DE1240747C2 - JET THROTTLE FOR HOT GASES WITH JET DEFLECTION DUE TO THE INTRODUCTION OF AN AUXILIARY FLUID - Google Patents

Description

th distance from the wall have a common line. The expansion zone of the Auxiliary fluid can thereby be localized in a precise manner. Because the reaction is more reactive Auxiliary fluid is dependent on the temperature and / or on the chemical constituents and these reactions also in the supply line (ζ. B. when this heats up due to heat conduction, while the deflector is not in use) can drain and damage the line it is advantageous to use one end of the supply line as a tube bundle with a small cross-section dtr to train individual tubes. The advantage is that individual damage is thinner Pipes, as opposed to damaging a single strong pipe, do not cause the entire failure Plant leads.

Embodiments of the invention are explained in more detail below with reference to the drawings.

F i g. 1 and 1 a show schematically in a radial and cross section a nozzle with a Deflector using two reactive liquids is equipped;

F i g. Figure 2 is a perspective, partially sectioned view of an assembled nozzle again, which is provided with a deflector operating with two liquids. of the

Fi g. Figure 3 illustrates a detail in detail;

Fig. 4 is a radial section on a larger scale through one of the injection nozzles according to FIG. 2;

Fig. 5 shows in a schematic manner in section a part of a nozzle wall which is provided with two lines for feeding in ergols, and also the various associated fluid zones;

F i g. 6 shows in the same way a wall part that, in a modification with two mutually adjacent Lines are provided for feeding the ergole;

F i g. 7 shows schematically in a perspective view a rocket nozzle with a perforated Insert is equipped for feeding an Ergol ς;

Fig. 8 shows in the same way a nozzle with a perforated feed insert M provided to two ergoles at a plurality of each other • Recreate points on a wall;

Fig. 9 is a schematic Schmu of a wall part, which is made of porous material.

An arrangement shown in FIGS. 1 and la is where several fluids react among themselves to form the localized one blocking the nozzle Creating expansion allows the location in the nozzle to be determined with great precision Expansion results, and to extend the residence time of an ergol in the nozzle.

! A first row of fuel injectors 7 ft that run through a line 8 ft are fed, opens z. B. a little downstream of the neck 5 and with one orientation downstream into the nozzle. A second row of injection nozzles 7 r, slightly downstream of the Injector nozzles are located 7 ft, is fed by a line 8c and opens into the nozzle with a Orientation upstream, but this should only be an example. These injectors are via spaces 15, 16, which at the junctions between the lining blocks 2, 3 and a third block 14 are arranged, fed.

The first ergol is thus distributed in the boundary layer of the main flow, which has the purpose of to thicken and slow them down as this ergol heats up.

The second Ergol, the exceptionally gaseous one

State is injected with a relatively large movement size, which is the purpose at the location of the blocking shock wave 12 between the two rows of injectors help me. The main gaseous jet dissolves

ίο from the wall by forming a vortex zone 13, away.

The shock wave 12 and the vortex zone 13 are also located on the figures described above. The fluid dynamic The operation of the deflection device is the same in all cases. It will the control is facilitated in all cases in the same way by the use of liquid. The construction of nozzles does not encounter particular difficulties, the injection chambers 15 and 16 and the injection nozzles 7 can be easily formed at the joints.

With the help of FIG. 5, which is on a larger scale, the operation of a device like that of Fig. 1 can be shown in detail. Two rows of lines 37 can be seen there, which are arranged next to one another perpendicular to the plane of the drawing (or two individual mouth pipes which extend essentially in the same direction) and which are arranged in the wall 31 of a nozzle. A first ergol is introduced through the upstream line (s) 37a, which can be said auxiliary lines, into the boundary layer 32, where it heats up and partially evaporates. The second ergol is injected with a relatively stronger propulsion and preferably in countercurrent through the downstream line (s) 37 ft. This second injection causes a separation of the boundary layer a little upstream, creating a shock wave 38 which deflects the main gas flow V , this separation defining an upstream dead zone 33 in which flows at a velocity much weaker than that of the main flow, and even back currents arise. That in the

Ergol sprayed upstream from this boundary layer mixes with the second ergol in this zone where the mixture ignites. It then continues to burn in the vortex 34, which accelerates progressively towards the exit of the nozzle, causing the main flow to reappear is prevented. The orifice pipe 37fl upstream must be downstream of the located muzzle tube 37 ft far enough away to allow adequate heating of the first Ergols and a noticeable thickening of the boundary layer 32, which is an important mixing zone 33 manages to get.

The F i g. 6 shows a modification which works in a similar manner to the device according to FIG. 5, and arranged side by side according to the mouth pipes serving to supply the ergole

Line first line 37c, which has a certain transverse direction possesses and can preferably be directed in the opposite direction to the flow, conducts a first ergol into the boundary layer, where its relatively large amount of motion creates a shock wave and by the formation of a vortex 34. before the

a downstream dead zone 35 is attenuated. A second line 37 d, which can be referred to as an auxiliary line, opens downstream from the first, at a small distance from this and in such a way that the low local velocities and the backflows that are present in the downstream dead zone35, the allow the second ergol to remain in this zone for a period of time that is at least equal to the time delay necessary to initiate the reaction. In other words, the purely aerodynamic boundary layer 32, which is disturbed by the flow of the first ergol, is established by a dead zone 35, which from a point 36 onwards into a turbulence 34, which is under excess pressure and through the gases of the Reaction is fed, transformed. The flow is separated from this turbulence by an interface.

The F i g. 2 to 4 relate to an embodiment, according to which the nozzle, which from the composite Type is a HaIsSa made of graphite and convergent walls 4 α and divergent walls 6 α comprises, which from consist of a material based on layered plastic. A metallic bezel ring 17 supports the various parts of the nozzle and forms at 18 a connection collar to the rocket body there. A double injection is shown as an example.

A first series of injection nozzles Id may consist d of tubes 8, which immediately in the cl by means of a putty (F i g. 2); forming n-necked graphite block 5 are cemented α.

A second series of injectors 7 e, which is the divergent Teil6α in a lined with plastic material zone, for example, is composed of for example four Einsetzstücken 19 made of graphite, which are fixedly connected by means of a putty 20 with the plastics material and whose cross-section is preferably trapezoidal. The feed lines 8 e are divided into tubes 8 f, each of which is cemented in the piece 19 or is held at its outer end by an extension. This piece 19 can protect against erosion, which would be due in particular to the reaction, by an electrolytic deposit of a metal with a high melting point, such as. B. tungsten, are protected. The liquid is directed around the rounded edge 21 and remains adhering to the wall.

The F i g. 7 and 8 finally show other modifications in the design of the device, which make it possible to see a zone in the boundary layer where the velocities are dampened enough are to physical or chemical expansion

ίο allow the injected liquids.

According to these modifications, the conduits in 37 are formed by a plurality of small mouth pipes 39 replaced. These are arranged according to a network that forms several rows in the direction of flow, and they produce many small rays, which at first act simply by mixing them around the To delay the boundary layer and to favor its progressive thickening. Then they work through Expansion of the liquid with the creation of the

ao shock wave. This expansion takes place through evaporation or decomposition of an ergol, through reaction of two ergols and / or even by reaction of an ergol with the gases of the main flow instead of.

»5 The various mouth pipes 39 can be in a part 40 of the wall 31, which has a distribution chamber 41 (see Fig. 7) is provided. When two liquids at the same time to be fed to each point of the injection network (see FIG. 8), pipes 42 can be concentric to the mouth tubes 39 open in the same way by the chamber 41, which the mouth tubes feeds, traverse. The lines 39 and 42 can be directed against the current.

Finally (Fig. 9) the openings can be microscopic and be very numerous if the wall part 40 a made of a porous material, for. B. a sintered metal, the chamber 41 α in this case for example between the lining 43 of the wall 44 of the nozzle and this actual wall is formed. Set the seals 45 in such a case the seal is secure, but the chamber can also be a cleaner one Part of the wall part as shown in FIG. 1 off

For this purpose 3 sheets of drawings

Claims (10)

Nozzle wall for generating a local expansion of the boundary layer, the auxiliary flow medium entering into a chemical reaction. 1. Jet thrust nozzle for hot gases with jet In known jet thrusters of this type goes deflection by introducing an auxiliary flow 5 that is supplied on the inside of the nozzle wall by means of an exothermic chemical regeneration on the inside of the nozzle wall to the auxiliary fluid a local extension of the boundary action with the gas of the jet, so that a layer, with the auxiliary fluid providing an additional lateral force component for deflection chemical reaction enters, thereby ge the nozzle jet and the local expansion of the indicates that a second auxiliary current boundary layer is generated. is introduced and the chemical The invention is based on the object of the reaction between the two auxiliary flow striving to increase nozzle jet deflection. Investigate he follows. according to this is achieved in that a 2. Jet thrust nozzle according to claim 1, characterized in that the second auxiliary fluid is introduced and the characterized in that in a known manner 15 chemical reaction between the two auxiliary currents Auxiliary fluids are fluids and fluids are done. the reaction product is a gas Independence from reactivity 3. Jet thrust nozzle according to claim 1 and 2, the auxiliary fluid with the gas of the nozzle thereby characterized in that along a transverse beam achieved by the invention has the section of the inner wall of the nozzle feed opening 20 advantage that a free choice of auxiliary flow openings for the auxiliary fluids regularly distributed medium according to the point of view of the greatest reaction are. effect can take place. Furthermore, auxiliary currents 4. Jet thrust nozzle according to claim 1 to 3, mung ^ medium use, which are characterized in that for at least one of the times in which no injection takes place, the two auxiliary fluids do not decompose the feed openings 25 in the lines in front of the nozzles,
The deflection of the jet depends on the strong gases are directed. Measures of the response time to the triggering of the chemical 5. Jet thrust nozzle according to claim 1 to 4. da- mical reaction of the auxiliary fluid. For characterized in that at least one of the particular reactive auxiliary fluids or ergols Feed openings consist of a slot that has 30 (under Ergolen, e.g. Monergolen, Propergolen, nvei sections of an inner lining of the hangover goli, hypergoles, lithergoles, become liquid Separating nozzle wall. or solid chemical agents whose decomposition 6. Jet thrust nozzle according to claim 1 to 5, setting the energy required to drive it through characterized in that the edges that produce the) response time is longer than the stay feeder openings with the inner wall of the nozzle formed 35 times in the nozzle jet. So there must be action which are rounded, are preferably provided upstream, which allow the ergole to stay in towards. extend accordingly to the nozzle jet. In wide- 7. Jet thrust nozzle according to Claim 1 to 6, this is what makes this embodiment of the invention characterized in that the feed openings are released, that the ergole against the direction of flow are injected into a plate 40 of the hot gases inserted into the nozzle wall. As an advantage (40) are arranged and shared by a decrease in the speed of the Chamber to be fed in this plate. hot gases along the wall. A longer term 8. Jet thrust nozzle according to claim 1 to 7, because of the injected ergole and the desirably characterized in that porous material is valued as the course of the chemical reaction Feed openings is used. 45 ensured. At great speed in the opposite 9. Jet thrust nozzle according to claims 1 to 8, but ergols fed into the stream result on the one hand characterized in that the second auxiliary also has a discharge means upstream of the injection point through tubes (42) into the nozzle loosening the boundary layer from the inside of the nozzle which is concentric to the feed wall and on the other hand a vortex opening downstream of the first auxiliary fluid 50 flow. This arranges two "perpendicular" zones are. create, in which then advantageously part of the 10. Jet thrust nozzle according to claim 1 to 9, Ergole can be fed. characterized in that at least one supply The creation of a zone in which the speed Guiding line for the auxiliary fluid of a kind along the wall are small enough so that Bundle (8a) of tubes with small cross-section 55 the expansion of the auxiliary fluid takes place, exists, which at a certain distance from is still possible according to the invention in that in the nozzle wall to a common line flow direction the auxiliary fluid staf- (8) are affiliated. feit is fed, reducing the thickness of the boundary shift progressively increases and the speed! 60 decreases progressively. These auxiliary fluids can by means of wall elements of the nozzle, which with min- deslens a network of possibly microscopic openings are provided, which odei by sintering Perforating received and connected with suitable lines 65 are initiated. The invention relates to a jet thrust nozzle for In a further embodiment of the invention hot gases with jet deflection by introducing auxiliary reactive currents through a bundle an auxiliary fluid on the inside of the pipes of small cross-section: cuts which are in a certain