초록 ▼

A panel for a nacelle structure that surrounds a jet engine core includes a longitudinally extending, generally semicircular center region, an upper bifurcation region, a lower bifurcation region, a hinge beam region extending from the upper bifurcation region and configured to receive an upper thru

A panel for a nacelle structure that surrounds a jet engine core includes a longitudinally extending, generally semicircular center region, an upper bifurcation region, a lower bifurcation region, a hinge beam region extending from the upper bifurcation region and configured to receive an upper thrust reverser track guide, and a latch beam region extending from the lower bifurcation region and configured to receive a lower thrust reverser track guide. A bypass duct is formed in a space between the panel and the nacelle structure. A hinge beam structure and latch beam structure are integrally formed with the panel. An inner skin layer extends continuously across a bond panel surface generally facing the engine core and an outer skin layer extends continuously across a bond panel surface generally facing the bypass duct, the inner and outer skin layers extending across the center region, upper and lower bifurcation regions, hinge beam region, and latch beam region. The outer skin layer may have an acoustic treatment, such as being perforated in at least the center region and the upper and lower bifurcation regions. In this way, a separate hinge beam and latch beam are not used, and therefore there is no need to couple the panel to the respective beams.

대표청구항 ▼

1. A panel for a nacelle structure that surrounds a jet engine core, the panel comprising: a center region that extends along a longitudinal axis of the jet engine core;an upper bifurcation region extending radially from the center region;a lower bifurcation region extending radially from the center

1. A panel for a nacelle structure that surrounds a jet engine core, the panel comprising: a center region that extends along a longitudinal axis of the jet engine core;an upper bifurcation region extending radially from the center region;a lower bifurcation region extending radially from the center region;a hinge beam region extending from the upper bifurcation region and configured to receive an upper thrust reverser track guide;a latch beam region extending from the lower bifurcation region and configured to receive a lower thrust reverser track guide;wherein a bypass duct is formed in a space between the panel and the nacelle structure;wherein the hinge beam region includes a lower flow portion that defines a portion of the bypass duct and an upper attachment portion that receives the upper thrust reverser track guide, and wherein the latch beam region includes an upper flow portion that defines a portion of the bypass duct and a lower attachment portion that receives the lower thrust reverser track guide;wherein the center region, upper bifurcation region, and lower bifurcation region are constructed from a honeycomb core having an inner honeycomb side generally facing the engine core and an outer honeycomb side generally facing the bypass duct, and wherein an inner skin layer extends continuously across a bond panel surface generally facing the engine core and an outer skin layer extends continuously across a bond panel surface generally facing the bypass duct, the inner and outer skin layers extending across the center region, upper and lower bifurcation regions, hinge beam region, and latch beam region, and the outer skin layer is perforated in at least the center region and the upper and lower bifurcation regions; andwherein, within the upper attachment portion, the inner skin layer is bonded to the outer skin layer without any honeycomb core material therebetween. 2. A panel as in claim 1, wherein the lower flow portion of the hinge beam region is constructed from a honeycomb core having an inner honeycomb side generally facing the engine core and an outer honeycomb side generally facing the bypass duct, and the outer skin layer in the lower flow portion is perforated. 3. A panel as in claim 1, wherein the upper flow portion of the latch beam region is constructed from a honeycomb core having an inner honeycomb side generally facing the engine core and an outer honeycomb side generally facing the bypass duct, and the outer skin layer in the upper flow portion is perforated. 4. A panel as in claim 1, wherein the upper attachment portion of the hinge beam region and the lower attachment portion of the latch beam region are constructed of at least one of the outer skin layer or the inner skin layer. 5. A panel as in claim 1, wherein the hinge beam region receives at least one hinge station along its axial length, and the hinge beam region is constructed from a honeycomb core having an inner honeycomb side generally facing the engine core and an outer honeycomb side generally facing the bypass duct, except for a portion of the hinge beam region where the hinge station is received. 6. A panel as in claim 1, wherein the latch beam region receives at least one hinge station along its axial length, and the latch beam region is constructed from a honeycomb core having an inner honeycomb side generally facing the engine core and an outer honeycomb side generally facing the bypass duct, except for a portion of the latch beam region where the hinge station is received. 7. A panel as in claim 1, wherein at least one of the inner skin layer is constructed of a composite material or the outer skin layer is constructed of a composite material. 8. A panel as in claim 1, wherein the honeycomb core is constructed of a metal material. 9. A panel as in claim 1, wherein the hinge beam region has a generally C-shaped cross-sectional geometry. 10. A panel as in claim 1, wherein the lower flow portion extends laterally between the upper bifurcation region and the upper attachment portion such that the respective portion of the bypass duct is formed radially between the lower flow portion and the center region; andthe upper attachment portion projects radially outward from the lower flow portion, and the upper attachment portion is integrated into the panel. 11. A panel as in claim 1, wherein a thickness of the panel defined between exterior surfaces of the inner and the outer skin layers decreases as the panel extends along the lower flow portion towards the upper attachment portion. 12. A panel as in claim 1, further comprising a second honeycomb core disposed next to the honeycomb core within the lower flow portion, wherein a thickness of the second honeycomb core which extends between the first and the second skin layers is smaller than a thickness of the honeycomb core which extends between the first and the second skin layers. 13. A panel as in claim 12, further comprising a third honeycomb core disposed next to the second honeycomb core within the lower flow portion, wherein the second honeycomb core is between the honeycomb core and the third honeycomb core, and wherein a thickness of the third honeycomb core which extends between the first and the second skin layers is smaller than the thickness of the second honeycomb core. 14. A panel for a nacelle structure that surrounds a jet engine core, the panel comprising a honeycomb core configured in a center region that extends along a longitudinal axis of the jet engine core, the center region having a generally semicircular cross-section, in an upper bifurcation region extending radially from the center region, in a lower bifurcation region extending radially from the center region, in a hinge beam region extending from the upper bifurcation region and configured to receive an upper thrust reverser track guide, and in a latch beam region extending from the lower bifurcation region and configured to receive a lower thrust reverser track guide; wherein a bypass duct is formed in a space between the panel and the nacelle structure;wherein the hinge beam region includes a lower flow portion that defines a portion of the bypass duct and an upper attachment portion that receives the upper thrust reverser track guide, and wherein the latch beam region includes an upper flow portion that defines a portion of the bypass duct and a lower attachment portion that receives the lower thrust reverser track guide;wherein an inner skin layer extends continuously from the upper attachment portion to the lower attachment portion, and an outer skin layer extends continuously from the upper attachment portion to the lower attachment portion, and wherein the outer skin layer is perforated in at least the center region and the upper and lower bifurcation regions;wherein, within the upper attachment portion, the inner skin layer is bonded to the outer skin layer without any honeycomb core material therebetween. 15. A panel as in claim 14, wherein the outer skin layer in the lower flow portion is perforated. 16. A panel as in claim 14, wherein the outer skin layer in the upper flow portion is perforated. 17. A panel as in claim 14, wherein the upper attachment portion of the hinge beam region and the lower attachment portion of the latch beam region are constructed of at least one of the outer skin layer or the inner skin layer. 18. A panel as in claim 14, wherein the hinge beam region receives at least one hinge station along its axial length, and the hinge beam region is constructed from a material other than the honeycomb core in a portion of the hinge beam region where the hinge station is received. 19. A panel as in claim 14, wherein the latch beam region receives at least one hinge station along its axial length, and the latch beam region is constructed from a material other than the honeycomb core in a portion of the latch beam region where the hinge station is received. 20. A panel as in claim 14, wherein at least one of the inner skin layer is constructed of a composite material or the outer skin layer is constructed of a composite material. 21. A panel as in claim 14, wherein the honeycomb core is constructed of a metal material. 22. A nacelle structure for an aircraft jet engine, comprising: an integrally formed bond panel structure comprising: a center region that extends along a longitudinal axis of the jet engine core;an upper bifurcation region extending radially from the center region; anda hinge beam region extending from the upper bifurcation region;wherein a bypass duct is formed partially by the integrally formed bond panel;wherein the hinge beam region includes a lower flow portion that defines a portion of the bypass duct and an upper attachment portion that receives the upper thrust reverser track guide;wherein the center region, upper bifurcation region are constructed from a honeycomb core having an inner honeycomb side generally facing an engine core of the aircraft jet engine and an outer honeycomb side generally facing the bypass duct;wherein an inner skin layer extends continuously across a bond panel surface generally facing the engine core and an outer skin layer extends continuously across a bond panel surface generally facing the bypass duct, the inner and outer skin layers extend across the center region, upper bifurcation region and hinge beam region, and the outer skin layer is perforated in at least the center region and the upper bifurcation region;wherein the lower flow portion extends laterally between the upper bifurcation region and the upper attachment portion such that the respective portion of the bypass duct is formed radially between the lower flow portion and the center region;wherein the upper attachment portion projects radially outward from the lower flow portion; andwherein, within the upper attachment portion, the inner skin layer is bonded to the outer skin layer without any honeycomb core material therebetween;an upper thrust reverser track guide mounted to the hinge beam region on a first side of the hinge beam region; anda hinge station mounted to the hinge beam region on a second side of the hinge beam region that is opposite the first side of the hinge beam region.