DE2033072C - Arc plasma torch with a cooled cathode and cooled anode - Google Patents

Description

45

The invention relates to a plasma arc torch with a cooled cathode and a cooled anode, which are coaxially and axially spaced from one another and on the Burner voltage lie, with a protective gas supply in the cathode holder, which the protective gas in axial Can flow direction along the cathode, as well as a tangentially directed operating gas supply in an insulating body spacing the electrodes.

Arc plasma torches of this type are already known (French patent specification 1 225 906), wherein around the cathode and optionally additionally in the anode a sleeve forming a Annular gap is arranged through which a protective gas flows to protect the electrodes; to ignite the Arc must be the distance between anode and cathode by turning the cathode holder can be reduced, so that the structural solution is expensive.

uer invention is based on the object be. Arc plasma torches of the type mentioned at the beginning G «Sing the protection of the cathode even more effectively to design and at the same time to simplify their structural design.

This object is achieved according to the invention in that between the anode and the cathode holder r there is arranged an ignition anode which is spaced apart from the anode by means of an insulating ring body * and is coaxial with the ubngen EIek trod · η the ring SS'Jr has bores, you. ^ h which the operation ^ flows in and in which there is a gas pressure of the cathode, the cathode holder and the ignition anode " ^mschl ° ^sse ? f" * ^ ^π> which is above the gas pressure lu., ·. which is present in the space that is formed by the Zünianode, the ring body and the anode u "-

^A further embodiment of the invention is a cutting gas supply in the cathode holder em Rm, spal or a coaxial ring of bores

h yet another embodiment of the invention the ignition anode has a cylindrical water cooler on. In an even more furious stable of the invention includes the anode. 1 cylindrical space for cooling water

In this arc plasma torch, at d _t .: I the inert gas between the ignition of a pilot arc. Cathode and first anode, ie ignition anode around, subsequent transition of the arc to the second anode, ie actual anode allowed, u .-. D to which a higher voltage is applied than to o-.r ignition anode, it is possible to use compressed air as the ub . -you should use most of the constituents of the plasma, so there is a risk of damage to the cathode as a result of the reaction of the oxygen in the air at the high temperatures. The inert gas supplied around the cathode acts as a protective shield, so that the oxygen is prevented from promoting the oxidation of the cathode. It can therefore be made from a material that has other special properties for this purpose.

The overpressure of the inert gas entering the bore of the first anode by means of an annular gap and / or a ring of bores around the cathode prevents air from entering Diffused back up the bore and caused corrosion of the cathode. Ion bombardment the cathode is limited to the inert gas ions, particularly the argon ions alone. However, only the cathode is shielded in this way.

The first-mentioned gas, which is substantially tangential and preferably in a downward direction in

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the plasma chamber is initiated, supports a constriction of the arch and increases the protection of the burner from being destroyed by heat.

Another advantage of the torch is that the base of the arc is at that of the cathode remote point is held in the hole of the anode and also rotates around this hole. This Measure ensures even distribution of heat in the anode opening and allows an effective ■ arrangement of channels for the cooling water L ■: outside the anode due to the fact that the base of the arch is fixed in the longitudinal direction.

With a burner in which the air is the predominant component, up to 95%, with argon as Residual gas or another inert gas, the arc voltage is higher and - for a given power. - The current drawn by the torch is lower than with other gases, so that the erosion of the electrode is decreased. Typical working conditions ao -ind about 120 volts and about 160 amps; however is a larger voltage range, for example between. hen 100 and 300 volts and a current range for example applicable above 130 amps.

The burner allows a greater length of the arch to be obtained, thus reducing the erosion of the Electrodes is additionally reduced for a given power, due to the fact that the voltage drop across the arc is increased and the current is reduced.

An embodiment of a burner construction is explained with reference to the drawing, soft shows a schematic axial section through a burner.

In the torch shown, a water-cooled cathode 1 is provided, the water being fed up to a point above a tip 2 made of tungsten by means of a central line 3 and carried away in an upward direction through an annular gap 4 between this line and the outside of the cathode. An outer part 5 of the cathode tip 2 is of an inverted conical shape and is arranged in an inverted conical space 6 of the ignition anode 7. The ignition anode 7 is provided with a cylindrical jacket water cooler 8, which surrounds this space and a coaxial channel 9 of the ignition anode, which leads to a plasma chamber 10 of the burner. Above the ignition anode 7, an insulating body 11 extends in the upward direction, which is separated from the outside of the cathode 1 by an annular gap 12 and is supplied by soft argon at a point 13 under excess pressure, for example at a pressure of less than 0.703 kg / cm ² and a throughput of about 0.22 to 0.28 m ³ per hour.

In a modification of this exemplary embodiment or in addition to the gap 12, a coaxial ring of bores 15 can be provided, specifically for the supply of argon. The bottom surface of the ignition anode 7 is separated from the top of a second anode, ie the actual anode 16, by means of an annular body 17 made of heat-resistant insulating material. Transverse bores 18 are guided through it, via which compressed air is supplied which enters the plasma chamber 10 essentially tangentially and in a downward direction; for example at a pressure of approximately 0.56 kg / cm ² and at a throughput of about 4.8 m ³ per hour.

The ring body 17 can suitably consist of an asbestos mixture. The anode 16 has a cylindrical space 19 for water, which surrounds its central channel 20, which the Forms the outlet of the burner. The anodes 7, 16 can, for. B. made of copper or a copper alloy be made.

In terms of construction, the parts 11, 7, 17 and 16 can be connected to one another by means of bolts be that extend in the longitudinal direction of the anodes; They can also be made by embedding them in a heat-resistant Insulating material are held together tightly.

The negative pole of an energy source 21 is connected to the cathode 1 and its positive output to the second anode 16 and further - separately - via a switch 22 and a resistor 22 'with the first anode 7 connected. When the switch is closed, a voltage is applied to the cathode 1 and the first anode 7 is applied so that the pilot or ignition arc, as mentioned above, is ignited. To the When the burner is ignited, the arc goes partially by itself from the first anode 7 to the second anode 16 over; by opening the switch 22, the so-called sheet transfer process is ended The torch then works with a non-transferred arc.

Such a torch can suitably operate at a torch voltage of approximately 170 volts and with a torch current of approximately 180 amps operate.

1 sheet of drawings

Claims (5)

Patent claims: 1. Arc plasma torch with a cooled cathode and a cooled anode, the are coaxially and axially spaced from one another and on the burner voltage lie, with a protective gas supply in the cathode holder, which the protective gas in axial Can flow direction along the cathode, as well as a tangentially directed operating gas supply in an insulating body spacing the electrodes, characterized in that that between the anode (16) and the cathode holder (11) one by means of an insulating Ring body (17) spaced apart from the anode and coaxial with the other electrodes, ignition anode (7) a - '. Is arranged, the ring body (17) has bores (Ϊ8) through which the operating gas flows in and in that of the cathode (1). the cathode holder (11) and the ignition anode (7) enclosed space (6) a gas pressure prevails, which is above the gas pressure ", which is present in the space (10) that of the ignition anode (7). the ring body (17) and the anode (16) is surrounded. 2. Arc plasma torch according to claim 1, characterized in that the protective gas supply there is an annular gap in the cathode holder. 3. Arc plasma torch nac ^u . Claim 1, characterized in that the protective gas supply in the cathode holder is a coaxial ring of bores (15). 4. plasma arc torch according to claim 2 or 3, characterized in that the ignition anode (7) has a cylindrical jacket water cooler (8). 5. arc plasma torch according to one of claims 1 to 4, characterized in that the anode (16) has a cylindrical space (19) for cooling water. It is also known (French patent 1301 52) by a turbulent flow of the Drafts of gas on the surface of the cathode emÄerdmck, creating a djrek he Contact of the cathode with the hot gases is lost and consequently an increase in the service life the cathode can be achieved. It is also known (Zeitschrift ur angewandte Phvs k Volume 23, 1967, page 316) with a plasma torch to produce a fast argon atom beam The cathode and anode have an intermediate current electrode To be attached in an isolated manner, to center the gas flow and the arc