Embodiments of the present invention relate to electrical power distribution systems for aircraft and methods of providing electrical power to aircraft systems.
Traditionally, to provide electrical power to essential and non-essential electrical loads, aircraft have relied on generators that are driven by the propelling gas turbine engines and in some cases on an auxiliary power unit (APU), which generates power independently of the generators. In the event of failure of these systems, a “ram air turbine” (RAT) has been used to maintain power to the essential aircraft loads. Essential aircraft loads include the avionics systems, for example, and any other flight-critical equipment. Non-essential aircraft loads include cabin lighting, food preparation and entertainment systems, for example, and other equipment that is not flight-critical. The RAT comprises a turbine/propeller that is retractably releasable from the under-carriage of the aircraft to extend into the external airflow to be driven thereby and thus drive a generator. RATs are inefficient because almost all of the time, they are not utilized, yet they add weight to the aircraft. Additionally, functionality testing of the RAT is required by annually performing a test flight without passengers on-board. Both RATs and APUs are inefficient ways of generating power and there is a need to reduce consumption of aviation fuel wherever possible, due to environmental and cost considerations.
An embodiment of the invention provides a method of providing electrical power to an aircraft. The method comprises selectively sourcing power from a plurality of power sources, the power sources comprising one or more generators driven by an engine, and at least one other power source comprising one or more batteries, one or more fuel cells and/or one or more thermo-electric power sources.
Further, an embodiment of the invention provides an electrical power distribution system for an aircraft. The electrical power distribution system comprises a plurality of power sources comprising one or more engine-driven generators, and at least one other power source comprising one or more batteries, one or more fuel cells and/or one or more thermo-electric power sources. The electrical power distribution system further comprises an electrical power bus connecting the plurality electrical power sources to loads of the aircraft, and a controller configured to selectively source power from each of the plurality of power sources.
There follows a detailed description of embodiments of the invention by way of example only with reference to the accompanying drawings, in which:
The thermal electrical generation means are shown and described in a co-pending British patent application in the name of GE Aviation Systems Ltd and having an application reference of 249731/16389, the disclosure of which is incorporated herein by reference. This source of power comprises an array of thermocouples mounted on the exhaust section of the engines which utilize waste exhaust heat that would otherwise be discarded.
As shown by the reference numerals 6 and 7, the RAT and the APU have been eliminated, as they are no longer required.
In the embodiment shown in
The selective sourcing or co-ordination of power from an appropriate one or more of the power sources is controlled by a controller of the power distribution system. Under normal conditions, power is derived from the fuel cells, the batteries and/or the thermo-electric power sources in any desired combination. Under normal conditions, the choice of power source can be made so as to maximize the efficiency of the power distribution system, i.e. minimize fuel usage. Fuel cells produce water in operation, which in accordance with an embodiment of the invention, can be used in the toilet and hand wash facilities of the aircraft. This correspondingly allows a reduction in the amount of water carried at take-off. The fuel cells and the thermo-electric power source are thus preferred means of deriving power in normal operation, so that water can be generated while at the same time taking advantage of the efficiency of the thermo-electric power source.
The relative power levels producible by each of the power sources is roughly 90-120 kW per engine-driven generator, 15-30 kW per fuel cell, 15 kW per battery (approx. ½ hour life) and 70 kW per engine through thermoelectric waste heat generation.
Under emergency conditions, power is diverted to essential loads away from non-essential loads. The power distribution system described herein can be retrofitted to existing aircraft whereby the RAT and APU can be removed. Embodiments of the invention are also compatible with aircraft in which one or both of the RAT and APU are retained, in which case, the power distribution system would provide high levels of redundancy and hence safety.
Number | Date | Country | Kind |
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1118314.2 | Oct 2011 | GB | national |