53.8
Case Example #10
Effect of Punching Speed on Punched Edge Property Reversibility
[0191] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 34 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0192] Tensile specimens in the ASTM E8 geometry were prepared by punching at three different speeds of 28 mm/s, 114 mm/s, and 228 min/s. Wire EDM cut specimens from the same materials were used for the reference. A part of punched tensile specimens from selected alloys was then put through a recovery anneal for 10 minutes at 850° C., followed by an air cool. Tensile properties were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.012 min/s. Strain data was collected using Instron's Advanced Video Extensometer. Tensile testing results are listed in Table 34 and tensile properties as a function of punching speed for selected alloys are illustrated in
TABLE-US-00034 TABLE 34 Tensile Properties of Specimens Punched at Different Speed vs EDM Cut Sample Yield Tensile Tensile Preparation Strength Strength Elongation Alloy Method (MPa) (MPa) (%) Alloy 1 EDM 459 1255 51.2 443 1271 46.4 441 1248 52.7 453 1251 55.0 467 1259 51.3 228 mm/s Punched 474 952 21.8 498 941 21.6 493 956 21.6 114 mm/s Punched 494 798 13.4 487 829 15.1 474 792 14.1 28 mm/s Punched 464 770 12.8 479 797 13.7 465 755 12.1 Alloy 9 EDM 468 1166 56.1 480 1177 52.4 475 1169 56.9 228 mm/s Punched 500 1067 35.1 493 999 28.8 470 1042 31.8 114 mm/s Punched 508 1018 29.2 507 1007 28.6 490 945 23.3 28 mm/s Punched 473 851 19.7 472 841 16.4 494 846 18.9 Alloy 12 EDM 481 1094 54.4 479 1128 64.7 495 1126 62.4 228 mm/s Punched 495 1124 53.8 484 1123 53.0 114 mm/s Punched 521 954 27.1 468 978 30.7 506 975 31.2 28 mm/s Punched 488 912 23.6 472 900 21.7 507 928 22.9
[0193] This Case Example demonstrates that punching speed can have a significant effect on the resulting tensile properties in steel alloys herein. Localized heat generation at punching might be a factor in recovery of the structure near the edge leading to property improvement.
Case Example #11
Edge Structure Transformation During Hole Punching and Expansion
[0194] Slabs with thickness of 50 mm were laboratory cast from Alloy 1 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0195] Specimens for testing with a size of 89×89 mm were wire EDM cut from the sheet. The hole with 10 mm diameter was cut in the middle of specimens by utilizing two methods: punching and drilling with edge milling. The hole punching was done on an Instron Model 5985 Universal Testing System using a fixed speed of 0.25 mm/s with 16% clearance. Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation. The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0196] Results of HER testing are shown in
[0197] Microhardness was measured for Alloy 1 at all relevant stages of the hole expansion process. Microhardness measurements were taken along cross sections of sheet samples in the annealed (before punching and HER testing), as-punched, and HER tested conditions. Microhardness was also measured in cold rolled sheet from Alloy 1 for reference. Measurement profiles started at an 80 micron distance from the edge of the sample, with an additional measurement taken every 120 microns until 10 such measurements were taken. After that point, further measurements were taken every 500 microns, until at least 5 mm of total sample length had been measured. A schematic illustration of microhardness measurement locations in HER tested samples is shown in
[0198] As shown in
[0199] To prepare the TEM specimens, the HER test samples were first sectioned by wire EDM, and a piece with a portion of hole edge was thinned by grinding with pads of reduced grit size. Further thinning to ˜60 μm thickness is done by polishing with 9 μm, 3 μm, and 1 μm diamond suspension solution respectively. Discs of 3 mm in diameter were punched from the foils near the edge of the hole and the final polishing was completed by electropolishing using a twin-jet polisher. The chemical solution used was a 30% Nitric acid mixed in Methanol base. In case of insufficient thin area for TEM observation, the TEM specimens may be ion-milled using a Gatan Precision Ion Polishing System (PIPS). The ion-milling usually is done at 4.5 keV, and the inclination angle is reduced from 4° to 2° to open up the thin area. The TEM studies were done using a JEOL 2100 high-resolution microscope operated at 200 kV. Since the location for TEM study is at the center of the disc, the observed microstructure is approximately ˜1.5 mm from the edge of hole.
[0200] The initial microstructure of the Alloy 1 sheet before testing is shown on
[0201] To analyze in more detail the reason causing the poor HER performance in samples with punched holes, Focused Ion Beam (FIB) technique was utilized to make TEM specimens at the very edge of the punched hole. As shown in
Case Example #12
HER Testing Results With and Without Annealing
[0202] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 35 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0203] Test specimens of 89×89 mm were wire EDM cut from the sheet from larger sections. A 10 mm diameter hole was made in the center of specimens by punching on an Instron Model 5985 Universal Testing System using a fixed speed of 0.25 mm/s at 16% punch to die clearance. Half of the prepared specimens with punched holes were individually wrapped in stainless steel foil and annealed at 850° C. for 10 minutes before HER testing. Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0204] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0205] .The results of the hole expansion ratio measurements on the specimens with and without annealing after hole punching are shown in Table 35. As shown in
TABLE-US-00035 TABLE 35 Hole Expansion Ratio Results for Select Alloys With and Without Annealing Measured Average Hole Hole Punch Expansion Expansion Clearance Ratio Ratio Material Condition (%) (%) (%) Alloy 1 Without 16 3.00 3.20 Annealing 3.90 2.70 With 16 105.89 93.10 Annealing 81.32 92.11 Alloy 9 Without 16 3.09 3.19 Annealing 3.19 3.29 With 16 78.52 87.84 Annealing 97.60 87.40 Alloy 12 Without 16 4.61 4.91 Annealing 5.21 With 16 69.11 77.60 Annealing 83.60 80.08 Alloy 13 Without 16 1.70 1.53 Annealing 1.40 1.50 With 16 32.37 31.12 Annealing 29.00 32.00 Alloy 17 Without 16 12.89 21.46 Annealing 28.70 22.80 With 16 104.21 103.74 Annealing 80.42 126.58
[0206] This Case Example demonstrates that edge formability demonstrated during HER testing can yield poor results due to edge damage during the punching operation as a result of the unique mechanisms in the alloys listed in Table 2. The fully post processed alloys exhibit very high tensile ductility as shown in Table 6 through Table 10 coupled with very high strain hardening and resistance to necking until near failure. Thus, the material resists catastrophic failure to a great extent but during punching, artificial catastrophic failure is forced to occur near the punched edge. Due to the unique reversibility of the identified mechanisms, this deleterious edge damage as a result of Nanophase Refinement & Strengthening (Mechanism #3,
[0207] In addition, it can be appreciated that the alloys herein that have undergone the processing pathways to provide such alloys in the form of Structure #4 (Recrystallized Modal Structure) will indicate, for a hole that is formed by shearing, and including a sheared edge, a first hole expansion ratio (HER.sub.1) and upon heating the alloy will have a second hole expansion ratio (HER.sub.2), wherein HER.sub.2>HER.sub.1.
[0208] More specifically, it can also be appreciated that the alloys herein that have undergone the processing pathways to provide such alloys with Structure #4 (Recrystallized Modal Structure) will indicate, for a hole that was placed in the alloy through methods (i.e. waterjet cutting, laser cutting, wire-edm, milling etc.) where the hole that is formed that does not rely primarily on shearing, compared to punching a hole, a first hole expansion ratio (HER.sub.1) where such value may itself fall in the range of 30 to 130%. However, when the same alloy includes a hole formed by shearing, a second hole expansion ratio is observed (HER.sub.2) wherein HER.sub.2=(0.01 to 0.30)(HER.sub.1). However, if the alloy is then subject to heat treatment herein, it is observed that HER.sub.2 is recovered to a HER.sub.3=(0.60 to 1.0) HER.sub.1.
Case Example #13
Edge Condition Effect on Alloy Properties
[0209] Slabs with thickness of 50 mm were laboratory cast from Alloy 1 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from Alloy 1 with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0210] Tensile specimens of AS TM E8 geometry were created using two methods: Punching and wire EDM cutting. Punched tensile specimens were created using a commercial press. A subset of punched tensile specimens was heat treated at 850° C. for 10 minutes to create samples with a punched then annealed edge condition.
[0211] Tensile properties of ASTM E8 specimens were measured on an Instron 5984 mechanical testing frame using Instron's Bluehill 3 control software. All tests were conducted at room temperature, with the bottom grip fixed and the top grip set to travel upwards at a rate of 0.025 mm/s for the first 0.5% elongation, and at a rate of 0.125 mm/s after that point. Strain data was collected using Instron's Advanced Video Extensometer. Tensile properties of Alloy 1 with punched, EDM cut, and punched then annealed edge conditions are shown in Table 36. Tensile properties of Alloy 1 with different edge conditions are shown in
TABLE-US-00036 TABLE 36 Tensile Properties of Alloy 1 with Different Edge Conditions Ultimate Tensile Tensile Edge Elongation Strength Condition (%) (MPa) Punched 12.6 798 14.3 829 15.3 792 EDM Cut 50.5 1252 51.2 1255 52.7 1248 55.0 1251 51.3 1259 50.5 1265 Punched 52.0 1248 Then 47.8 1260 Annealed 48.5 1258
[0212] Specimens for hole expansion ratio testing with a size of 89×89 mm were wire EDM cut from the sheet. The holes with 10 mm diameter were prepared by two methods: punching and cutting by wire EDM. The punched holes with 10 mm diameter were created by punching at 0.25 mm/s on an Instron 5985 Universal Testing System with a 16% punch clearance and with using the flat punch profile geometry. A subset of punched samples for hole expansion testing were annealed with an 850° C. for 10 minutes heat treatment after punching.
[0213] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0214] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0215] Hole expansion ratio testing results are shown in Table 37. An average hole expansion ratio value for each edge condition is also shown. The average hole expansion ratio for each edge condition is plotted in
TABLE-US-00037 TABLE 37 Hole Expansion Ratio of Alloy 1 with Different Edge Conditions Measured Average Hole Hole Expansion Expansion Edge Ratio Ratio Condition (%) (%) Punched 3.00 3.20 3.90 2.70 EDM Cut 92.88 82.43 67.94 86.47 Punched 105.90 93.10 Then 81.30 Annealed 92.10
[0216] This Case Example demonstrates that the edge condition of Alloy 1 has a distinct effect on the tensile properties and edge formability (i.e. HER response). Tensile samples tested with punched edge condition have diminished properties when compared to both wire EDM cut and punched after subsequent annealing. Samples having the punched edge condition have hole expansion ratios averaging 3.20%, whereas EDM cut and punched then annealed edge conditions have hole expansion ratios of 82.43% and 93.10%, respectively. Comparison of edge conditions also demonstrates that damage associated with edge creation (i.e. via punching) has a non-trivial effect on the edge formability of the alloys herein.
Case Example #14
HER Results as a Function of Hole Punching Speed
[0217] Slabs with thickness of 50 mm were laboratory cast from selected alloys listed in Table 38 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0218] Specimens for testing with a size of 89×89 mm were wire EDM cut from the sheet. The holes with 10 mm diameter were punched at different speeds on two different machines but all of the specimens were punched with a 16% punch clearance and with the same punch profile geometry. The low speed punched holes (0.25 mm/s, 8 mm/s) were punched using an Instron 5985 Universal Testing System and the high speed punched holes (28 mm/s, 114 mm/s, 228 mm/s) were punched on a commercial punch press. All holes were punched using a flat punch geometry.
[0219] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0220] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0221] Hole expansion ratio values for tests are shown in Table 37. An average hole expansion value is shown for each speed and alloy tested at 16% punch clearance. The average hole expansion ratio as a function of punch speed is shown in
TABLE-US-00038 TABLE 38 Hole Expansion Ratio at Different Punch Speeds Measured Average Hole Hole Punch Expansion Expansion Speed Ratio Ratio Material (mm/s) (%) (%) Alloy 1 0.25 3.00 3.20 0.25 3.90 0.25 2.70 8 4.49 3.82 8 3.49 8 3.49 28 8.18 7.74 28 8.08 28 6.97 114 17.03 17.53 114 19.62 114 15.94 228 20.44 21.70 228 21.24 228 23.41 Alloy 9 0.25 3.09 3.19 0.25 3.19 0.25 3.29 8 6.80 6.93 8 7.39 8 6.59 28 21.04 19.11 28 17.35 28 18.94 114 24.80 24.29 114 19.74 114 28.34 228 26.00 30.57 228 35.16 228 30.55 Alloy 12 0.25 4.61 4.91 0.25 5.21 8 7.62 11.28 8 14.61 8 11.62 28 29.38 31.59 28 33.70 28 31.70 114 40.08 45.50 114 48.11 114 48.31 228 50.00 49.36 228 40.56 228 57.51
[0222] This Case Example demonstrates a dependence of edge formability on punching speed as measured by the hole expansion ratio. As punch speed increases, the hole expansion ratio generally increases for the alloys tested. With increased punching speed, the nature of the edge is changed such that improved edge formability (i.e. HER response) is achieved. At punching speeds greater than those measured, edge formability is expected to continue improving towards even higher hole expansion ratio values.
Case Example #15
HER in DP980 as a Function of Hole Punching Speed
[0223] Commercially produced and processed Dual Phase 980 steel was purchased and hole expansion ratio testing was performed. All specimens were tested in the as received (commercially processed) condition.
[0224] Specimens for testing with a size of 89×89 mm were wire EDM cut from the sheet. The holes with 10 mm diameter were punched at different speeds on two different machines but all of the specimens were punched with a 16% punch clearance and with the same punch profile geometry using a commercial punch press. The low speed punched holes (0.25 min/s) were punched using an Instron 5985 Universal Testing System and the high speed punched holes (28 mm/s, 114 mm/s, 228 min/s) were punched on a commercial punch press. All holes were punched using a flat punch geometry.
[0225] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0226] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0227] Values for hole expansion tests are shown in Table 39. The average hole expansion value for each punching speed is also shown for commercial Dual Phase 980 material at 16% punch clearance. The average hole expansion value is plotted as a function of punching speed for commercial Dual Phase 980 steel in
TABLE-US-00039 TABLE 39 Hole Expansion Ratio of Dual Phase 980 Steel at Different Punch Speeds Measured Average Hole Hole Punch Expansion Expansion Speed Ratio Ratio Material (mm/s) (%) (%) Commercial Dual 0.25 23.55 22.45 Phase 980 0.25 20.96 0.25 22.85 28 18.95 18.26 28 17.63 28 18.21 114 17.40 20.09 114 23.66 114 19.22 228 27.21 23.83 228 24.30 228 19.98
[0228] This Case Example demonstrates that no edge performance effect based on punch speed is measureable in Dual Phase 980 steel. For all punch speeds measured on Dual Phase 980 steel the edge performance (i.e. HER response) is consistently within the 21%±3% range, indicating that edge performance in conventional AHSS is not improved by punch speed as expected since the unique structures and mechanisms present in this application as for example in
Case Example #16
HER Results as a Function of Punch Design
[0229] Slabs with thickness of 50 mm were laboratory cast from Alloys 1, 9, and 12 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Resultant sheet from each alloy with final thickness of 1.2 mm and Recrystallized Modal Structure (Structure #4,
[0230] Tested specimens of 89×89 mm were wire EDM cut from larger sections. A 10 mm diameter hole was punched in the center of the specimen at three different speeds, 28 mm/s, 114 min/s, and 228 mm/s at 16% punch clearance and with four punch profile geometries using a commercial punch press. These punch geometries used were flat, 6° tapered, 7° conical, and conical flat. Schematic drawings of the 6° tapered, 7° conical, and conical flat punch geometries are shown in
[0231] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0232] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0233] Hole expansion ratio data is included respectively in Table 40, Table 41, and Table 42 for Alloy 1, Alloy 9, and Alloy 12 at four punch geometries and at two different punch speeds. The average hole expansion values for Alloy 1, Alloy 9, and Alloy 12 are shown in
TABLE-US-00040 TABLE 40 Hole Expansion Ratio of Alloy 1 with Different Punch Geometries Measured Average Hole Hole Punch Expansion Expansion Punch Speed Ratio Ratio Geometry (mm/s) (%) (%) Flat 28 8.18 7.74 Flat 28 8.08 Flat 28 6.97 Flat 114 17.03 17.53 Flat 114 19.62 Flat 114 15.94 Flat 228 20.44 21.70 Flat 228 21.24 Flat 228 23.41 6° Taper 28 7.87 8.32 6° Taper 28 8.77 6° Taper 114 19.84 18.48 6° Taper 114 16.55 6° Taper 114 19.04 7° Conical 28 8.37 10.56 7° Conical 28 12.05 7° Conical 28 11.25 7° Conical 114 23.41 22.85 7° Conical 114 21.14 7° Conical 114 24.00 7° Conical 228 21.71 21.37 7° Conical 228 19.50 7° Conical 228 22.91 Conical Flat 28 8.47 11.95 Conical Flat 28 13.25 Conical Flat 28 14.14 Conical Flat 114 20.42 19.75 Conical Flat 114 19.22 Conical Flat 114 19.62 Conical Flat 228 24.13 22.39 Conical Flat 228 23.31 Conical Flat 228 19.72
TABLE-US-00041 TABLE 41 Hole Expansion Ratio of Alloy 9 with Different Punch Geometries Measured Average Hole Hole Punch Expansion Expansion Punch Speed Ratio Ratio Geometry (mm/s) (%) (%) Flat 28 21.04 19.11 Flat 28 17.35 Flat 28 18.94 Flat 114 24.80 24.29 Flat 114 19.74 Flat 114 28.34 Flat 228 26.00 30.57 Flat 228 35.16 Flat 228 30.55 6° Taper 28 17.35 19.36 6° Taper 28 19.06 6° Taper 28 21.66 6° Taper 114 29.64 31.14 6° Taper 114 32.14 6° Taper 114 31.64 7° Conical 28 22.63 24.05 7° Conical 28 23.61 7° Conical 28 25.92 7° Conical 114 34.36 32.60 7° Conical 114 31.67 7° Conical 114 31.77 7° Conical 228 36.28 36.44 7° Conical 228 38.87 7° Conical 228 34.16 Conical Flat 28 27.72 25.59 Conical Flat 28 24.63 Conical Flat 28 24.43 Conical Flat 114 30.28 32.64 Conical Flat 114 32.87 Conical Flat 114 34.76 Conical Flat 228 32.90 35.45 Conical Flat 228 37.45 Conical Flat 228 35.99
TABLE-US-00042 TABLE 42 Hole Expansion Ratio of Alloy 12 with Different Punch Geometries Measured Average Hole Hole Punch Expansion Expansion Punch Speed Ratio Ratio Geometry (mm/s) (%) (%) Flat 28 29.38 31.59 Flat 28 33.70 Flat 28 31.70 Flat 114 40.08 45.50 Flat 114 48.11 Flat 114 48.31 Flat 228 50.00 49.36 Flat 228 40.56 Flat 228 57.51 6° Taper 28 29.91 30.67 6° Taper 28 32.50 6° Taper 28 29.61 6° Taper 114 38.42 41.19 6° Taper 114 44.37 6° Taper 114 40.78 7° Conical 28 34.90 33.76 7° Conical 28 33.00 7° Conical 28 33.37 7° Conical 114 45.72 49.10 7° Conical 114 49.30 7° Conical 114 52.29 7° Conical 228 58.90 54.36 7° Conical 228 53.43 7° Conical 228 50.75 Conical Flat 28 37.15 34.43 Conical Flat 28 31.47 Conical Flat 28 34.66 Conical Flat 114 45.76 46.36 Conical Flat 114 45.96 Conical Flat 114 47.36 Conical Flat 228 57.51 54.11 Conical Flat 228 53.48 Conical Flat 228 51.34
[0234] This Case Example demonstrates that for all alloys tested, there is an effect of punch geometry on edge formability. For all alloys tested, the conical punch shapes resulted in the largest hole expansion ratios, thereby demonstrating that modifying the punch geometry from a flat punch to a conical punch shape reduces the damage within the material due to the punched edge and improves edge formability. The 7° conical punch geometry resulted in the greatest edge formability increase overall when compared to the flat punch geometry with the conical flat geometry producing slightly lower hole expansion ratios across the majority of alloys tested. For Alloy 1 the effect of punch geometry is diminished with increasing punching speed, with the three tested geometries resulting in nearly equal edge formability as measured by hole expansion ratio (
Case Example #17
HER in Commercial Steel Grades as a Function of Hole Punching Speed
[0235] Hole expansion ratio testing was performed on commercial steel grades 780, 980 and 1180. All specimens were tested in the as received (commercially processed) sheet condition.
[0236] Specimens for testing with a size of 89×89 mm were wire EDM cut from the sheet of each grade. The holes with 10 mm diameter were punched at different speeds on two different machines with the same punch profile geometry using a commercial punch press. The low speed punched holes (0.25 mm/s) were punched using an Instron 5985 Universal Testing System at 12% clearance and the high speed punched holes (28 mm/s, 114 mm/s, 228 mm/s) were punched on a commercial punch press at 16% clearance. All holes were punched using a flat punch geometry.
[0237] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0238] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0239] Results from hole expansion tests are shown in Table 43 through Table 45 and illustrated in
TABLE-US-00043 TABLE 43 Hole Expansion Ratio of 780 Steel Grade at Different Punch Speeds Punch Punch to die Punch Sample Speed clearance Geo- # (mm/s) (%) metry HER 1 5 mm/s 12% Flat 44.74 2 12% Flat 39.42 3 12% Flat 44.57 1 28 mm/s 16% Flat 35.22 2 16% Flat 28.4 3 16% Flat 36.38 1 114 mm/s 16% Flat 31.58 2 16% Flat 33.9 3 16% Flat 22.29 1 228 mm/s 16% Flat 31.08 2 16% Flat 31.85 3 16% Flat 31.31
TABLE-US-00044 TABLE 44 Hole Expansion Ratio of 980 Steel Grade at Different Punch Speeds Punch Punch to die Punch Sample Speed clearance Geo- # (mm/s) (%) metry HER 1 5 mm/s 12% Flat 33.73 2 12% Flat 35.02 1 28 mm/s 16% Flat 26.88 2 16% Flat 26.44 3 16% Flat 23.83 1 114 mm/s 16% Flat 26.81 2 16% Flat 30.56 3 16% Flat 29.24 1 228 mm/s 16% Flat 30.06 2 16% Flat 30.98 3 16% Flat 30.62
TABLE-US-00045 TABLE 45 Hole Expansion Ratio of 1180 Steel Grade at Different Punch Speeds Punch Punch to die Punch Sample Speed clearance Geo- # (mm/s) (%) metry HER 1 5 mm/s 12% Flat 26.73 2 12% Flat 32.9 3 12% Flat 25.4 1 28 mm/s 16% Flat 35.32 2 16% Flat 32.11 3 16% Flat 36.37 1 114 mm/s 16% Flat 35.15 2 16% Flat 30.92 3 16% Flat 32.27 1 228 mm/s 16% Flat 27.25 2 16% Flat 23.98 3 16% Flat 31.18
[0240] This Case Example demonstrates that no edge performance effect based on hole punch speed is measureable in tested commercial steel grades indicating that edge performance in conventional AHSS is not effected or improved by punch speed as expected since the unique structures and mechanisms present in this application as for example in
Case Example #18
Relationship of Post Uniform Elongation to Hole Expansion Ratio
[0241] Existing steel materials have been shown to exhibit a strong correlation of the measured hole expansion ratio and the material's post uniform elongation. The post uniform elongation of a material is defined as a difference between the total elongation of a sample during tensile testing and the uniform elongation, typically at the ultimate tensile strength during tensile testing. Uniaxial tensile testing and hole expansion ratio testing were completed on Alloy land Alloy 9 on the sheet material at approximately 1.2 mm thickness for comparison to existing material correlations.
[0242] Slabs with thickness of 50 mm were laboratory cast of Alloy 1 and Alloy 9 according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling annealing at 850° C. for 10 min as described in the Main Body section of this application.
[0243] Tensile specimens in the ASTM E8 geometry were prepared by wire EDM. All samples were tested in accordance with the standard testing procedure described in the Main Body of this document. An average of the uniform elongation and total elongation for each alloy were used to calculate the post uniform elongation. The average uniform elongation, average total elongation, and calculated post uniform elongation for Alloy 1 and Alloy 9 are provided in Table 46.
[0244] Specimens for hole expansion ratio testing with a size of 89×89 mm were wire EDM cut from the sheet of Alloy 1 and Alloy 9. Holes of 10 mm diameter were punched at 0.25 mm/s on an Instron 5985 Universal Testing System at 12% clearance. All holes were punched using a flat punch geometry. These test parameters were selected as they are commonly used by industry and academic professionals for hole expansion ratio testing.
[0245] Hole expansion ratio (HER) testing was performed on the SP-225 hydraulic press and consisted of slowly raising the conical punch that uniformly expanded the hole radially outward. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0246] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0247] The measured hole expansion ratio values for Alloy 1 and Alloy 9 are provided in Table 46.
TABLE-US-00046 TABLE 46 Uniaxial Tensile and Hole Expansion Data for Alloy 1 and Alloy 9 Post Average Average Uniform Hole Uniform Total Elongation Expansion Elongation Elongation (ε.sub.pul) Ratio Alloy (%) (%) (%) (%) Alloy 1 47.19 49.29 2.10 2.30 Alloy 9 50.83 56.99 6.16 2.83
[0248] Commercial reference data is shown for comparison in Table 47 from [Paul S. K., J Mater Eng Perform 2014; 23:3610.]. For commercial data, S. K. Paul's prediction states that the hole expansion ratio of a material is proportional to 7.5 times the post uniform elongation (See Equation 1).
HER=7.5(ε.sub.pul) Equation 1
TABLE-US-00047 TABLE 47 Reference Data from [Paul S.K., J Mater Eng Perform 2014;23:3610.] Post Uniform Hole Commercial Uniform Total Elongation Expansion Steel Elongation Elongation (ε.sub.pul) Ratio Grade (%) (%) (%) (%) IF-Rephos 22 37.7 15.7 141.73 IF-Rephos 22.2 39.1 16.9 159.21 BH210 19.3 37.8 18.5 151.96 BH300 16.5 29 12.5 66.63 DP 500 18.9 27.5 8.6 55.97 DP 600 16.01 23.51 7.5 38.03 TRIP 590 22.933 31.533 8.6 68.4 TRIP 600 19.3 27.3 8 39.98 TWIP940 64 66.4 2.4 39.1 HSLA 350 19.1 30 10.9 86.58 340 R 22.57 36.3 13.73 97.5
[0249] The Alloy 1 and Alloy 9 post uniform elongation and hole expansion ratio are plotted in
[0250] This Case Example demonstrates that for the steel alloys herein, the correlation between post uniform elongation and the hole expansion ratio does not follow that for commercial steel grades. The measured hole expansion ratio for Alloy 1 and Alloy 9 is much smaller than the predicted values based on correlation for existing commercial steel grades indicating an effect of the unique structures and mechanisms are present in the steel alloys herein as for example shown in
Case Example #19
HER Performance as a Function of Hole Expansion Speed
[0251] Slabs with thickness of 50 mm were laboratory cast from three selected alloys according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Sheet from each alloy possessing the Recrystallized Modal Structure with final thickness of 1.2 mm were used to demonstrate the effect of hole expansion speed on HER performance.
[0252] Specimens for testing with a size of 89×89 mm were cut via wire EDM from the sheet. Holes of 10 mm diameter were punched at a constant speed of 228 mm/s on a commercial punch press. All holes were punched with a flat punch geometry, and with approximately 16% punch to die clearance.
[0253] Hole expansion ratio (HER) testing was performed on an Interlaken Technologies SP-225 hydraulic press and consisted of raising the conical punch that uniformly expanded the hole radially outward. Four hole expansion speeds, synonymous with the conical ram travel speed, were used; 5, 25, 50, and 100 mm/min. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0254] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0255] Hole expansion ratio values for the tests are shown in Table 48. The average hole expansion ratio value is shown for each speed and alloy tested showing an increase in HER values with increasing hole expansion speed in all three alloys. The effect of hole expansion speed is also demonstrated in
TABLE-US-00048 TABLE 48 Hole Expansion Ratio in Selected Alloys at Different Expansion Speeds Measured Average Hole Hole Hole Punch Expansion Expansion Expansion Speed Speed Ratio Ratio Material (mm/s) (mm/min) (%) (%) Alloy 1 228 5 19.09 20.55 22.54 20.02 25 30.70 28.58 29.14 25.91 50 34.05 34.63 36.43 33.42 100 37.11 37.19 38.52 35.93 Alloy 9 228 5 34.06 34.15 34.07 34.31 25 32.87 40.77 45.46 43.98 50 38.39 44.17 39.71 54.42 100 48.01 49.50 55.27 45.23 Alloy 12 228 5 48.61 43.51 34.79 47.14 25 42.13 50.64 57.82 51.96 50 63.77 62.97 68.46 56.68 100 57.79 56.73 49.28 63.11
[0256] This Case Example demonstrates that formability of the edge, i.e. its ability to be deformed with relatively reduced cracking, as measured by HER testing, can be affected by the speed of deformation of the hole edge (i.e. hole expansion speed). The alloys tested in this Case Example demonstrated a positive correlation between hole expansion ratio and the hole expansion speed, with increasing hole expansion speed resulting in relatively higher measured hole expansion ratios.
[0257] Accordingly, in the broad context of the present disclosure, it has been established that once an edge is formed, of any geometry by any edge formation method which causes deformation of the metal alloy when forming the edge (e.g. by punching, shearing, piercing, perforating, cutting, cropping, stamping,), by increasing the speed at which that edge once formed is then expanded, one observes that the edge itself is then capable of more expansion with a relatively reduced tendency to crack. The edge herein can therefore include an edge that defines an internal hole in a metal sheet of the alloys described herein, or an external edge on such metal sheet. In addition, the edge herein may be formed in a progressive die stamping operation which is reference to metal working operation that typically includes punching, shearing, coining and bending. The edge herein may be present in a vehicle, or more specifically, part of a vehicular frame, vehicular chassis, or vehicle panel.
[0258] Reference to edge expansion herein is understood as increasing the length of such edge with a corresponding change in the thickness of the edge. That is confirmed by the above data in Table 48, which shows that with respect to an edge that is present in a hole, when such edge in the hole is expanded at a speed of greater than or equal to 5 min/min, one observes an increase in the hole expansion ratio (i.e. the edge in the hole is capable of expansion to higher percentages over the original diameter) and the edge getting thinner as shown for example in the cross sections of the expanded edges in
Case Example 20
HER Performance as a Function of Punch Speed and Hole Expansion Speed
[0259] Sheet from Alloy 9 was produced according to the atomic ratios provided in Table 2. Slabs produced by continuous casting were hot rolled into hot band which was subsequently processed into sheet with thickness of approximately 1.4 mm by cold rolling and annealing cycles. The microstructure of the produced sheet using both SEM and etched optical microscopy is demonstrated in
[0260] In
[0261] The sheet with Recrystallized Modal Structure was used for HER testing. Specimens for testing with a size of 89×89 mm were cut via wire EDM from the sheet. Holes of 10 mm diameter were punched at two different speeds of 5 mm/s using an Instron mechanical test frame and at 228 mm/s using a commercial punch press with a flat punch geometry and with punch to die clearances of approximately 12.5% and 16%, respectively.
[0262] Hole expansion ratio (HER) testing was performed on an Interlaken Technologies SP-225 hydraulic press and consisted of raising the conical punch that uniformly expanded the hole radially outward. Two hole expansion speeds of 3 mm/min and 50 mm/min, synonymous with the conical ram travel speed, were used. A digital image camera system was focused on the conical punch and the edge of the hole was monitored for evidence of crack formation and propagation.
[0263] The initial diameter of the hole was measured twice with calipers, measurements were taken at 90° increments and averaged to get the initial hole diameter. The conical punch was raised continuously until a crack was observed propagating through the specimen thickness. At that point the test was stopped and the hole expansion ratio was calculated as a percentage of the initial hole diameter measured before the start of the test. After expansion four diameter measurements were taken using calipers every 45° and averaged to account for any asymmetry of the hole due to cracking.
[0264] Hole expansion ratio values for tests are listed in Table 49. HER values vary from 2.4 to 18.5% in the samples with holes punched at 5 mm/s. In the case of 228 mm/s hole punching speed, HER values are significantly higher in a range from 33.8 to 75.0%. The effect of expansion speed is illustrated in
TABLE-US-00049 TABLE 49 Hole Expansion Ratio in Alloy 9 Sheet at Different Punching and Expansion Speeds Hole Hole Punch Punch Expansion Clearance Speed Speed HER (%) (mm/s) (mm/min) (%) 16 228 3 33.8 16 228 3 41.3 16 228 50 63.1 16 228 50 75.0 12.5 5 3 2.4 12.5 5 3 7.9 12.5 5 50 12.7 12.5 5 50 18.5
[0265] The magnetic phases volume percent (Fe %) was measured in the HER tested samples with different hole punching speed and hole expansion speed using a Fischer Feritscope FMP30. The results are listed in Table 50.
TABLE-US-00050 TABLE 50 Magnetic Phases Volume (Fe%) in Alloy 9 at Different Hole Punching Speeds and Hole Expansion Speeds as a Function of Distance from Hole Edge After Expansion Hole Creation and Expansion Parameters Hole Punching Speed 228 228 228 228 5 5 5 5 (mm/s) Punch Clearance (%) 16 16 16 16 12.5 12.5 12.5 12.5 Hole Expansion Speed 3 3 50 50 3 3 50 50 (mm/min) HER (%) 33.8 41.3 63.1 75.0 2.4 7.9 12.7 18.5 Distance from hole (mm) Magnetic Phases Volume % (Fe %) 1 27.3 31.6 37.9 39.1 7.1 9.5 13.5 20.1 2.5 17 21.1 29.6 36 2.4 2.7 6.5 6.2 4 6 7.5 17.4 24.6 0.94 1.1 2.4 2.4 5.5 2.2 2.8 6.3 11.3 0.47 0.45 0.96 0.75 7 0.82 0.89 2.8 4.4 0.21 0.29 0.38 0.28 8.5 0.33 0.35 1.3 1.9 0.23 0.22 0.24 0.16 10 0.21 0.21 0.66 1.1 0.21 0.2 0.2 0.13 11.5 0.15 0.16 0.42 0.67 0.2 0.18 0.21 0.12 13 0.13 0.14 0.26 0.37 0.18 0.18 0.22 0.11 14.5 0.12 0.13 0.25 0.31 0.19 0.18 0.23 0.11 16 0.13 0.14 0.31 0.38 0.19 0.19 0.22 0.13 17.5 0.2 0.22 0.53 0.84 0.19 0.2 0.24 0.14 19 0.16 0.25 0.37 0.61 0.2 0.22 0.22 0.12 22 0.11 0.13 0.21 0.24 0.19 0.21 0.22 0.1 25 0.12 0.12 0.19 0.23 0.19 0.2 0.2 0.11
[0266] This Case Example illustrates that the relative resistance to cracking of an edge as confirmed by HER testing can be increased by, in the exemplary case of forming an edge within a hole, by either increasing hole punching speeds, hole expansion speeds or both. The sheet from Alloy 9, tested in this Case Example, demonstrated an increase in hole expansion ratio with increasing hole punching speed (i.e. 5 to 228 mm/s) and/or the hole expansion speed (i.e. 3 to 50 mm/min). Accordingly, preferably herein for the subject alloys, one forms an edge in the alloy and expands the edge at a speed of greater than or equal to 5 mm/min. The magnetic phases volume percent (Fe %) in tested samples increases with increasing hole punching speed and/or the hole expansion speed over the ranges studied. With this relatively greater amount of deformation available in and adjacent to the hole edge during the now disclosed increased hole punching speed or hole expansion speed, the higher local formability and resistance to cracking of the edge is achieved in the material as measured by the HER.
Case Example #21
HER Performance as a Function of Hole Preparation Method
[0267] Slabs with thickness of 50 mm were laboratory cast from three selected alloys according to the atomic ratios provided in Table 2 and laboratory processed by hot rolling, cold rolling and annealing at 850° C. for 10 min as described herein. Sheet from each alloy possessing the Recrystallized Modal Structure with final thickness of 1.2 mm were used to demonstrate an effect of hole expansion speed on HER performance.
[0268] Specimens for testing with a size of 89×89 mm were cut via wire EDM from the sheet. A 10 mm diameter hole was prepared by various methods including punching, EDM cutting, milling, and laser cutting. Hole punching was done at a low quasistatic punching speed of 0.25 mm/s at 16% punch to die clearance using a Komatsu OBS80-3 press. EDM cut holes were first rough cut then the final cut was made at parameters to yield a visually smooth surface. During hole milling, holes were pilot drilled, reamed to size, and then deburred. Laser cut samples were cut on a 4 kW fiber optic Mazak Optiplex 4020 Fiber II machine.
[0269] Hole expansion ratio (HER) testing was performed on an Interlaken Technologies SP-225 hydraulic press and consisted of raising the conical punch that uniformly expanded the hole radially outward. In
[0270] In
[0271] In