The present invention relates to a nozzle protection cap for an arc plasma torch. The arc plasma torch can be used both for dry cutting and underwater cutting of different metal workpieces.
During plasma cutting, an arc (pilot arc) is first ignited between a cathode (electrode) and anode (nozzle) and then directly transferred to a workpiece in order to carry out cutting.
The arc produces a plasma which is a highly heated, electrically conductive gas (plasma gas) consisting of positive and negative ions, electrons as well as excited and neutral atoms and molecules. By way of plasma gas, gases such as argon, hydrogen, nitrogen, oxygen or air are used. These gases are ionised and disassociated through the energy of the arc. The plasma beam produced is used to cut the workpiece.
A modern arc plasma torch consists largely of base components such as a torch body, electrode (cathode), nozzle, one or a plurality of caps such as the nozzle cap and nozzle protection cap, which surround the nozzle, and connections which are used to supply the arc plasma torch with power, gases and/or liquids. Nozzle protection caps can be used to protect the nozzle during the cutting process against the heat and sprayed-out molten metal of the workpiece.
The nozzle can consist of one or more components. With directly water-cooled arc plasma torches the nozzle is 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 nozzle protection cap. This serves for the creation of a defined atmosphere, for tapering the plasma beam, and for protection against spraying during penetration.
In the case of gas-cooled arc plasma torches and indirectly water-cooled arc plasma torches, the nozzle cap can be omitted. The secondary gas then flows between the nozzle and nozzle protection cap.
The electrode and the nozzle are arranged relative to each other in a certain spatial relationship and define a space, the plasma chamber, in which the plasma beam is produced. The plasma beam can be greatly influenced in its parameters, such as, for example, diameter, temperature, energy density and through-flow rate of the plasma gas, through the design of the nozzle and electrode.
Electrodes and nozzles are produced from different materials and in different forms for different plasma gases. They are generally produced from copper and directly or indirectly water-cooled. Depending upon the cutting task and electric power of the arc plasma torch, nozzles are used which have different inner contours and openings with different diameters and thus provide optimum cutting results.
For example German Document DE 10 2004 049 445 A1 shows an arc plasma torch with a water-cooled electrode and nozzle and a gas-cooled nozzle protection cap. The secondary gas is fed through a nozzle protection cap holder inside past a screw connection region between the nozzle protection 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 beam.
European Document EP 0 573 653 B1 relates to an arc plasma torch with a water-cooled electrode and nozzle and also a water-cooled nozzle protection cap. As in the case of the arc plasma torch disclosed in DE 10 2004 049 445 A1, in EP 0 573 653 B1 a secondary gas is fed within a nozzle protection cap holder inside past a screw connection region between the nozzle protection cap holder and a nozzle protection cap to a plasma beam. Also as in the arc plasma torch disclosed in DE 10 2004 049 445 A1, the arc plasma torch of EP 0 573 653 B1 comprises insufficient cooling of the nozzle protection cap for certain applications.
In addition, the arc plasma torch of EP 0 573 653 B1 is designed so that an annular cooling water chamber is formed within the base end region of the nozzle protection cap. Flowing cooling water cools the nozzle protection cap. This structure has the additional disadvantage that upon unscrewing the nozzle protection cap, the cooling water leaves the cooling chamber and drips or runs on to the outer surface of the nozzle cap and the inner surface of the nozzle protection cap. This gives rise to cooling medium residue in the secondary gas chamber formed by the nozzle cap and the nozzle protection cap, which both impairs cutting quality and operational security and also leads to loss of cooling medium.
It is thus an object of the invention to improve the cooling of the nozzle protection cap of an arc plasma torch. This is achieved according to the invention through a nozzle protection cap for an arc plasma torch comprising a front end section and a rear end section with a thread region on its inner surface for screwing into a torch body of an arc plasma torch, with at least one groove crossing the thread region on the inner surface.
This object is further realized through a nozzle protection cap holder for an arc plasma torch, comprising a section with a thread region on its outer surface for screwing into a nozzle protection cap of an arc plasma torch, with at least one groove crossing the thread region on its outer surface.
This object is also achieved through an arc plasma torch comprising a torch body and a nozzle protection cap screwed thereto in a screw connection region, the torch body and/or the nozzle protection cap being designed so that at least one channel is formed between them which crosses the screw connection region.
In the nozzle protection cap, it is contemplated that the thread region can be designed for screwing into the torch body via a nozzle protection cap holder.
According to some contemplated embodiments of the invention, at least one groove or grooves cross the thread region parallel to the longitudinal axis of the nozzle protection cap. Alternatively, at least one groove or grooves can cross the thread region obliquely to the longitudinal axis of the nozzle protection cap. It can also be provided that the groove or grooves cross the thread region in the manner of a screw.
In some contemplated embodiments, the nozzle protection cap can be constructed in two parts. Such construction allows just one worn part to be replaced if needed.
In some contemplated embodiments, a nozzle protection cap holder can be provided where the groove or grooves cross the thread region parallel to the longitudinal axis of the nozzle protection cap.
According to some embodiments of the invention, at least one groove or grooves cross the thread region obliquely to the longitudinal axis of the nozzle protection cap. In other embodiments, the at least one groove or grooves cross the thread region in the manner of a screw. In some contemplated embodiments of the arc plasma torch, the nozzle protection cap is screwed in the screw connection region via a nozzle protection cap holder.
At least one channel or channels are preferably formed from a groove in the torch body or nozzle protection cap holder and/or a groove in the nozzle protection cap. It can be provided in particular that the channel is a secondary medium channel. The secondary medium can, for example, be a liquid such as water or oil, or a gas such as water vapour. It can therefore be provided that the secondary medium channel is a secondary gas channel.
In some contemplated embodiments, a secondary medium inlet channel can be provided in the torch body, in particular in the nozzle protection cap holder, which is connected to at least one secondary medium channel or channels.
It is also contemplated that the arc plasma torch can be both a water-cooled or gas-cooled arc plasma torch having regard to the electrode and nozzle. The nozzle protection cap can be water-cooled or gas-cooled.
The invention is based upon the surprising discovery that upon use with, for example a secondary gas, improved cooling of the nozzle protection cap is achieved by feeding the secondary gas through the screw connection region. At the same time, symmetry and thus homogeneity of the secondary gas in the whole region are improved, resulting in improved cutting results. In some cases it is even possible for a secondary gas guiding component to be omitted. In addition, operational security is also improved. When using the invention with a secondary gas, advantages such as tapering of the plasma beam, protection of the nozzle from highly spraying metal during penetration, creation of a defined atmosphere around the plasma beam, and active participation of the secondary gas in the plasma process are realized while simultaneously securing stability of the plasma beam.
Further features and advantages of the invention will be best understood from the claims and the following Detailed Description, in which several embodiments are explained individually by reference to the schematic drawings, in which:
A secondary gas SG flows through a secondary gas inlet channel 2.1.3 and an orifice 2.1.4 perpendicularly into a circular space 9a formed by the outer surface 2.1.1 of the nozzle protection cap holder 2.1 and the inner surface 7.1 of the nozzle protection cap 7 and is distributed. To the rear, the space 9a is sealed with an O-ring 2.5. The secondary gas SG then flows through the secondary gas channels 9b (see
In contrast with the prior art, the secondary gas SG is introduced having regard to the tip of the plasma torch 1 behind the screw connection region into the space 9. Thus, cooling of the nozzle protection cap 7 is improved. The secondary gas SG cools the inner surface of the nozzle protection cap 7 over almost its entire length. This is true even though the screw connection region is cooled with limited resources through the secondary gas flow. This is particularly significant as the nozzle protection cap holder 2.1 consists of plastic and can be damaged in the event of overheating. In the secondary gas channels 9b formed in the screw connection region or in the thread region, the secondary gas SG flows more quickly than in the following space 9c, as the sum of the surfaces of the flow cross-sections is smaller than the flow cross-section of the space 9c. This high flow speed also improves the cooling effect. With corresponding dimensioning, the secondary gas can be set in rotation, the flow speed thus also increased in the space 9c, and the cooling improved.
The embodiment depicted in
In
In the embodiment shown and described in
It is within the contemplated scope of the invention that triple start or multiple start threads can also be used. However, in such cases, the pitch significantly increases, which can potentially complicate screwing.
The features of the invention disclosed in the present description, in the drawings and in the claims can be essential both individually and in any combinations for the realization of the invention in its different embodiments.
Number | Date | Country | Kind |
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10 2009 037 376 | Aug 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2010/000921 | 8/4/2010 | WO | 00 | 2/24/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/018070 | 2/17/2011 | WO | A |
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5362938 | McGee et al. | Nov 1994 | A |
5393952 | Yamaguchi et al. | Feb 1995 | A |
5440094 | Zapletal | Aug 1995 | A |
5440100 | Stuart et al. | Aug 1995 | A |
5569397 | Tsurumaki et al. | Oct 1996 | A |
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20090230095 | Liebold et al. | Sep 2009 | A1 |
20090230097 | Liebold et al. | Sep 2009 | A1 |
Number | Date | Country |
---|---|---|
214 318 | Oct 1984 | DE |
27 55 461 | Nov 1988 | DE |
10 2004 049 445 | Apr 2006 | DE |
10 2007 005 316 | Dec 2009 | DE |
0 573 653 | Dec 1993 | EP |
0 629 106 | Dec 1994 | EP |
WO 2010073223 | Jul 2010 | WO |
Entry |
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International Search Report for PCT/DE2010/000921, Dec. 15, 2010. |
Statement of Relevance: The International Search Report cites US 5,362,938 (“D1”), EP 573 653 A1 (“D2”), and WO 2010/073223 A1 (“D3”), Dec. 15, 2010. |
English Translation of DE 10 2007 005 316 B4; Publication Date: Dec. 3, 2009; Applicant: Kjellberg Finsterwalde Plasma und Maschinen GmbH. |
Number | Date | Country | |
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20120138580 A1 | Jun 2012 | US |