초록 ▼

A method of forming a vehicle component, particularly an elongated impact beam, having an open section structure, in a manner to provide predetermined strategically strengthened portions, comprising the steps of cold forming unhardened steel into a workpiece having mounting surfaces, selectively fix

A method of forming a vehicle component, particularly an elongated impact beam, having an open section structure, in a manner to provide predetermined strategically strengthened portions, comprising the steps of cold forming unhardened steel into a workpiece having mounting surfaces, selectively fixturing the mounting surfaces, static induction heating the workpiece with lengthwise surface eddy currents on selected portions, followed by quenching of the fixtured heated workpiece to form strengthened portions, and unfixturing the resulting component. Also disclosed is apparatus to accomplish this, and the resulting novel vehicle component.

대표청구항 ▼

1. In a method for forming a vehicle impact beam of the type having a predetermined open section configuration, the improvement comprising:cold forming unhardened steel at substantially ambient temperature into an elongated vehicle impact beam having opposite ends, and an elongated open section ther

1. In a method for forming a vehicle impact beam of the type having a predetermined open section configuration, the improvement comprising:cold forming unhardened steel at substantially ambient temperature into an elongated vehicle impact beam having opposite ends, and an elongated open section therebetween having an offset lateral cross-sectional configuration with a center portion and a pair of elongated flanges extending along opposite sides of the center portion which collectively define the predetermined open section configuration; positioning an elongated induction coil lengthwise along at least one of the center portion and the flanges of the formed vehicle impact beam for induction heating the same with lengthwise moving surface eddy currents; and induction heating the one of the center portion and the flanges of the formed vehicle impact beam through activation of the elongated induction coil creating primarily lengthwise surface eddy currents on at least selected portions of the one of the center portion and the flanges to selectively strengthen the formed vehicle impact beam. 2. A method for forming a vehicle impact beam as set forth in claim 1, including:fixturing the formed vehicle impact beam prior to said induction heating step. 3. A method for forming a vehicle impact beam as set forth in claim 2, including:quenching the formed vehicle impact beam after said induction heating step. 4. A method for forming a vehicle impact beam as set forth in claim 3, including:unfixturing the formed vehicle impact beam after said quenching step. 5. A method for forming a vehicle impact beam as set forth in claim 4, wherein:said induction heating step is executed in pulses followed by conductance pauses to create substantially uniform heating of the selected portions. 6. A method for forming a vehicle impact beam as set forth in claim 5, wherein:said induction coil positioning step includes positioning an elongated induction coil lengthwise along the center portion and both of the flanges of the formed vehicle impact beam, and actuating the same to induction heat the predetermined open section configuration with lengthwise surface eddy currents. 7. A method for forming a vehicle impact beam as set forth in claim 6, wherein:said cold forming step includes shaping the elongated open section into a generally hat-shaped configuration. 8. A method for forming a vehicle impact beam as set forth in claim 7, wherein:said cold forming step further includes cold forming an elongated indentation into the central portion to define a rib. 9. A method for forming a vehicle impact beam as set forth in claim 8, wherein:said cold forming step further includes cold forming curled outer edges along the flanges. 10. A method for forming a vehicle impact beam as set forth in claim 9, wherein:said cold forming step further comprises cold forming the hat-shaped configuration with a crown and a pair of sidewalls; and said induction heating step further comprises the steps of orienting and activating an elongated induction coil lengthwise of the crown, lengthwise of the sidewalls, and lengthwise of the flanges, to cause lengthwise induction heating and strengthening of the crown, sidewalls and flanges. 11. A method for forming a vehicle impact beam as set forth in claim 10, wherein:the formed vehicle impact beam is strengthened to a tensile strength of at least 228 ksi and a yield strength of at least 170 ksi. 12. A method for forming a vehicle impact beam as set forth in claim 11, wherein:the formed vehicle impact beam is strengthened to a tensile strength of about 238 ksi and a yield strength of about 191 ksi. 13. A vehicle impact beam manufactured in accordance with the method set forth in claim 12.14. A method for forming a vehicle impact beam as set forth in claim 1, including:quenching the formed vehicle impact beam after said induction heating step. 15. A method for forming a vehicle impact beam as set forth in claim 1, including:fixturing the formed vehicle impact beam prior to said induction heating step; and unfixturing the formed vehicle impact beam after said induction heating step. 16. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said induction heating step is executed in pulses followed by conductance pauses to create substantially uniform heating of the selected portions. 17. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said induction heating step includes positioning the elongated induction coil lengthwise along each of the center portion and the flanges, and actuating the same to induction heat the open section with lengthwise surface eddy currents. 18. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said cold forming step includes shaping the elongated open section into a generally hat-shaped configuration. 19. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said cold forming step includes cold forming an elongated indentation into the central portion to define a rib. 20. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said cold forming step includes cold forming curled outer edges along the flanges. 21. A method for forming a vehicle impact beam as set forth in claim 1, wherein:said cold forming step further comprises cold forming a hat-shaped configuration with a crown and a pair of sidewalls; and said induction heating step comprises the steps of orienting and activating an elongated induction coil lengthwise of the crown, lengthwise of the sidewalls, and lengthwise of the flanges, to cause lengthwise induction heating and strengthening of the crown, sidewalls and flanges. 22. A method for forming a vehicle impact beam as set forth in claim 1, wherein:the formed vehicle impact beam is strengthened to a tensile strength of at least 228 ksi and a yield strength of at least 170 ksi. 23. A method for forming a vehicle impact beam as set forth in claim 1, wherein:the formed vehicle impact beam is strengthened to a tensile strength of about 238 ksi and a yield strength of about 191 ksi. 24. A vehicle impact beam manufactured in accordance with the method set forth in claim 1.25. A vehicle impact beam as set forth in claim 12, wherein:said fixturing step includes clamping the formed vehicle impact beam in a manner which permits at least one end of the vehicle impact beam to shift longitudinally to accommodate for thermal expansion and contraction. 26. A vehicle impact beam as set forth in claim 25, wherein:said clamping step includes retaining the vehicle impact beam in a manner which prevents significant vertical or torsional distortion from the predetermined open section configuration. 27. A vehicle impact beam as set forth in claim 26, wherein:said fixturing step includes clamping the formed vehicle impact beam in a manner which permits the opposite ends thereof to shift longitudinally to accommodate for thermal expansion and contraction. 28. A vehicle impact beam as set forth in claim 27, wherein:said induction coil positioning step includes positioning an elongated induction coil along an interior surface of the center portion of the formed vehicle impact beam, and between inside surfaces of the flanges thereof. 29. A vehicle impact beam as set forth in claim 27, wherein:said induction coil positioning step includes positioning an elongated induction coil along an exterior surface of the center portion of the formed vehicle impact beam. 30. A vehicle impact beam as set forth in claim 29, wherein:said induction coil positioning step includes positioning an elongated induction coil along exterior surfaces of the curled outer edges on the flanges of the formed vehicle impact beam. 31. A vehicle impact beam as set forth in claim 30, wherein:said cold forming step includes cold forming flattened, paddle-shaped ends at the opposite ends of the vehicle impact beam, wherein the elongated open section extends between the paddle-shaped ends. 32. A vehicle impact beam as set forth in claim 31, wherein:said induction coil positioning step includes positioning an elongated induction coil along only a portion of the length of the elongated open section of the vehicle impact beam. 33. A vehicle impact beam as set forth in claim 32, wherein:said induction coil positioning step includes positioning an elongated induction coil along substantially the entire length of the elongated open section of the vehicle impact beam. 34. A vehicle impact beam as set forth in claim 33, wherein:said induction coil positioning step includes positioning an elongated induction coil across only a portion of the width of the elongated open section of the vehicle impact beam to selectively heat treat only the portion of the width. 35. A vehicle impact beam as set forth in claim 34, wherein:said induction coil positioning step includes positioning the elongated induction coil along only selected portions of the flanges, such that the heat treated portion of the width is disposed only in the flanges. 36. A vehicle impact beam as set forth in claim 34, wherein:said induction coil positioning step includes positioning the elongate induction coil along only selected portions of the center portion, such that the heat treated portion of the width is disposed only in the center portion. 37. A vehicle impact beam as set forth in claim 33, wherein:said induction coil positioning step includes positioning an elongated induction coil across substantially the entire width of the elongated open section of the vehicle impact beam. 38. A vehicle impact beam as set forth in claim 2, wherein:said fixturing step includes clamping the formed vehicle impact beam in a manner which permits at least one end of the vehicle impact beam to shift longitudinally to accommodate for thermal expansion and contraction. 39. A vehicle impact beam as set forth in claim 38, wherein:said clamping step includes retaining the vehicle impact beam in a manner which prevents significant vertical or torsional distortion from the predetermined open section configuration. 40. A vehicle impact beam as set forth in claim 2, wherein:said fixturing step includes clamping the formed vehicle impact beam in a manner which permits the opposite ends thereof to shift longitudinally to accommodate for thermal expansion and contraction. 41. A vehicle impact beam as set forth in claim 1, wherein:said induction coil positioning step includes positioning an elongated induction coil along an interior surface of the center portion of the formed vehicle impact beam, and between inside surfaces of the flanges thereof. 42. A vehicle impact beam as Set forth in claim 1, wherein:said induction coil positioning step includes positioning an elongated induction coil along an exterior surface of the center portion of the formed vehicle impact beam. 43. A vehicle impact beam as set forth in claim 1, wherein:said induction coil positioning step includes positioning an elongated induction coil along exterior surfaces of the flanges of the formed vehicle impact beam. 44. A vehicle impact beam as set forth in claim 1, wherein:said cold forming step includes cold forming flattened, paddle-shaped ends at the opposite ends of the vehicle impact beam, wherein the elongated open section extends between the paddle-shaped ends. 45. A vehicle impact beam as set forth in claim 44, wherein:said induction coil positioning step includes positioning an elongated induction coil along only a portion of the length of the elongated open section of the vehicle impact beam. 46. A vehicle impact beam as set forth in claim 44, wherein:said induction coil positioning step includes positioning an elongated induction coil along substantially the entire length of the elongated open section of the vehicle impact beam. 47. A vehicle impact beam as set forth in claim 1, wherein:said induction coil positioning step includes positioning an elongated induction coil across only a portion of the width of the elongated open section of the vehicle impact beam to selectively heat treat only the portion of the width. 48. A vehicle impact beam as set forth in claim 47, wherein:said induction coil positioning step includes positioning the elongated induction coil along only selected portions of the flanges, such that the heat treated portion of the width is disposed only in the flanges. 49. A vehicle impact beam as set forth in claim 1, wherein:said induction coil positioning step includes positioning the elongate induction coil along only selected portions of the center portion, such that the heat treated portion of the width is disposed only in the center portion. 50. A vehicle impact beam as set forth in claim 1, wherein:said induction coil positioning step includes positioning an elongated induction coil across substantially the entire width of the elongated open section of the vehicle impact beam.