Printed capacitive liquid level sensor for fire suppression

What is claimed is: 1. A fire suppressant storage device ( 20 ) comprising: a tank ( 22 ) having a first port and an interior for storing a fire suppressant; and a discharge assembly mounted to the first port and comprising: a discharge valve ( 48 ); and a discharge conduit ( 50 ) at least partially within the interior and having: an interior surface ( 60 ); and an exterior surface ( 58 ), wherein the discharge assembly further comprises: a capacitive gauge ( 80 ) on the discharge conduit comprising: a first conductor ( 82 A); a second conductor ( 82 B) spaced apart from the first conductor; a plurality ( 180 A) of first branches ( 182 A) of the first conductor extending away from the second conductor on the discharge conduit; and a plurality ( 180 B) of second branches ( 182 B) of the second conductor extending away from the first conductor on the discharge conduit opposite respective said first branches. 2. The fire suppressant storage device of claim 1 wherein the gauge is along the exterior surface. 3. The fire suppressant storage device of claim 1 wherein: the first branches are a plurality of groups at intervals along the first conductor; and the second branches are a plurality of groups at intervals along the second conductor. 4. The fire suppressant storage device of claim 1 wherein the gauge further comprises: a first insulative layer ( 90 ) between: the first conductor; and the discharge conduit; and a second insulative layer ( 94 ) over the first conductor and the second conductor. 5. The fire suppressant storage device of claim 4 wherein the first and second insulative layers are polymeric layers. 6. The fire suppressant storage device of claim 4 wherein the first and second insulative layers comprise a polyimide. 7. The fire suppressant storage device of claim 1 wherein the gauge further comprises: the plurality ( 180 A) of first branches ( 182 A) of the first conductor extend circumferentially away from the second conductor; and the plurality ( 180 B) of second branches ( 182 B) of the second conductor extend circumferentially away from the first conductor opposite respective said first branches. 8. The fire suppressant storage device of claim 1 further comprising: said fire suppressant within the tank interior, the discharge conduit at least partially immersed in the fire suppressant. 9. The fire suppressant storage device of claim 8 wherein: said fire suppressant comprises a clean agent. 10. The fire suppressant storage device of claim 8 further comprising: a compressed gas propellant in a headspace of the tank. 11. The fire suppressant storage device of claim 8 wherein: the tank has a second port; a closure ( 130 ) seals the second port; and first ( 92 A) and second ( 92 B) leads from the gauge extend to the closure. 12. The fire suppressant storage device of claim 8 further comprising: an electronics module ( 132 ) electrically coupled to the gauge and comprising a function generator ( 324 ) for supplying an AC signal to the gauge. 13. The fire suppressant storage device of claim 12 wherein: the electronics module is configured to split an output of the function generator between said signal to the gauge and a signal to a reference capacitor ( 320 ). 14. A method for using the fire suppressant storage device of claim 1 , the method comprising: applying a voltage across the gauge; and measuring a response of the gauge. 15. The method of claim 14 wherein: the applying a voltage comprises applying an AC signal; and the measuring a response comprises taking a difference between said AC signal and an AC signal applied to a reference capacitor ( 320 ). 16. The method of claim 14 further comprising: from the response, determining a level of said fire suppressant in the tank. 17. A method for manufacturing a fire suppressant discharge assembly, the discharge assembly comprising: a discharge valve ( 48 ); and a discharge conduit ( 50 ) having: an interior surface ( 60 ); and an exterior surface ( 58 ), the method comprising: forming, in situ on the discharge conduit, a gauge ( 80 ) having a first conductor ( 82 A) and a second conductor ( 82 B), the forming including providing a plurality of branches of the first conductor on the discharge conduit extending away from the second conductor and a plurality of branches of the second conductor on the discharge conduit extending away from the first conductor. 18. The method of claim 17 further comprising: prior to the forming in situ of the first conductor and the second conductor, forming in situ a first polymeric layer on the discharge conduit; and after the forming in situ of the first conductor and the second conductor, forming in situ a second polymeric layer over the first conductor, the second conductor, and the first polymeric layer. 19. The method of claim 17 wherein: the forming in situ of the first conductor and the second conductor comprises spraying. 20. The method of claim 17 further comprising: connecting respective first and second leads ( 92 A, 92 B) to the first and second conductors by conductive paste.