DE958165C - Combustion chamber for continuous combustion - Google Patents

Description

Combustion chamber for continuous combustion When performing a continuous combustion in combustion chambers, it is a main task of the designer, initiate and maintain the incineration by means of special measures, that as complete a combustion as possible is achieved in the smallest possible space. This becomes all the more important, the more the space required and the weight of the combustion chamber as a constructive point of view also fall into the balance, which is particularly strong This is the case with the use of combustion chambers on vehicles and in still to a greater extent on airplanes. The volume of the combustion chamber, on the other hand, is largely determined by the flow velocity of the burning or burnt gas in the chamber, d. that is, from this point of view it is important to keep the gas in the chamber to give as high a speed as possible. On the other hand, the ignition rate is d. H. the propagation speed of the flame within the mixture physical data given and can also be used with the finest atomization and for do not increase the combustion beyond a certain level in the most favorable conditions, so that there is a risk that if the flow velocity is greater than just this ignition rate is the flame is not fast enough on the inflowing Medium passes over and with the outflowing Gas migrates out of the chamber. For this reason, different paths are taken, some of which are aimed at by a glowing body that is fixed in place and held in embers, where the ignition should start continuously in a continuous flow to maintain the combustion, but partly strives, by local delay and turbulence of the flow velocity to maintain the flame.

For the purpose of swirling the combustion air and making it even Mixing the fuel with the air was already the arrangement of a circulating Proposed burner head in the combustion chamber, the structure of the oil firing known, consisting of one or more concentric cylindrical rings, Similar to rotating atomizer beakers through which the combustion air flows axially and which the combustion air drives by means of a turbine.

The object of the invention is to provide a combustion chamber with a circumferential Propose burner head in a new design, which meets the requirements the operation of gas turbines and recoil propulsion devices for vehicles or aircraft is even better adapted.

According to the invention, the rotating burner head should be designed in such a way that that the turbine blades carry the orbits. If necessary, before the rotor blades fixed guide vanes be arranged, which for example carry the bearing parts for the circumferential rings.

This is relatively due to the new arrangement of the turbine blades short burner design has the advantage that it is already inside the burner head a good swirl of fuel and air takes place, so that also at this Place the incineration can already start. Next allows the relative lightweight design according to the invention, through which the required drive power is kept small, a particularly low-loss drive. For example there is this makes it possible to use only part of the total air required, the primary air, to use to drive the burner while another part without pressure loss outside around the burner, possibly separated from the combustion chamber by a wall, flow and fed to the combustion gas later as secondary air or only as mixed air can be, with this outer air at the same time a cooling of the combustion chamber outer walls can make in a known manner. A possible pressure drop in the secondary air towards the interior of the circumferential rings is beneficial in that it leads to acceleration and swirling this out of the already swirled and ignited mixture Fuel and primary air to be supplied air amount can be used.

This can be ensured by suitable positioning of the turbine blades be that the air flows completely axially behind the same or what for the turbulence it is better that, according to the invention, it is also behind the circumferential ring has a more or less large circumferential component, which by their twist and the Centrifugal force swirls the air and promotes the mixture with secondary air. Naturally Care must be taken that at the rotor blades, at their exit under certain circumstances by tearing off the eddies, the burn that took place in these eddies underneath Circumstances already set in, does not cause destruction. Also should the blades as well as storage etc. at a sufficient distance from the possibly glowing rearmost part of the circumferential ring held or by interposing heat throttling Cross-section constrictions or insulating layers must be protected from heating.

The storage of the burner head can, for. B. be accomplished by that a shaft lying in the axis of the rotating ring is attached to the rotating part is the z. B. runs in a fixed cylindrical sleeve in ball bearings. Likewise, of course, the cylindrical part can also revolve and the stationary part as Axle bolts protrude into the circumferential ring. To protect the bearings from excessive temperatures to protect if .z. B. the combustion takes place under pressure and the heat of compression of the combustion air an unacceptably high level of heating of the combustion air around the camp can be feared, for example, one of a coolant, z. B. surrounded by fuel, flow-through protective cap the entire storage. To the other hand to prevent the bearings from heating up due to radiation from the combustion chamber, Radiation protection can be attached in such a way that it is stationary or rotating protects storage from exposure to heat.

This can also improve the arrangement of the circumferential rings be achieved that several, for example two circumferential rings are arranged concentrically and rotate around each other in opposite directions if possible. The drive Both rings are again carried out according to the invention by the combustion air. Here the options listed for the first rotating ring also apply to the second.

The nozzles for injecting the fuel can be of various types Be arranged in a manner. A central one lying in the axial direction of the burner head Injection in the direction of flow of the air has the advantage that by a suitable Choosing the cone will keep the spokes free of fuel and thereby prevent burning can be protected. However, the same is also possible if in the outer wall nozzles are attached to the combustion chamber, which spray the air flow against it, whereby they are expediently arranged so that they are tangential to the direction of rotation of the circumferential ring splash back. Here, too, the nozzles can be arranged so that those Parts to be protected from burning are covered and the atomized Fuel partly in the space inside, partly in the annulus outside of the circumferential ring (s) is injected. Are the injectors central or tangential, but attached against the direction of flow of the air, this has the advantage a very early initiation of the combustion, i.e. a good utilization of the combustion chamber space, as well as a high relative speed between the air and the fuel particles, a good mix. When using two mutually revolving Circumferential rings can also or only be used with nozzles from the front or from the rear axially or tangentially into the space between the circumferential rings inject. In addition, the fuel can also be supplied inside the rotor blades and in the case of two orbital rings, for example, from the rotor blades of the outer one in injected into the space between the two circumferential rings. Here comes the Pumping effect of the circulating. Rings benefit from an increase in fuel pressure, so that under certain circumstances a supply of fuel under pressure is possible at all unnecessary. The fuel nozzles can also be advantageously arranged so that the Rotation of the burner head due to the recoil effect of the sprayed fuel is generated or amplified.

According to the invention, to increase the turbulence when the Burner head consists of two circumferential rings, the same independently of one another, e.g. B. against each other, circulate. This can further improve the turbulence be that in the circumferential ring holes are made, which are drilled radially as inclined or straight slots or channel-shaped and in any way with axially or radially standing ridges or ribs or other protrusions, which are attached to the circumferential ring to increase the turbulence, be combined can. It is important that especially in the cases where the speed is so high that an additional turbulence in the air and the resulting turbulence Delay in flow to initiate ignition are essential for a The flow is torn off at suitable edges. The less value must be relied on, the more so can the aspects of reduction the flow resistances are pushed into the foreground.

Finally, the rotating ring can also be used to the one described at the beginning, which is often problematic in combustion chambers To enable reignition of the fuel by having the one facing the combustion chamber End due to irradiation and due to the combustion already taking place at this point is kept glowing.

The drawing illustrates the invention at three, for example Embodiments of the new combustion chamber, each schematically in a cross section are shown, namely Fig. i shows a combustion chamber with a fixed burner head bearing and tangential fuel injection against the direction of air flow, Fig. 2 a combustion chamber with a circumferential burner head bearing and central fuel injection in the direction of the air flow and Fig. 3 another combustion chamber design with two, appropriately counter-rotating concentric burner rings.

In all three figures, i denotes a combustion chamber more known Design type. In the embodiment according to Fig. i is the chamber in an air duct housing 2 and provided with slots 3 in its rear part. On the air inlet side the chamber are formed as guide vanes webs d. arranged the storage 5 of the burner head. This consists of a cylindrical Circumferential ring 6 with a streamlined cross-section, carried by spokes 7 and with an axis 8 in the webs q. is stored. The spokes 7 are like turbine blades designed and drift in conjunction with the stationary, vane-like webs q.- the burner head. A fuel line 9 leads through the webs q. in a the storage 5 surrounding cooling jacket io. In the spokes 7 can be injected nozzles i i be arranged, which are connected to the cooling jacket io by channels. In the Injection nozzles 12 behind the end of the circumferential ring 6 are the combustion chamber wall arranged that they the fuel against the air flow and optionally tangential to this in the interior of the ring 6 and the space between this and inject into the chamber wall. Inside the chamber is 5 of the burner head before storage a protective shield 13 attached against thermal radiation.

In the embodiment according to Fig.2, the burner head is with his Storage 5 'on a fixed axle bolt attached to the combustion chamber i 14 stored. The burner head in turn consists of a circumferential ring 6, which with the Hub by turbine blades 7 and in contrast to the first embodiment with Through holes 15 and strips 16 is provided. The guide vanes consist of here rib-like projections a 'on the combustion chamber i. A fuel injector 17 is fixedly arranged at the rear end of the axle bolt 1.4, which is with a bore 18 is provided for supplying the fuel. Before storage 5 ' a radiation protection 13 is in turn attached.

In the embodiment shown in Fig. 3, there is the burner head of two concentrically arranged circumferential rings 6 and 6 'with spokes 7 and 7'. The inner ring 6 is with its axis 8 in the in the webs q. fixedly arranged Storage 5 and the outer ring 6 'on this with its circumferential bearing 5' stored. Here, too, a radiation protection 13 is arranged in front of the bearings 5 and 5 '. The turbine blades 7 and 7 'are designed so that they are in connection with the stationary guide vanes q. ' the two circumferential rings 6 and 6 'in opposite directions drive. To the better swirling of the air are for example attached to the inner circumferential ring 6 axial strips 16 and radial ribs i9, and the outer circumferential ring 6 'is provided with channel-shaped slots 2o. At the bottom Part of Fig. 3 is the arrangement of a fixed nozzle in one of the vanes 4 'illustrated, and in the upper part is a nozzle i i' in a blade 7 'attached, which the fuel in the space between the two circumferential rings 6 and 6 'injects.

Claims (18)

PATENT CLAIMS: i. Combustion chamber for continuous combustion, in particular for gas turbines and recoil propulsion devices for vehicles or aircraft, with circumferential burner head consisting of one or more concentric, cylindrical or conical rings through which the combustion air flows axially and by means of a turbine drives, characterized in that the turbine blades the Wear circumferential rings. 2 "combustion chamber according to claim i, characterized in that only the primary air is used to drive the burner head. 3. Combustion chamber according to claim i and 2, characterized in that the turbine blades (7, 7 ') are designed so that the air flowing through flows out of the blading with a swirl. 4. Combustion chamber according to claim i to 3, characterized in that fixed guide vanes (4 4!) Are attached in front of the turbine blades (7, 7 '). 5. Combustion chamber according to claim i to 4, characterized in that the guide vanes (4) carry the bearing parts (5) for the circumferential rings (6). 6th Combustion chamber according to Claims 1 to 5, characterized in that the rotating parts are stored in ball bearings. 7. Combustion chamber according to claim i to 6, characterized in that that the bearing (5) is surrounded by cooling channels (io) through which a coolant, z. B. the fuel flows. B. Combustion chamber according to Claims i to 7, characterized in that that the storage (5, 5 ') with a radiation protection (13) opposite the combustion chamber is provided. 9. Combustion chamber according to claim i to 8, characterized in that the fuel nozzles are arranged so that the fuel enters the burner head axially injected in the same direction as the air flow or in the opposite direction will. ok Combustion chamber according to Claims i to 9, characterized in that the fuel nozzles (12) are arranged in the chamber wall so that the fuel from the outside into the outlet end of the circumferential rings (6) are preferably injected tangentially against the direction of rotation will. i i. Combustion chamber according to Claims i to io, characterized in that the fuel nozzles are arranged so that part of the fuel in the annular space between the circumferential ring and chamber wall, part of which is injected into the interior of the circumferential ring (6). 12th Combustion chamber according to Claims i to i i, characterized in that the fuel nozzles are arranged so that the fuel in the space between the circumferential rings (6, 6 ') is injected. 13. Combustion chamber according to claim 9, ii and 12, characterized in that the fuel nozzles (ii, i i ') in a circumferential part, for. B. in the turbine blades (7,7 ') are arranged. 14. Combustion chamber according to claim 9 to 12, characterized characterized in that the fuel nozzles (21) are fixed, e.g. B. in the guide vanes (4 '), are arranged. 15. Combustion chamber according to claim 13, characterized in that that the fuel nozzles are arranged so that the rotation of the burner head by the recoil effect of the injected fuel is generated or intensified. 16. Combustion chamber according to claim i to 15, characterized in that a plurality of circumferential rings (6, 6 ') independently of one another, e.g. B. against each other, circulate. 17. Combustion chamber after Claim i to 16, characterized in that the circumferential rings (6, 6 ') through bores (15), slots, channels (2o) or the like. Are interrupted. 18. Combustion chamber according to claim i to 17, characterized in that the circumferential rings (6 in Fig. 2 and 3) with projections, such as strips (16), ribs (i9) or the like. Are provided. Considered publications: German Patent Nos. 702 339, 701 672, 685683, 672311, 66o2,92, 656987, 653492, 626 993, 435 658, 359 448 Austrian Patent No. 86 942; Swiss patent specification No. 168 028. Cited earlier rights: German Patent No. 734 1o1.