Patent Grant
7935909
The present disclosure relates to plasma arc torches and more specifically to devices and methods for controlling shield gas flow in a plasma arc torch.
The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.
Plasma arc torches, also known as electric arc torches, are commonly used for cutting, marking, gouging, and welding metal workpieces by directing a high energy plasma stream consisting of ionized gas particles toward the workpiece. In a typical plasma arc torch, the gas to be ionized is supplied to a distal end of the torch and flows past an electrode before exiting through an orifice in the tip, or nozzle, of the plasma arc torch. The electrode has a relatively negative potential and operates as a cathode. Conversely, the torch tip constitutes a relatively positive potential and operates as an anode during piloting. Further, the electrode is in a spaced relationship with the tip, thereby creating a gap, at the distal end of the torch. In operation, a pilot arc is created in the gap between the electrode and the tip, often referred to as the plasma arc chamber, wherein the pilot arc heats and subsequently ionizes the gas. The ionized gas is blown out of the torch and appears as a plasma stream that extends distally off the tip. As the distal end of the torch is moved to a position close to the workpiece, the arc jumps or transfers from the torch tip to the workpiece with the aid of a switching circuit activated by the power supply. Accordingly, the workpiece serves as the anode, and the plasma arc torch is operated in a “transferred arc” mode.
In high precision plasma arc torches, both a plasma gas and a secondary gas are provided, wherein the plasma gas is directed to the plasma arc chamber and the secondary gas is directed around the plasma arc to constrict the arc and to achieve as close to a normal cut along the face of a workpiece as possible. The secondary gas flow cannot be too high, otherwise the plasma arc may become destabilized, and the cut along the face of a workpiece deviates from the desired normal angle. With such a relatively low flow of secondary gas, cooling of components of the plasma arc torch becomes less effective, and piercing capacity is reduced due to splash back of molten metal.
Improved methods of controlling the secondary gas are continuously desired in the field of plasma arc cutting in order to improve both cut quality and cutting performance of the plasma arc torch.
In one form of the present disclosure, a method of controlling the flow of gases through a plasma arc torch having an electrode adapted for electrical connection to a cathodic side of a power supply and a tip positioned distally from the electrode to define a plasma chamber therebetween is provided. The method comprises directing a flow of plasma gas to the plasma chamber, directing a first flow of auxiliary gas around a plasma stream that exits the tip in one of a swirling manner and a radial manner, and directing a second flow of auxiliary gas around the first flow of auxiliary gas and the plasma stream in one of a coaxial manner, an angled manner, and a radial manner. The first flow of auxiliary gas functions to constrict and shape the plasma stream to improve cut quality and cut speed, and the second flow of auxiliary gas functions to protect the plasma arc torch during piercing and cutting and to cool components of the plasma arc torch such that thicker workpieces may be processed with a highly shaped plasma stream.
In another form of the present disclosure, a method of controlling the flow of gases through a plasma arc torch having an electrode adapted for electrical connection to a cathodic side of a power supply and a tip positioned distally from the electrode to define a plasma chamber therebetween is provided. The method comprises directing a flow of plasma gas to the plasma chamber, directing a first flow of auxiliary gas through an inner auxiliary gas chamber of a shield device and around a plasma stream that exits the tip, and directing a second flow of auxiliary gas through an outer auxiliary gas chamber of the shield device and around the first flow of auxiliary gas and the plasma stream.
In yet another form of the present disclosure, a shield device for use in a plasma arc torch having an electrode adapted for electrical connection to a cathodic side of a power supply and a tip positioned distally from the electrode to define a plasma chamber therebetween in which a plasma gas flows, the tip being adapted for electrical connection to an anodic side of the power supply and defining an exit orifice through which a plasma stream exits is provided. The shield device comprises an inner shield member surrounding the tip to define an inner auxiliary gas chamber between the inner shield member and the tip to direct a first flow of auxiliary gas around the plasma stream, and an outer shield member secured to the inner shield member to define an outer auxiliary gas chamber between the outer shield member and the inner shield member to direct a second flow of auxiliary gas through a distal end portion of the outer shield member. The shield device is adapted for being secured to the plasma arc torch by a retaining cap.
In still another form, a shield device for use in a plasma arc torch for the management of an auxiliary gas flow around a plasma stream that exits a tip of the plasma arc torch to improve cut quality and cut speed, and to reduce molten splatter from contacting components of the plasma arc torch during operation is provided. The shield device comprises an inner auxiliary gas chamber that surrounds at least a portion of the tip and directs a portion of the auxiliary gas flow around the plasma stream in one of a swirling manner and a radial manner. The shield device also comprises an outer auxiliary gas chamber that directs another portion of the auxiliary gas flow around the flow through the inner auxiliary gas chamber in one of a coaxial manner, an angled manner, and a radial manner.
Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features. It should also be understood that various cross-hatching patterns used in the drawings are not intended to limit the specific materials that may be employed with the present disclosure. The cross-hatching patterns are merely exemplary of preferable materials or are used to distinguish between adjacent or mating components illustrated within the drawings for purposes of clarity.
Referring to
As used herein, a plasma arc torch, whether operated manually or automated, should be construed by those skilled in the art to be an apparatus that generates or uses plasma for cutting, welding, spraying, gouging, or marking operations, among others. Accordingly, the specific reference to plasma arc cutting torches, plasma arc torches, or automated plasma arc torches herein should not be construed as limiting the scope of the present invention. Furthermore, the specific reference to providing gas to a plasma arc torch should not be construed as limiting the scope of the present invention, such that other fluids, e.g. liquids, may also be provided to the plasma arc torch in accordance with the teachings of the present invention. Additionally, as used herein, the words “proximal direction” or “proximally” is the direction as depicted by arrow X, and the words “distal direction” or “distally” is the direction as depicted by arrow Y.
The consumable components also include a shield device 30 that is positioned distally from the tip 24 and which is isolated from the power supply. The shield device 30 generally functions to shield the tip 24 and other components of the plasma arc torch 20 from molten splatter during operation, in addition to directing a flow of shield gas that is used to stabilize and control the plasma stream. Additionally, the gas directed by the shield device 30 provides additional cooling for consumable components of the plasma arc torch 20, which is described in greater detail below. Preferably, the shield device 30 is formed of a copper, copper alloy, stainless steel, or ceramic material, although other materials that are capable of performing the intended function of the shield device 30 as described herein may also be employed while remaining within the scope of the present disclosure.
More specifically, and referring to
As further shown, the shield device 30 comprises an outer shield member 42, which is secured to the inner shield member 32 in one form of the present disclosure. In another form, both the inner shield member 32 and the outer shield member 42 form a single piece such that the shield device 30 is a unitary body. An outer auxiliary gas chamber 44 is formed between the outer shield member 42 and the inner shield member 32, which directs a second flow of auxiliary gas through a distal end portion 46 of the outer shield member 42. This second flow of auxiliary gas functions to protect the plasma arc torch 20 during piercing and cutting and also cools components of the plasma arc torch 20 such that thicker workpieces may be processed with a highly shaped plasma stream 36. Moreover, the second flow of auxiliary gas functions to add momentum to the removal of metal and acts as a buffer between the plasma stream 36 and the outside environment. Therefore, the shield device 30 comprises an inner auxiliary gas chamber 34 and an outer auxiliary gas chamber 44, which provide multiple injection mechanisms of the auxiliary gas around the plasma stream 36 in order to achieve improved cut quality and speed, in addition to improved life of consumable components. Therefore, the shield device 30 in accordance with the teachings of the present disclosure provides a hybrid injection mechanism for the auxiliary gas.
As used herein, the term “auxiliary gas” should be construed to mean any gas other than the plasma gas, such as a secondary gas, tertiary gas, shield gas, or other gas as contemplated in the art. Additionally, the first and second flow of auxiliary gas in one form are provided from a single gas source (not shown), and in another form, these auxiliary gases are provided from a plurality of gas sources (not shown). The plurality of gas sources may be the same gas type, such as air, or different gas types, such as, by way of example, air, oxygen, nitrogen, and H35, among others, which may be further mixed as required.
Referring back to
As further shown in
Referring now to
As further shown, the outer shield member 42 comprises an exit orifice 80 formed through its distal end portion 46. A recess 84 is also formed in a distal end face 86 of the outer shield member 42 in one form of the present disclosure, wherein edge extensions 88 function to further protect the inner shield member 32 during piercing and cutting. As an alternative to the orifice 80, the outer shield member 42 may comprise individual gas passageways (not shown) rather than the orifice 80 as illustrated and described herein, wherein the gas passageways direct the second flow of auxiliary gas around the plasma stream.
The inner shield member 32 comprises a distal extension 90, which defines an outer distal wall portion 92 as shown. In one form as shown in
In another form as shown in
In another form as shown in
Referring to
Therefore, in general, the inner auxiliary gas chamber 34 surrounds at least a portion of the tip 24 and directs a portion of the auxiliary gas flow around the plasma stream 36 in one of a swirling manner and a radial manner. The outer auxiliary gas chamber 44 directs another portion of the auxiliary gas flow around the flow through the inner auxiliary gas chamber 34 in one of a coaxial manner, an angled manner, and a radial manner, each of which may also have a swirling component. Accordingly, the outer auxiliary gas chamber 44 may define a coaxial configuration, an angled configuration, or a radial configuration around a distal end portion of the shield device 30.
The description of the disclosure is merely exemplary in nature and, thus, variations that do not depart from the substance of the disclosure are intended to be within the scope of the invention. For example, the inner shield member 32 in one form is recessed from the outer shield member 42 proximate the distal end portion 46 of the outer shield member 42 (e.g.,
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