Patent Description:
Conventional aircraft propulsion systems often include a gas turbine engine that produces thrust and mechanical power. The gas turbine engine generally includes a compressor, one or more combustors downstream from the compressor, and a turbine downstream from the combustor(s). Ambient air enters the compressor as a working fluid, and one or more stages of rotating blades and stationary vanes in the compressor progressively increase the pressure of the working fluid. The working fluid exits the compressor and flows to the combustors where it mixes with fuel and ignites to generate combustion gases having a high temperature, pressure, and velocity. The combustion gases flow to the turbine where they produce work by rotating the turbine before exhausting from the turbine to provide thrust. A spool or shaft connects the turbine to a propulsor, such as a propeller or a fan, so that rotation of the turbine drives the propulsor to generate additional thrust. The spool or shaft may also connect the turbine to a rotor of an electric generator located inside the fuselage of the aircraft. In this manner, the gas turbine engine may also drive the rotor to produce sufficient electricity to power the hotel loads of the aircraft.

The output power of the electric generator is a function of the size of the rotor and the strength of the magnetic field associated with the electric generator. Specifically, increasing the size of the rotor and/or the strength of the magnetic field increases the output power of the electric generator. However, increasing the size of the rotor and/or incorporating larger permanent magnets on the rotor produces larger centrifugal forces that tend to separate the permanent magnets from the rotor, particularly at the high rotational speeds associated with a single-spool gas turbine engine that directly drives the rotor of the electric generator. Although multiple spools or shafts, gears, and/or transmissions may be used to reduce the centrifugal forces by reducing the rotational speed of the rotor, the additional weight and support systems associated with multiple spools or shafts, gears, and/or transmissions may be undesirable, particularly in aircraft applications. Therefore, the need exists for a power generation system that can be driven by a gas turbine engine to generate <NUM> MW, <NUM> MW, <NUM> MW, or more of electric power without requiring multiple spools or shafts, gears, and/or transmissions.

<CIT> describes and illustrates a two-spool gas turbine engine and explains that three-spool architectures are also possible. Both <CIT> and <CIT> describe and illustrate a two-spool gas turbine engine in which a high-speed spool connects a high pressure turbine section to a high pressure compressor section, and a low-speed spool connects a low pressure turbine section to a low pressure compressor section. In addition, both <CIT> and <CIT> disclose that the generator is located inside the low pressure compressor section. Finally, <CIT> describes a multi-spool gas turbine engine, wherein a motor is located upstream of said gas turbine engine.

Aspects and advantages of the invention are set forth below in the following description, or may be obvious from the description, or may be learned through practice of the invention.

The invention relates to a power generation system according to claim <NUM>.

Advantageous embodiments are characterized by the features of the dependent claims.

Those of ordinary skill in the art will better appreciate the features and aspects of such embodiments, and others, upon review of the specification.

A full and enabling disclosure of the present invention, including the best mode thereof to one skilled in the art, is set forth more particularly in the remainder of the specification, including reference to the accompanying figures, in which:.

In fact, it will be apparent to those skilled in the art that modifications and variations can be made in the present invention without departing from the scope thereof. For instance, features illustrated or described as part of one embodiment may be used on another embodiment to yield a still further embodiment.

As used herein, the terms "first," "second," and "third" may be used interchangeably to distinguish one component from another and are not intended to signify location or importance of the individual components. As used herein, the terms "upstream" and "downstream" refer to the location of items with reference to the direction of fluid flow in a fluid pathway. For example, item A is "upstream" from item B and item B is downstream from item A if fluid normally flows from item A to item B. As used herein, "axial" refers to the direction of the longer axis of a component, "radial" refers to the direction perpendicular to the axial direction, and "circumferential" refers to the direction around a component.

Embodiments of the present invention include a power generation system that can be driven by a gas turbine engine to generate <NUM> MW, <NUM> MW, <NUM> MW, or more of electric power without requiring multiple spools or shafts, gears, and/or transmissions. The power generation system may be incorporated into any vehicle and/or used as a portable power supply for geographically remote areas or following a natural disaster. For example, the power generation system may be housed in a nacelle and attached to the fuselage or wing of an aircraft. The power generation system generally includes a gas turbine engine and an electric generator. The gas turbine engine generally includes a compressor, a combustor, and a turbine, and the gas turbine engine drives the electric generator to produce electricity that may provide a portable power supply. Alternately or in addition, the electricity produced by the electric generator may be used to power a propulsor, such as a propeller or a fan enclosed by a shroud or cowling. In this manner, the propulsor may be rotationally isolated from the gas turbine engine so that rotation of the propulsor is completely independent from operation of the gas turbine engine. As used herein, the phrase "rotationally isolated" means that no mechanical coupling exists between two components to transfer rotation between the two components, in this case, the gas turbine engine and the propulsor. As a result, rotation of the propulsor is completely independent from operation of the gas turbine engine, allowing each to operate at its most efficient speed independently from the other.

Particular embodiments of the present invention may include additional design features to reduce the weight, manufacturing cost, and/or maintenance associated with the gas turbine engine. For example, the gas turbine engine may be a single-spool gas turbine engine. As used herein, a "single-spool gas turbine engine" means a gas turbine engine in which a single spool or shaft, which may include multiple segments, connects the turbine to the compressor so that the turbine and compressor rotate at the same speed. The single spool or shaft may also connect the gas turbine engine to the electric generator so that the turbine and electric generator rotate at the same speed. The use of a single spool or shaft reduces the weight and parts associated with the gas turbine engine, simplifying manufacture, maintenance, and repairs compared to multi-spool and/or geared systems. In addition, the reduced weight associated with a single-spool gas turbine engine reduces the need for a separate lube oil system to lubricate and cool the rotating components of the gas turbine engine. As a result, in particular embodiments the gas turbine engine may include non-lubricated bearings and/or an integrally bladed rotor that further reduce manufacturing, maintenance, and repair costs. As used herein, "non-lubricated bearings" means that the bearings are not supplied external lubrication, such as from a lube oil system, during operation of the gas turbine engine.

<FIG> provides a side cross-section view of a gas turbine propulsion system <NUM> that includes a power generation system <NUM> according to one embodiment of the present invention. In the particular embodiment shown in <FIG>, the gas turbine propulsion system <NUM> includes a gas turbine engine <NUM>, an electric generator <NUM>, an electric motor <NUM>, and a propulsor <NUM>. The power generation system <NUM> generally includes the gas turbine engine <NUM> and the electric generator <NUM>. As will be described in more detail, the electric motor <NUM> and propulsor <NUM> are rotationally isolated from the gas turbine engine <NUM> so that the propulsor <NUM> rotates independently from operation of the gas turbine engine <NUM> at all times. A shroud <NUM> supported by struts <NUM> may surround the gas turbine engine <NUM> and propulsor <NUM> to define a fluid flow path <NUM> from the propulsor <NUM> to the gas turbine engine <NUM>. If present, the shroud <NUM> focuses the airflow produced by the propulsor <NUM> that enters the gas turbine engine <NUM>, as well as the airflow that bypasses the gas turbine engine <NUM> and exits the shroud <NUM> as thrust.

<FIG> provides an enlarged side cross-section view of the gas turbine engine <NUM> and electric generator <NUM> shown in <FIG>. In the particular embodiment shown in <FIG> and <FIG>, the gas turbine engine <NUM> is located in the fluid flow path <NUM> downstream from the propulsor <NUM>. The gas turbine engine <NUM> generally includes a compressor <NUM>, combustors <NUM> downstream from the compressor <NUM>, and a turbine <NUM> downstream from the combustors <NUM>, as is known in the art. The compressor <NUM> includes a rotor <NUM> with one or more alternating stages of rotating blades <NUM> and fixed vanes <NUM> that progressively increase the pressure of the working fluid entering the compressor <NUM>. The combustors <NUM> mix the compressed working fluid with fuel and ignite the mixture to generate combustion gases having a high temperature, pressure, and velocity. The turbine <NUM> includes a rotor <NUM> with one or more alternating stages of rotating blades <NUM> and fixed vanes <NUM> to extract work from the combustion gases exiting the combustors <NUM>. In the particular embodiment shown in <FIG> and <FIG>, the compressor <NUM> is a single stage, axial-flow compressor, and the turbine <NUM> is a two-stage axial-flow turbine. However, unless specifically recited in the claims, the gas turbine engine <NUM> included in the present invention is not limited to any particular design or size and may include a multi-stage axial or radial-flow compressor <NUM>, one or more combustors <NUM>, and an axial or radial-flow turbine <NUM> with one or more stages.

Gas turbine engines are generally more efficient at higher turbine inlet temperatures which may damage the rotating blades in the turbine. As a result, the rotating blades are often hollow so that cooling may be supplied through the rotor to the hollow rotating blades to prevent damage from the higher turbine inlet temperatures. In the present invention, the rotational isolation between the gas turbine engine <NUM> and the propulsor <NUM> allows the gas turbine engine <NUM> to operate at lower turbine inlet temperatures than what may otherwise be preferred to achieve a desired efficiency for the gas turbine engine <NUM>. The lower turbine inlet temperatures in turn reduce the need for internal cooling to the rotating blades <NUM> in the turbine <NUM>. As a result, in particular embodiments of the present invention, the rotor <NUM> in the turbine <NUM> may be an integrally bladed rotor <NUM> or "blisk" in which the rotating blades <NUM> are solid and integrally formed as a solid piece with the rotor <NUM>. The integrally bladed rotor <NUM> may be manufactured by additive printing, casting, machining from a solid piece of material, or welding individual blades <NUM> to the rotor <NUM>, as is known in the art. The resulting integrally bladed rotor <NUM> reduces the complexity, weight, and cost of manufacturing and assembly by avoiding the intricacy of hollow blades, dovetail connections to the rotor, and forced cooling through the rotor and blades.

The gas turbine engine <NUM> may include one or more spools or shafts that rotationally couple the turbine <NUM> to the compressor <NUM>, as is known in the art. In a multi-spool gas turbine engine, for example, the compressor and the turbine may each include a high pressure stage and a low pressure stage, and a first spool may connect the high pressure stage of the turbine to the high pressure stage of the compressor, while a second spool may connect the low pressure stage of the turbine to the low pressure stage of the compressor. In this manner, each turbine stage drives the corresponding compressor stage with a separate spool, with one spool inside the other spool.

In the particular embodiment shown in <FIG> and <FIG>, the gas turbine engine <NUM> is a single-spool gas turbine engine <NUM> in which a single spool or shaft <NUM> connects the turbine <NUM> to the compressor <NUM>. The single spool or shaft <NUM> may include multiple segments connected together to rotate in unison and transmit rotation of the turbine rotor <NUM> directly to the compressor rotor <NUM> without the use of gears.

The single-spool gas turbine engine <NUM> shown in <FIG> and <FIG> is lighter and generates less heat compared to a similarly-sized gas turbine engine with multiple spools or shafts and/or gears. As a result, bearings that support the rotating components of the gas turbine engine <NUM> do not require an external source of lube oil to lubricate and cool the bearings, and particular embodiments of the present invention may include non-lubricated bearings <NUM> that rotatably support the shaft <NUM> or single-spool gas turbine engine <NUM>. As shown most clearly in <FIG>, for example, the non-lubricated bearings <NUM> may support the single spool or shaft <NUM> at various positions in the gas turbine engine <NUM> and/or electric generator <NUM>. The non-lubricated bearings <NUM> may include, for example, air-lubricated bearings or ceramic bearings encapsulated in a casing that allows periodic addition of lubrication to the bearings without the ability to permit lube oil flow through the bearings during operation. The non-lubricated bearings <NUM> thus further reduce the weight, manufacturing cost, maintenance cost, and complexity of the gas turbine engine <NUM> by obviating the need for a separate lube oil system and associated pumps, sumps, and filters.

<FIG> provides an enlarged front perspective cross-section view of the electric generator <NUM> shown in <FIG> and <FIG>. The electric generator <NUM> generally includes a rotor <NUM> and a stator <NUM>, and relative movement between the rotor <NUM> and the stator <NUM> disrupts a magnetic field between the two to convert mechanical energy into electrical energy, as is known in the art. In the particular embodiment shown in <FIG> and <FIG>, the rotor <NUM> includes permanent magnets <NUM> that create the magnetic field, and the stator <NUM> includes conductive windings <NUM> so that relative movement between the permanent magnets <NUM> on the rotor <NUM> and the conductive windings <NUM> on the stator <NUM> disrupts the magnetic field and induces current flow in the conductive windings <NUM>. One of ordinary skill in the art will readily appreciate that the magnetic field may be created by a current applied to the rotor <NUM> instead of permanent magnets, or the stator <NUM> may generate the magnetic field, and the rotor <NUM> may include the conductive windings <NUM>, and the present invention is not limited to the particular configuration of the electric generator <NUM> unless specifically recited in the claims.

The electric generator <NUM> may be located outside of the shroud <NUM> or remote from the fluid flow path <NUM>, and the present invention is not limited to a particular location for the electric generator <NUM> unless specifically recited in the claims. In the particular embodiment shown in <FIG>, the electric generator <NUM> is located in the fluid flow path <NUM> upstream from the gas turbine engine <NUM> and downstream from the propulsor <NUM>. In addition, the rotor <NUM> of the electric generator <NUM> is coaxially aligned with the compressor <NUM>, the turbine <NUM>, and the turbine rotor <NUM> to avoid the need for gears or universal joints that would otherwise be needed to transfer rotational work from the gas turbine engine <NUM> to the electric generator <NUM>.

The use of a gas turbine engine to drive an electric generator is known in the art. For example, <CIT> describes a micro gas turbine in which a single-spool gas turbine engine drives a coaxially aligned electric generator to produce <NUM>-<NUM> kW of power. The power output of the electric generator may be increased by increasing the strength of the magnetic field, e.g., by incorporating larger permanent magnets on the rotor. However, the additional mass associated with larger permanent magnets produces larger centrifugal forces that tend to separate the permanent magnets from the rotor, particularly at the high rotational speeds associated with a single-spool gas turbine engine that directly drives the electric generator. Therefore, gas turbine engines that drive higher power output generators generally require multiple spools or shafts, gears, and/or transmissions that allow the electric generator to rotate at substantially lower speeds than the turbine in the gas turbine engine to prevent the centrifugal forces from separating the permanent magnets from the rotor.

In the particular embodiment shown in <FIG>, the single spool or shaft <NUM> connects the turbine rotor <NUM> to the rotor <NUM> of the electric generator <NUM> so that the turbine rotor <NUM> and the generator rotor <NUM> rotate at the same speed. Although the output power of the electric generator <NUM> is not a limitation of the present invention unless recited in the claims, in particular embodiments, the electric generator <NUM> may produce an output of greater than <NUM> MW, <NUM> MW, or <NUM> MW. Inasmuch as the turbine rotor <NUM> may rotate at <NUM>,<NUM> rpm or more, the incorporation of larger permanent magnets <NUM> on the rotor <NUM> to produce output power greater than <NUM> MW requires additional structure to hold the permanent magnets <NUM> in place. Therefore, the electric generator <NUM> may further include means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM>.

The function of the means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> is to prevent movement between the rotor <NUM> and the permanent magnets <NUM> during operations. The structure for performing this function may be any mechanical coupling with the permanent magnets <NUM> that prevents the permanent magnets <NUM> from moving with respect to the rotor <NUM>. For example, the mechanical coupling may be one or more clamps, bolts, screws, or dovetail fittings that mechanically couple some or all of the permanent magnets <NUM> to the rotor <NUM>. Alternately, the mechanical coupling may be a series of rails or other projections that extend radially from the rotor <NUM> combined with an overwrap that circumferentially surrounds the permanent magnets <NUM>. The rails or other projections engage with some or all of the permanent magnets <NUM> to transfer torque between the rotor <NUM> and the permanent magnets <NUM> and prevent the permanent magnets <NUM> from moving circumferentially with respect to the rotor <NUM>. In particular embodiments, the rails or other projections may be contoured, ribbed, tapered, or flanged to match a complementary recess in the permanent magnets <NUM>. The overwrap that circumferentially surrounds the permanent magnets <NUM> provides sufficient centripetal force against the permanent magnets <NUM> to offset the centrifugal forces caused by rotation of the rotor <NUM> to prevent the permanent magnets <NUM> from moving radially away from the rotor <NUM>. The overwrap may be a fiber or composite material sprayed or wrapped around the outer circumference of the permanent magnets <NUM>. In combination, the rails or projections and overwrap thus securely hold the permanent magnets <NUM> in contact with the rotor <NUM> to prevent circumferential and radial movement between the rotor <NUM> and the permanent magnets <NUM> during operations.

<FIG> provides an axial cross-section view of the rotor <NUM> of the electric generator <NUM> taken along line A-A of <FIG> according to one embodiment of the present invention. In this particular embodiment, the permanent magnets <NUM> are arranged circumferentially around the rotor <NUM> and extend longitudinally along the rotor <NUM> to create the magnetic field. The means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> includes multiple rails <NUM> and an overwrap <NUM>. The multiple rails <NUM> extend radially from the rotor <NUM> and may extend longitudinally along some or all of the rotor <NUM>. As shown in <FIG>, the permanent magnets <NUM> are arranged in repeating groups <NUM> of four magnets <NUM>, and the outer surface of the rotor <NUM> in contact with the permanent magnets <NUM> is substantially flat. Three permanent magnets <NUM> in each group <NUM> are sandwiched between or engaged with adjacent rails <NUM>, and one permanent magnet <NUM> in each group <NUM> has a shorter radial dimension and is on top of a rail <NUM>. In this manner, the rails <NUM> provide the mechanical coupling between the rotor <NUM> and the permanent magnets <NUM> to transfer torque between the rotor <NUM> and the permanent magnets <NUM> and prevent the permanent magnets <NUM> from moving circumferentially with respect to the rotor <NUM>. The overwrap <NUM> circumferentially surrounds the permanent magnets <NUM> to provide sufficient centripetal force against the permanent magnets <NUM> to offset the centrifugal forces caused by rotation of the rotor <NUM> to prevent the permanent magnets <NUM> from moving radially away from the rotor <NUM>. The rails <NUM> and overwrap <NUM> thus combine to provide the structure for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM>.

<FIG> provides an axial cross-section view of the rotor <NUM> of the electric generator <NUM> taken along line A-A of <FIG> according to an alternate embodiment of the present invention. As shown in <FIG>, the permanent magnets <NUM> are again arranged circumferentially around the rotor <NUM> and extend longitudinally along the rotor <NUM> to create the magnetic field, and the means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> again includes multiple rails <NUM> and an overwrap <NUM> as described with respect to <FIG>. The permanent magnets <NUM> are again arranged in eight repeating groups <NUM> of four magnets <NUM>. In this particular embodiment, however, the outer surface of the rotor <NUM> in contact with the permanent magnets <NUM> is curved, with the magnitude of the curve based on the radius of the rotor <NUM>. As a result, this particular embodiment only requires fabrication of two different magnet sizes. Specifically, the three permanent magnets <NUM> in each group <NUM> that are sandwiched between or engaged with adjacent rails <NUM> are identical to one another, and the permanent magnet <NUM> in each group <NUM> on top of a rail <NUM> differs only in its radial dimension. The use of substantially identical permanent magnets <NUM> simplifies construction by reducing the manufacturing and maintenance costs associated with the permanent magnets <NUM>.

<FIG> provides an axial cross-section view of the rotor <NUM> of the electric generator <NUM> taken along line A-A of <FIG> according to an alternate embodiment of the present invention. As shown in <FIG>, the permanent magnets <NUM> are again arranged circumferentially around the rotor <NUM> and extend longitudinally along the rotor <NUM> to create the magnetic field, and the means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> again includes multiple rails <NUM> and an overwrap <NUM> as described with respect to <FIG>. In this particular embodiment, the means further includes a recess <NUM> in some or all of the permanent magnets <NUM>. Each recess <NUM> may have a shape that is complementary to the shape of the rails <NUM> to allow each rail <NUM> to extend into a recess <NUM> of a different permanent magnet <NUM>. The mechanical coupling between the rails <NUM> and recesses <NUM> prevents the permanent magnets <NUM> from moving circumferentially with respect to the rotor <NUM>, and the overwrap <NUM> prevents the permanent magnets <NUM> from moving radially away from the rotor <NUM>. The rails <NUM>, recesses <NUM>, and overwrap <NUM> thus combine to provide the structure for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM>.

<FIG> provides an axial cross-section view of the rotor <NUM> of the electric generator <NUM> taken along line A-A of <FIG> according to an alternate embodiment of the present invention. As shown in <FIG>, the means for holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> again includes multiple rails <NUM> and recesses <NUM> in the permanent magnets <NUM>. In this particular embodiment, the rails <NUM> are T-shaped, and the recesses <NUM> in the permanent magnets <NUM> have a complementary shape to receive the T-shaped rails <NUM>. The rails <NUM> and recesses <NUM> thus provide the mechanical coupling that prevents the permanent magnets <NUM> from moving both circumferentially and radially with respect to the rotor <NUM>, and an overwrap is not needed in this embodiment to perform the function of holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM>. One of ordinary skill in the art will readily appreciate that other shapes for the rails <NUM> and recesses <NUM> would similarly perform the function of holding the permanent magnets <NUM> in place on the rotor <NUM> during operation of the gas turbine engine <NUM>, the turbine <NUM>, and/or the turbine rotor <NUM> without the need for an overwrap. For example, alternate embodiments of the present invention may include rails <NUM> and recesses <NUM> having a fir tree shape, an L-shape, a dovetail shape, etc., and the present invention is not limited to any particular shape for the rails <NUM> and recesses <NUM> unless specifically recited in the claims.

The embodiments shown in <FIG> thus allow larger and heavier permanent magnets <NUM> to be incorporated into the electric generator <NUM> to increase the output power of the electric generator <NUM>. For example, embodiments in which the single spool or shaft <NUM> rotates the rotor <NUM> of the electric generator <NUM> at the same speed as the turbine rotor <NUM> may generate an output of more than <NUM> MW, <NUM> MW, or even <NUM> MW, depending on the radius of the rotor <NUM> and the size of the permanent magnets <NUM>. This substantial output power may be used for any purpose, such as providing a portable power supply to remote geographic areas or following weather-related catastrophes.

Alternately, as shown in <FIG>, the electric generator <NUM> may be incorporated into the gas turbine propulsion system <NUM> to provide electric power to drive the electric motor <NUM> of the propulsor <NUM>. As shown by the dashed lines of <FIG>, the output from the electric generator <NUM> may be routed to an electric bus <NUM>. In this manner, the electric bus <NUM> may supply electric power to the electric motor <NUM> to drive the propulsor <NUM> or to a storage device, such as a battery <NUM>, for subsequent use by the electric motor <NUM> to drive the propulsor <NUM> when the gas turbine engine <NUM> is not operating.

<FIG> and <FIG> provide enlarged side and perspective cross-section views of the electric motor <NUM> and propulsor <NUM> shown in <FIG>. As shown in <FIG>, a casing <NUM> may surround the electric generator <NUM> and electric motor <NUM> to minimize disruption in the fluid flow path <NUM> between the electric generator <NUM> and electric motor <NUM>. However, the electric motor <NUM> and propulsor <NUM> are rotationally isolated from the gas turbine engine <NUM> so that the propulsor <NUM> rotates independently from operation of the gas turbine engine <NUM> at all times.

The electric motor <NUM> provides the sole driving force for the propulsor <NUM>. The electric motor <NUM> generally includes a rotor <NUM> and a stator <NUM>, and current flow disrupts a magnetic field between the two to convert electrical energy into mechanical energy, as is known in the art. In the particular embodiment shown in <FIG> and <FIG>, the rotor <NUM> provides the magnetic field, and the stator <NUM> includes conductive windings so that current flow through the stator <NUM> disrupts the magnetic field and induces rotational movement in the rotor <NUM>. One of ordinary skill in the art will readily appreciate that the stator <NUM> may generate the magnetic field, and the rotor <NUM> may include the conductive windings, and the present invention is not limited to the particular configuration of the electric motor <NUM> unless specifically recited in the claims.

The electric motor <NUM> may be located outside of the shroud <NUM> or remote from the fluid flow path <NUM>, and the present invention is not limited to a particular location for the electric motor <NUM> unless specifically recited in the claims. In the particular embodiment shown in <FIG>, <FIG>, and <FIG>, the electric motor <NUM> is located in the fluid flow path <NUM> upstream from the gas turbine engine <NUM> and downstream from the propulsor <NUM>. A shaft <NUM> couples the rotor <NUM> to the propulsor <NUM>, and the rotor <NUM> is coaxially aligned with the propulsor <NUM> to avoid the need for gears or universal joints that would otherwise be needed to transfer rotational work from the electric motor <NUM> to the propulsor <NUM>.

The propulsor <NUM> may be a propeller that rotates outside of the shroud <NUM> or a fan enclosed by the shroud <NUM> or cowling. In either event, the propulsor <NUM> may be either axially offset from or coaxially aligned with the gas turbine engine <NUM> and/or electric motor <NUM>, depending on the particular design. In the particular embodiment shown in <FIG>, <FIG>, and <FIG>, the propulsor <NUM> is a fan <NUM> surrounded by the shroud <NUM> or cowling and coaxially aligned with the electric motor <NUM> and gas turbine engine <NUM>. Rotation of the fan <NUM> increases the pressure and velocity of air in the fluid flow path <NUM>. As a result, air from the fluid flow path <NUM> entering the compressor <NUM> is supercharged, increasing the efficiency of the gas turbine engine <NUM>. In particular embodiments, the increased efficiency on the gas turbine engine <NUM> may allow for a reduction in the turbine inlet temperature of approximately <NUM> degrees Fahrenheit or produce an increase of approximately <NUM> kW for the same turbine inlet temperature.

Referring again to <FIG>, the rotational isolation between the gas turbine engine <NUM> and the propulsor <NUM> allows the gas turbine propulsion system <NUM> to operate in multiple modes, depending on the particular operational needs. For example, the efficiency of the gas turbine propulsion system <NUM> may be optimized by operating the gas turbine engine <NUM> at its most efficient power level and varying the power level or speed of the propulsor <NUM> as needed to produce a desired amount of thrust. In this operating mode, the gas turbine engine <NUM> drives the electric generator <NUM> to produce <NUM> MW, <NUM> MW, <NUM> MW, or more of electric power which is then supplied through the electric bus <NUM> to either the electric motor <NUM> to drive the propulsor <NUM> or to the battery <NUM>. As another example, the sound signature of the gas turbine propulsion system <NUM> may be minimized by operating the propulsor <NUM> with the gas turbine engine <NUM> secured. The electric bus <NUM> may supply electric power from the battery <NUM> to the electric motor <NUM> to drive the propulsor <NUM> to produce a desired amount of thrust.

The embodiments previously described and illustrated with respect to <FIG> may also provide a method for starting the gas turbine engine <NUM> without requiring a separate starter motor. For example, the electric bus <NUM> may supply electric power from the battery <NUM> or an external source of power to the electric generator <NUM>, causing the electric generator <NUM> to act as an electric motor. The single spool or shaft <NUM> then transmits rotation from the generator rotor <NUM> to the compressor rotor <NUM> and turbine rotor <NUM>. The combustors <NUM> may be ignited once the compressor rotor <NUM> and turbine rotor <NUM> reach a minimum sustained speed, typically approximately <NUM>% of idle speed. Electric power to the electric generator <NUM> and fuel flow to the combustors <NUM> may be gradually increased until the combustors can provide sufficient combustion gases to the turbine <NUM> to achieve a self-sustaining speed for the gas turbine engine <NUM>, typically approximately <NUM>% of idle speed. At the self-sustaining speed, the single spool or shaft <NUM> again transmits rotation from the turbine rotor <NUM> to the generator rotor <NUM> as the turbine <NUM> accelerates to the steady state operating speed of approximately <NUM>%. At this speed, the electric generator <NUM> may be connected to a load or power electronics to produce electric output.

Claim 1:
A power generation system (<NUM>), comprising:
a shroud (<NUM>) that defines a fluid flow path (<NUM>);
a single-spool gas turbine engine (<NUM>) in said fluid flow path (<NUM>) comprising:
a compressor (<NUM>),
a combustor (<NUM>) downstream from said compressor (<NUM>), and
a turbine (<NUM>) downstream from said compressor (<NUM>) and said combustor (<NUM>);
an electric generator (<NUM>) in said fluid flow path (<NUM>) upstream from said single-spool gas turbine engine (<NUM>), wherein said electric generator (<NUM>) comprises a rotor (<NUM>) coaxially aligned with said turbine (<NUM>); and
a shaft (<NUM>) that connects said turbine (<NUM>) to said rotor (<NUM>) of said electric generator (<NUM>) so that said turbine (<NUM>) and said rotor (<NUM>) rotate at the same speed.