Method of high energy density radiation beam lap welding

Claims

What is claimed is:

1. A method of welding using a high energy density radiation beam comprising the steps of:

(a) providing a sheet having a sheet edge and another sheet having a sheet edge;

(b) overlapping one of the sheets with the other sheet such that the edge of one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet forming a lap joint having a plane of overlap where the sheets overlap with the overlap forming an overlap interface and defining a weld line;

(c) training a high energy density radiation beam on at least one of the sheets for a period of time and with sufficient energy density to weld the sheets together where overlapped such that the sheets are substantially completely fused together across the cross sectional width of overlap of the sheets; and

(d) forming or shaping the sheets after the high energy density radiation beam has been trained on at least one of the sheets with the sheets being formed such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured during forming.

2. The high energy density beam welding method of claim 1 wherein the beam of high energy density radiation is a laser beam.

3. The high energy density beam welding method of claim 1 wherein the beam of high energy density radiation is an electron beam.

4. The high energy density radiation beam welding method of claim 1 wherein the sheets are formed using one of the following methods of forming: shaping, drawing, deep drawing, hydro-forming, bending, or roll forming wherein at least one of the sheets and a portion of the weld are bent or three dimensionally contoured during forming.

5. The high energy density radiation beam welding method of claim 1 wherein:

(1) the sheets are oriented relative to a vertical plane generated by the direction of the local gravity and the tangent to the weld line in the plane of the overlap interface such that the plane of the overlap interface is acutely angled relative to the vertical plane so that the direction of the local gravity influences at least one of the following: formation, geometry or flow of a weld nugget of molten sheet material that is formed during welding; and

(1) the beam is angled acutely to the plane of overlap and trained (aa) on a sheet edge of one of the sheets or (bb) on a sheet edge of one of the sheets and a portion of the other of the sheets.

6. The high energy density radiation beam welding method of claim 5 wherein the angle between the plane of the overlap interface and the vertical plane is within the range of about .+-.20.degree..

7. The high energy density radiation beam welding method of claim 6 wherein the sheets are oriented relative to the direction of gravity such that the plane of the overlap interface is substantially parallel to the direction of gravity.

8. The high energy density radiation beam welding method of claim 1 wherein the beam is acutely angled relative to the plane of overlap of the sheets during welding.

9. The high energy density radiation beam welding method of claim 1 wherein the weld produced is a lap weld having no lip or portion of width of the overlap interface of the sheets left unfused when welding is completed.

10. The high energy density radiation beam welding method of claim 1 wherein the lap weld produced is continuous along the weld line.

11. The high energy density radiation beam welding method of claim 1 wherein one of the sheets has at least one (1) mechanical property or (2) at least one metallurgical property that is different than the other of the sheets.

12. The high energy density radiation beam welding method of claim 1 wherein one of the sheets is thicker than the other of the sheets.

13. The high energy density radiation beam welding method of claim 1 wherein the weld line is not straight.

14. The high energy density radiation beam welding method of claim 1 wherein one of the sheets has a thickness of t.sub.1 and the other of the sheets has a thickness of t.sub.2 and the sheets are overlapped such that the cross sectional width of overlap of the weld interface is at least about 50% of the thickness of the smallest of t.sub.1 and t.sub.2 and no greater than about twice the thickness of the largest of t.sub.1 and t.sub.2.

15. The high energy density radiation beam welding method of claim 14 wherein the cross sectional thickness of each sheet before welding is at least about 0.5 millimeter and no greater than about 5 millimeters.

16. The high energy density radiation beam welding method of claim 15 wherein after forming at least one of the sheets and a portion of the weld line are bent.

17. The high energy density radiation beam welding method of claim 1 wherein at least one of the sheets is coated with an organic or metallic coating.

18. The high energy density radiation beam welding method of claim 1 wherein both of the sheets have a thickness greater than 0.2 millimeter.

19. The high energy density radiation beam welding method of claim 18 wherein the cross sectional thickness of each sheet before welding is at least 0.5 millimeter and no greater than 5 millimeters.

20. A method of welding using a high energy density radiation beam comprising the steps of:

(a) providing a first sheet having a thickness t.sub.1 with the first sheet having a sheet edge, a second sheet having a sheet edge and being of a thickness t.sub.2 that is less than the thickness t.sub.1 of the first sheet, and an emitter of a beam of high energy density radiation for welding the sheets together;

(b) overlapping one of the sheets with the other sheet such that the edge of one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet forming a plane of overlap where the sheets overlap, with the overlap between the sheets forming an overlap interface or a weld interface that defines a weld line and which has a cross sectional width of overlap of the weld interface that extends from the edge of the first sheet to the edge of the second sheet;

(c) orienting the sheets relative to the emitter of high energy density radiation such that at least one of the sheets is exposed to the emitter;

(d) training a high energy density radiation beam on at least one of the sheets for a period of time and with sufficient energy density to weld the sheets together where overlapped such that along a portion of the weld line the sheets are substantially completely fused across the cross sectional width of overlap of the sheets; and

(e) forming or shaping at least one of the sheets and at least a portion of the weld line such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured.

21. The high energy density radiation beam welding method of claim 20 wherein the lap weld joining the sheets together is continuous longitudinally along the weld line.

22. The high energy density radiation beam welding method of claim 20 wherein the sheets are overlapped such that the cross sectional width of overlap of the weld interface is at least about 50% of the thickness of the smallest of t.sub.1 and t.sub.2 and no greater than about twice the thickness of the largest of t.sub.1 and t.sub.2.

23. The high energy density radiation beam welding method of claim 22 wherein the high energy density radiation beam is acutely angled relative to the plane of overlap of the sheets.

24. The high energy density radiation beam welding method of claim 23 wherein the cross sectional thickness of each sheet before welding is at least 0.5 millimeter and no greater than 5 millimeters.

25. The high energy density radiation beam welding method of claim 24 wherein during welding the high energy density radiation beam is trained on at least a portion of the edge of the thicker sheet.

26. The high energy density radiation beam welding method of claim 25 wherein the sheets are oriented such that the plane of overlap is acutely angled relative to the direction of the local gravity with the thicker sheet edge being above the thinner sheet edge such that during welding molten liquid sheet material from the thicker sheet edge flows in between the overlapped region of the sheets for helping to produce a weld that completely fuses the sheets together across the entire width of overlap of the sheets.

27. The high energy density radiation beam welding method of claim 26 wherein at least a portion of both sheets are galvanized and overlapped such that the sheet surfaces which face each other in the region of overlap are coated with a zinc coating.

28. The high energy density radiation beam welding method of claim 20 wherein one of the sheets has (1) at least one mechanical property or (2) at least one metallurgical property that is different from the other of the sheets.

29. The high energy density radiation beam welding method of claim 20 wherein during step (d) the high energy density radiation beam is trained on the sheet edge of one of the sheets and a portion of the other of the sheets.

30. The high energy density radiation beam welding method of claim 20 wherein after step (d), comprising the further step of forming or shaping the sheets such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured during forming using one of the following methods of forming: drawing, deep drawing, hydro-forming, bending, or roll forming.

31. The high energy density radiation beam welding method of claim 30 wherein a portion of the weld is bent or three dimensionally contoured during forming.

32. The high energy density radiation beam welding method of claim 22 wherein in step (c) the sheets are oriented relative to the beam emitter such that the sheet edge of the thicker sheet is exposed to the emitter, and during step (d) the beam is trained on at least a portion of the sheet edge of the thicker sheet to weld the sheets together.

33. The high energy density radiation beam welding method of claim 20 wherein the sheets are oriented relative to a vertical plane generated by the direction of the local gravity and the tangent to the weld line in the plane of the overlap interface such that the plane of the overlap interface is acutely angled relative to the vertical plane so that the direction of the local gravity influences at least one of the following: formation, geometry or flow of a weld nugget of molten sheet material that is formed during welding.

34. The high energy density radiation beam welding method of claim 20 wherein after forming at least one of the sheets and a portion of the weld line are three dimensionally contoured.

35. A method of welding using a high energy density radiation beam comprising the steps of:

(a) providing a first sheet having a top surface, a bottom surface and a sheet edge, a second sheet having a top surface, a bottom surface and a sheet edge, and one of the sheets having a burr extending outwardly from adjacent its sheet edge, a clamp for engagement with the first sheet, another clamp for engagement with the second sheet, and an emitter of a beam of high energy density radiation for welding the sheets together;

(b) overlapping the sheets with a clamp in engagement with the first sheet, a clamp in engagement with the second sheet, and having one of the sheets overlapped with the other of the sheets such that the edge of the one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet forming a lap joint having a plane of overlap where the sheets overlap each other, with the overlapped sheets spaced apart by a gap between the sheets with the burr on one sheet facing generally toward one of the top and bottom surfaces of the other sheet, and the overlap between the sheets forming a weld interface or overlap interface that defines a weld line and which has a cross sectional width of overlap of the overlap interface that extends from the edge of one of the sheets to the edge of the other of the sheets;

(c) orienting the sheets relative to the emitter such that a sheet edge of one of the sheets is exposed to the emitter; and

(d) training a high energy density radiation beam angled acutely to the plane of overlap on the sheet edge of the first sheet and along the weld line for a period of time and with sufficient energy density to weld the sheets together where overlapped such that along at least a portion of the weld line the sheets are completely fused across the cross sectional width of the overlap interface of the sheets with there being no lip or portion of the width of the overlap interface of the sheets left unfused.

36. The high energy density radiation beam welding method of claim 35, after step (c), comprising the further step of forming or shaping the sheets such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured during forming using one of the following methods of forming: shaping, drawing, deep drawing, hydro-forming, roll forming, or any other forming or shaping method wherein at least one of the sheets and the weld line are bent or three dimensionally contoured during forming or shaping.

37. The high energy density radiation beam welding method of claim 36 wherein a portion of the weld is bent or three dimensionally contoured during forming or shaping.

38. The high energy density radiation beam welding method of claim 35 further comprising:

(1) orienting the sheets relative to the emitter such that the sheet edge of the first sheet is exposed to the emitter;

(2) orienting the sheets relative to the direction of the local gravity such that the sheet edge of the first sheet lies above the sheet edge of the second sheet wherein the plane of overlap of the sheets is downwardly inclined and acutely angled relative to the direction of the local gravity; and

(3) during step (b) or after step (b), controlling the gap between the sheets such that the gap between the sheets is no greater than about ten percent of sheet thickness of the thicker of the sheets.

39. The high energy density radiation beam welding method of claim 38 wherein the gap between the overlapped sheets is controlled to be no greater than about 0.1 millimeter by (1) selectively regulating the distance the clamps are spaced apart from each other or (2) selectively regulating force applied by at least one of the clamps against at least one of the sheets.

40. The high energy density radiation beam welding method of claim 35 wherein at least one of the sheets has a zinc coating.

41. A method of welding using a high energy density radiation beam comprising the steps of:

(a) providing a first sheet having a sheet edge and composed of a material having mechanical or metallurgical properties, a second sheet having a sheet edge and composed of a material having (1) mechanical or metallurgical properties and (2) at least one mechanical or metallurgical property that is different than the mechanical or metallurgical properties of the first sheet;

(b) overlapping one of the sheets with the other sheet such that the edge of one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet forming a plane of overlap where the sheets overlap, with the overlap between the sheets forming an overlap interface that defines a weld line and which has a cross sectional width of overlap of the overlap interface that extends from the edge of one of the sheets to the edge of the other of the sheets;

(c) training a high energy density radiation beam on one of the sheets and along the weld line for a period of time and with sufficient energy density to weld the sheets together where overlapped such that along at least a portion of the weld line the sheets are completely fused across the cross sectional width of overlap of the sheets; and

(d) forming or shaping at least one of the sheets and at least a portion of the weld line such that at least one of the sheets and at least a portion of the weld line are bent and possess a radius of curvature after forming or shaping is completed.

42. The high energy density radiation beam welding method of claim 41 wherein forming is done using one of the following methods of forming: shaping, drawing, deep drawing, hydro-forming, and roll forming.

43. The high energy density radiation beam welding method of claim 42 wherein a portion of the weld is bent or three dimensionally contoured during forming.

44. The high energy density radiation beam welding method of claim 41 wherein the high energy density radiation beam is trained on a sheet edge of one of the sheets during step (c) for a period of time and with sufficient energy density to weld the sheets together where overlapped such that the sheets are completely fused across the entire cross sectional width of overlap of the sheets along at least a portion of the weld line in a longitudinal direction along the weld line.

45. The high energy density radiation beam welding method of claim 41 wherein one of the sheets is thicker than the other of the sheets.

46. The high energy density radiation beam welding method of claim 41 wherein one of the sheets possesses greater strength than the other of the sheets.

47. A product resulting from practicing the method of lap welding two sheets overlapped with each other using a high energy density radiation beam with one sheet overlapped with the other sheet such that the edge of one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet defining a weld line and an overlap interface, with the width of overlap extending from the edge of one of the sheets to the edge of the other of the sheets, and the high energy density radiation beam trained on at least one of the sheets for a period of time and with sufficient energy density to weld the sheets together where overlapped wherein the welded sheets are formed or shaped such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured after welding.

48. The product of claim 47 wherein during welding the high energy density radiation beam is angled acutely to the plane of overlap of the sheets and trained on either the edge of one of the sheets or on the edge of one of the sheets and a portion of the other sheet.

49. The product of claim 47 wherein one of the sheets has at least one mechanical or metallurgical property that is different than the other of the sheets.

50. The product of claim 49 wherein the different property relates to one of the following: toughness, impact resistance, ductility, formability, yield strength, ultimate strength, surface texture, surface hardness, wear resistance, fatigue resistance, electrical conductivity, flexural rigidity, stiffness or another sheet material property that is a mechanical or metallurgical property.

51. The product of claim 47 wherein one of the sheets has a greater thickness than the other of the sheets.

52. The product of claim 47 wherein before forming the weld line is not straight.

53. The product of claim 47 wherein the weld is continuous along the weld line.

54. The product of claim 47 wherein the weld produced is a lap weld having no lip or portion of the width of the overlap interface of the sheets left unfused when welding is completed.

55. The product of claim 47 wherein one of the sheets has a thickness of t.sub.1 and the other of the sheets has a thickness of t.sub.2 and the sheets are overlapped such that the cross sectional width of overlap of the overlap interface is at least about 50% of the thickness of the smallest of t.sub.1 and t.sub.2 and no greater than about twice the thickness of the largest of t.sub.1 and t.sub.2.

56. The product of claim 55 wherein the cross sectional thickness of each sheet before welding is at least 0.5 millimeter and no greater than 5 millimeters and after welding the sheets are joined together such that along at least a portion of the weld line the sheets are completely fused across the entire cross sectional width of overlap.

57. The product of claim 47 wherein forming is done using one of the following methods of forming: shaping, drawing, deep drawing, hydro-forming, and roll forming.

58. The product of claim 47 wherein the welded sheets are formed or shaped such that at least one of the sheets and a portion of the weld are bent or three dimensionally contoured after welding.

59. A method of welding using a laser beam comprising the steps of:

(a) providing a metal sheet having a cross sectional thickness, t.sub.1, and a sheet edge and another metal sheet having a cross sectional thickness, t.sub.2, and a sheet edge wherein each sheet has a cross sectional thickness of at least about 0.5 millimeter and no greater than about 5 millimeters;

(b) overlapping one of the sheets with the other sheet such that the edge of one sheet underlies the other sheet and the edge of the other sheet overlies the one sheet forming a lap joint having a plane of overlap where the sheets overlap, with the overlap forming a weld interface and defining a weld line, and the sheets overlapped such that the cross sectional width of overlap of the weld interface is at least about fifty percent of the thickness of the smallest of t.sub.1 and t.sub.2 and no greater than about twice the thickness of the largest of t.sub.1 and t.sub.2 ;

(c) training the laser beam angled acutely to the plane of overlap on at least one of the sheets for a period of time and with sufficient energy density to weld the sheets together where overlapped such that the sheets are substantially completely fused together across the cross sectional width of overlap of the sheets; and

(d) forming or shaping the sheets such that at least one of the sheets and a portion of the weld line are bent or three dimensionally contoured.

60. The method of claim 59 wherein the laser beam spot where focused on at least of the sheets has an energy density of at least about 10.sup.5 watts per square centimeter for achieving deep penetration keyhole mode welding.

61. The method of claim 60 wherein the laser beam is trained on a portion of the sheet edge of one of the sheets and a portion of the other of the sheets.

62. The method of claim 60 wherein the sheets are oriented such that the plane of overlap is acutely angled relative to the direction of the local gravity with the sheet edge of one of the sheets being above the sheet edge of the other sheet for helping to produce a weld that substantially completely fuses the sheets together across the entire width of overlap of the sheets.

63. The method of claim 62 wherein both sheets are constructed of galvanized steel coated with zinc at least on the surfaces that face each other in the region where the sheets are overlapped with each other.

64. The method of claim 59 further comprising reducing the thickness of the sheets where they are overlapped before, during or after welding.

65. The method of claim 64 wherein the combined total thickness of the overlapped sheets is reduced by planishing.

66. The method of claim 59 wherein during welding the beam path of travel overlaps itself as the laser beam travels along the weld interface to melt, solidify, remelt, and resolidify sheet material to remove gas trapped in the sheet material.

67. The method of claim 59 wherein during welding the laser beam oscillates across the weld interface as it travels longitudinally along the weld interface.