Air data probe with fluid intrusion sensor

The invention claimed is: 1. An air data probe comprising: a stationary housing assembly including a mounting plate secured over an opening in a housing to define a probe cavity; an air data measurement unit rotatable about a longitudinal axis of the air data probe, relative to the stationary housing assembly; a fluid sensing unit disposed proximate to an interface between the housing assembly and the air data measurement unit, the fluid sensing unit comprising: a first electrically conductive sensing surface; and a second electrically conductive sensing surface physically and dielectrically spaced from the first sensing surface; and a combination ring fastened to an inner side of the mounting plate, the combination ring including a dielectric substrate portion having a first side with a conductive metal ring portion formed concentrically between inner and outer edges of the dielectric substrate; wherein the combination ring is fastened with the first side facing the inner side of the mounting plate and such that only the dielectric substrate portion contacts the inner side of the mounting plate, for dielectrically spacing the conductive metal ring portion from the first sensing surface. 2. The air data probe of claim 1 , wherein the mounting plate includes an outer side adapted to be substantially flush with an air vehicle skin when the air data probe is installed. 3. The air data probe of claim 1 , wherein the air data measurement unit comprises: a hub disposed about the longitudinal axis of the air data probe; a sensing fin mounted to an outer side of the hub; and a shaft connected to an inner side of the hub, and extending into a probe cavity. 4. The air data probe of claim 3 , wherein the air data measurement unit further comprises: a cover plate fastened to the hub and the strut for rotation with the sensing fin about the longitudinal axis. 5. The air data probe of claim 1 , further comprising: a tortuous fluid collection path, at least a portion of which is defined by a plurality of annular spaces between overlapping projections and recesses disposed along the interface between the air data measurement unit and the housing assembly. 6. The air data probe of claim 5 , wherein the tortuous fluid intrusion path extends between an external location along the interface, and a fluid collection space defined proximate to the fluid sensing unit. 7. An air data probe comprising: a stationary housing assembly; an air data measurement unit rotatable about a longitudinal axis of the air data probe, relative to the stationary housing assembly, the air data measurement unit having at least one sensor for measuring an aspect or a parameter of flight data; and a fluid sensing unit disposed proximate to an interface between the housing assembly and the air data measurement unit, the fluid sensing unit comprising: a first electrically conductive sensing surface connected to an electrical circuit; a second electrically conductive sensing surface connected to the electrical circuit, the second electrically conductive sensing surface physically spaced and dielectrically spaced apart from the first sensing surface; and a fluid collection space defined between the spaced apart first and second electrically conductive sensing surfaces; wherein the fluid collection space is adapted to collect a portion of an infiltrating fluid other than air such that collected fluid bridges the fluid collection space between the first and second electrically conductive sensing surfaces, resulting in a change of resistance in the electrical circuit. 8. The air data probe of claim 1 , wherein the inner side of the mounting plate includes a pocket formed on an inner side of the mounting plate adapted to physically and dielectrically space the conductive metal ring portion from the first sensing surface. 9. The air data probe of claim 1 , wherein the dielectric substrate portion is also adapted to form a substrate for a printed wiring board. 10. The air data probe of claim 1 , wherein a space between the first sensing surface and the second sensing surface defines a fluid collection and sensing region for the fluid sensing unit. 11. A method for sensing fluid intrusion, the method comprising: collecting at least a portion of an intruding fluid other than air at an exterior location along an interface between a stationary housing assembly and a rotatable air data measurement unit; directing the fluid to a fluid sensing unit disposed proximate to an interface between the housing assembly and the air data measurement unit, the fluid sensing unit comprising: a first electrically conductive sensing surface connected to an electrical circuit; a second electrically conductive sensing surface connected to the electrical circuit, the second electrically conductive sensing surface physically spaced and dielectrically spaced apart from the first sensing surface; and a fluid collection space defined between the spaced apart first and second electrically conductive sensing surfaces, adapted to collect a portion of an infiltrating fluid other than air such that collected fluid bridges the fluid collection space; and measuring an electrical resistance value in the fluid sensing unit between the first and second electrically conductive sensing surfaces, resulting in a change of resistance in the electrical circuit. 12. The method of claim 11 , further comprising: comparing the measured electrical resistance value to at least one of a baseline electrical resistance value and a minimum acceptable electrical resistance value, the at least one value corresponding to a maximum acceptable fluid contamination level. 13. The method of claim 12 , further comprising: upon determining that the measured electrical resistance value is less than the baseline electrical resistance value or the minimum electrical resistance value, providing an indication corresponding to unwanted fluid intrusion into the transducer assembly. 14. The method of claim 11 , wherein the interface includes a tortuous path extending generally along a plurality of annular spaces between the stationary housing assembly and the rotatable air data measurement unit. 15. The air data probe of claim 7 , further comprising: a dielectric spacer ring fastened to an inner side of the mounting plate; and a conductive metal ring fastened over the dielectric spacer ring such that a surface of the metal ring is physically and dielectrically spaced from the inner side of the mounting plate; wherein the first sensing surface includes a surface on the inner side of the mounting plate, and the second sensing surface includes a surface of the metal ring physically and dielectrically spaced from the first sensing surface. 16. The air data probe of claim 7 , wherein the air data measurement unit comprises: a hub disposed about the longitudinal axis of the air data probe; a sensing fin mounted to an outer side of the hub; and a shaft connected to an inner side of the hub, and extending into a probe cavity. 17. The air data probe of claim 16 , wherein the air data measurement unit further comprises: a cover plate fastened to the hub and the strut for rotation with the sensing fin about the longitudinal axis. 18. The air data probe of claim 7 , further comprising: a tortuous fluid collection path, at least a portion of which is defined by a plurality of annular spaces between overlapping projections and recesses disposed along the interface between the air data measurement unit and the housing assembly.