NL7600359A - DEVICE FOR MIXING GAS FLOWS. - Google Patents

Description

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753760 / Timmers - 1 - COMPAGNIE GENERALE D · SLECTRICITE S.A. in Paris "Device for mixing gas streams"

The invention relates to a mixing device for gas flows.

The device according to the invention is particularly applicable where the flow of a first gas 5 into which a second gas is to be introduced is present, such that a homogeneous mixture is quickly obtained.

A known device for this consists of a series of pipes which are arranged mutually parallel in the same plane perpendicular to the flow, with space between them for the passage of the first gas. The second gas is introduced into the tubes, each of which has openings downstream of the flow which form a plurality of injection holes through which the second gas escapes and mixes with the first gas.

This known device does not make it possible to always obtain good mixing as quickly as desired, in particular not in the case where the first gas is nitrogen energized by an electric discharge or where the second gas is carbon dioxide to be energized by molecular action with the nitrogen before the natural de-excitation of the nitrogen, so that the carbon dioxide gas, energized in this way, can form the active environment of a laser.

The object of the invention is to enable duck homogeneous mixing of two gases.

The device according to the invention with means for guiding a second gas in a flow of a first gas, which means comprising injection holes distributed over the cross section of this flow, it is to this end characterized that the means for guiding the second gas comprise: a plate placed so upstream detects the flow of the first gas and hits it with a large 7600359

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- 2 - numerous upstream transmission openings; a second plate located downstream of the first place, having on the one hand a number of downstream transmission openings corresponding to the upstream transmission openings and on the other a number of injection openings; a plurality of transmission tubes, each sealingly connected to the edge of one of the upstream transmission openings for guiding the first gas from the transmission opening to the corresponding downstream transmission openings: means for introducing the second gas under pressure into the gap between the roots upstream plate and downstream plate such that this gas escapes downstream through the injection ports.

The invention is illustrated by the drawings. Herein is: rig. 1 is a sectional view of a carbon dioxide welder into which carbon dioxide gas is introduced into a nitrogen flow by means of a compound according to the invention; plane A of this cross-section is perpendicular to the plates of this device; FIG. 2 is an enlarged sectional view through the same plane A of the device of FIG. 1; FIG. 3 is an enlarged end view of the device of FIGS. 1 and 2.

Laser generators are known in which an electrical discharge is generated in the first gas (nitrogen) which is set in motion at a very great speed and in which this first gas is mixed with a second gas (carbon dioxide gas) in an expansive chamber. an optical resonance cavity is formed. As a result of the electric discharge, the nitrogen receives an extraction energy which is transferred to the carbon dioxide gas by molecular interaction during the mixing. The rapid displacement of the mixture in the expansion chamber results in the mixture reaching the optical cavity for the de-excitation of the carbon dioxide gas, so that the latter can produce a stimulated light emission in the optical cavity, i.e. a laser emission.

The nitrogen molecules can have three different modes of excitation - 7500359 ~ 3: thermal, rotation and vibration excitation. When the nitrogen molecules and the carbon dioxide gas molecules mix in the expansion chamber, only the vibrational energy of the nitrogen can remain and invoke the population in the carbon dioxide gas leading to the occurrence of a high power laser pulse. For this it is necessary that the mixing of the two gases is very narrow and homogeneous before a significant part of the nitrogen molecules become de-excited.

The device according to the invention makes it possible to fulfill this condition.

Fig. 1 shows a gas flux laser generator with a cylinder shell 1 at the end of which an injection tube 2 emerges which forms an anode and is connected to a voltage generator G via the resistor R. The tube 2 has an axial line 3 connected to 13 a source of nitrogen under pressure SN, schematically indicated. The front surface has an injection opening b, which diverges inwards into the envelope 1. At the other end of the casing 1, an apparatus 200 is placed for mixing the carbon dioxide gas and helium with the nitrogen. The apparatus is fed from -20 from a carbon dioxide source and a source of SC, and is more specifically explained by reference to FIGS. 2 and 3 * Se device is electrically connected to the other pool of generator G. The assembly contains a number of passage openings such as 202 which allow the nitrogen to pass through.

The casing 1 opens via the transmission openings 202 into an expansion chamber 6 provided with two mirrors 7 and 8 which form an optical resonance cavity; the mirrors 8 are semi-transparent and allow the laser emission at the output in the direction of the arrow F.

The largest end of the expansion chamber is kept at a very low pressure by means of evacuation means formed by channels connecting the chamber to a vacuum space SV, schematically shown, and of such dimensions that the pressure remains practically zero during the operation of the laser generator. · ^ 5 Such a generator works as follows: Q 7600359

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The nitrogen, introduced under pressure into the axial channel 3 of the tube 2, is injected into the casing 1 at supersonic speed through the injection port 4. By an appropriate selection of the parameters, the generator, length and diameter 5 of the casing 1, the velocity and introduction rate of the nitrogen in the envelope, and the attitude of the total surface of the transmission openings 202 relative to the cross-section of the envelope 1 produces a main vortex flow of the nitrogen in the envelope 1. This flow is drawn with arrows indicated. This gives a homogeneous distribution of the electrical discharge which is switched when the anode 2 and the device 200 are powered by the generator G.

A portion of the nitrogen, driven by the main flow, flows through the openings 202 to form a secondary flow, indicated by dashed arrows, and drives the carbon dioxide gas and the helium injected through the device 200. The carbon dioxide gas is excited and produces a laser emission in the direction of the arrow F.

Figures 2 and 3 show the mixing device according to the invention 200 with an upstream brass plate 20 * f, with a thickness of 2 mm and provided with a large number of round transmission openings, also located upstream, indicated by the reference number 202, with a diameter of 5 mm, placed according to a square network with a pass of 6 mm.

In addition, a downstream plate 206 of brass, of a thickness of 3 mm, is parallel to the plate 204, leaving between these two plates a gap of 5 mm, while this plate is also pierced with a large number of openings 208 opposite openings 202.

The upstream plate 2Qb is on the side of the casing 1 and the other plate 206 is on the side of the expansion chamber 6.

The transmission openings are connected to each other by transmission tubes 210, also made of brass, with a round cross-section and welded with their ends sealed at the edges of the Q 76 0 0 3 5 9.

- 5 -% i transmission openings 202.3rd length var. the tubes are equal to the distance between the front surface of the upstream site 2CA and the rear surface of the downstream plate 206, and they do not protrude from the device 5 on either side. The external side surface in an o-rotation cylinder

The thickness of the walls is practically zero at the two ends. The thickness increases from the upstream face to a top about 1.5 ram from this location and then decreases again at the other end.

10 The inner diameter of the tube is 2.5 mm. In this way a tubing is obtained which makes it possible to inject nitrogen into chamber 6 at supersonic speed.

In addition, the downstream plate 206 has a number of injection operations which can be divided into two types: 1-5 The first type is formed by injection rings 212, formed by round tubes 2 ^ 0, through the peripheral part of the transmission openings. 208, the diameter of which is 5 ^ mm, the central portion of these openings occupied by the tubes 2 ^ 0 has a diameter of 5 ram.

The second type of openings is formed by cylindrical injection holes 21 * 1 with a diameter of 0.7 mm.

i Hike downstream transmission outlet is surrounded j

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j through four injection holes 21 ^, evenly spaced 90 degrees, relative to the axis of the orifice, and 4 * 5 from the directions j ^ 5 of the centers of the other transmission orifices nearest thereto. The holes 21H are such that the distance of the axis of each of these holes from the axis of the tube 210 is closest to 3 7 mm on the upstream surface of the plate and 3 ram on the downstream face. This results in 2D that the gas flow leaving this gas practically as soon as the annular jet exits the injection ring 212 hits it and is directed; to the nitrogen beam from the tube 21C.

The upstream pressure, so the pressure of the nitrogen in the envelope 1 can lay between 0.1 and several bars, for example 22 1 bar.

Q 160035¾

Claims (6)

1. Device for mixing gas flows, with means for guiding a second gas in a flow of a first gas, which means comprise injection holes distributed over the cross section of this flow, characterized in that the means for guiding the second gas comprise: a plate placed upstream so that the flow of the first gas strikes it and provided with a large number of upstream transmission openings, - a second plate placed downstream of the first place, with on the one hand a number of downstream transmission openings corresponding with the upstream transmission openings and a number of injection openings on the other hand; 30 a plurality of transmission tubes, each affixed to the edge of one of the upstream transmission openings for guiding the first gas from the transmission opening to the corresponding downstream transmission openings; 7600359% -> f - 7 - means for introducing the second pressurized gas into the gap between the upstream plastics and the downstream plate such that this gas escapes downstream through the injection ports. 2. Device as claimed in claim 1, characterized in that the injection openings are at least partly formed by the peripheral part of the downstream transmission openings, the central part of the transmission openings being occupied by the downstream end of the transmission tubes. . 3. Device as claimed in claim 1, characterized in that the injection openings are formed, at least in part, by injection holes separated from the downstream transmission openings. K5 k. Apparatus according to claim 3, characterized in that the injection holes are each arranged on the sides of one of the downstream transmission openings and distributed around this opening, their trajectory being oriented through the thickness of the downstream plate such that the radius of the second gas is directed to the radius of the first gas leaving the downstream transmission openings. Device according to claim 1, characterized in that the length of the transmission tubes lies entirely between the front surface of the upstream plate and the rear surface of the downstream plate. Apparatus according to claim characterized in that the transmission tubes internally have a tubular profile with a cross section which decreases at its upstream end to a minimum with a subsequently increasing cross-section to the downstream end, the minimum being closer to upstream than at the downstream end and the total cross section of the downstream transmission openings is greater than the total cross section of the upstream transmission openings. 7000359 r% n s f% ν - - Β - 7. Device according to claim 6, characterized in that the first gas is nitrogen, excited by | an electric discharge, and the second gas is a mixture of J-coco-dioxide gas and helium. i \ 76 0 03 5 9. O