KR200204919Y1 - Plasma torch - Google Patents

Abstract

This design provides a torch that improves the cutting cuff angle by uniformly improving the gas pressure distribution supplied to the arc tunnel by installing a dual gas distribution device in the gas stabilizer installed between the gas supply channel and the tubular gas supply port. Is to provide. This design supplies the gas supplied from the gas passage 71 to the annular gas supply port 72 of the domed arc tunnel 21 through the ceramic gas ballast 3, but is closed by the O-ring 30. The annular primary distribution space 31 and the secondary distribution space 34 are formed inside the secondary distribution space 31 through the primary spiral distribution passage 33. The secondary distribution space 34 is connected to the annular gas supply port 72 through the subdivision secondary spiral dispersion passage 35 to supply gas to the annular gas supply port 72 at a uniform pressure. It is a plasma torch. According to this design, the conventional allowable cuff angle of 5 ° was improved to 3 °.

Description

Plasma torch

This design provides a torch that improves the cutting cuff angle by uniformly improving the gas pressure distribution supplied to the arc tunnel by installing a dual gas distribution device in the gas stabilizer installed between the gas supply channel and the tubular gas supply port. Is to provide.

Plasma torch for cutting is a high-speed pilot arc containing a tens of thousands of ℃ plasma by supplying nitrogen gas (hydrogen + nitrogen), argon gas (argon + hydrogen), oxygen or dehumidified air into the arc salt. An apparatus for obtaining (340 m / sec) is classified into an air-cooled torch and a water-cooled torch according to a cooling method.

Water-cooled plasma torches, for example, supply dissociation gas into the arc current-carrying tip and electrode gaps, and circulate cooling water inside and outside the electrode to protect the tip and electrode from arc heat. Avoids the cooling system distributed inside the torch center electrode and the outside of the torch tip tip, and through the gas stabilizer and tubular gas supply on one side of the torch, the gas in the dome arc tunnel between the torch center tip and the electrode And the plasma arc is discharged through the tunnel nozzle, the gas supply pressure flowing into the dome arc tunnel through the tubular gas supply port is not uniform, resulting in malformation of the plasma distribution in the arc salt. In the torch, which has a structure in which an electrode substrate having an electron-radiating surface is centered and a working gas is sorted on the inner and outer surfaces of the tip based on an orifice which connects to a tip that constricts the plasma, a gas classification small hole is formed on the outer peripheral surface of the orifice. Although the plasma torch having the annular projection and the annular projection is provided in the circumference of the prior art, Japanese Unexamined Patent Application Publication No. Hei 1-50476, the torch has a non-uniform gas supply pressure flowing into the domed arc tunnel. Plasma distribution in the salt was irregular. Therefore, the conventional plasma torch had to use a gas distribution accessory inside the torch to overcome this.

This design improves the above-mentioned problems. The dual gas distribution device is installed in the gas stabilizer installed between the gas supply channel and the tubular gas supply port to uniformly improve the gas pressure distribution supplied to the arc tunnel. It is to provide a torch to improve the cutting cuff angle.

1 is a cross-sectional view of the entire assembly of the present invention.

2 is an enlarged perspective view of a bisecting section of the gas ballast.

3A, 3B, and 3C are enlarged cross-sectional views taken along lines A-A, B-B, and C-C of FIG. 2, respectively.

* Explanation of symbols for main parts of the drawings

71 gas passage 3: gas ballast

21: arc tunnel 72: annular gas supply port

30: O-ring 31: primary allocation space

33: primary spiral dispersion path 34: secondary distribution space

35: secondary spiral dispersion passage

Figure 1 shows the configuration of a water-cooled plasma torch including this design.

Specifically, the torch forms an arc tunnel 21 between the tip 1 and the electrode 2, and the cooling water W supplied from the main water pipe 41 is a tubular cooling tube 40 and an electrode 2. And the passages 42 and 43 formed by the electrode body 4 to cool the inside of the electrode 2 in which the heat collecting metal 22 is installed, and the composition is formed on the electric heating body 5 and the tip body 6. After passing through the passage (51, 52) to cool the tip (1) is recovered to the cooling water pump through the drain pipe (53); Gas is supplied to the dome arc tunnel 21 through the gas pipe 7, the gas passage 71, the gas stabilizer 3, and the annular gas supply port 72 to blow off the plasma arc to the nozzle 11. To; In order to supply the arc current to the tip 1 and the electrode 2, the tip body 6 and the electrode body 4 supported on both ends of the insulator 5 are used as electrical conductors, and the main water pipe 41 and the gas pipe (7) and the insulated Teflon tube 55 are covered with the drain pipe 53, and the insulated Teflon coating is applied to the outer periphery of the electrode body stand 4; In order to strictly block the cooling flow path and the gas flow path and prevent cooling water leakage, a heat resistant O-ring 54 is installed in the composition of the flow paths.

This design uses the gas supplied from the gas passage 71 to the annular gas of the domed arc tunnel 21 through the ceramic gas stabilizer 3 as shown in FIGS. 1, 2, and 3. Supply to the supply port 72, the annular primary distribution space 31 and the secondary distribution space 34 is formed in the ballast (3) closed by the O-ring 30, the primary distribution space 31 By connecting to the secondary distribution space 34 through the primary spiral distribution passage 33, and connecting the secondary distribution space 34 to the annular gas supply port 72 through the subdivision secondary spiral distribution passage 35 The gas is supplied at a uniform pressure to the annular supply port. In the embodiment, the primary spiral dispersion passage 35 is four passages obtained by dividing the gas flow volume of the passage 71 at equal intervals, and the secondary secondary spiral dispersion passage 35 has the gas flow volume of the passage 71 at equal intervals. It was configured as eight divided passages and the spiral angle was 15 °.

Thus, this design is a gas distribution from the one-side passage 71 inside the torch, but the dual gas distribution device, that is, the gas is distributed in the annular primary distribution space 31, the primary spiral in the ballast 3 closed by the O-ring 30 While passing through the passage 33, the secondary distribution space 34 and the secondary spiral dispersion passage 35, the circulating gas is supplied at a pressure uniformly distributed to the annular gas supply port 72, The plasma distribution is adjusted to have a linearity, thereby improving cutting quality (improving cutting angle) and cutting efficiency of the metal material M. FIG.

Kerf effect by this design was improved as shown in Table 1.

As described above, this design eliminates arc deflection between the electrode and the tip and improves plasma linearity in the arc salt by uniformly dispersing and flowing the gas pressure in the gas ballast without using a gas distribution accessory. It is to improve the cutting efficiency and the kerf improvement effect of the cutting material.

Claims (1)

An arc tunnel 21 is formed between the tip 1 and the electrode 2, and cooling water is formed in the passages 42 and 43 formed of the tubular cooling tube 40, the electrode 2, and the electrode body 4. Passes through to cool the electrode 2, coolant passes through the passages 51 and 52 formed in the electric heat transfer body 5 and the tip body 6 to cool the tip 1, and the gas pipe 7, Gas is supplied to the domed arc tunnel 21 through the gas passage 71, the gas stabilizer 3, and the annular gas supply port 72 to eject the plasma arc to the nozzle 11, and the tip 1 ) And the gas supplied from the gas passage 71, the annular gas supply port of the domed arc tunnel 21 via the ceramic gas stabilizer 3. 72 to form an annular primary distribution space 31 and secondary distribution space 34 in a ballast 3 closed with an O-ring 30 and dispersing the primary distribution space 31 with primary spirals. Secondary distribution through passage 33 It connects to the space part 34, and connects the secondary distribution space part 34 to the cyclic gas supply port 72 through the subdivision secondary helical dispersion channel 35, and pressurizes gas to the cyclic gas supply port 72 uniformly. Plasma torch, characterized in that the supply.