BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1A is a vertical cross sectional view of an embodiment of a portion of a plasma arc torch with an electrode, a nozzle with a central exit orifice, a retaining cap, and a shield positioned relative to the nozzle.
FIG. 1B is a perspective view of a nozzle with flutes that allow for a secondary gas passage when the dielectrically coated shield having a non-ceramic substrate is in contact with the nozzle.
FIG. 2A is a perspective view of a dielectrically coated shield having spring tangs for easy connection and disconnection relative to the torch.
FIG. 2B is a perspective view showing a dielectrically coated shield having a single dielectric coating disposed over the entirety of the shield.
FIG. 2C is a perspective cross sectional view showing a dielectrically coated shield with multiple dielectric coatings and/or layers.
FIG. 3A is a cross sectional view of a portion of a torch head including a nozzle surrounded by a conductive shield located at an arcing distance away from the nozzle.
FIG. 3B is a cross sectional view of a portion of a torch head including a dielectric shield located a distance less than the arcing distance of FIG. 3A away from the nozzle.
FIG. 3C is a cross sectional view of a portion of a torch head including a dielectric shield having a surface in contact with the nozzle.
FIG. 3D is a cross sectional view of a portion of a torch head including a dielectric shield in direct contact with a nozzle.
FIG. 4 is a vertical cross sectional view of a torch head with a dielectrically coated nozzle.
FIG. 5 is a vertical cross sectional view of an embodiment of the plasma arc torch with an electrode, a nozzle with a central exit orifice, a retaining cap, and a shield having multiple portions.
DETAILED DESCRIPTION
The present invention features a device for a plasma arc torch that minimizes the possibility of double arcing and maximizes cutting accuracy by improving operator visibility and edge starting (i.e., minimizing nozzle stickiness).
FIG. 1A shows a vertical cross sectional view of one embodiment of a plasma arc torch 100. The torch includes an electrode 140, a nozzle 150 with a central exit orifice 160, a retaining cap including an inner portion 120 and an outer portion 110, and a dielectric shield 130. The dielectric shield 130 can be positioned to contact the nozzle 150 without the threat of double arcing, due to the non-conductive nature of dielectric materials. That is, the dielectric shield 130 electrically insulates the conductive nozzle 150. The dielectric shield 130 extends at least to the end face of the nozzle 170 and is sized so that the nozzle 150 does not protrude pass an end face 132 of the shield 130. The plasma arc torch 100 produces a plasma arc, which is an energized conductive plasma gas that forms a current path between the electrode 140 and a workpiece. During torch start up, a current flows between the electrode 140 and the nozzle 150 facilitating the formation of a plasma arc pilot from gas flowing within a plasma chamber (i.e., a space between the nozzle 150 and the electrode 140). Positioning the nozzle 150 near the workpiece causes the arc to transfer, such that the torch current flows between the electrode 140 and the workpiece due to electrical potential of the workpiece. The dielectric shield 130 prevents double arcing caused by the formation of a second current path, protects the nozzle 150 and retaining cap 110 and 120 from slag, and protects the nozzle 150 and electrode 140 from the damaging effects of a torch head/workpiece collision.
In order to minimize the dielectric shield's 130 bulkiness and at the same time provide the shield with enough strength and rigidity to withstand use in the plasma arc torch, the dielectric shield is formed of multiple materials (i.e., is a composite material). For example, the body or substrate of the dielectric shield 130 can be formed of an electrically conductive, resilient material (e.g., a non-ceramic material, such as a metal, alloy, or conductive plastic) and a dielectric or insulative material (e.g., a ceramic coating) can be disposed over at least one surface (e.g., a surface adjacent to the nozzle 150, the end face 132 of the shield) of the body of the shield 130. The dielectric coating on the body of the shield 130 allows for positioning of the shield in direct contact with or proximate to the nozzle 150, while still reducing or eliminating double arcing.
The dielectric shield 130 can be positioned relative to the nozzle 150 such that at least portion of an interior surface of the shield directly contacts the nozzle. FIG. 1B shows a nozzle 175 with flutes 177. The flutes 177 form a secondary gas passage, which can allow for the flow of gas (e.g., plasma arc cooling gas or plasma arc shield gas) while the dielectric shield 130 directly contacts the nozzle 150. The cooling gas is commonly used to cool the nozzle or impinge on the plasma arc. An example of a nozzle with flutes is shown in U.S. application Ser. No. 11/432,282. There are several advantages to having the dielectric shield 130 in contact with the nozzle 150 or 175, such as higher operator visibility, lack of an otherwise required shield assembly, and longer nozzle and shield life. In addition, contact between the dielectric shield 130 and nozzle 150 can prevent slag from wedging in between the nozzle 150 and the dielectric shield 130. Slag prevention reduces the risk of double arcing, thereby allowing the nozzle end face 170 to be exposed.
FIG. 2A shows a perspective view of an embodiment of a dielectrically coated shield 200. The dielectrically coated shield 200 has spring tangs 201 for quick removal and attachment to the plasma arc torch 100. In addition, the dielectrically coated shield 200 includes a frustro-conically upper body portion 202 integrated with a cylindrically shaped lower body portion 203. The upper and lower body portions 202 and 203 can be formed of the same non-ceramic material. Alternatively, in some embodiments, the upper and lower portions 202 and 203 are formed from different non-ceramic materials. For example the upper portion 202 can be made of a copper alloy, while the lower portion 203 can be formed of copper, aluminum, or steel. In the embodiment shown in FIG. 2A, interior and exterior surfaces 205 and 206 of the shield 200 are coated with a dielectric coating 208.
The dielectric coating can be applied to the different portions of the shield and cover various percentages of the surface of the shield. The thickness of the dielectric coating and percentage of shield surface area coated is such that only a portion of the surface of the shield large enough to electrically isolate the nozzle needs to be coated. For example, if only 30 percent of an interior surface of the shield surrounds the nozzle, then about 30 percent of that interior surface is dielectrically coated. In some embodiments, 5, 10, 15, 20, 25, 30, 40, 50, 60, 70, 80, 90, 99, 99.9 or more percent of a surface of the shield can be dielectrically coated. Alternatively, in some embodiments, it is desirable to coat the entire surface area of the shield (e.g., both interior and exterior surface area and the end face), such as by dielectric coating using an anodized bath. In the embodiment shown in FIG. 2B, dielectrically coated shield 210 includes a dielectric material disposed over both interior surface 212 and exterior surface 213, as well as end face 215. In certain embodiments, the dielectric coating is even disposed within openings 218 configured for cooling or shielding gas flow.
The dielectric coating 211 can be formed of any type of dielectric material, such as, for example, porcelain, plasma sprayed ceramics, ceramic paint, titanium oxide, aluminum oxide, or any anodized material. Anodization of material occurs, for example, when a conductive substrate material, such as copper or aluminum, is submerged in an acidic charged bath, which causes an exterior surface of the material to oxidize and become non-conductive. An advantage of an anodized material, such as anodized aluminum, is that it can make an otherwise conductive durable material electrically insulative, therefore electrically insulating the shield while, e.g., absorbing torch head-to-workpiece impacts.
There are numerous combinations of non-ceramic substrates and dielectric coatings materials. Examples of some combinations include porcelain on a steel substrate, plasma spray ceramic on a copper substrate, ceramic paint on a steel substrate, titanium oxide on a titanium substrate, anodized aluminum on an aluminum substrate, anodized copper on a copper substrate, and ceramic on a plastic substrate. Other combinations are also possible.
FIG. 2C shows another embodiment of a dielectric shield 220 having multiple dielectric coatings. For example, the bottom layer 222 can be an insulative ceramic coating and the top layer 221 can be a durable coating that is either insulative or conductive (e.g., a polymer layer or a chromate layer). By using multiple layers to form the coating, the material properties of the shield 220 can be enhanced. For example, by including a durable layer on top of a less durable or fragile layer, the durability of the coating is enhanced while its complementary property of electrical insulation is achieved by the bottom layer 222. Another possible embodiment includes providing multiple dielectric layers, such that the body of the shield is dielectrically coated multiple times to increase material strength and resist torch head-to-workpiece impacts. There are many ways to dielectrically coat materials, for example, by chemical vapor deposition (see, e.g., U.S. Pat. No. 5,451,550), physical vapor deposition, vacuum deposit (see, e.g., U.S. Pat. No. 5,312,647), powder coating, spraying (see, e.g., U.S. Pat. No. 5,900,282), dipping, over-molding and/or brushing, each of which can be used with the invention.
As previously described, conventional conductive shields require a gap or spacing from the nozzle equal to or greater than the arcing distance d, 305, in order to decrease or prevent the occurrence of double arcing. FIG. 3A illustrates the minimum distance d, 305 required in conventional torches. Due to the isolative properties of the dielectric coating, shields in accordance with the present technology, such as, for example shield 301, can be positioned at a smaller distance s, 310, away from the nozzle 303 (i.e., within the arcing distance 305) as shown in FIG. 3B. By providing a small gap 310 between the nozzle and the shield cooling gasses can flow through the gap 310 and cool the exterior of the nozzle 303, while at the same time increasing operator visibility over conventional torches that have the larger spacing of d, 305 or greater. In addition, as shown in FIGS. 3C and 3D, at least a portion of the shield 301 can be in direct contact with the nozzle 303 while still preventing double arcing events. Positioning the dielectric shield 301 in contact with the nozzle 303 is advantageous because it reduces the total overall width of the torch head, thereby permitting better operator visibility of the workpiece and plasma arc. Direct contact between the nozzle and the shield can also reduce or eliminate slag wedged between the shield and nozzle. To cool the nozzle 303 in direct contact embodiments, the nozzle 303 and/or shield 301 includes flutes to form fluid passageways for flow of a cooling gas about the exterior of the nozzle. The gas used to cool the nozzle 303 and shield 301 escapes through openings disposed within the shield (e.g., openings 218 shown in FIGS. 2B and 2C).
While the above embodiments show a dielectrically coated shield device for protecting the nozzle from double arcing events, there are other devices that can also be used. For example, embodiments can feature a plasma arc torch having a nozzle with a dielectric coating disposed on an exterior surface. Referring to FIG. 4, a dielectric coating 401 can be disposed on an exterior surface of the nozzle head 402 of a nozzle 400 for a plasma arc torch. In cutting situations where a shield is not needed to protect the nozzle 400 from collision, one or more dielectric coating(s) 401 on the nozzle head 402, (e.g., on an exterior surface of the nozzle) prevents arcing with the nozzle and increases operator visibility by reducing the total cross-sectional area and width of the torch head (e.g., the nozzle and electrode). The dielectric coating 401 need not be applied to an interior surface 403 of the nozzle head. One skilled in the art will recognize that the one or more dielectric coating(s) must be applied to a portion of a nozzle 400 that electrically insulates the electrode and maintains nozzle conductivity for the pilot arc between the electrode and the nozzle head portion during pilot arc operation of the torch. The dielectrically coated nozzle head portion 402 may be formed of copper or aluminum and is coated with an insulative material 401. In certain embodiments, a nozzle hollow body portion 404 integrally connected to the nozzle head 402 is formed of the same material as the nozzle head portion 402. In other embodiments, the nozzle body portion is formed from a different material than the nozzle head 402. Examples of materials for use as the nozzle head portion 402 and/or the nozzle body portion 404 include, copper, aluminum, steel, gold, silver, titanium, and alloys thereof. The dielectric coating 401 material can be made of any dielectric, electrically insulating material, such as ceramics or an anodized metal layer.
Another embodiment of the invention features a dielectric shield that has connectable portions. For example, FIG. 5 shows the shield with a bottom portion 510 connected to a top portion 570. These two portions are mechanically connectable to form the dielectric shield. Other embodiments include a shield that has a bottom portion 510 that disconnects from a top portion 570. Another example is a dielectrically coated shield that includes a bottom portion 510 that connects and disconnects to a top portion 570. An advantage of connecting and disconnecting two shield portions is that the bottom portion can be made out of an expensive robust material, which easily protects the nozzle, without having to manufacture the entire shield of the expensive material. Slag created during torch operation is more likely to attach to the bottom part of the shield. Over time, the slag builds up or the bottom part of the shield wears away to a point that the shield needs replacement. By providing detachable top and bottom shield portions, replacement of only bottom portion 510 of the shield is necessary.
To protect an electrode and a nozzle from double arcing and damaging contact with a workpiece caused by poor operator visibility, an operator can remove an old or used shield surrounding the nozzle, and secure a shield including a non-ceramic substrate and a dielectric coating to the torch body. The shield should be secured such that at least a portion of the nozzle is covered by the shield. Thus, the shield with its dielectric coating electrically insulates the nozzle from the workpiece, thereby decreasing damage caused by double arcing. To further protect the nozzle and the electrode, cooling gas is flowed through the torch body between the nozzle and the shield. As a result, the consumable portions of the torch are cooled during use and wear at a slower rate than without the cooling.
A nozzle and electrode can also be protected against double arcing by mounting a nozzle including at least one dielectric coating on its exterior surface to the torch body. Specifically, by mounting a nozzle with a dielectric coating on its exterior, such as the nozzle illustrated in FIG. 4, to a torch body, the electrode becomes insulated from double arcing events due to the dielectric coating on the exterior of the nozzle. In addition, the operator does not have to secure an additional shield over the nozzle. As a result, operator visibility of the plasma arc is maximized because the nozzle is no longer covered by or obstructed by the shield and optional shield assembly. The nozzle can be further protected by flowing cooling gas over a portion of the exterior surface of the nozzle during operation. There are many possible embodiments of a dielectrically coated nozzle (400, 401). For example, the dielectrically coated nozzle can include multiple coatings some which can be formed of dielectric materials. In certain embodiments, it is advantageous to apply multiple dielectric coatings. The dielectrically coated nozzle can also have various configurations. For example, the dielectrically coated nozzle can also include flutes 177 (see FIG. 1B) or other passageways through or around the nozzle head and/or body portions.
All patents cited here are incorporated by reference in their entirety. One skilled in the art will realize the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The foregoing embodiments are therefore to be considered in all respects illustrative rather than limiting of the invention described herein. Scope of the invention is thus indicated by the appended claims, rather than by the foregoing description, and all changes, which come within the meaning and range of equivalency of the claims, are therefore intended to be embraced therein.