DE2202679C3 - Silencer device for a multi-body nozzle - Google Patents

Description

The invention relates to a silencer device for a multi-body nozzle, in particular an aircraft jet engine, with a primary nozzle, a secondary nozzle having a diverging section, which is formed by the inner wall of a housing jacket with a profiled outer wall, the Primary nozzle a hot primary jet, surrounded by a secondary jet, into the diverging channel section the secondary nozzle ejects, and with several muffler elements, which between an operating position in which they with their upstream end shovel-like protrude into the primary jet and secondary jet, and an inoperative position in which they sit in a recess of the housing shell and form a continuous part of the wall of the diverging Form channel section, are adjustable.

In a previously known muffler device ^ft 5 of this type (GB-PS 11 97 104), the muffler elements consist of flaps which are hinged at their downstream end to the housing shell and can be pivoted inwardly so that their upstream end protrudes into the primary jet. This is intended to accelerate the mixing of the secondary jet with the primary jet within the closed housing jacket. Since the muffler elements act as pure flow obstacles, they cause a considerable loss of thrust

The invention is based on the object of designing a shock absorber device of this type in such a way that that the loss of thrust is reduced and at the same time the damping effect is increased.

This object is achieved according to the invention in a silencer device of the type specified at the beginning solved by the following features:

a) the muffler elements are designed as a guide channel so that they have a Direct part of the primary and secondary radiation into the atmosphere;

b) the recesses of the housing shell for receiving the silencer elements are as Passages formed through when the silencer elements are inoperative these are covered.

The muffler elements thus serve a part of the primary and secondary jet through the divert certain passage openings into the atmosphere. This way the main ray is over its circumference indented at those points where the partial beams are removed, whereby the surface of the main ray that comes into contact with the atmosphere is increased. the Partial beams arranged in a star shape around the main beam also ensure that the primary and Mix the secondary jet faster with the atmosphere be able. The loss of thrust is significantly less than in the case of the previously known silencer device, since the muffler elements of the solution according to the invention only for the low-loss deflection of Partial jets, but not act as flow obstacles.

In the case of single-body nozzles, however, it was already known to use partial jets of the main jet in a star shape for the purpose branch off the sound attenuation (cf. z. B. US-PS 30 61 038). However, the problem arises with single-body nozzles the mixing of a primary stream with a secondary stream does not occur. In addition, the known single-body nozzle, the muffler elements from pipe elbows at the end of the thrust nozzle are articulated. Since this pipe bend in its operating position, the effective cross-section of the Enlarging the nozzle, Versrhlußelemente must be provided at the end of the nozzle, which the cross-section the thrust nozzle again by a corresponding amount. In the silencer device according to the invention on the other hand, the muffler elements in the recesses of the housing jacket are like this arranged that they practically the effective cross section of the multi-body nozzle in its operating position Don `t change.

Preferred exemplary embodiments of the invention are explained in more detail with the aid of the drawing. It shows:

Fig. I a schematic axial section through a Multi-body nozzle with a silencer device according to the invention;

FIG. 2 is a view corresponding to FIG. 1 slightly different embodiment;

Fig. 3 is an axial section along the line HI-III in F i g. 4, the further details of the in F i g. 1 shown

Represents silencer device, wherein the silencer device their operating position in the upper half of the figure and theirs in the lower half of the figure Takes out of service position;

4 shows a vertical section along the line IV-IV in F i g. 3, but with the actuating device omitted;

FIG. 5 shows a vertical section along the line V-V of FIG. which schematically shows the shape of the Represents beam splitting.

Di? F i g. 1 and 2 show very schematically two embodiments of the invention. By reference numeral 1 is a primary nozzle is designated, which is flowed through by a schematically by an arrow Fp shown hot gas stream A housing jacket 2 surrounding the primary nozzle and forms together with it a Rirsgraum 3 which is traversed by a schematically indicated by an arrow Fs secondary air stream. The housing jacket 2 extends beyond the outlet opening 4 of the primary nozzle, the housing jacket forming with its inner wall a secondary nozzle 5 provided with a diverging section and having a profiled outer wall 6. Flaps 7 allow the outlet cross-section of the nozzle to be controlled. The hot gases leave the primary nozzle 1 and when they leave the outlet opening 4 form a primary jet 8, the profile of which is shown schematically under 8a and which is surrounded by an annular secondary jet 9 which is formed by the secondary fluid emerging from the annular space 3. The muffler device has a multiplicity of muffler elements 10a and 106. The silencer elements are mounted in recesses 11 which are arranged with the same angular spacing in the housing jacket 2 downstream of the outlet opening 4 of the primary nozzle. Each of the silencer elements is pivotably mounted about a transverse axis 12, and corresponding means (not shown) are provided for the simultaneous swiveling of all silencer elements between a position drawn in solid lines and an operating position shown in dashed lines.

The muffler elements 10a of FIG. 1 are tubular guide channels with a closed rectangular cross-section and openings at the two ends. In the inoperative position, the inner walls 13 restore the continuity of the secondary nozzle 5 and its outer walls 14 restore the continuity of the profiled outer wall 6 of the housing jacket. When they are in their operating position, the silencer elements 10a capture part of the primary jet 8 and part of the secondary jet 9 and guide them into the outer space of the nozzle, as shown schematically by the arrow FD , around the nozzle a plurality to form of partial flows, which are indicated schematically with y.

In Fig. 2 there are the sound absorber elements 106 from an outwardly open U-profile, d. H. they only have an inner wall 13, which is in the Inoperative position restores the continuity of the surface of the secondary nozzle 5, and two side walls 15. The outer wall 6 of the housing jacket continues at 16 over part of the length of the recesses 11, leaving openings 17 which are closed by flaps 18 when the <>? Shield damper elements 106 are in their inoperative position. The flaps 18 are around at 18a Transverse axes at the rear end of the wall sections 16

pivoted. The flaps 18 can pivot freely so that the pressure of the over the length of the Outer wall 6 sireichenden outside air keeps the flaps closed (shown with solid lines Position) when the shield damper elements 106 are in their inoperative position. If the Shield damper elements are in their operating position, they skim part of the beam 8 from what is in the Recesses 11 causes the opening of the flaps 18 causing overpressure, whereby the Openings 17 are released for the passage of the downstream ends of the muffler elements.

The gases deflected by means of the upstream ends and part of the primary air which flow in the silencer elements in the direction of arrow Fd hold the flaps 18 in the position shown in dashed lines in the figure so that the partial flows j can exit unhindered. It goes without saying that forced pivoting of the flaps 18 also remains within the scope of the invention, be it a return by means of springs or a synchronization of their movement with the movement of the shield damper elements.

The F i g. 3, 4 and 5 show in detail the arrangement and the mode of operation of a silencer device, as has been described in connection with FIG. 1; Elements which play the same role as in FIG. 1 are provided with the same reference symbols. The multi-body nozzle shown in these figures is arranged behind an engine, which in turn is arranged in a nacelle (not shown) or in the fuselage of an aircraft. The primary nozzle 1 provided with flaps 1 a is connected to a part of the engine not shown, which is usually referred to as a gas generator and which provides the hot gas flow Fp during operation. The housing jacket 2 forms a nozzle channel which surrounds the nacelle or the fuselage (not shown) in an extended manner and which has a converging section 2a followed by the diverging section of the secondary nozzle 5. The two sections are separated from one another by a constriction 26 of the thrust jet formed by the primary jet 8 and the secondary jet 9. The primary jet 8 and the secondary jet 9 mix within the housing jacket 2 downstream of the primary nozzle 1 along a central contact surface fm.

Downstream of the constriction 26, seven recesses 11 are cut out at the same angular distance along the circumference of the housing jacket 2; they establish a connection between the interior of the secondary nozzle and the exterior via rectangular openings 11a and 116, which are formed in a corresponding manner in the inner wall forming the secondary nozzle 5 and in the outer wall 6. The tubular shield damper elements 10c are inserted into the recesses 11 from the interior of the secondary nozzle. They are of a substantially rectangular cross-section in the transverse direction and have openings at both ends; they are delimited by an inner wall 13a, an outer wall 14a and by two side walls 15a. The shield damper elements are pivotably mounted in the vicinity of their inner walls 13a about axes 12 which are tangents to a circle about the axis XX 'of the nozzle, and along the intersection of a plane perpendicular to said axis with the wall of the secondary nozzle 5 Bei In another embodiment (not shown) the axes 12 are in the vicinity of this line of intersection

arranged. As shown in FIG. 1 can be seen, the surfaces 13a and 14a of the muffler elements in the inoperative position (lower part of FIGS. 3 and 4) represent the wall of the secondary nozzle 5 and the outer wall 6. In the operating position (upper part 5 of FIG 4) the upstream ends of the muffler elements 10c move into the secondary nozzle and the downstream ends move outward. The upstream ends move sufficiently far into the secondary nozzle to break through the middle boundary 8a of the main jet 8, part of which is skimmed off together with part of the secondary flow 9, whereupon the deflected gases flow along Fd through the silencer elements and to them their downstream end on the 15 outer ropes of the housing shell. The remaining part of the main flow essentially contains that part of the main flow which is enclosed inside the surface of rotation 8b , which is determined by the front edge of the walls 13a, and the 20 parts which flow outside of said surface of rotation and are guided between the side walls of adjacent silencer elements will. The remaining part is not deflected and follows its normal path to the outlet opening of the nozzle in order to ensure the propulsion of the aircraft.

FIG. 5 shows the changes which are caused by the muffler device in the contour of the jet flowing out of the nozzle. Vertically below the seven silencer elements 10c in the operating position 30, the deflection of gas causes a negative pressure on the surface of the jet, and seven partial jets j are deflected around the housing jacket. On the one hand, this results in a corrugation 19 of the surface of the thrust jet, which increases the area for contact with the ambient air and therefore accelerates the mixing of the jet with the air, on the other hand, a reduction in the sound energy of the residual jet as a result of the reduction in its cross section. These two effects work in terms of sound attenuation with that of the partial beams
caused shielding effect, whereby the partial jets are very quickly thinned behind the multi-body nozzle.

In the embodiment shown, the swiveling of the silencer elements 10c between the inoperative position and the operating position is reversed by means of a piston-cylinder device mounted in the housing jacket (cf. FIG. 3). Jedi of the side walls 15a of each Silencerelemen tes 10c is provided on its outer surface with a Schwenkach se 20a on which one end of a pivot arm 20 is attached, the other end be 206 is hinged to an arm 21a of a double-armed lever 2. The two double-armed levers 21, which are each individually linked to one of the associated Seitenwändi one and the same silencer element 10c, are pivotably mounted in the housing shell about pivot axis 22, which extends parallel to pivot axis 12 of the associated Schalldamperele Mentes. The other arms 21 b are connected miteinande by eim the axes 22 and 12 parallel to the axis 23 at the center thereof, the piston rod 24a of a piston-cylinder device is articulated 24, derei cylinder in the housing jacket at one to the axes of 2.1 22 and 12 parallel to the axis 246 hinged is.

For this purpose 4 sheets of drawings

h 901

Claims (3)

Patent claims: 1. Silencer device for a multi-body nozzle, in particular an jet engine, with a primary nozzle, a secondary nozzle having a diverging section, which is formed by the inner wall of a housing jacket with a profiled outer wall, the primary nozzle sending a hot primary jet, surrounded by a secondary jet, into the diverging duct section ejects the secondary nozzle,! ind with several muffler elements, which between an operating position in which they protrude with their upstream end like a shovel into the primary jet and secondary jet, and an inoperative position in which they sit in a recess of the housing shell and a continuous part of the wall of the diverging duct section, are adjustable , characterized by the following features: a) the muffler elements (10a - = - 1Oa ^ are as Guide channel designed so that it is part of the primary and in its operating position Direct the secondary beam into the atmosphere; b) the recesses (11, 11a, Lindes housing jacket (2) to accommodate the silencer elements (IO3 - = - 10 <#are as passage openings formed, which are covered by this when the silencer elements are inoperative are. 2. Silencer device according to claim I _1, characterized in that the silencer elements (10a, 1Oc ^ are tubular components with a closed jacket, which ensure the continuity of the profiled outer wall of the housing jacket in the inoperative position. 3. Schalldämpfereinrichlung according to claim 1, characterized in that the passage openings are provided on their outside with pivotably mounted flaps (18) which in the inoperative position of the silencer elements (IQb) form part of the profiled outer wall and in the operating position part of the guide channels. 45