The present invention relates to a nozzle protection cap for a plasma arc torch, to a plasma arc torch having said nozzle protection cap, and to the use of the plasma arc torch.
The plasma arc torch may be used both for dry cutting but in particular also advantageously for the underwater cutting of various metallic workpieces.
In the case of plasma cutting, an arc (pilot arc) is firstly ignited between a cathode (electrode) and an anode (nozzle), and is subsequently transferred directly to a workpiece in order to perform a cut there.
Said arc forms a plasma which is a thermally highly heated, electrically conductive gas (plasma gas) which is composed of positive and negative ions, electrons and excited and neutral atoms and molecules. As plasma gas, use is made of gases such as argon, hydrogen, nitrogen, oxygen or air. These gases are ionized and dissociated by the energy of the arc. The resulting plasma jet is used for cutting the workpiece.
A modern plasma arc torch is composed substantially of a number of basic elements such as torch body, electrode (cathode), nozzle, one or more caps, in particular a nozzle cap and a nozzle protection cap which surround the nozzle, and connections which serve for the supply of electrical current, gases and/or liquids to the plasma arc torch.
Nozzle protection caps serve for protecting a nozzle, during the cutting process, against heat and sputtering molten metal of the workpiece.
A nozzle may be composed of one or more component parts. In the case of directly water-cooled plasma arc torches, the nozzle is commonly held by a nozzle cap. Cooling water flows between the nozzle and the nozzle cap. A secondary gas then flows between the nozzle cap and a nozzle protection cap. The latter serves for creating a defined atmosphere, for constricting the plasma jet and for protecting against the sputtering as the plasma jet pierces into the respective workpiece.
In the case of gas-cooled plasma arc torches and indirectly water-cooled plasma arc torches, the nozzle cap may be omitted. The secondary gas then flows between the nozzle and the nozzle protection cap.
The electrode and the nozzle are arranged in a particular spatial relationship with respect to one another and delimit a space, the plasma chamber, in which the plasma jet is formed. The plasma jet may be greatly influenced in terms of its parameters, such as for example diameter, temperature, energy density and through flow rate of the plasma gas, by the design of the nozzle and electrode.
For the different plasma gases, the electrodes and nozzles are produced from different materials and in different forms.
Nozzles and nozzle protection caps are generally produced from copper and directly or indirectly water-cooled. Depending on the cutting task and electrical power of the plasma arc torch, nozzles are used which have different inner contours and openings with different diameters and which thus provide the optimum cutting results.
For example, DE 10 2004 049 445 A1 describes a plasma arc torch with a water-cooled electrode and nozzle and with a gas-cooled nozzle protection cap. For this purpose, the secondary gas is fed through a nozzle protection cap holder, at the inside past a screw connection region between the nozzle cap holder and a nozzle protection cap, through a secondary gas channel formed between the nozzle protection cap and a nozzle cap, to a plasma jet.
EP 2 465 334 B1 presents a nozzle protection cap and a nozzle protection cap holder and a plasma arc torch. The nozzle protection cap comprises a front end portion and a rear end portion, with a thread region on the inner surface thereof for screw connection to a torch body of a plasma arc torch, wherein at least one groove passes through the thread region on the inner surface.
EP 0 573 653 B1 relates to a plasma arc torch with water-cooled electrode and nozzle and water-cooled nozzle protection cap. Exactly as in the case of the plasma arc torch as per DE 10 2004 049 445 A1, a secondary gas is, within a nozzle protection cap holder, fed at the inside past a screw connection region between the nozzle protection cap holder and a nozzle protection cap to a plasma jet.
The structural variants known per se from the prior art may also be used in principle in the case of a nozzle protection cap according to the invention and in a plasma arc torch equipped therewith.
In the described plasma torches, the nozzle protection cap is composed of copper or another non-ferrous metal, which normally exhibits particularly good thermal conductivity. In particular in the case of plasma cutting underwater, that is to say the tip of the plasma torch and thus also the nozzle protection cap are, during the cutting process, situated in the water in which the workpiece is also arranged, increased wear occurs on the surfaces of the bore of the nozzle protection cap during the piercing or cutting. This leads to a deterioration of the cut quality, because the gas flow of the secondary gas is disrupted. Furthermore, the useful service life is shortened, which leads to more frequent exchange and downtimes. This is caused in particular by electro-erosive processes, for example the spark discharge during the ignition, electrochemical processes, and physical overloading of the material owing to temperature and/or cavitation.
A further problem is the required mechanical strength of the nozzle protection caps, in particular if the tip of the plasma torch and thus also the nozzle protection cap comes into contact with the workpiece. This can lead to defamation of the nozzle protection cap and likewise results in a deterioration of the cut quality owing to the disruption of the gas flow of the secondary gas.
The invention is thus based on the object of improving the service life of the nozzle protection cap of a plasma arc torch. This relates in particular to plasma cutting underwater. Furthermore, it is the intention to be able to keep the cut quality constantly high over a relatively long time period, and it is sought to reduce the risk of mechanical damage to the nozzle protection cap. At the same time, it is the intention for the nozzle protection cap to exhibit good thermal conductivity in order to avoid overheating.
According to the invention, said object is achieved by means of a nozzle protection cap which has the features of the claims.
Advantageous embodiments and refinements of the invention may be realized with features specified in dependent claims.
The nozzle protection cap according to the invention for a plasma arc torch is arranged and fastened at the outside on the tip of the plasma arc torch, at which a plasma jet emerges from the plasma arc torch through nozzle-like openings. Said nozzle protection cap is produced from an iron alloy including sulfur in a fraction of at least 0.05%.
It is the intention for the iron alloy to include sulfur in a fraction in the range from 0.05% to 0.5%, preferably in a fraction in the range from 0.1% to 0.4%, particularly preferably in the range from 0.15% to 0.35%.
Aside from the sulfur, at least one further additional alloy element selected from chromium, nickel, manganese, molybdenum, niobium, titanium, tungsten and vanadium may be included.
One or more additional alloy elements may be included in a fraction of at most 35%. Here, the respective individual fractions of multiple additional alloy elements amounts to at most 35% in sum total. It is however the intention for the fraction of one or more additional alloy elements, aside from the sulfur, to amount to at least 5%. Aside from the fraction of alloy elements and sulfur, it is the intention for the material used for the nozzle protection cap according to the invention to comprise only iron.
It is the intention for chromium and nickel to be jointly included in the iron alloy as additional alloy elements.
It is expediently the intention for the iron alloys to comprise no carbon or a very small fraction of carbon. It is the intention for the carbon fraction to be limited to a maximum fraction of 2.1%, preferably a maximum fraction of 1.2%, particularly preferably a fraction of at most 0.5%.
It is also the intention for the iron alloy to include less than 0.1%, preferably less than 0.05%, cobalt, and particularly preferably no cobalt.
It is the intention for the iron alloy used for the production of the nozzle protection cap to have a thermal conductivity of at least 10 W/m*K, have a hardness of at least HB 150, and/or be oxidation-resistant and corrosion-resistant under normal ambient or usage conditions. Here, “normal” is to be understood to mean a conventional ambient atmosphere and use in water which comprises at least no chemically aggressive substances, or an additional introduction of energy is performed.
It is the intention for a plasma arc torch to which a nozzle protection cap according to the invention is fastenable to at least be designed so as to have a torch body, an electrode arranged on the torch body, a nozzle which has a central nozzle opening and which is arranged so as to cover the electrode in a manner separated by a plasma gas channel formed between said nozzle and electrode. It is the intention for the nozzle protection cap, which has an outlet opening, arranged at the front end side of said nozzle protection cap and situated opposite the nozzle opening, and a ring-shaped secondary gas channel within the nozzle protection cap, which secondary gas channel is connected to the outlet opening, to be detachably fastened to the plasma arc torch. It is the intention for the nozzle protection cap to be electrically insulated with respect to the electrode and the nozzle and form a secondary gas guide part, which has at least one passage.
A plasma arc torch equipped with a nozzle protection cap according to the invention may be used for cutting workpieces. Here, at least the nozzle protection cap and the respective workpiece are arranged below a water surface.
The invention will be discussed in more detail by way of example below.
In the FIGURE:
A ring-shaped secondary gas guide part 8 with a multiplicity of passages, in particular in the form of bores, of which only one is denoted by the reference designation 8a, is arranged in a secondary gas channel 9 formed between the nozzle cap 5 and a nozzle protection cap 7, between a secondary gas inlet 8b and the front end of the secondary gas channel 9, such that the secondary gas SG flowing through the passages 8a impinges on the outer shell surface of the nozzle cap 5. The secondary gas SG is subsequently conducted through the secondary gas channel 9, which is delimited by the shell surface of the nozzle cap 5 and by the inner surface 7b of the nozzle protection cap 7, to the front end of the plasma torch 1, is then fed to a plasma jet (not shown), and emerges through an outlet opening 7a of the nozzle protection cap 7. The rotating secondary gas SG flows around the plasma jet after it emerges from a nozzle opening 4a, and additionally creates a defined atmosphere around the plasma jet.
The passages 8a of the secondary gas guide part 8 are arranged such that a rotating flow of the secondary gas SG is realized. For example, the passages 8a in the secondary gas guide part 8a may be arranged equidistantly over the circular circumference of the secondary gas guide part 8 and so as to extend radially or with an offset with respect to the radial, that is to say so as to be oriented toward a point in each case offset with respect to the actual circle central point.
It is also possible for the torch to have no nozzle cap 5, and for the nozzle 4 to be screwed into the torch body 2, for example. Then, the chamber 5 through which the secondary gas SG flows is delimited by the shell surface of the nozzle 4 and by the inner surface 7b of the nozzle protection cap 7.
In the case of this plasma arc torch, use may, according to the invention, be made of a nozzle protection cap 7 as claimed in any of claims 1 to 8. In a specific individual example, the nozzle protection cap 7 may be composed of an alloy which has been produced with iron and additionally 17 to 19% chromium, 8% to 10% nickel and 0.15% to 0.35% sulfur. The maximum carbon fraction may amount to 0.1%.
Number | Date | Country | Kind |
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10 2016 219 350.3 | Oct 2016 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/075482 | 10/6/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2018/065578 | 4/12/2018 | WO | A |
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5334235 | Dorfman | Aug 1994 | A |
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Entry |
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Number | Date | Country | |
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20200045804 A1 | Feb 2020 | US |