SU332644A1 - GAS-OXYGEN CUTTER - Google Patents

Description

Cutters are known; the mouthpiece is mounted in a housing with two cylindrical channels for cutting oxygen, converting into conical mouthpieces extending to the end, one of which is angled to the axis of the burner, and gas supply tubes, while the channels for cutting oxygen are surrounded channels for the warming flame at an angle to the axis of the cutter. However, these cutters are not productive enough.

The purpose of the invention is to increase productivity. To do this, above the cutting oxygen channels, symmetrically with respect to them, is placed a supplemental stepped channel also for cutting oxygen, which has an elongated cross section at the end of the mouthpiece, the short side of which is parallel to the treated surface.

one additional stream of oxygen located symmetrically above them.

The axis of the mouthpiece of the gas cutter is inclined at an angle of attack to the surface of the material /. The cutting torch contains mouthpieces 2 and gas supply tubes (not shown in Fig.). In the mouthpiece there are two expanding cutting oxygen channels 3 with a neck 4 and an additional stepped oxygen channel with a neck 5.

The cylindrical neck 4, with its inlet cross section Fi, passes into the cutting oxygen channel 3 itself, which is conically widened up to the outlet cross section FZ, in order to provide oxygen output without turbulence. The neck 5, with its smallest inlet section FZ, passes into an additional oxygen channel 6, having an elongated cross section F ,,.

The ratio of the input cross section Fi and the output section FZ is 0.1-1 and the ratio of the input cross section FS and the output section L 0.05-0.2. Blagodanale 3 can reach about 500 m1s and in additional channel 6 about 250 Ml s. The axis of the expanding oxygen channels 3 is located below and the axis of the additional stepped channel is higher than the axis of the common oxygen supply channel 7. The axes of channel 3 and additional channel 6 have an opening angle b in the cutting direction equal to about O-30 °. The mouthpiece 2 is provided with a certain number of channels 8 for the heating flame connected to the recess 9. The axes of the channels 8 and thereby the heating flame are inclined at an angle of 7 equal to Approximately 25 ° C to the axis of the oxygen supply channel 7.

In the example shown in FIG. 2 and 3, the output cross section Fi of the supplemental oxygen channel 6 is shown rectangular.

The ratio of the short side b to the long side h is 0.5-0.03. The short side of the rectangle is located parallel to the surface of material 1 and across to the direction of the cut. In this example, the additional oxygen channel 6 is located symmetrically above the two adjacent cutting oxygen channels 3.

The output part of the stepped channel can be made triangular or trapezoidal, with the short side of a trisolnik or trapezium placed parallel to the surface to be treated.

The principle of action of the cutter is as follows.

The additional oxygen stream passes due to the appropriate location of the additional channel 6 to the expanding oxygen channels 3 in front of the cutting oxygen stream and causes an intense preheating of the cutting zone. The formation of slag and liquid metal, whose heat content is high, causes a significant increase in the temperature of the product, moreover, due to the inclination of the stream of oxygen, almost all of the slag remains on the surface of the material.

The subsequent cutting oxygen jet separates the remaining layer of material in a very strongly preheated cutting zone. Since the oxygen cutting stream is likewise inclined, on the underside of the product, in the direction of the incision,

the second slag stream, which also heats the material below. Due to the increase in the contact surface between the additional stream of oxygen and the product, and in particular between the cutting stream of oxygen and the product, the utilization rate of oxygen increases. At the same time, the cutting speed is significantly increased.

The proposed cutter can be used when cutting metallic materials with an edge thickness of 3-50 mm.

Subject invention

Claims (4)

1. An oxygen-gas cutter containing a mouthpiece mounted in a housing with two cylindrical channels for cutting oxygen, passing into conical mouthpieces extending to the end, one of which is angled to the axis of the burner, and gas supply tubes, cutting oxygen are surrounded by preheating flame channels at an angle to the axis of the cutter, characterized in that, in order to increase productivity, above the channels for cutting oxygen, symmetrically with respect to them, an additional stepped channel is also placed for cutting oxygen, having at the end The mouthpiece has an elongated cross section, the short side of which is parallel to the surface to be treated, the ratio of the smallest cross section of the wider channels and their output cross section being 0.1-1, the ratio of the smallest cross section of the stepped channel to the largest cross section is 0.05- 0,2, and the angle between} is expanded with a step channel rg veins 0-30 °. 2. A cutter according to claim 1, characterized in that the output part of the additional oxygen channel is made triangular. 3. A cutter according to claim 1, characterized in that the output part of the additional oxygen channel is trapezoidal. 4. A cutter according to claim 1, characterized in that the output part of the additional oxygen channel is rectangular with a short side to long side in the range of 0.5-0.03. . , -IU, .and V "T  -. h 1 Rig 2