DE913485C - Process for the operation of combustion chambers for jet engines or the like. - Google Patents

Description

Method for operating combustion chambers for jet engines od. Dql. In combustion chambers for oil firing, gas turbines, jet engines or the like. With forced Air ducting there is a risk that the flame will be blown out at higher speeds and the operational safety is thereby significantly reduced. The disorder stems from the fact that the ignition rate of the gaseous or vaporous or liquid atomized fuels are often less than the flow rate of the forced air so that the flame breaks down.

The jet engines of aircraft are particularly difficult Od. Like. Where the flame is to be limited to the shortest length and high air velocities are inevitable. Blowing out the flames can result in the loss of the entire aircraft to lead.

With certain missiles you have this danger by using liquid Oxygen banned, which is five times more concentrated by weight than air and also occupies only a negligible volume in the liquid state, so that the Combustion takes place in and of itself in a very confined space.

The invention for air operation is based on a paradox that the Inventor. Has observed showers for showering purposes. If you hold such a fine-holed If you shower over water, a surface hit by the rays is repelled, but if you hold the shower under water, one will be at a sufficiently close distance held not too large area, z. B. the surface of a phalanx opposite sucked in by the impulses of the rays.

The expectation that this phenomenon will be similar in the corresponding Air or gas jets enter and even extend to sucked gas masses, has @saved true; it there is a certain relationship with the known toy in which a suitably shaped plate or ball passes through Counter-blowing a single strong. Air jet into a corresponding cavity is sucked into it.

If you bring (Fig. I) according to the invention z. B. a longer gas flame is sufficient close to an umbrella-like plate interspersed with sufficiently small blowholes 2, the flame is shortened and nestles in the spaces 3 near the plate; there it withstands the greatest increases in the speed of both the individual Air jets as well as the external flow around the screen 2 without tearing off.

From this follows the basic possibility, the tinny one that is customary today Combustion chambers, which are used for the strict separation between faster external flow and slower serve to avoid the internal flow of flames and thereby accelerate the danger Overheating and the need for frequent replacements, as well as the overall length, To save weight and precious alloy materials and to increase operational safety significantly to increase. If necessary, an additional fan level can also be saved.

It should be noted that the phenomenon described in the case of a liquid oxygen carrier in this way does not occur. The present proceedings are therefore not related on combustion chambers with liquid oxygen or oxygen carriers, such as. B. with certain Missiles. However, the fuel can be in gaseous or vaporous or liquid or dust form be firm.

The theory of this suction process shows that the effective pressure difference dp, in addition to the dynamic pressure q of the jet velocity, is also proportional to the ratio a of the jet cross-section F to the corresponding expanded cross-section of the jet propagation field F (Fig. 2, hatched). It is generally a = FSIF and Figure 3 shows the course of f (a) over a . The optimal intake pressure dp would result from this for a = 0.5 or F, = 0.5 F and would then be equal to 0.5 q; but one still observes favorable suction even with much smaller cross-sectional ratios a, if only the dynamic pressure q of the jets is sufficiently high.

The small individual openings i in the faceplate 2 can according to Fig i as cylindrical or rectangular holes, as diffusers 5 to reduce the Speed and implementation of the same in pressure (venturi nozzles) or as ring-shaped fine slots or arched like fine turbine guide vanes or turbine diffusers are executed.

The openings can be parallel or inclined to one another or below common slope z. B. to generate a twist or an otherwise divergent one Current lie.

The screen 2 itself can be flat (picture i) or curved, e.g. B. as a cylinder jacket or spherical section (Fig. q.), or ring-shaped or as a cone or in some other way be in order to achieve a more favorable discharge of the external flow. To make things easier the entry of the latter into the distribution holes i can with a lateral flow Cross ribs or the well-known staggered baffles 6, accordingly z. B. Fig. 4., arranged «- earth.

The suction of the flame can be supported by straight, annular, spiral or intersecting furrows (trench-like depressions, fig 5) between the rows of holes. These furrows bring the further advantage, the thermal stress to reduce considerably in the perforated plate.

A favorable production results according to Fig. 6, if the furrows and the whole perforated plates made of corrugated iron g with punched holes will. The supply of the gaseous or liquid fuel can be through a or several separate lines in or above the shield plate (7 in Fig q. or 14 iin, Fig. 6).

In any case, care must be taken to ensure that at least one Part of the immediate exit i i of the fuel (Fig. 7), d. H. also the Attachment part of the flame, not immediately hit by one of the small partial air jets is, but in one of the free lanes 3 or the furrows 8 between the air jets or otherwise, e.g. B. by a small flat or cylindrical screen 15 (Fig 7) protected from the latter, lies.

The slowing down of the external inflow speed to sufficient low speed of the individual air jets can be in the already mentioned diffuser openings 5 (picture i); but it can also be in or in front of or behind the cylindrical Jet openings i any throttling obstacles (sieves, rectifiers, winding Sheets, panels, sharp edges, threads, roughness or the like.) Arranged or combined with diffuser openings.

According to the invention, the external flow around the face plates be disciplined by the arrangement of suitable baffles or vanes; z. B. helically wound guide elements 12 (Fig. Q.) Serve to take place of the irregular (statistical) eddy formations behind the plate - a regular one To generate screw vortices of the desired pitch and number of threads that the Flame (burning zone) envelops behind the screen and further downstream in controllable Remove a sufficiently strong mixing movement between the combustion gases and the cooling outside air. Instead, any other way of guiding the outside air by blades, gutters or other fixed guide elements or by rotating propellers to discipline the external vortex movement in the desired sense (small or low mixing of the cooling air with the flame zone, strong mixing behind the flame) be applied.

The required mixing movement can also be achieved through the choice of twist the flame flow can be influenced by z. B. the one flame a Left-hand twist, the neighboring one right-hand twist, or all flames have the same direction Twist is granted. The one between the screens, farther away from the flames Fresh air can additionally through separate, z. B. shovel-like guide elements in be steered in the desired direction. These governing bodies are also here in cooling, outside the range of combustion gases from 160 to 200 ° C. The In the present process, shield plates are already largely due to the and air passing through it is cooled, especially with the type shown in Figure 6 wavy furrows. If necessary, however, liquid cooling can also be used take place, for which liquid fuel is particularly suitable, the z. B. in ring grooves can be guided along and partially evaporated.

The entire burn zone z. B. a .jet engine can be known in Way to be resolved into individual separate flames and screens, but also as connected ring can be operated.

In addition to the stated advantages of the present process, from Meaning that here the flames, even if locally a small zone through one Partial beam is blown out, but again and again in their neighborhood ignite the screen.

In summary, the effect of the process is based on the novel full control of the turbulence, namely the small turbulence inside the combustion zones (through the fine partial jets) as well as the great turbulence outside, which is caused by Art the tip vortex causes the mixing process downstream.

Claims (9)

PATENT CLAIMS: i. Procedure for the operation of combustion chambers for jet engines, Gas turbines or the like with air as the oxygen carrier, characterized in that the flames, without the use of fully jacketed combustion chambers, separate or ring-shaped behind plate-like screens that are so fine and numerous Individual air jets are penetrated so that there is a sufficient vacuum in the spaces between them arises in order to draw the flame up to the faceplate and so the Shorten the flames as much as possible. 2. The method according to claim i, characterized in that that the individual air jets in the area of the faceplate through diffuser-like holes or slots are delayed and thereby create such negative pressure on the plate, that the flame is sucked into the diffusers. 3. The method according to claim i, characterized in that the flames by arranging grooves (8) to in the depth of the faceplates are sucked in. q .. Method according to claim i to 3, characterized in that the approach areas (io and i i) of the flames through special small partial screens (i5) protected from the blowing effect of the individual air jets are (picture 7). 5. The method according to claim i to q., Characterized in that the individual air jets before entering the flames through throttle obstacles in front of, in or behind the faceplates. 6. The method according to claim i to 5, characterized in that air flowing in at an angle through staggered guide surfaces (6) or the like is directed as normally as possible onto the faceplate. 7. Procedure according to Claims i to 6, characterized in that the outflow of the external cooling air disciplined by leading organs, in particular through the formation of prescribed vortex shapes is brought to a controlled mixing movement behind the flame. B. procedure according to claims i to 7, characterized in that with the aid of suitable fixed guide elements (i2) systems of screw vortices are generated on the screens (2), which the Surrounded by flames. 9. The method according to claim i to 7, characterized in that these vortices are generated by rotating propellers. ok Procedure according to Claims i to 9 for influencing the mixture of the flame exhaust gases with the cooling air by the swirl of the flame gases, characterized in that adjacent individual flames each received opposite twist.