Fuel spray nozzle

We claim: 1. A fuel spray nozzle for generating a spray of atomised liquid fuel in a combustor of a gas turbine engine, wherein the fuel spray nozzle includes: a fuel circuit having an inlet port for receiving a flow of liquid fuel and having an annular exit port for discharging the received fuel as a swirling fuel flow; and an annular prefilming surface downstream of the annular exit port, and configured such that the swirling fuel flow discharged from the exit port spreads, as a film of fuel, across the prefilming surface, whereupon one or more swirling air flows generated by the nozzle shear the fuel film towards a trailing edge of the prefilming surface and atomise the fuel film into a spray of fine droplets; wherein the fuel circuit has in flow series: a gallery which wraps circumferentially around the nozzle and receives the fuel flow from the inlet port; plural circumferentially spaced passages arranged in a row around the nozzle, each passage having an inlet for receiving a respective portion of the fuel flow from the gallery, a metering orifice for discharging its portion of the fuel flow, and being configured to impart a circumferential component to its discharged portion of the fuel flow; and an annular spin chamber which receives the respective discharged portions of the fuel flow from the metering orifices of the passages to form the swirling fuel flow which is discharged at the exit port; and wherein: the passages are configured such that, when the flow of liquid fuel to the inlet port is shut off, a respective differential static pressure develops across stagnant liquid fuel remaining between the inlet and the metering orifice of each passage, and the passages are further configured such that one or more selected passages develop a different differential static pressure to the remaining passages, the different differential static pressure causing a flow of purging air to enter the gallery from the combustor through the selected passages and exit through the remaining passages, thereby purging the gallery and the passages of fuel; and wherein the selected passages extend further axially into the annular spin chamber than the remaining passages to develop the different differential static pressure. 2. The fuel spray nozzle according to claim 1 , wherein an internal geometry of the selected passages is different from a corresponding internal geometry of the remaining passages to reduce a threshold differential static pressure of the selected passages relative to a corresponding threshold differential static pressure of the remaining passages, whereby a given differential static pressure developed across stagnant liquid fuel remaining between the inlets and the metering orifices of the selected and remaining passages causes a flow of purging air to enter the gallery from the combustor through the selected passages and exit through the remaining passages, thereby purging the gallery and the passages of fuel. 3. The fuel spray nozzle according to claim 2 , wherein a flow cross-sectional area of the metering orifices of the selected passages is larger than a flow cross-sectional area of the metering orifices of the remaining passages to reduce the threshold differential static pressure of the selected passages. 4. The fuel spray nozzle according to claim 2 , wherein the internal geometry of the selected passages is different from the corresponding internal geometry of the remaining passages to vary a stagnant liquid fuel meniscus contact angle in the selected passages relative to a corresponding stagnant liquid fuel meniscus contact angle of the remaining passages to reduce the threshold differential static pressure of the selected passages. 5. The fuel spray nozzle according to claim 1 , wherein: the passages are divided into plural mutually exclusive subgroups such that each subgroup contains plural of the passages and each subgroup receives its fuel from a respective branch of the gallery; the gallery is configured such that, when the flow of liquid fuel to the inlet port is shut off, the stagnant fuel remaining in each branch of the gallery is substantially isolated from the stagnant fuel remaining in the other branches of the gallery; and each subgroup contains one of the selected passages and one or more of the remaining passages. 6. The fuel spray nozzle according to claim 1 , which is a lean burn nozzle in which the fuel circuit is a mains fuel circuit, and the nozzle further includes a pilot fuel circuit, the mains fuel circuit being stageable to effect pilot-only and pilot-and-mains staging control. 7. A fuel spray nozzle for generating a spray of atomised liquid fuel in a combustor of a gas turbine engine, wherein the fuel spray nozzle includes: a fuel circuit having an inlet port for receiving a flow of liquid fuel and having an annular exit port for discharging the received fuel as a swirling fuel flow; and an annular prefilming surface downstream of the annular exit port, and configured such that the swirling fuel flow discharged from the exit port spreads, as a film of fuel, across the prefilming surface, whereupon one or more swirling air flows generated by the nozzle shear the fuel film towards a trailing edge of the prefilming surface and atomise the fuel film into a spray of fine droplets; wherein the fuel circuit has in flow series: a gallery which wraps circumferentially around the nozzle and receives the fuel flow from the inlet port; plural circumferentially spaced passages arranged in a row around the nozzle, each passage having an inlet for receiving a respective portion of the fuel flow from the gallery, a metering orifice for discharging its portion of the fuel flow, and being configured to impart a circumferential component to its discharged portion of the fuel flow; and an annular spin chamber which receives the respective discharged portions of the fuel flow from the metering orifices of the passages to form the swirling fuel flow which is discharged at the exit port; and wherein: the passages are configured such that, when the flow of liquid fuel to the inlet port is shut off, a respective differential static pressure develops across stagnant liquid fuel remaining between the inlet and the metering orifice of each passage, and an internal geometry of one or more selected passages is different from a corresponding internal geometry of the remaining passages to reduce a threshold differential static pressure of the selected passages relative to a corresponding threshold differential static pressure of the remaining passages, whereby when a given differential static pressure develops across the stagnant liquid fuel remaining between the inlets and the metering orifices of the selected and remaining passages exceeds the threshold differential static pressure of the selected passages, a flow of purging air enters the gallery from the combustor through the selected passages and exits through the remaining passages, thereby purging the gallery and the passages of fuel. 8. The fuel spray nozzle according to claim 7 , wherein a flow cross-sectional area of the metering orifices of the selected passages is larger than a flow cross-sectional area of the metering orifices of the remaining passages to reduce the threshold differential static pressure of the selected passages. 9. The fuel spray nozzle according to claim 7 , wherein the internal geometry of the selected passages is different from the corresponding internal geometry of the remaining passages to vary a stagnant liquid fuel meniscus contact angle in the selected passages relative to a corresponding stagnant liquid fuel meniscus contact angle of the remaining passages to reduce the threshold differential static pressure of the selected pas