The present invention relates to a nozzle for a liquid cooled plasma torch, a nozzle cap for a liquid cooled plasma torch and a plasma torch head with same.
A plasma is an electrically conductive gas thermally heated to a high temperature and consisting of positive and negative ions, electrons and excited and neutral atoms and molecules.
Different gases are used as plasma gas, for example the single-atom argon and/or the two-atom gases hydrogen, nitrogen, oxygen, and air. These gases ionise and dissociate through the energy of an arc. The arc constricted through a nozzle is described as a plasma beam.
The parameters of a plasma beam can be greatly influenced by the form of the nozzle and electrode. Such parameters of the plasma beam can, for example, include the beam diameter, temperature, energy density and the flow speed of the gas.
In plasma cutting, for example, plasma is constricted through a nozzle which can be gas cooled or water cooled. Energy densities of up to 2×106 W/cm2 can thereby be reached. Temperatures of up to 30,000° C. arise in the plasma beam, which realize, in association with the high flow speed of the gas, very high material cutting speeds.
Plasma torches can be operated directly or indirectly. In a direct mode of operation, current flows from a current source via the electrode of a plasma torch. The plasma beam produced by means of an arc and constricted through the nozzle directly via the work piece back to the current source. Electrically conductive materials can be cut with such direct mode of operation.
In an indirect mode of operation, current flows from the current source via the electrode of a plasma torch, the plasma beam, produced by means of an arc and constricted through a nozzle, and the nozzle back to the current source. The nozzle is thereby more greatly loaded than during direct plasma cutting, as it does not only constrict the plasma beam but also realizes the starting point of the arc. With such indirect mode of operation, both electrically conductive and non-electrically conductive materials can be cut.
Due to high thermal load, nozzles are generally made from a metal material, preferably from copper due to its high electrical conductivity and heat conductivity. The same applies to the electrode holders, which are also frequently made from silver. The main components of a plasma torch include a plasma torch head, a nozzle cap, a plasma gas guiding part, a nozzle, a nozzle holder, an electrode receiving element, an electrode holder with electrode insert and, in modern plasma torches, a nozzle protection cap holder and a nozzle protection cap. The electrode holder fixes a sharp electrode insert made of tungsten, which is suited for the use of non-oxidizing gases such as plasma gas, for example an argon-hydrogen mixture. A flat electrode, of which the electrode insert is made, for example, of hafnium, is also suited for the use of oxidizing gases such as plasma gas, for example air or oxygen. In order to achieve a longer lifespan for the nozzle, the latter is cooled with a liquid such as water. The coolant is supplied via a water supply element to the nozzle and carried away from the nozzle by a water return element and thereby flows through a coolant chamber, which is delimited by the nozzle and the nozzle cap.
Former East Germany document DD 36014 B1 describes a nozzle. This consists of a material with good conductivity, for example copper, and has a geometric form assigned to the respective plasma torch type, for example a conically formed discharge chamber with a cylindrical nozzle outlet. The outer form of the nozzle is formed as a cone, whereby a virtually equal wall thickness is achieved, and whereby such dimensions allow that good stability of the nozzle and good head conduction to the coolant. The nozzle is located in a nozzle holder. The nozzle holder consists of corrosion resistant material, for example brass, and has internally a centring receiving element for the nozzle and a groove for a sealing rubber, which seals the discharge chamber against the coolant. Furthermore, bores offset by 180° are disposed in the nozzle holder for the coolant supply and return. On the outer diameter of the nozzle holder there is a groove for a rubber o-ring for sealing the coolant chamber in relation to the atmosphere and also a thread and a centring receiving element for a nozzle cap. The nozzle cap, made of a corrosion resistant material such as brass, is formed at an acute angle and has a wall thickness usefully dimensioned to facilitate removal of radiation heat to the coolant. The smallest inner diameter is provided with an o-ring. Water is used as a coolant in the simplest case. This arrangement is intended to facilitate simple manufacture of the nozzles with sparing use of materials and rapid exchange of the nozzles as well as allowing, through acute angle construction, a pivoting of the plasma torch in relation to the work piece to allow for inclined cuts.
German document DE-OS 1 565 638 describes a plasma torch, preferably for plasma fusion cutting of work pieces and for preparation of welding edges. The narrow form of the torch head is achieved through the use of a particularly acute-angled cutting nozzle, of which the inner and outer angles are equal to each other and also equal to the inner and outer angle of the nozzle cap. A coolant chamber is formed between the nozzle cap and the cutting nozzle, in which coolant chamber the nozzle cap is provided with a collar, which seals metallically with the cutting nozzle, so that an even annular gap is thereby formed as a coolant chamber. The supply and removal of the coolant, generally water, is realized through two slots in the nozzle holder, which are arranged offset in relation to each other by 180°.
German document DE 25 25 939 describes a plasma arc torch, particularly for cutting or welding, wherein the electrode holder and the nozzle body form an exchangeable unit. The outer coolant supply is formed essentially through a clamping cap enclosing the nozzle body. The coolant flows via channels into an annular space, which is formed by the nozzle body and the clamping cap.
German document DE 692 33 071 T2 relates to a plasma arc cutting device. An embodiment of a nozzle is described therein for a plasma arc cutting torch, which nozzle is formed from a conductive material and comprises an outlet opening for a plasma gas beam and a hollow body section. Said body section is formed so that it has a generally conical, thin-walled configuration, which is inclined towards the outlet opening, and has an enlarged head section, which is formed integrally with the body section. The head section is thereby solid with the exception of a central channel, which is aligned with the outlet opening and has a generally conical outer surface, which is also inclined towards the outlet opening and has a diameter adjacent to that of the adjacent body section which exceeds the diameter of the body section, in order to form an undercut recess. The plasma arc cutting device has a secondary gas cap. A water cooled cap is arranged between the nozzle and the secondary gas cap in order to form a water cooled chamber for the outer surface of the nozzle for highly effective cooling. The nozzle is characterised by a large head, which surrounds an outlet opening for the plasma beam, and a sharp undercut or a recess to a conical body. This nozzle construction encourages the cooling of the nozzle.
In the plasma torches described above the coolant is supplied through a water supply channel to the nozzle and carried away from the nozzle by a water removal channel. These channels are mostly offset by 180° relative to each other and the coolant is intended to flow around the nozzle as evenly as possible on the way from the supply to the removal channel. Nonetheless, overheating in proximity to the nozzle channel is ascertained again and again.
Former East Germany document DD 83890 B1 describes another coolant guide for a torch, preferably a plasma torch, in particular for plasma welding, plasma cutting, plasma fusion and plasma spraying purposes, which withstands high thermal loads of the nozzle and the cathode. A coolant guide ring, which can be easily inserted into the nozzle holding part and easily removed from it, is provided for the cooling of the nozzle. Said coolant guide ring has, for the purpose of limitation of the coolant guide to a thin layer of maximum 3 mm in thickness, along the outer nozzle wall, a surrounding groove. Running into this surrounding groove are multiple cooling lines, preferably two to four in number, which are arranged in a star form radially thereto and symmetrically to the nozzle axis and in a star form in relation thereto at an angle of between 0 and 90°, such that the cooling lines are respectively adjacent two coolant outflows and each coolant outflow is adjacent to two coolant inflows.
However, such arrangement has the disadvantage that greater resources are necessary for the cooling through the use of an additional component, the coolant guide ring. In addition, such arrangement requires a larger construction.
The invention allows overheating to be avoided in a plasma torch in the vicinity of the nozzle channel and the nozzle bore. This is achieved according to the invention through a plasma torch head, having a nozzle, a nozzle holder, and a nozzle cap, wherein the nozzle cap and the nozzle form a cooling liquid chamber which can be connected to a cooling liquid supply line and a cooling liquid return line via two bores offset respectively by 60° to 180°. The nozzle holder is formed such that the cooling liquid is conveyed virtually perpendicular to the longitudinal axis of the plasma torch head, contacting the nozzle, into the cooling liquid chamber and/or virtually perpendicular to the longitudinal axis out of the cooling liquid chamber into the nozzle holder.
The invention includes a nozzle including a nozzle bore for the exit of a plasma gas beam at a nozzle tip, a first section, of which the outer surface is essentially cylindrical, and a second section connecting thereto towards the nozzle tip, of which second section the outer surface tapers essentially conically towards the nozzle tip. At least one liquid supply groove can be provided to extend over a part of the first section and over the second section in the outer surface of the nozzle towards the nozzle tip and one liquid return groove separate from the liquid supply groove(s) can be provided to extend over the second section, or one liquid supply groove can be provided to extend over a part of the first section and over the second section in the outer surface of the nozzle towards the nozzle tip and at least one liquid return groove separate from the liquid supply groove can be provided to extend over the second section. “Essentially cylindrical” is contemplated to mean that the outer surface, at least without consideration of the grooves, such as liquid supply and return grooves, is more or less cylindrical. Similarly, “tapering essentially conically” is contemplated to mean that the outer surface, at least without consideration of the grooves, such as liquid supply and return grooves, tapers more or less conically.
The invention also provides a nozzle cap for a liquid cooled plasma torch, wherein the nozzle cap comprises an essentially conically tapering inner surface, characterised in that the inner surface of the nozzle cap comprises at least two recesses in a radial plane.
According to some embodiments of the invention, the nozzle of the plasma torch head comprises one or more cooling liquid supply groove(s) and the nozzle cap comprises on its inner surface at least two or three recesses of which the openings facing the nozzle respectively extend over an arc length (b2), whereby the arc length of the regions of the nozzle adjacent in the circumferential direction to the cooling liquid supply groove(s) and outwardly projecting in relation to the cooling liquid supply groove(s) is respectively greater than the arc length (d4, e4). This avoids the need for a secondary connection from the coolant supply to the coolant return.
It can further be provided in the plasma torch head that the two bores each extend essentially parallel to the longitudinal axis of the plasma torch head. This reduces the amount of space necessary to connect cooling liquid lines to the plasma torch head. In some embodiments the bores for the cooling liquid supply can also be arranged offset in relation to the cooling liquid return by 180°.
The circular measure of the section between the recesses of the nozzle cap is advantageously as a maximum half the size of the minimum circular measure of the cooling liquid return groove or the minimum circular measure of the cooling liquid supply groove(s) of the nozzle. In some embodiments the liquid return groove(s) can also favourably extend over a part of the first section in the outer surface of the nozzle.
In some embodiments at least two liquid supply grooves are provided. Some embodiments provide at least two liquid return grooves. Some embodiments also allow the middle point of the liquid supply groove and the middle point of the liquid return groove to be arranged offset by 180° to each other around the circumference of the nozzle. In the resulting configuration, the liquid supply groove and the liquid return groove lie opposite each other.
It is contemplated the width of the liquid return groove and the width of the liquid supply groove can lie in the circumferential direction in the range of from about 90° to 270°. Such a particularly wide liquid return/supply groove allows for enhanced cooling of the nozzle. It is further contemplated that a groove can be disposed in the first section, the groove being in connection with the liquid supply groove. In some embodiments a groove can be disposed in the first section, the groove being in connection with the liquid return groove.
It is also contemplated the groove can extend in the circumferential direction of the first section of the nozzle around the whole circumference. It is contemplated the groove can extend in the circumferential direction of the first section of the nozzle over an angle from about 60° to 300°, and the groove can also extend in the circumferential direction of the first section of the nozzle over an angle in the range from about 60° to 300°. It is further contemplated the groove can extend in the circumferential direction of the first section of the nozzle over an angle in the range from about 90° to 270°. The groove can also extend in the circumferential direction of the first section of the nozzle over an angle in the range from about 90° to 270°.
In one contemplated embodiment, two liquid supply grooves are provided. In a further embodiment, precisely two liquid return grooves are provided.
The two liquid supply grooves can be arranged around the circumference of the nozzle symmetrically to a straight line extending from the middle point of the liquid return groove at a right angle through the longitudinal axis of the nozzle. The two liquid return grooves can be arranged around the circumference of the nozzle symmetrically to a straight line extending from the middle point of the liquid supply groove at a right angle through the longitudinal axis of the nozzle.
The middle points of the two liquid supply grooves and/or the middle points of the two liquid return grooves can be arranged offset by an angle in relation to each other around the circumference of the nozzle, which angle lies between about 30° and 180°. The width of the liquid return groove and/or the width of the liquid supply groove can lie in the circumferential direction in the range from about 120° to 270°.
It is also contemplated the two liquid supply grooves can be connected to each other in the first section of the nozzle and/or the two liquid return grooves can be connected to each other in the first section of the nozzle. The two liquid supply grooves can also be connected to each other in the first section of the nozzle by a groove. The two liquid return grooves can also be connected to each other in the first section of the nozzle by a groove.
In some embodiments, the groove can extend beyond one or both liquid supply grooves. The groove can also extend beyond one or both liquid return grooves. In some embodiments, the groove can extend in the circumferential direction of the first section of the nozzle around the whole circumference. The groove can also extend in the circumferential direction of the first section of the nozzle over an angle in the range from about 60° to 300°. It is contemplated the groove can extend in the circumferential direction of the first section of the nozzle over an angle in the range from about 90° to 270°.
By supplying and/or removing the cooling liquid at a right angle to the longitudinal axis of the plasma torch head instead of—as in the prior art—parallel to the longitudinal axis of the plasma torch head, improved cooling of the nozzle is achieved through longer contact of the cooling liquid with the nozzle.
If more than one cooling liquid supply groove is provided, enhanced vorticity of the cooling liquid can thus be achieved in the region of the nozzle tip through the convergence of the liquid flows, which also tends to enhance cooling of the nozzle.
Further features and advantages of the invention follow from the attached claims and the following description, in which several embodiments are explained individually by reference to the schematic drawings, in which:
a depicts a sectional representation along the line A-A of
b depicts a sectional representation along the line B-B of
a depicts a sectional representation along the line A-A of
b depicts a sectional representation along the line B-B of
a depicts a sectional representation along the line A-A of
b depicts a sectional representation along the line B-B of
a depicts a sectional representation along the line A-A of
b depicts a sectional representation along the line B-B of
a depicts a sectional representation along line A-A of
b depicts a sectional representation along the line B-B of
a depicts a sectional representation along the line A-A of
b depicts a sectional representation along the line B-B of
In the following description, embodiments are shown which comprise at least one liquid supply groove, referred to here as a cooling liquid supply groove, and one liquid return groove, referred to here as a cooling liquid return groove. However, the invention is not limited to any particular number of liquid supply grooves and liquid return grooves, and it is contemplated that the number of liquid supply and return grooves will vary considerably for different embodiments within the intended invention scope.
Referring to
In prior art plasma torches, overheating of the nozzle 4 tends to occur frequently in the region of the nozzle bore 4.10. However, overheating can also arise between the cylindrical section of the nozzle 4 and the nozzle holder 5. This is particularly true for plasma torches operated with a high pilot current or indirectly. This problem also tends to manifest itself by discoloration of the copper after a short operating time. For example, at currents of 40 A, discoloration can occur in as little as 5 minutes. Likewise the sealing point between the nozzle 4 and the nozzle cap 2 can be overloaded, which can lead to damage to the o-ring 4.6 and thus to interference with sealing and cooling liquid escaping. This effect has been observed to occur particularly on the side of the nozzle 4 facing the cooling liquid return. It is assumed that the region subject to the highest thermal load, the nozzle bore 4.10 of the nozzle 4, is inadequately cooled because the cooling liquid flows insufficiently through the part 10.20 of the cooling liquid chamber 10 lying closest to the nozzle bore and/or does not even reach this part 10.20, particularly on the side facing the cooling liquid return.
Referring to the plasma torch of the invention in
The plasma torch head 1 is equipped with a nozzle protection cap holder 8 and a nozzle protection cap 9. The secondary gas SG which surrounds the plasma beam flows through this region. The secondary gas SG flows through a secondary gas guide element 9.1 and can thereby be set in rotation.
a shows a sectional representation along the line A-A of the plasma torch of
This configuration allows for effective cooling of the nozzle 4 in the region of the nozzle tip and prevents thermal overload. The configuration also ensures that as much cooling liquid as possible reaches the area 10.20 of the cooling liquid chamber 10. The configuration has also been observed to prevent discoloration of the nozzle in the region of the nozzle bore 4.10 and further observed to prevent problems in the sealing between the nozzle 4 and the nozzle cap 2 and overheating of the O-ring.
b shows a sectional representation along the line B of the plasma torch head of
a shows a sectional representation along the line A-A of the plasma torch of
b is a sectional illustration along the line B-B of the plasma torch of
a shows a sectional representation along the line A-A of the plasma torch of
b is a sectional illustration along the line B-B of the plasma torch of
The alpha width 4 of the cooling liquid return groove 4.22 in the circumferential direction is approximately 190°. Disposed between the cooling liquid grooves 4.20; 4.21 and the cooling liquid return groove 4.22 are the outwardly projecting regions 4.31; 4.32 and 4.33 with the associated sections 4.41; 4.42 and 4.43. The cooling liquid supply grooves 4.20 and 4.21 are connected to each other by the groove 4.6 of the nozzle.
a shows a sectional representation along the line A-A of the plasma torch of
b shows a sectional illustration along the line B-B of the plasma torch head of
a shows a sectional representation along the line A-A of the plasma torch of
b shows a sectional representation along the line B-B of the plasma torch head of
a shows a sectional representation along the line A-A of the plasma torch of
b shows a sectional representation along the line B-B of the plasma torch of
The nozzle caps shown in
The features disclosed in the present description, in the drawings, and in the claims will be essential to the realization of the invention in its different embodiments both individually and in any combinations thereof.
Number | Date | Country | Kind |
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10 2008 050 770 | Oct 2008 | DE | national |
10 2009 006 132 | Jan 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2009/001169 | 8/14/2009 | WO | 00 | 4/11/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/040328 | 4/15/2010 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5120930 | Sanders et al. | Jun 1992 | A |
7683342 | Morfill et al. | Mar 2010 | B2 |
8389887 | Liebold et al. | Mar 2013 | B2 |
20050082263 | Koike et al. | Apr 2005 | A1 |
20080093346 | Yamaguchi et al. | Apr 2008 | A1 |
20080210669 | Yang et al. | Sep 2008 | A1 |
20090230095 | Liebold et al. | Sep 2009 | A1 |
20120055906 | Shipulski et al. | Mar 2012 | A1 |
20130026141 | Liebold et al. | Jan 2013 | A1 |
Number | Date | Country |
---|---|---|
36014 | Aug 1967 | DE |
1565638 | Apr 1970 | DE |
OS 1 565 638 | Apr 1970 | DE |
83890 | May 1973 | DE |
25 25 939 | Dec 1976 | DE |
26 51 185 | Nov 1978 | DE |
40 30 541 | Apr 1992 | DE |
198 28 633 | Dec 1999 | DE |
692 33 071 | Mar 2004 | DE |
10 2007 005 316 | Mar 2008 | DE |
0585977 | Mar 1994 | EP |
0794697 | May 2003 | EP |
1 524 887 | Apr 2005 | EP |
1416783 | Dec 1975 | GB |
WO 9200658 | Jan 1992 | WO |
WO 9201360 | Jan 1992 | WO |
Entry |
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International Search Report—PCT/DE2009/001169. |
Number | Date | Country | |
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20110284502 A1 | Nov 2011 | US |