DE102004049445C5 - plasma torch - Google Patents

Abstract

Plasma torch (1) having • a torch body (2) • an electrode (3) arranged in the torch body (2) • a nozzle (4) which has a central nozzle opening (4a) and is arranged so as to hold the electrode (3) separated by a plasma gas channel (6a) formed therebetween; a nozzle protection cap (7) having an outlet opening (7a) located at the front end side thereof opposite the nozzle opening (4a) and an annular secondary gas passage (9) inside the nozzle protection cap (7) communicating with the outlet opening (7a), the nozzle protection cap (7) being electrically insulated with respect to the electrode (3) and the nozzle (4), one between a secondary gas inlet (8b) and the front one Secondary gas guide part (8) arranged at the end of the secondary gas channel (9), which is a ring in which at least two passages (8a) are arranged equidistantly over its circumference, wherein the Durchl (8a) extend radially or have an offset to the radial, wherein - the secondary gas channel (9) between the secondary gas guide part (8) and its front end is formed such that - immediately after passing through the secondary gas guide part (8) to the longitudinal axis L of Plasma torch (1) at an angle in the range of 0 ° ± 15 ° to the longitudinal axis L of the plasma torch (1) inclined secondary gas passage part (9a) is provided, - the substantially parallel Sekundärgaskanalteil (9a) obliquely to the longitudinal axis L of the plasma torch (1 ) in the direction of the front end of the plasma torch (1) leading secondary gas channel part connects, and - at the front end of the Sekundärgaskanalteils a arranged at a right angle to the longitudinal axis L of the plasma torch secondary gas channel followed, so that the secondary gas is supplied perpendicular to the plasma jet.

Description

The present invention relates to a plasma torch which serves both for dry cutting and underwater cutting of various metallic workpieces.

In plasma cutting, an arc (pilot arc) is first ignited between a cathode (electrode) and anode (nozzle) and then transferred directly to a workpiece to produce a cut.

This arc creates a plasma, which is a thermally highly heated, electrically conductive gas consisting of positive and negative ions, electrons, and excited and neutral atoms and molecules.

As plasma gas, gases such as argon, hydrogen, nitrogen, oxygen or air are used. These gases are ionized and dissociated by the energy of the arc. The resulting plasma jet is used to cut the workpiece.

A modern plasma torch is made up of basic components such as torch body, electrode (cathode), nozzle, one or more protective caps surrounding the nozzle, as well as connections that serve to supply the burner with electricity, gases and / or liquids.

The nozzle may consist of one or more parts. For direct water-cooled burners, the nozzle is held by a nozzle cap. Cooling water flows between the nozzle and the nozzle cap. The secondary gas flows between the nozzle and protective cap.

For gas-cooled burners and indirect water-cooled burners, the nozzle cap can be omitted. Then the secondary gas flows between the nozzle and protective cap.

The electrode and the nozzle are arranged in a certain spatial relationship to one another and delimit a space - the plasma chamber in which this plasma jet is generated. The plasma jet can be used in its parameters such. As diameter, temperature, energy density and flow rate of the plasma gas are strongly influenced by the design of the nozzle and electrode.

For the different plasma gases, the electrodes and nozzles are made of different materials and in different shapes.

Nozzles are usually made of copper and water cooled directly or indirectly. Depending on the cutting task and electrical power of the plasma torch, nozzles are used which have different inner contours and openings with different diameters and thus provide the optimum cutting results.

To protect a nozzle from the heat and spewing molten metal of the workpiece during the cutting process, nozzles are enclosed by protective caps. Through the space between the nozzle and cap flows a secondary gas. This serves to create a defined atmosphere, to constrict the plasma jet and to protect against splashing during piercing.

In the patent application DE 38 32 630 A1 In the case of underwater cutting, the plasma jet is protected by a gas vortex, which rotates at high speed around the plasma jet. On the nozzle cap five to twenty gas guide in the form of a rod are arranged symmetrically. The secondary gas flowing through the conical tangential arrangement of the Gasleitführungen and the burner cap flowing secondary gas flows tangentially around the plasma jet and forms a hyperbolic vortex, which prevents the access of the water to the plasma jet. However, this burner can also be used for dry cutting, wherein the swirling secondary gas protects the burner tip in front of the molten metal of the workpiece, especially during piercing substantially.

In order to prevent the oxidation of the cut surfaces by a reaction with the oxygen in the ambient air, the selection of the secondary gas plays an important role. In the earlier patent application DE 101 44 516 A1 Applicant uses nitrogen as the secondary gas. The plasma jet is flowed around with the secondary gas, which is passed between the nozzle cap and protective cap through the resulting passage and exits from the annular opening in the direction of the workpiece. This ensures a substantially non-oxidizing atmosphere on the workpiece. This effect can be enhanced by adding small amounts of hydrogen (eg 1 to 20%).

In the plasma torch according to the patent EP 0 573 653 B1 For example, the secondary gas passing through an annular secondary gas passage is aligned by an insulator between the nozzle cap and the protective cap. The insulator has small holes that are shaped so that the secondary gas exits along the axial direction of the burner body and surrounds the plasma arc with sufficient quantity and speed. In another insulator, the secondary current is generated as a circulating current, in which the insulator formed in the Directional channel is formed spirally with respect to the central region of the burner.

In the patent EP 0 801 882 B1 A protective cap directs a secondary gas flow along the arcuate surface of a nozzle cap onto the arc. During cutting, the velocity of this flow is reduced so that the arc is not destabilized. This cap contains some vents that divert the excess gas away. The protective cap and secondary gas flow protect the nozzle from molten metal that can splash from a workpiece onto the nozzle and cause damage or parallel arcing.

In the abovementioned examples, there is the disadvantage that the plasma jet becomes unstable as a result of the direct flow of secondary gas, in particular in the case of a secondary gas volume flow which is greater than the plasma gas volume flow. The instability is especially when driving over technologically related kerfs and direction and speed changes, such. B. noticeable at corners and at the beginning of cutting. When crossing a kerf, the cutting arc stabilizes only slowly. It comes to swinging the cutting arc. This swinging forms on the resulting cut edge and thus leads to a deterioration in quality.

In US Pat. No. 6,207,923 B1 A secondary gas flows in a gap between a nozzle with an extended nozzle mouth and a protective cap. The outlet opening of the protective cap is shaped so that the nozzle mouth is partially between the inlet and the outlet of the outlet opening. Such an arrangement produces a substantially columnar flow of secondary gas around the plasma jet without substantially disturbing the plasma jet and is intended to protect the nozzle from spattering metal of the workpiece.

Disadvantage of this method is that the nozzle mouth is insufficiently protected against high-spraying metal in particular when piercing the plasma jet into the workpiece. Furthermore, the secondary gas can not be targeted in the plasma jet to achieve a good quality cut.

For certain gas combinations, the active participation of the secondary gas in the plasma process is desired. This applies z. B. for cutting stainless steels with an ArH ₂ mixture as a plasma gas and nitrogen as a secondary gas. Here, the secondary gas nitrogen not only acts as a protective gas to protect the interfaces of the oxidizing oxygen in the ambient air, but also actively participates in the plasma process. It reduces the surface tension of the melt, which becomes less viscous and better expelled from the kerf. The result is a beard-free cut. With the in US Pat. No. 6,207,923 B1 this arrangement is not possible. Even when using oxygen as the plasma gas for cutting structural steels, different effects on the quality of cut can be achieved by different composition of the secondary gas, for example different nitrogen and oxygen fractions.

From the US 5,132,512 A For example, a plasma torch with a secondary gas channel is known. In this case, the secondary gas is guided through bores which are directed parallel to the burner axis, in a channel which has one radial, one parallel, one oblique and one radial section in succession.

The invention is therefore based on the object to eliminate the disadvantages of the prior art described. The functions of the secondary gas, such as protection against high-velocity metal, creation of a defined atmosphere around the plasma jet and the active participation of the secondary gas in the plasma process should be ensured without affecting the plasma jet in its stability.

According to the invention this object is achieved by a plasma torch according to claim 1.

The subclaims relate to advantageous developments of the invention.

The invention generates a homogeneous secondary gas flow. This homogeneous secondary gas flow leads to a stabilization of the plasma jet. As a result, the oscillation of the cutting arc in difficult to be controlled technologically induced cutting situations, such. B. driving over the kerf and the corner and cutting start prevented. This results in a significant improvement in the quality of the cut and a higher cutting speed.

Studies have shown that the disadvantages described can be eliminated by a new form of secondary gas supply. As a result, the advantages of the secondary gas, such as Einschürung the plasma jet, protection of the nozzle against high-spraying metal during piercing, creating a defined atmosphere around the plasma jet and the active participation of the secondary gas in the plasma process further used and simultaneously secured the stability of the plasma jet.

The secondary gas is passed through a secondary gas guide part in the secondary gas channel, that the secondary gas flow initially on a nearly cylindrical first lateral surface of the nozzle or nozzle cap, which is directed substantially parallel to the longitudinal axis of the plasma torch hits. Thereafter, the secondary gas is passed through the secondary gas channel part, which is bounded by almost conical mantle or inner surfaces of the nozzle or the nozzle cap and nozzle cap, to the front end of the plasma torch and then fed at an angle of almost 90 ° to the longitudinal axis of the plasma torch a plasma jet. It is assumed that the particularly good homogeneity of the secondary gas, ie the particularly good distribution around a plasma jet, is achieved by first of all directing the secondary gas flow onto the lateral surface of the nozzle in a plane extending essentially at right angles to the longitudinal axis of the plasma torch the nozzle cap hits and is further set back from the front end of the plasma torch and thus the secondary gas has additional time to disperse.

It is also advantageous, the secondary gas by a suitable design of the secondary gas guide part, z. B. to rotate by displacement of the passages. Then the supply of the secondary gas to the plasma jet is not radial, but tangential. The plasma jet is not unstable in this arrangement due to the great homogeneity of the secondary gas flow, but also retains its stability in transition phases.

This effect is reinforced even if, after passing through the secondary gas guide part, the secondary gas initially not only on the almost cylindrical first lateral surface of the nozzle or the nozzle cap, but at the same time flows into a relaxation space extension, which allows a greater relaxation of the secondary gas before the secondary gas then over the conical shell or inner surfaces of the plasma jet is supplied radially or tangentially. In this case, this area of the nozzle cap with expansion chamber extension has a smaller diameter than the beginning of the subsequent conical section.

If a gas-cooled or indirectly water-cooled plasma torch is used, the nozzle cap is often omitted. Then the nozzle takes over the space-limiting task of the nozzle cap. The nozzle is geometrically formed in this case as the nozzle cap. Thus, the advantages of the invention are also guaranteed in this plasma torch variant.

Further features and advantages of the invention will become apparent from the claims and from the following description, are explained in the embodiments with reference to the schematic drawings in detail. Showing:

1 a partial sectional view of the front portion of a plasma torch according to a particular embodiment of the invention;

1.1 to 1.9 Details of 1 with variants of the design of the secondary gas channel as well 1.10 - 1.12 not belonging to the invention embodiments;

2.1 an embodiment of a secondary gas guide member in plan view from above partially in section; and

2.2 a further embodiment of a secondary gas guide part in plan view from above partially in section.

1 shows a plasma torch 1 according to a particular embodiment of the invention. The plasma torch 1 has a burner body 2 with an electrode 3 and a nozzle 4 , the longitudinal axis L of the plasma torch 1 Are defined. The electrode 3 and the nozzle 4 are in the burner body 2 Coaxially arranged, are in a certain spatial relationship and form a plasma chamber 6 through which a plasma gas PG flows through a plasma gas channel 6a is supplied. A nozzle cap 5 is coaxial with the longitudinal axis L of the plasma torch 1 arranged and holds the nozzle 4 , Between the nozzle 4 and the nozzle cap 5 there is a room 11 through which cooling water flows. The cooling water is supplied via a water feed WV and flows through a water return WR.

An annular secondary gas guide part 8th with a plurality of passages in the form of bores, of which only one with the reference numeral 8a is so in one between the nozzle cap 5 and a nozzle cap 7 formed secondary gas channel 9 between a secondary gas inlet 8b and the front end of the secondary gas passage 9 arranged that through the passage 8a flowing secondary gas SG on a nearly cylindrical first surface of the nozzle cap 5 which has a first cylindrical section 5a the nozzle cap 5 results, meets. The secondary gas SG is then passed through the secondary gas passage 9 by a nearly conical second lateral surface of the nozzle cap 5 in a lower section 5b and a corresponding conical inner surface 7b the nozzle protection cap 7 is limited to the front end of the plasma torch 1 guided, then at an angle of almost 90 ° to the longitudinal axis L of the plasma torch 1 a plasma jet (not shown) and passes through an exit port 7a the nozzle protection cap 7 out. The rotating secondary gas SG flows around the plasma jet after its exit from a nozzle opening 4a and also creates a defined atmosphere around the plasma jet.

The passages 8a the secondary gas guide part 8th are arranged so that a rotating flow of the secondary gas SG is formed. For example, the passages in the secondary gas guide part 8a , Equidistant over the circumference of the secondary gas guide part 8th and extending radially ( 2.1 ) or with an offset to the radial ( 2.2 ), ie, aligned with a respective point offset from the actual center of the circle.

The inclination of the almost cylindrical first lateral surface of the nozzle cap 5 can be up to ± 15 ° ( 1.1 . 1.2 , and 1.3 ) with respect to the longitudinal axis L of the plasma torch 1 be. At an inclination of W3 = -15 ° ( 1.3 ) the effect of homogeneity is achieved similar to enlargement of space by cylindrical surfaces and achieves a particularly good homogeneity.

The transitions between the first and second lateral surfaces of the nozzle cap 5 and corresponding first and second inner surfaces of the nozzle guard 7 can be sharp-edged ( 1.1 - 1.3 ), with bevels ( 1.4 - 1.6 ) or radii ( 1.4 - 1.9 ) be provided. There is also the possibility of combinations of radii and chamfers at the transitions.

1.10 - 1.12 show not belonging to the invention embodiments with a relaxation space extension 10 into which the secondary gas SG from the passages 8a the secondary gas guide part 8th flows to further improve the stability of the plasma jet. This relaxation room extension 10 For example, a round ( 1.10 ), a rectangular ( 1.11 ) or a multi-faceted ( 1.12 ) Have shape.

The features of the invention disclosed in the foregoing description, in the drawings and in the claims may be essential both individually and in any combination for the realization of the invention in its various embodiments.

LIST OF REFERENCE NUMBERS

1

plasma torch

2

torch body

3

electrode

4

jet

4a

nozzle opening

5

nozzle cap

5a

first section

5b

second part

6

plasma chamber

6a

Plasma gas channel

7

Nozzle cap

7a

outlet opening

7b

palm

8th

Secondary gas guide part

8a

Passage

8b

Secondary gas inlet

9

Secondary gas channel

9a

Secondary gas passage part

10

Relaxation room extension

11

room

L

longitudinal axis

PG

plasma gas

SG

secondary gas

WV

water flow

WR

Water return

Claims (7)

Plasma torch ( 1 ) with a torch body ( 2 ) • one in the burner body ( 2 ) arranged electrode ( 3 ) • a nozzle ( 4 ), which has a central nozzle opening ( 4a ) and is arranged so that the electrode ( 3 ) through a plasma gas channel ( 6a ), which is formed between them, • a nozzle cap ( 7 ), which is arranged at its front end side, the nozzle opening ( 4a ) opposite outlet opening ( 7a ) and an annular secondary gas channel ( 9 ) inside the nozzle protection cap ( 7 ) which communicates with the outlet opening ( 7a ), wherein the nozzle protection cap ( 7 ) with respect to the electrode ( 3 ) and the nozzle ( 4 ) is arranged electrically isolated, • one between a secondary gas inlet ( 8b ) and the front end of the secondary gas channel ( 9 ) arranged secondary gas guide part ( 8th ), which is a ring in which over its circumference at least two passages ( 8a ) are arranged equidistantly, wherein the passages ( 8a ) extend radially or have an offset to the radial, wherein - the secondary gas channel ( 9 ) between the secondary gas guide part ( 8th ) and its front end is formed such that - immediately after passing through the secondary gas guide part ( 8th ) to the longitudinal axis L of the plasma torch ( 1 ) at an angle in the range of 0 ° ± 15 ° to the longitudinal axis L of the plasma torch ( 1 ) inclined secondary gas channel part ( 9a ), - the substantially parallel secondary gas channel part ( 9a ) obliquely to the longitudinal axis L of the plasma torch ( 1 ) towards the front end of the plasma torch ( 1 ) leading secondary gas duct part connects, and - at the front end of the secondary gas duct part at a right angle to the longitudinal axis L the plasma torch arranged secondary gas channel part connects, so that the secondary gas is supplied to the plasma jet vertically. Plasma torch according to claim 1, characterized in that a nozzle cap ( 5 ) is provided, which the nozzle ( 4 ) with the exception of at least the nozzle opening ( 4a ) and within the nozzle cap ( 7 ) and from this at its front end side through the secondary gas channel ( 9 ) is disconnected. Plasma torch according to claim 1 or 2, characterized in that the nozzle ( 4 ) or the nozzle cap ( 5 ) in the region of the secondary gas guidance part ( 8th ) has a substantially cylindrical first lateral surface and towards the front end of the plasma torch ( 1 ) towards the front end of the plasma torch ( 1 ) in the substantially conically tapered second lateral surface of the nozzle ( 4 ) or the nozzle cap ( 5 ). Plasma torch ( 1 ) according to claim 3, characterized in that the first lateral surface at an angle in the range of 0 ° ± 15 ° to the longitudinal axis L of the plasma torch ( 1 ) is inclined. Plasma torch ( 1 ) according to claim 3 or 4, characterized in that the transition between the first and second lateral surfaces is rounded, beveled or sharp-edged. Plasma torch ( 1 ) according to one of the preceding claims, characterized in that the offset to the radial is in the range of 0.5 to 4 millimeters. Plasma torch ( 1 ) according to one of the preceding claims, characterized in that the passage ( 8a ) has a diameter in the range of 0.2 to 1.0 millimeters.

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