DE1179421B - Fuel injection nozzle for combustion chambers of gas turbine engines - Google Patents

Description

Fuel injector for combustion chambers of gas turbine engines The invention relates to a fuel injection nozzle with control of the injection quantity in the return for combustion chambers of gas turbine engines, with one around the central one Fuel return line arranged fuel supply line, from the tangential Inflow holes in a cylindrical, lead conically tapering vortex chamber, between the and the return line a throttle is provided, the connection between the swirl chamber and the return line through an axially rearwardly directed, annular overflow opening and subsequent return bores are carried out.

Fuel injectors of the type described above are known. The annular opening provided within the throttle or the bores provided here, through which the return flow from the vortex chamber flows over to the return line, are arranged so that their radially outer contour - in the radial direction considered -relatively far within the leading edge of the tangential to Vortex chamber directed inflow bores is located. However, this arrangement harbors there is a risk that air can disadvantageously get into the return system, especially with temporarily small amounts of fuel. With so-called vortex burners - refers to these, the invention - forms, namely with respect to the law of twist in the center. of the fluid vortex inside the injection nozzle an air core that expands towards 'the' nozzle. The excess '' Return fuel flows at the rear end of the conical swirl flow through the annular return opening, from, ",., If this return opening is radial is too far inside, for which constructive reasons are responsible, there is Danger that, as already mentioned, air gets into the return lines. aside from that the return flow is complicated in the known constructions in the area of the throttle designed insofar as that provided after the annular overflow opening Return bores are located radially further out and to the longitudinal axis of the device are inclined, so that here in the return flow through increased flow resistances an increased pressure drop sets.

The object of the invention is to reduce the risk that in the Return system from the vortex chamber, switch off with safety, and furthermore it consists in the recirculation for the amount of overflow fuel in the area of the throttle with as little loss of flow as possible. There is a minimum of pressure drop within the injector return of great importance with regard to the same injection quantities as possible for everyone existing injection nozzles; because conversely, increase with a higher pressure drop the differences between the injection quantities of the individual nozzles due to the unavoidable inaccuracies in their manufacture. .

The object set is achieved by the fact that, according to the invention, the cylindrical T61 of the vertebral comb merges without interruption into the outer circumference of the annular overflow opening: In addition to the vvöi @ parts already mentioned, there is a further advantage of the. Däriü invention; `that by: - is'" the ", this arrangement radially outer annular äng eordnäte Überstfömöffnüiig in their clearance." Gleichet over the known Weife'bei held 1, -1 close '' kailil "thereby increasing the fluid friction, so that the calming space available after the throttle can be kept smaller for reducing the swirl flow.

Another feature of the invention is that the outer circumference the return flow throttle consisting of a cylindrical disc with the inner wall of the actual nozzle body forms the annular overflow opening.

Furthermore, according to the invention for the free-standing arrangement of the return flow throttle within the nozzle body a holder in the form of one opposite the throttle plate Larger diameter disc is provided between the front face of the return pipe and a radial step in the nozzle body by screwing on the rear end of the latter is attached to the front end of the return pipe is. In addition, the return bores provided in the holder run here in the direction of the longitudinal axis of the injection device, and its outer contours is also in Height of the leading edges of the tangential vortex chamber inflow bores.

The above features bring a, in the area of the return throttle, seen from the vortex chamber flow, in the axial direction continuous "smooth" Course of the return flow with itself.

Details of the invention emerge from the description of the drawings.

An exemplary embodiment of the invention is shown in the drawing. It shows F i g. 1 shows an injection device, partly in section, FIG. 2 one Section along line II-11 of FIG. 1 and F i g. 3 a section along the line 111-III of FIG. 2.

The fuel arrives via the fuel supply line 11 to the inflow bores 13 arranged tangentially with respect to the swirl chamber 12. A part of the fuel is injected through the nozzle 14 into the combustion chamber; the excess fuel reaches the return line 17 via the annular overflow opening 15 and through return bores 16. Between this and the swirl chamber 12 , a return flow throttle 18 in the form of a cylindrical disk is provided, which is used to form the annular return opening and its position is provided by a bracket 19 is set in the form of a larger diameter disc. The holder 19 is fastened between a step in the nozzle body 20 and the front end wall of the return pipe 21.

As is known, a swirl flow 22 with a central air core 23 (see FIG. 2) arises within the swirl chamber 12. Because the outer circumference of the annular overflow opening 15 - viewed in the radial direction - is at the same height as the mouths of the tangential vortex chamber inflow bores 13, the risk that harmful air can get into the return system under certain operating conditions is practically excluded. In addition, compared to known constructions, where the annular overflow opening is located radially further inward, the annular gap (15) is smaller according to the proposal for the same overflow amount, so that the swirling movement of the return flow is already visibly reduced here due to increased fluid friction, whereby the calming space 24 in front of the return bores 16 is reduced can be.

Claims (1)

Claims: 1. Fuel injection nozzle with control of the injection quantity in the return for combustion chambers of gas turbine engines, with a fuel supply line arranged around the central fuel return line, from which tangential inflow bores lead into a cylindrical, conically tapering vortex chamber located in front of the mouth of the injection nozzle, between the and the return line a throttle is provided, the connection between the vortex chamber and the return line being made through an axially rearwardly directed, annular overflow opening and subsequent return bores, characterized in that the cylindrical part of the vortex chamber (12) extends into the outer circumference of the annular overflow opening (15 ) transforms. z. Fuel injection nozzle according to Claim 1, characterized in that the outer circumference of the return flow throttle (18) consisting of a cylindrical disk forms the annular overflow opening (15) with the inner wall of the actual nozzle body (20). That a holder (19) in the form provided a with respect to the throttle disc (18) larger in diameter pulley 3. The fuel injector of claim 1 and 2, characterized in that the free-standing arrangement of the return throttle (18) in the nozzle body (20) between the front end face of the return pipe (21) and a radial step in the nozzle body (20) by screwing the rear end of the latter on the front end of the return pipe (21) and that ferrisr the return bores (16) provided in the holder (19 ) in Run in the direction of the longitudinal axis of the injection device and that their outer contours are also at the level of the leading edges of the tangential swirl chamber inflow bores (13) .