RU2277178C2 - Noise-damping device for double-flow turbojet engine - Google Patents

Abstract

FIELD: aircraft engineering; double-flow turbojet engines.

SUBSTANCE: noise-damping device for double-flow turbojet engine has ring rows of panels in engine outer loop, each including wall of load-bearing housing, perforated duct wall and layer of cellular filler. Layer of cellular filler is placed between wall of load-bearing housing and perforated duct wall. Two panels arranged in cross section of at least one ring layer of panels, each containing flanges arranged over perimeter of wall of load-bearing housing. Two longitudinal flanges are connected to longitudinal flanges of adjacent panel, and front and rear flanges are connected to engine housing or to adjacent rear and front flanges of adjacent panel. Rows of damping stops with holes are arranged between walls of load-bearing housing and perforated duct wall of each panel. Holes in stops are used to connect walls by fasteners. Damping frame is placed over perimeter of each panel, height of frame being equal to height of cellular filler. Each panel of ring row, from side of front and rear flanges, is made aerodynamically streamlined, with decrease of height of panel to joint with each flange. At least one ring row of panels forms diffuser-contraction resonance with walls of housing of low-pressure turbine of engine or housing of gas-generator.

EFFECT: improved efficiency of noise damping of double-flow turbojet engine without material losses of thrust.

6 cl, 10 dwg

Description

The invention relates to the field of aircraft engine manufacturing, namely, to noise suppression devices for turbojet bypass engines.

A sound-absorbing lining of a turbojet engine path is known, containing a honeycomb core placed between the outer and inner walls, the first of which is located with a gap relative to the power housing, and the second is perforated, while the outer wall is also perforated with a degree of perforation of 3 ... 20 %, and the ratio of the gap to the distance from the inner wall to the housing is 0.3 ... 0.7 [1].

A disadvantage of the known design is the small resource and low strength of the wall 2 of the power housing, made without supports relative to the perforated wall, as well as lower vibroacoustic strength of the wall 4, mainly in the mode of resonant vibrations (flutter).

Also known is a serial single-layer sound-absorbing structure containing a wall of the power housing, a perforated path wall, a layer of honeycomb placed between the wall of the power housing and the perforated path wall [2].

A disadvantage of the known sound-absorbing design is that the resonant sound absorption method used in it allows achieving high acoustic characteristics in a narrow frequency range - not more than 500 ... 700 Hz. And the frequency range of noise of modern aircraft power plants is in the range from 500 to 8000 Hz. Therefore, to achieve high performance in such a wide range, the construction of multilayer sound-absorbing structures (ZPK) is required. A disadvantage of the known design is also the incomplete use of the possibility of increasing the acoustic characteristics of single-layer sound-absorbing structures.

Also known is a sound-absorbing acoustic panel of a turbofan engine nacelle with a wedge-shaped cowl and a front integral ring, comprising a wall of the power housing, a perforated path wall, a perforated wall in the cavity outside the path, a front layer of honeycomb placed between the perforated path wall and the wall in the cavity outside the path, and also the back layer of the honeycomb core, located between the perforated wall in the cavity outside the path and the wall of the power housing [3].

A disadvantage of the known design is the high height of the panel to ensure high acoustic characteristics, which does not allow the use of such panels in operating power plants.

Closest to the claimed design is a noise attenuation system of a power plant containing annular rows of panels in the outer circuit of the engine, each of which includes a wall of the power casing, a perforated path wall, a layer of honeycomb placed between the wall of the power casing and the perforated path wall [4].

A disadvantage of the known design adopted for the prototype is the high cost of the panels and the low utilization of the material. Stresses that occur during the operation of bending flat panels and heating during heat-setting have a negative effect on the strength of products, and therefore, it is impossible to use power (titanium) motor housings having, for example, meridian horizontal joints. Another disadvantage of the known design is the incomplete use of the possibility of increasing the magnitude of sound absorption and expanding the frequency range of the absorption characteristic.

The technical problem, which is aimed by the invention, is to increase the sound absorption efficiency of a turbojet bypass engine without significant loss of thrust.

The essence of the technical solution lies in the fact that in the noise suppression device in a turbojet bypass engine containing annular rows of panels in the external circuit of the engine, each of which includes a wall of the power casing, a perforated path wall, a layer of honeycomb placed between the wall of the power casing and the perforated path wall according to the invention, in cross section of at least one annular row of panels, two panels are placed, each of which includes flanges, located The walls of the power casing along the perimeter, two longitudinal flanges are fastened to the longitudinal flanges of the adjacent panel, and the front and rear flanges are fastened to the motor casing or to the adjacent rear and front flanges of the adjacent panel, between the walls of the power casing and the perforated path wall of each panel there are rows of damper stops with holes through which these walls are connected by fasteners, and a damper frame is placed around the perimeter of each panel, the height of which is equal to the height of the honeycomb core, and with For the front and rear flanges, each panel of the annular row is aerodynamically streamlined, with a decrease in the panel height to the joint with each of the flanges, and at least one ring row of the panels forms a diffuser-confuser resonant cavity with the walls of the low-pressure turbine casing of the engine or casing gas generator. The perforated path wall and the honeycomb core are made of a two-dimensional polymer composition, which is fiberglass, organoplastic or a hybrid material based on layers of fabric, bundles or tape materials. The damper frame around the perimeter of the panel is covered by layers of material from the polymer two-dimensional composition and is connected by fasteners to the flanges, while at least one layer of material of the path wall is located in the rear of the panel above the layers of material of the damper frame. The outer layers of the path wall material include abrasive powder with a particle size of up to 0.05 mm. Perforation on the path wall is made in the form of groups of holes located around the damper stops, and any three adjacent perforation holes at a distance of more than one annular row of holes from the damper stops are an equilateral triangle, while the area of the perforation holes is 8-12% of the area of the path wall . At least one of the panels is provided with a hatch made of damping frame material, and the edges of the honeycomb cells along the perimeter of the panel are filled with damping frame material.

Placement in cross section of at least one annular row of panels of two panels, each of which includes flanges located along the perimeter of the wall of the power housing, while two longitudinal flanges are fastened to the longitudinal flanges of the adjacent panel, and the front and rear flanges are fastened to the motor housing or with adjacent rear and front flanges of an adjacent panel, between the walls of the power housing and the perforated path wall of each panel there are rows of damper stops with holes through which these walls are connected fasteners, and a damper frame is placed around the perimeter of each panel, the height of which is equal to the height of the honeycomb core, and on the front and rear flanges each panel of the annular row is aerodynamically streamlined, with a decrease in the height of the panel to the junction with each of the flanges, at least one annular row of panels forms a diffuser-confuser resonant cavity with the walls of the housing of the low pressure turbine of the engine or the body of the gas generator, which reduces the amplitude of the oscillation th across the permeable composite path walls with acoustic resistance, i.e. through perforation and resonant attenuation of oblique reflected sound waves in resonant sound-absorbing structures due to the cut-off of shock waves propagating up and down the stream in the resonant annular cavities of the outer motor circuit.

The implementation of the perforated path wall and honeycomb of a two-dimensional polymer composition, which is fiberglass, organoplastics or a hybrid material based on layers of fabric, bundles or tape materials, allows to reduce the tonal noise of a low-pressure compressor in the source itself - in a turbojet bypass engine, and at the same time reduce broadband noise of low pressure compressor stages.

The implementation of the damper frame in such a way that it is surrounded by layers of material from the polymer two-dimensional composition along the perimeter of the panel and connected by fasteners to the flanges, at least one layer of the path wall material located in the rear part of the panel above the layers of the damper frame material increases the vibroacoustic durability of sound-absorbing panels, reliability and resource in technical condition, prevents tearing and delamination of the path wall.

The inclusion in the outer layers of the material of the path wall of the abrasive powder with a particle size of up to 0.05 mm reduces erosion of the path wall, wear and "weathering" of the polymer component of the material. This increases the life and reliability of acoustic panels.

Perforation on the path wall in the form of groups of holes located around the damper stops in such a way that any three adjacent perforation holes at a distance of more than one annular row of holes from the damper stops are an equilateral triangle, while the area of the perforation holes is 8-12% of the area path wall, as well as the implementation of one of the panels with a hatch made of damping frame material and filling the edges of the honeycomb cells along the perimeter of the panel with damping frame material allows m optimize zone (vectors) acoustic flows in opposite phase to provide attenuation of resonant oblique reflected sound waves in confuser-diffuser annular cavity of the outer contour of the turbojet.

Figure 1 - shows a turbojet dual-circuit engine.

In Fig.2 - element I in Fig.1 diffuser-confuser resonant cavity.

Figure 3 - acoustic panel of the lower hemisphere.

Figure 4 is a section aa in figure 3 across the acoustic panel.

Figure 5 - element B in figure 3 of the rear flange of the acoustic panel.

In Fig.6 is a section bb In Fig.3 of one of the hatches of the acoustic panel.

Fig.7 is a section GG in Fig.3 (option 1).

On Fig - section GG in figure 3 (option 2).

In Fig.9 - section GG in Fig.3 (option 3).

Figure 10 is a view of D in Fig.7.8 or 9.

The noise suppression device in a turbojet dual-circuit engine contains in the outer circuit 1 of the engine ring rows of panels 2 and 3, 4 and 5, each of which includes a wall of the power casing 6, a perforated path wall 7, a layer of honeycomb 8 placed between the wall of the power casing 6 and perforated path wall 7. Two panels are placed in the cross section of the annular row of panels 2 and 3, each of which includes flanges 9, 10, 11, 12 located along the perimeter of the wall of the power housing 6, two longitudinal flanges 9, 10 fastened They are connected with the longitudinal flanges of the adjacent panel, and the front 11 and rear 12 flanges are fastened to the motor housing or to the adjacent rear and front flanges of the adjacent panel. Between the walls 6 of the power housing and the perforated path wall 7 of each panel 2, 3 there are rows of damper stops 13 with holes through which these walls 6, 7 are connected by fasteners 14. A damper frame 15 is placed around the perimeter of each panel 2, 3, whose height is 16 equal to the height of the honeycomb core 8, and from the front 11 and rear 12 flanges, each panel of the annular row 2, 3 is aerodynamically streamlined with a decrease in the height of the panel 17 to the joint 18 and 19 with each of the flanges 2, 3, and pos.20 - air flow discarded by low pressure pressor 21. The annular row of panels 2, 3 forms a diffuser-confuser resonant cavity 22 with the walls of the housing 24 of the low pressure turbine of the engine and the housing of the gas generator 25, while items 26, 27, 28 are the distances from the path wall 7 of the panel 2, 3 explaining the formation of a diffuser-confusor cavity 22. The perforated path wall 7 and the honeycomb core 8 are made of a two-dimensional polymer composition, which is fiberglass, organoplastic or a hybrid material based on layers of fabric, bundles or tape m materials under. The perforated path wall 7 is made of a non-metallic two-dimensional composition, which is a fiberglass or organoplastics based on tissue layers, the density of which is from 1.35 to 1.85 g / cm ³ , and at a temperature of from -60 ° C to 80 ° C the tensile strength at tensile strength along layers from 41 to 55 kgf / mm ² , compressive strength along layers from 14 to 32 kgf / mm ² , tensile strength across layers from 23 to 29 kgf / mm ² , compressive strength across layers from 12 up to 18 kgf / mm ² . The damper frame 15 around the perimeter of the panel 2, 3 is covered by layers of material 29 from a two-dimensional polymer composition and connected by fasteners 30 to the flanges 9, 10, 11, 12, while at least one layer of material 29 of the path wall 7 is located in the rear 31 panels 2,3 above the layers of material of the damper frame 15. The outer layers of the material of the path wall 7 include abrasive powder with a particle size of up to 0.05 mm (not shown). Perforation on the path wall 7 is made in the form of groups of holes located around the damper stops 13, and any three adjacent holes 32, 33, 34 of the perforation at a distance of more than one annular row of holes 35 from the damper stops 13 are an equilateral triangle, while the area of the holes 32 , 33, 34, 35 and other perforations is 8-12% of the area of the path wall 7. One of the panels 2, 3 is equipped with a hatch 36 made of the material of the damper frame 15, and the edges 37 of the cells of the honeycomb core 8 along the perimeter of the panel are filled with material damper th frame 15. The damping material 13 and stops the damper frame 15 is a semi-rigid adhesive with a content of hollow glass microspheres to 30 parts by weight, a density of from 0.1 to 0.75 g / m ³ and an air permeability for the samples 100 mm in diameter by 3 up to 50 l / min. In one embodiment of the manufacture of acoustic panels, the material of the damper stops 13 and the damper frame 15 is a semi-rigid polyurethane foam, the density of which is from 0.1 to 0.75 g / cm ³ and the air permeability for samples with a diameter of 100 mm is from 3 to 50 l / min.

The sound attenuation device in a turbojet bypass engine operates as follows. The determining parameter of the noise spectrum from the side of the perforated path wall 7 are the peaks of the tonal noise of the low pressure compressor 21 and the noise of the jet. Sound pressure ≈150 ... 180 dB generated by discrete harmonics of the stages of the low-pressure compressor in the conditions of high-speed (≈250 m / s) air flow of the low-pressure compressor 21 is perceived by the perforated path wall 7 of the panels of the upper 2 and lower 3 hemispheres, package 8 of the cell filler in the form of numerous Helmholtz resonance chambers and a titanium wall of the power housing 6, is damped in the diffuser-confuser resonant (ring) cavity 22 formed by the path wall 7 of the panels of the upper 2 and lower 3 floor ospher with the walls of the housing of the low pressure turbine 24 and the housing 25 of the gas generator (combustion chamber). In this case, the damper frame 15 along the perimeter of the wall of the power housing 6 of the upper panel 2 and the lower panel 3 reduces the amplitude of oscillations across the permeable composite path walls 7 due to the resonant attenuation of oblique reflected sound waves in resonant sound-absorbing structures. Further, a reduced sound pressure level is perceived and damped, repeatedly reflected and damped in the diffuser-confuser cavity 22 due to the cut-off of shock waves caused by the repetition rate of the stages of the low-pressure compressor blades propagating up and downstream in the channel of the external motor circuit. This allows you to reduce the peaks of tonal noise of the stages of the low pressure compressor in the source itself - in a turbojet dual-circuit engine. In this case, the optimum, in the frequency range 1200 ... 5000 Hz, sound absorption occurs while minimizing pressure loss and engine traction.

The inventive sound attenuation device in a turbojet dual-circuit engine increases the acoustic vibration strength and provides noise reserves in accordance with Chapter 4 of the International Civil Aviation Organization (ICAO) standards introduced since 2006.

Information sources

1. RU, patent No. 1324376, F 02 C 7/24, 10.27.96.

2. RU, "Aerospace Courier" No. 2, 2003, serial single-layer ZPK, p. 16, Fig. 2.

3. US patent No. 6173807, F 02 K 1/00, 04/13/1998

4. RU, "Flight" No. 9, 2003, the sound attenuation system of the power plant of the TU-154M aircraft, page 12, Fig. 4 - prototype.

Claims (6)

1. The sound attenuation device in a turbojet dual-circuit engine, containing in the outer circuit of the engine ring rows of panels, each of which includes a wall of the power housing, a perforated path wall, a layer of honeycomb placed between the wall of the power body and the perforated path wall, characterized in that in the transverse the cross section of at least one annular row of panels contains two panels, each of which includes flanges located along the perimeter of the wall of the power housing, two The flanges are fastened to the longitudinal flanges of the adjacent panel, and the front and rear flanges are fastened to the engine housing or to the adjacent rear and front flanges of the adjacent panel, between the walls of the power housing and the perforated path wall of each panel there are rows of damper stops with holes through which these walls are connected fasteners, and along the perimeter of each panel there is a damper frame, the height of which is equal to the height of the honeycomb core, with each panel on the side of the front and rear flanges the central row is aerodynamically streamlined with decreasing panel height to the junction with each of the flanges, at least one annular row of panels forms a diffuser-confuser resonant cavity with the walls of the low-pressure turbine casing of the engine or the gas generator casing. 2. The sound attenuation device in a turbojet bypass engine according to claim 1, characterized in that the perforated path wall and honeycomb core are made of a polymer two-dimensional composition, which is fiberglass, organoplastics or a hybrid material based on layers of fabrics, bundles or tape materials. 3. The sound attenuation device in a turbojet bypass engine according to claim 1 or 2, characterized in that the damper frame around the perimeter of the panel is covered by layers of material from a polymer two-dimensional composition and connected by fasteners to the flanges, at least one layer of material of the path wall located in the rear of the panel above the layers of damper frame material. 4. The sound attenuation device in a turbojet bypass engine according to claim 1, characterized in that the outer layers of the path wall material include abrasive powder with a particle size of up to 0.05 mm. 5. The noise suppression device in a turbojet bypass engine according to claim 1, characterized in that the perforation on the path wall is made in the form of groups of holes located around the damper stops, and any three adjacent perforation holes at a distance of more than one annular row of holes from the damper stops an equilateral triangle, while the area of the perforation holes is 8-12% of the area of the path wall. 6. The sound attenuation device in a turbojet bypass engine according to claim 1, characterized in that at least one of the panels is provided with a hatch made of a damper frame material, and the edges of the honeycomb cells along the panel perimeter are filled with a damper frame material.

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