초록 ▼

Several improvements to an aircraft turbine engine and Auxiliary Power Unit (APU) are disclosed, as well as methods of using these improvements in routine and emergency aircraft operations. The improvements comprise the addition of cockpit-controllable clutches that can be used to independently disc

Several improvements to an aircraft turbine engine and Auxiliary Power Unit (APU) are disclosed, as well as methods of using these improvements in routine and emergency aircraft operations. The improvements comprise the addition of cockpit-controllable clutches that can be used to independently disconnect the engine's integrated drive generator (IDG), engine driven pump (EDP), fuel pump, and oil pump from the engine gearbox. These engine components may then be connected to air turbines by the use of additional clutches and then powered by the turbines. Similar arrangements are provided for the APU components. Cranking pads, attached to various engine and APU components, are disclosed to provide a means for externally powering the components for testing purposes and to assist with engine and APU start. Detailed methods are disclosed to use the new components for routine ground-testing and maintenance and for the enhancement of flight safety, minimization of engine component damage, and extension of engine-out flying range in the case of an emergency in-flight engine shutdown.

대표청구항 ▼

I claim: 1. An aircraft gas turbine engine, comprising a fan, a high pressure compressor, a combustor, a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated driv

I claim: 1. An aircraft gas turbine engine, comprising a fan, a high pressure compressor, a combustor, a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated drive generator (IDG) normally connected to the engine gearbox; an engine driven pump (EDP) normally connected to the engine gearbox; a fuel pump normally connected to the engine gearbox; a hydro-mechanical unit (HMU) connected to the fuel pump; and an oil pump normally connected to the engine gearbox, wherein the IDG includes: an IDG clutch which can be controlled to connect the IDG with or disconnect the IDG from the engine gearbox, such that the IDG is normally connected with the engine gearbox and the IDG can be disconnected from the engine gearbox for ground test and troubleshooting of the IDG and as a means to prevent damage to the IDG and the aircraft gas turbine engine in certain flight emergency cases; an IDG cranking pad which allows a motor to drive said IDG when said IDG is disconnected from the engine gearbox for ground test and troubleshooting of the IDG without running the aircraft gas turbine engine in its entirety; and an IDG air turbine clutch which can be controlled to connect the IDG with or disconnect the IDG from an air turbine, such that the IDG is normally disconnected from the air turbine and when the IDG is disconnected from the engine gearbox, the IDG can be connected with the air turbine for the air turbine to drive the IDG to provide back-up electric power in certain flight emergency and abnormal conditions and as a means to ground test and troubleshoot said IDG without running the aircraft gas turbine engine in its entirety; and when the IDG is connected with the engine gearbox, the IDG can be connected with the air turbine for the air turbine to drive the aircraft gas turbine engine through the IDG and the engine gearbox as back-up starter on ground and in flight. 2. An aircraft gas turbine engine of comprising a fan, a high pressure compressor, a combustor, a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated drive generator (IDG) normally connected to the engine gearbox; an engine driven pump (EDP) normally connected to the engine gearbox; a fuel pump normally connected to the engine gearbox; a hydro-mechanical unit (HMU) connected to the fuel pump; and an oil pump normally connected to the engine gearbox, wherein the EDP includes: an EDP clutch which can be controlled to connect the EDP with or disconnect the EDP from the engine gearbox, such that the EDP is normally connected with the engine gearbox and the EDP can be disconnected from the engine gearbox for ground test and troubleshooting of the EDP and as a means to prevent damage to the EDP in certain flight emergency cases and abnormal conditions; an EDP cranking pad which allows a motor to drive the EDP when the EDP is disconnected from the engine gearbox for ground test and troubleshooting of the EDP without running the aircraft gas turbine engine in its entirety; and an EDP air turbine clutch which can be controlled to connect the EDP with or disconnect the EDP from an air turbine, such that the EDP is normally disconnected from the air turbine and when the EDP is disconnected from the engine gearbox, the EDP can be connected with the air turbine for the air turbine to drive the EDP only to provide back-up hydraulic power in certain flight emergency cases and as a means to test and troubleshoot the EDP without running the aircraft gas turbine engine in its entirety; and when the EDP is connected to the engine gearbox, the EDP can be connected with the air turbine for the air turbine to drive the aircraft gas turbine engine through the EDP and the engine gearbox as back-up starter on ground and in flight. 3. An aircraft gas turbine engine, comprising a fan, a high pressure compressor a combustor a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated drive generator (IDG) normally connected to the engine gearbox; an engine driven pump (EDP) normally connected to the engine gearbox; a fuel pump normally connected to the engine gearbox; a hydro-mechanical unit (HMU) connected to the fuel pump; and an oil pump normally connected to the engine gearbox, wherein: the fuel pump includes a fuel pump clutch which can be controlled to engage the fuel pump with or disengage the fuel pump from the engine gearbox, such that the fuel pump is normally engaged with the engine gearbox and the fuel pump can be disengaged from the engine gearbox for ground test and troubleshooting of the fuel pump and as a means to prevent damage to the fuel pump and the HMU in certain flight emergency cases and abnormal conditions; and the HMU includes an HMU cranking pad which allows a motor to drive the fuel pump through the HMU when the fuel pump is disengaged from the engine gearbox for ground test and troubleshooting of the fuel pump without running the aircraft gas turbine engine in its entirety. 4. An aircraft gas turbine engine, comprising a fan, a high pressure compressor a combustor a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated drive generator (IDG) normally connected to the engine gearbox; an engine driven pump (EDP) normally connected to the engine gearbox; a fuel pump normally connected to the engine gearbox; a hydro-mechanical unit (HMU) connected to the fuel pump; and an oil pump normally connected to the engine gearbox, wherein the oil pump includes: an oil pump clutch which can be controlled to connect the oil pump with or disconnect the oil pump from the engine gearbox, such that the oil pump is normally connected with the engine gearbox and the oil pump can be disconnected from the engine gearbox in certain flight emergency cases and abnormal conditions to prevent damage to the oil pump, and for ground test and troubleshooting of the oil pump without running the aircraft gas turbine engine in its entirety; and an oil pump cranking pad which allows a motor to drive the oil pump when the oil pump is disconnected from the engine gearbox for ground test and troubleshooting of the oil pump without running the aircraft gas turbine engine in its entirety. 5. An aircraft gas turbine engine, comprising a fan, a high pressure compressor, a combustor, a high pressure turbine connected to the high pressure compressor by a core shaft, a low pressure turbine connected to the fan by a fan shaft, and an engine gearbox fitted with: an integrated drive generator (IDG) normally connected to the engine gearbox; an engine driven pump (EDP) normally connected to the engine gearbox; a fuel pump normally connected to the engine gearbox; a hydro-mechanical unit (HMU) connected to the fuel pump; an oil pump normally connected to the engine gearbox; a compressor including a compressor clutch that can be controlled to engage the compressor with or disengage the compressor from the engine gearbox; and a turbine including a turbine clutch that can be controlled to engage the turbine with or disengage the turbine from the compressor, such that the compressor is normally engaged with the engine gearbox and the turbine is normally disengaged from the compressor, wherein when the turbine is engaged with the compressor, the turbine drives the engine through the compressor and the engine gearbox as back-up starter on ground and in flight; and when the compressor is disengaged from the engine gearbox, the compressor can be engaged with the turbine for the turbine to drive the compressor to provide back-up pneumatic power in certain emergency cases and abnormal flight conditions, and for ground use.