Abstract
A wide area shield for use in a plasma cutting torch. The wide area shield has a projected surface that covers at least 75% of the distal end of the plasma cutting torch when viewed in a plane perpendicular to the central axis of the torch. The wide area shield is actively cooled by at least two separate cooling flows. One possible cooling flow is liquid and contacts at least 25% of the total surface area of the wide area shield. A second possible cooling flow is gaseous and contacts at least 6% of the total surface area of the wide area shield. The increased projected area is achieved by increasing the axial length of the shield and increasing the shielding surface of the wide area shield which also allows for a thicker cross-sectional area of the wide area shield as measured perpendicularly from the shielding surfaces.
Claims
1. A shield body for use in a plasma cutting torch, comprising a central axis that extends from a proximal end of the shield body to a distal end of the shield body, a central bore that extends from a proximal end of the shield body to a distal end of the shield body along the central axis, an external surface of the shield body, an internal surface created by the central bore, a first section of the internal surface of the shield body contoured to mate with a nozzle body and create a first fluid passage when assembled in a plasma torch, a first internal contact section of the internal surface of the shield body, a liquid cooled section of the internal surface of the shield body, a cooling passage created between the liquid cooled section of the internal surface of the shield body and a mating component of the plasma torch, wherein the liquid cooled section of the internal surface of the shield has a liquid cooled surface area that has at least one surface area increasing feature.
2. The shield body of claim 1, wherein the shield body has a plurality of shield gas passages that have a radial length that is at 54% of the length of an outer radius of the shield body.
3. The shield body of claim 2, wherein the shield body has a total surface area comprising the internal surface, the external surface and a sum of the surface area of the shield gas passages, wherein the liquid cooled surface area of the shield body is at least 25% of the total surface area of the shield body.
4. The shield body of claim 3, wherein the surface area increasing feature is at least 8% of the total surface area of the shield body.
5. The shield body of claim 3, wherein the sum of the surface area of the shield gas passages is at least 6% of the surface area of the total surface area of the shield body.
6. The shield body of claim 1, further comprising a cylindrical section of the external surface of the shield body, wherein the cylindrical section of the external surface of the shield body begins at the distal end of the shield body and extends, along the central axis, for at least 66% of the axial length of the shield body along the central axis.
7. The shield body of claim 1, wherein the external surface of the shield body is not cooled by liquid cooling.
8. The shield body of claim 6, wherein the cylindrical section of the shield body has an outer diameter that is the largest outer diameter of the shield body.
9. A shield body for use in a plasma cutting torch, comprising a central axis that extends from a proximal end of the shield body to a distal end of the shield body, a central bore that extends from a proximal end of the shield body to a distal end of the shield body along the central axils, an external surface of the shield body, an internal surface created by the central bore, a substantially cylindrical section of the shield body that begins at the distal end of the shield body and extends in the axial direction for at least half the axial length of shield body, a plurality of shield gas passages arranged concentrically about the central axis and extending from an outer diameter of the cylindrical section of the shield body and extending in the radial direction through the shield body into the internal surface of the central bore of the shield body; wherein a ratio of a length of the shield gas passages to a total axial length of the shield body is at least 0.5 to 1.
10. The shield body of claim 9, wherein the ratio of the length of the shield gas passages to a radius of the shield body is at least 0.5 to 1.
11. The shield body of claim 9, wherein a ratio of the radial length of the shield gas passages to a radius of the shield body is at least 0.5 to 1.
12. The shield body of claim 9, further comprising a total surface area that is the sum of the external surface, the internal surface and a combined surface area of the plurality of shield gas passages, wherein the combined surface area of the plurality of shield gas passages is at least 6% of the total surface area of the shield body.
13. The shield body of claim 12, further comprising a liquid cooled surface area.
14. The shield body of claim 13, wherein the liquid cooled surface area of the shield body is at least 25% of the total surface area of the shield body.
15. The shield body of claim 9, wherein the shield body is actively cooled by at least two active cooling flows.
16. A method for cooling a shield for use in a plasma cutting torch comprising: providing a shield body for use in a plasma cutting torch comprising: a shield body for use in a plasma cutting torch, comprising a central axis that extends from a proximal end of the shield body to a distal end of the shield body, a central bore that extends from a proximal end of the shield body to a distal end of the shield body along the central axis, an external surface of the shield body, an internal surface created by the central bore, a first section of the internal surface of the shield body contoured to mate with a nozzle body and create a first fluid passage when assembled in a plasma torch, a first internal contact section of the internal surface of the shield body, a liquid cooled section of the internal surface of the shield body, a cooling passage created between the liquid cooled section of the internal surface of the shield body and a mating component of the plasma torch, wherein the liquid cooled section of the internal surface of the shield has a liquid cooled surface area that has at least one surface area increasing feature.
17. The shield body of claim 8, wherein the outer diameter of the shield body is at least 75% of a diameter of the plasma cutting torch exposed to spatter.
18. The shield body of claim 9, wherein the outer diameter of the shield body is at least 75% of a diameter of the plasma cutting torch exposed to spatter.
19. The shield body of claim 16, wherein the cylindrical section of the shield body has an outer diameter that is the largest outer diameter of the shield body.
20. The shield body of claim 19, wherein the outer diameter of the shield body is at least 75% of a diameter of the plasma cutting torch exposed to spatter.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0006] Figures are not drawn to scale. The figures depict one or more embodiment of the present invention, additional embodiments are not illustrated.
[0007] FIG. 1 is a cross section of a partial plasma cutting torch assembly including an embodiment of the present invention;
[0008] FIG. 2 is a view of the embodiment of the present invention seen in FIG. 1 which is perpendicular to the view seen in FIG. 1 and depicts the proximal end of the of the present embodiment;
[0009] FIG. 3 is a cross section of the embodiment of the present invention seen in FIG. 1 along a cut plane that does not intersect the shield gas passages;
[0010] FIG. 4 is a cross section of the embodiment of the present invention seen in FIG. 1 along a cut plane that intersects the shield gas passages;
[0011] FIG. 5 is a cross section of a second embodiment of the present invention along a cut plane that intersects the shield gas passages;
[0012] FIG. 6 is a cross section of a third embodiment of the present invention along a cut plane that intersects the shield gas passages;
[0013] FIG. 7 is a cross section of a fourth embodiment of the present invention along a cut plane that intersects the shield gas passages;
[0014] FIG. 8 is a cross section of a fifth embodiment of the present invention along a cut plane that intersects the shield gas passages.
DETAILED DESCRIPTION OF THE INVENTION
[0015] Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, embodiments of the invention are shown. The present invention is a wide area shield for use in a plasma cutting torch.
[0016] A cross sectional view of an embodiment of the present invention installed in a plasma cutting torch can be seen in FIG. 1. The wide area shield 1 can be seen in a plasma cutting torch assembly 2. The wide area shield 1 is located at the distal end of the cutting torch assembly 2 and is held in place concentrically, about central axis 10, to the plasma cutting torch assembly 2 by outer retaining cap 3 which is threaded to the plasma cutting torch body (not shown) and compresses the wide area shield 1 via a flange 4 on the inner diameter of the outer retaining cap 3 and lip 5 on the outer diameter of the wide area shield 1. The lip 5 of the wide area shield 1 represents 4.6% of the total diameter of the wide area shield 1. A gas flow path 6 is created by the gap between the wide area shield 1 and the nozzle 7. An insulating spacer 8 is used to separate the cathode and anode circuits of the plasma cutting torch assembly 2. The insulating spacer 8 is sealed via O-rings, depicted as black circles in FIG. 1, to prevent gas flow 11 and liquid cooling cavity 12 from leaking into each other. Liquid cooling cavity 12 is in direct contact with surface area increasing feature 15 and surface 16 of the wide area shield 1. Surface area increasing feature 15 and shielding surface 18 are on opposite sides of the wide area shield 1. The portions of wide area shield 1 between surface area increasing feature 15, gas flow path 6 and shielding surface 18 are the thickest portions the wide area shield 1 as seen in the cross-section 35 presented in FIGS. 3 and 4. The maximum thickness 35 of the wide area shield 1 as measured through and perpendicular to shielding surface 18 is 6.43 mm (0.253 inches). Shielding surface 18 is cooled via conduction from at least two sources of active cooling that cool the wide area shield 1 via convection from the active cooling sources. The liquid cooling cavity 12 provides active cooling and the series of shield gas passages 17 also provide active cooling, via forced convection heat transfer, which allows for heat to be conducted away from at least shielding surface 18 of wide area shield 1. Wide area shield 1 has a total shielding surface, exposed to spatter, that comprises at least shielding surface 18, shielding surface 21, shielding surface 22 and shielding surface 23.
[0017] As seen in FIG. 2, the series of shield gas passages 17 are arranged concentrically about the center of wide area shield 1. In this embodiment of the present invention there are 12 shield gas passages 17 arranged concentrically about the central axis 10 in FIG. 1 or the center of the wide area shield 1 in FIG. 2. The shield gas passages 17 are at least equal in length, relative to the central axis 10, as the length of shielding surface 18. As seen in FIG. 4 shield gas passages 17 have gas inlet 30 and gas outlet 31. In the present embodiment of the invention shield gas passages 17 are longer then shielding surface 18 and shield gas passage length 41 measures 11.96 mm (0.471 inches) in length. The angle of the shield gas passages 17 relative to the shielding surface 23 is 9 degrees. The radial length of the shield gas passages 17, the horizontal length as measured perpendicular to the central axis 10, is 11.82 mm (0.4655 inches). The surface area of the 12 combined shield gas passages 7 is 459.9 mm.sup.2 (0.71 in.sup.2), this represents 6.8% of the total surface area of the wide area shield 1. The total length of the wide area shield 1 as measured along the central axis 10 is 21.03 mm (0.828 inches). The total mass of wide area shield 1 is 82.87 grams. The outer diameter 200 of the projected surface of the wide area shield 1 can be seen in FIG. 2 and is defined by the inner diameter of lip 5. The projected surface of wide area shield 1 is 1183.22 mm.sup.2 (1.834 in.sup.2) and the total projected surface of the surfaces exposed to spatter, projected surface of retaining cap 3 and wide area shield 1, is 2016.77 mm.sup.2 (3.13 in.sup.2). The diameter of the total projected surface exposed to spatter is 50.67 mm (1.995 in) and the outer diameter 200 is 38.81 mm (1.528 in). The outer diameter 200 is 76.6% of the diameter of the total projected surface exposed to spatter.
[0018] In the embodiment of the present invention seen in FIGS. 1, 2,3 and 4 surface area increasing feature 15 is shown as a rectangular cavity that creates an annulus about central axis 10. In prior art shields the percentage of liquid cool surface area was less than 22% of the total surface area of the shield. The wide area shield 1 of the present invention has a liquid cooled surface area of at least 25% of the total surface area of the wide area shield 1. The rectangular anulus created by the revolution of surface area increasing feature 15 about central axis 10 allows for a total liquid cooled surface area of 1809 mm squared (2.804 inches squared) for wide area shield 1, which represents 27% of the total surface area of wide area shield 1. The ratio of the length of the shield gas passages 17 to the axial length of the wide area shield 1 is 0.57:1. The ratio of the length of the shield gas passages 17 to the radius of the wide area shield 1 is 0.59:1. The ratio of the radial length of the shield gas passages 17 to the radius of the wide area shield 1 is 0.58:1.
[0019] FIG. 5 shows another embodiment of the present invention, wide area shield 59. This embodiment has a surface area increasing feature 51 in the shape of a rectangle which produces an anulus when rotated about central axis 50. Surface area increasing feature 51 increases the total water cooled surface area of this embodiment of the present invention to 2210.32 mm.sup.2 (3.43 in.sup.2), which represents 33% of the total surface area of the wide area shield 59. The total surface area of this embodiment is 7190.031 mm.sup.2 (11.15 in.sup.2). The shield gas passages 58 have a shield gas passage length 500 which measures 11.28 mm (0.444 inches) at a 12 degree angle relative to central axis 50. The radial length of shield gas passages 58 is 11.04 mm (0.4345 inches). The total length of the wide area shield 59 as measured along the central axis 50 is 18.75 mm (0.738 inches). The surface area of the 12 combined shield gas passages 58 is 432.18 mm.sup.2 (0.672 in.sup.2), this represents 6.01% of the total surface area of the wide area shield 59. The maximum thickness 501 of the wide area shield 59 as measured through and perpendicular to shielding surface 18 is 6.83 mm (0.269 inches). The total mass of wide area shield 59 is 83 grams. The ratio of the length of the shield gas passages 58 to the axial length of the wide area shield 59 is 0.60:1. The ratio of the length of the shield gas passages 58 to the radius of the wide area shield 59 is 0.55:1. The ratio of the radial length of the shield gas passages 58 to the radius of the wide area shield 59 is 0.54:1
[0020] FIG. 6 shows another embodiment of the present invention, wide area shield 61. This embodiment has a surface area increasing feature 62 in the shape of a circle which produces an anulus when rotated about central axis 60. Surface area increasing feature 62 increases the total water cooled surface area of this embodiment of the present invention to 2036.13 mm.sup.2 (3.16 in.sup.2). The total surface area of this embodiment is 6932.89 mm.sup.2 (10.75 in.sup.2), at least 29% of the surface area of this embodiment of the present invention is water cooled.
[0021] FIG. 7 shows another embodiment of the present invention, wide area shield 71. This embodiment has a surface area increasing feature 72 and surface area increasing feature 73. Surface are increasing feature 72 is in the shape of a circle and surface area increasing feature 73 is in the shape of a square tooth pattern. Both of these surface area increasing features, 72 and 73, produce an anulus when rotated about central axis 70. Surface area increasing features 72 and 73 increases the total water cooled surface area of this embodiment of the present invention to 5134.83 mm.sup.2 (7.96 in.sup.2). The total surface area of this embodiment is 10032.24 mm.sup.2 (15.55 in.sup.2), at least 51% of the surface area of this embodiment of the present invention is water cooled.
[0022] FIG. 8 shows another embodiment of the present invention, wide area shield 81. This embodiment has a surface area increasing feature 82 and surface area increasing feature 83. Surface area increasing feature 82 is in the shape of a rectangle and surface area increasing feature 83 is in the shape of an acme thread. Both of these surface area increasing features, 82 and 83, produce an annulus when rotated about central axis 80. Surface area increasing features 82 and 83 increases the total water cooled surface area of this embodiment of the present invention to 2518.06 mm.sup.2 (3.90 in.sup.2). The total surface area of this embodiment is 7415.47 mm.sup.2 (11.50 in.sup.2), at least 34% of the surface area of this embodiment of the present invention is water cooled.
