A gas turbine engine (20) and method for containing a fan inside an engine after a fan thrust bearing assembly failure. The engine (20) may comprise a fan (42), a housing (100) including a compartment (102), a fan shaft (104) inside the compartment (102) and comprising a bowl (108), a support struct
A gas turbine engine (20) and method for containing a fan inside an engine after a fan thrust bearing assembly failure. The engine (20) may comprise a fan (42), a housing (100) including a compartment (102), a fan shaft (104) inside the compartment (102) and comprising a bowl (108), a support structure (110) inside the compartment (102), a speed sensor pickup (114) mounted on the outer surface (120) of the bowl (108), a speed sensor (112) mounted on the support structure (110), and a fan thrust bearing assembly (41) disposed forward of the bowl (108). The fan thrust bearing assembly (41) including a bearing (126). The speed sensor (112) and the sensor pickup (114) define a defining a sensor gap (116). The bearing (126) and the outer surface (120) defining a fan thrust bearing gap (130), wherein the sensor gap (116) is less than the fan thrust bearing gap.
대표청구항▼
1. A gas turbine engine disposed about a longitudinal engine axis (A), the engine comprising: a fan;an exterior housing including an interior compartment disposed adjacent to the fan;a fan shaft disposed inside the compartment, the fan shaft configured to drive the fan, the fan shaft comprising an e
1. A gas turbine engine disposed about a longitudinal engine axis (A), the engine comprising: a fan;an exterior housing including an interior compartment disposed adjacent to the fan;a fan shaft disposed inside the compartment, the fan shaft configured to drive the fan, the fan shaft comprising an elongated pole and a bowl, the bowl including an outer surface and an inner surface;a forward bearing assembly forward of the bowl;a fan bearing support structure disposed inside the compartment;a speed sensor pickup mounted on the outer surface of the bowl;a speed sensor mounted on the fan bearing support structure, the speed sensor and the sensor pickup defining a sensor gap in the axial direction; anda fan thrust bearing assembly disposed forward of the bowl, the fan thrust bearing assembly including a bearing, the bearing and the outer surface of the bowl defining in the axial direction a fan thrust bearing gap, wherein the sensor gap is less than the fan thrust bearing gap. 2. The gas turbine engine of claim 1, in which the fan thrust bearing assembly includes mounting hardware, wherein the fan thrust bearing assembly is disposed adjacent to the pole and is mounted below the speed sensor to the fan bearing support structure by the mounting hardware. 3. The gas turbine engine of claim 2, wherein the mounting hardware and the outer surface of the bowl define a mounting gap in the axial direction, the mounting gap greater than the sensor gap. 4. The gas turbine engine of claim 1, further comprising a component mounted directly to the outer surface of the bowl, the sensor gap less than an axial distance between the bearing and the component. 5. The gas turbine engine of claim 1 further comprising a core flow path extending along the engine axis, the core flow path configured to guide air from the fan through the engine, wherein the compartment is disposed radially inward of the core flow path. 6. The gas turbine engine of claim 1, further comprising geared architecture disposed inside the bowl, a perimeter of the geared architecture and the inner surface of the bowl defining a Geared Architecture to Inner Surface (GAIS) gap, wherein the sensor gap is less than the GAIS gap. 7. The gas turbine engine of claim 6, in which the sensor pickup includes pickup sensor attachment hardware disposed inside the bowl, wherein the sensor gap is less than an axial distance between the pickup sensor attachment hardware and the perimeter of the geared architecture. 8. A method for containing a fan inside a housing of a gas turbine engine after a fan thrust bearing assembly failure, the engine including the housing, the fan thrust bearing assembly and a fan shaft, the housing including an interior compartment, the fan shaft disposed in the interior compartment and configured to drive the fan, the fan disposed forward of the fan thrust bearing assembly, the fan thrust bearing assembly disposed inside the interior compartment, the method comprising: contacting a speed sensor by a speed sensor pickup when the fan shaft moves axially forward after a failure of the fan thrust bearing assembly;detecting, by a controller, a loss of signal from the speed sensor resulting from the contacting;shutting down the engine; andmoving the fan aft onto a forward bearing assembly, the forward bearing assembly and the fan thrust bearing assembly disposed in the interior compartment, the forward bearing assembly disposed aft of the fan and forward of the fan thrust bearing assembly. 9. The method of claim 8, wherein the moving the fan aft onto the forward bearing assembly is via ram force. 10. The method of claim 8, the fan shaft including an elongated pole and a bowl, the speed sensor pickup mounted on the outer surface of the bowl. 11. The method of claim 10, wherein the fan thrust bearing assembly is disposed adjacent to the pole and the bowl. 12. The method of claim 8, wherein the speed sensor is mounted proximal to the speed sensor pickup disposed on the fan shaft. 13. The method of claim 8, wherein the sensor and the speed sensor pickup define a sensor gap in the axial direction, the sensor gap less than any other gap in the axial direction between the contents of the interior compartment disposed forward of the bowl and an outer surface of the bowl. 14. The method of claim 13, wherein the fan thrust bearing assembly includes a bearing, the bearing and the outer surface of the bowl defining in the axial direction a fan thrust bearing gap, wherein the sensor gap is less than the fan thrust bearing gap. 15. The method of claim 13, wherein the engine further includes geared architecture disposed inside the bowl, wherein a perimeter of the Geared Architecture and the inner surface of the bowl define a Geared Architecture to Inner Surface (GAIS) gap, wherein further the sensor gap is less than the GAIS gap. 16. The method of claim 8, wherein the loss of signal is a loss of fan to low pressure turbine shaft ratio signal. 17. A gas turbine engine having an engine axis, the engine comprising: a gas generator that includes a core flow path;a propulsor that includes a fan, a fan shaft and geared architecture that drives the fan, the fan shaft comprising an elongated pole and a bowl, the geared architecture disposed within the bowl of the fan shaft; anda housing defining a compartment adjacent to the fan and the core flow path, the compartment including a fan bearing support structure and enclosing a forward bearing assembly forward of the bowl, a fan thrust bearing assembly, the bowl, a speed sensor mounted on the fan bearing support structure, and a speed sensor pickup mounted on an outer surface of the bowl, the fan thrust bearing assembly disposed between the forward bearing assembly and the bowl, the speed sensor pickup and the speed sensor defining a sensor gap in the axial direction, wherein the sensor gap in the axial direction is less than a Geared Architecture to Inner Surface (GAIS) gap in the axial direction between the geared architecture and an inner surface of the bowl or a gap in the axial direction between the bowl and the fan thrust bearing assembly. 18. The gas turbine engine of claim 17, in which the fan thrust bearing assembly includes mounting hardware, wherein the fan thrust bearing assembly is disposed adjacent to the pole and is mounted, below the speed sensor, to the support structure by the mounting hardware. 19. The gas turbine engine of claim 18, wherein the mounting hardware and the outer surface of the bowl define a mounting gap in the axial direction, the mounting gap greater than the sensor gap. 20. The gas turbine engine of claim 17, gas turbine engine is a geared turbofan engine.
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이 특허에 인용된 특허 (2)
Schilling, Jan Christopher, Gas turbine engine assembly and method of assembling same.
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