Cabin blower system

The invention claimed is: 1. A gas turbine engine for an aircraft, the gas turbine engine comprising: a cabin blower and rotor bow mitigation system, the cabin blower and rotor bow mitigation system comprising: a cabin blower compressor mechanically coupled to one or more spools of the gas turbine engine; an electric machine mechanically coupled to the cabin blower compressor; and a controller configured to control the cabin blower and rotor bow mitigation system so that: in a cabin blower mode of operation, rotation of the cabin blower compressor is mechanically driven by the one or more spools, wherein the rotation of the cabin blower compressor in the cabin blower mode compresses air received through a manifold and provides a compressed output flow of air for delivery to a cabin of the aircraft; in a rotor bow mitigation mode of operation, rotation of the cabin blower compressor is driven by the electric machine using electrical power from an electrical power source, wherein the rotation of the cabin blower compressor in the rotor bow mitigation mode sucks or blows a flow of air through a core of the gas turbine engine to remove heat from the core. 2. The gas turbine engine of claim 1 , in which the controller is further configured to control the cabin blower and rotor bow mitigation system so that: in the rotor bow mitigation mode of operation, the electric machine and/or an additional electric machine of the cabin blower and rotor bow mitigation system drives rotation of one or more spools of the gas turbine engine. 3. The gas turbine engine of claim 1 , in which the controller is configured to operate the cabin blower and rotor bow mitigation system in the rotor bow mitigation mode in response to making a determination the gas turbine engine has shut down. 4. The gas turbine engine of claim 1 , in which the controller is further configured to control the cabin blower and rotor bow mitigation system so that: in a hybrid flight mode of operation, the cabin blower compressor is driven by the electric machine using electrical power from the electrical power source and provides the compressed output flow of air to the cabin of the aircraft. 5. The gas turbine engine of claim 4 , in which the controller is configured to operate the cabin blower and rotor bow mitigation system in the hybrid flight mode in response to making a determination the aircraft is descending. 6. The gas turbine engine of claim 1 , in which the electrical power source comprises an energy storage system. 7. The gas turbine engine of claim 6 , in which the controller is further configured to control the cabin blower and rotor bow mitigation system so that: in a charging mode of operation, the energy storage system is charged using electrical power generated by the electric machine and/or an additional electric machine using mechanical power extracted from the one or more spools of the gas turbine engine. 8. The gas turbine engine of claim 7 , in which the controller is configured to operate the cabin blower and rotor bow mitigation system in the charging mode in response to making a determination the aircraft is landing. 9. The gas turbine engine of claim 1 , in which the electric machine is a first electric machine and the cabin blower and rotor bow mitigation system further comprises: a second electric machine arranged to receive mechanical power from the one or more spools of the gas turbine engine; and the controller comprises: a power management system electrically connected to the first electric machine and the second electric machine. 10. The gas turbine engine of claim 9 , wherein the electrical power source is electrically connected to the power management system, whereby the first electric machine and/or second electric machine can receive electric power from the electrical power source via the power management system. 11. The gas turbine engine of claim 1 , wherein the cabin blower compressor is arranged in fluid communication with a gas path of the gas turbine engine. 12. The gas turbine engine of claim 1 , wherein: in the cabin blower mode, ram air or fan delivery air is supplied to the cabin blower compressor, and in the rotor bow mitigation mode, one or more valves are opened or closed to fluidly connect the cabin blower compressor to a gas path of the core. 13. The gas turbine engine of claim 12 , being of geared turbofan type. 14. An aircraft comprising the gas turbine engine of claim 1 . 15. A method of operating a cabin blower and rotor bow mitigation system of a gas turbine engine of an aircraft, the gas turbine engine comprising the cabin blower and rotor bow mitigation system, the cabin blower and rotor bow mitigation system comprising: a cabin blower compressor mechanically coupled to one or more spools of the gas turbine engine; an electric machine mechanically coupled to the cabin blower compressor; and a controller configured to control the cabin blower and rotor bow mitigation system so that: in a cabin blower mode of operation, rotation of the cabin blower compressor is mechanically driven by the one or more spools, wherein the rotation of the cabin blower compressor in the cabin blower mode compresses air received through a manifold and provides a compressed output flow of air for delivery to a cabin of the aircraft; in a rotor bow mitigation mode of operation, rotation of the cabin blower compressor is driven by the electric machine using electrical power from an electrical power source, wherein the rotation of the cabin blower compressor in the rotor bow mitigation mode sucks or blows a flow of air through a core of the gas turbine engine to remove heat from the core; the method comprising: during flight of the aircraft, using power extracted from the one or more spools of the gas turbine engine of the aircraft, driving the cabin blower compressor to provide the compressed output flow of air to the cabin of the aircraft; and after shutting down the engine, using the electric machine powered by the electrical power from the electrical power source, driving the cabin blower compressor to provide the flow of air through the core of the gas turbine engine to remove heat from the core. 16. The method of claim 15 , further comprising: after shutting down the engine, using the electric machine and/or an additional electric machine powered by the electrical power from the electrical power source, driving rotation of the one or more spools of the gas turbine engine. 17. The method of claim 16 , in which the electric machine and/or the additional electric machine drives the rotation of the one or more spools at a speed of less than 1,500 rpm. 18. The method of claim 15 , further comprising: during a descent phase of the flight of the aircraft, using the electric machine powered by the electrical power from the electrical power source, driving the cabin blower compressor to provide the compressed output flow of air to the cabin of the aircraft. 19. The method of claim 15 , wherein the electrical power source comprises an energy storage system and the method further comprises, during a landing phase of the flight of the aircraft: extracting, by the electric machine and/or an additional electric machine, mechanical power from a spool of the one or more spools of the gas turbine engine and generating electrical power therefrom; and charging the energy storage system using the generated electrical power.