Electrohydraulic valve including a vibration-resistant, flexible hermetic seal

What is claimed is: 1. A vibration-resistant, flexible metallic seal for use in an electrohydraulic servo valve (EHSV), the EHSV comprising an armature, an armature support comprising a base, and a flapper, the seal surrounding a portion of the flapper, the seal having a first end, a second end, a thickness along a length of the seal between the first end and the second end, the thickness being defined between first and second outer surfaces of the seal, and one or a plurality of convolutions between the first end and the second end, the first end disposed between and hermetically connected to the flapper and the armature, the second end disposed within a first opening and hermetically connected to the base, wherein the seal comprises: a non-porous metal that comprises a first fraction of the thickness; a porous metal comprising a plurality of pores that comprises a second fraction of the thickness; and an elastomeric material encompassed by the plurality of pores of the second fraction of the thickness, wherein the second fraction comprises one or both of the first and second outer surfaces of the seal. 2. The vibration-resistant, flexible metallic seal of claim 1 , wherein the non-porous metal comprises a first Ni—Co alloy. 3. The vibration-resistant, flexible metallic seal of claim 2 , wherein the porous metal comprises a partially-etched, second Ni—Co alloy, the second Ni—Co alloy having a different phase composition as compared to the first Ni—Co alloy. 4. The vibration-resistant, flexible metallic seal of claim 1 , wherein the elastomeric material is infiltrated into the plurality of pores of the second fraction. 5. The vibration-resistant, flexible metallic seal of claim 1 , wherein the first end has a smaller diameter as compared to a diameter of the second end. 6. A torque motor, comprising: the armature support comprising the base, an armature-flapper support, and a plurality of springs, the base having the first opening, the armature-flapper support having a second opening, the base and armature-flapper support spaced apart from each other, the springs coupled between the base and the armature-flapper support; the armature coupled to the armature-flapper support and having a third opening; the flapper coupled to the flapper support and to the armature, the flapper extending through the first and third openings, and extending at least partially into the second opening; and the vibration-resistant, flexible metallic seal of claim 1 . 7. An electrohydraulic valve, comprising: a nozzle housing including a first housing inlet, a second housing inlet, and a housing outlet; a first nozzle mounted within the nozzle housing, the first nozzle having a first nozzle inlet and a first nozzle outlet, the first nozzle inlet in fluid communication with the first housing inlet; a second nozzle mounted within the nozzle housings, the second nozzle having a second nozzle inlet and a second nozzle outlet, the second nozzle inlet in fluid communication with the second housing inlet; and the torque motor of claim 6 . 8. A vibration-resistant, flexible metallic seal for use in an electrohydraulic servo valve (EHSV), the EHSV comprising an armature, an armature support comprising a base, and a flapper, the seal surrounding a portion of the flapper, the seal having a first end, a second end, a thickness along a length of the seal between the first end and the second end, the thickness being defined between first and second outer surfaces of the seal, and a plurality of convolutions between the first end and the second end, the first end disposed between and hermetically connected to the flapper and the armature, the second end disposed within a first opening and hermetically connected to the base, wherein the seal comprises: a non-porous metal that comprises a first fraction of the thickness; a porous metal comprising a plurality of pores that comprises a second fraction of the thickness, wherein the porous metal is formed by chemically etching an etch-suscpetible metal from a composite metal that comprises both the etch-susceptible metal and an etch-insuscpetible metal; and an elastomeric material encompassed by the plurality of pores of the second fraction of the thickness, wherein the first fraction comprises both of the first and second outer surfaces of the seal, and wherein the second fraction is disposed in between the first and second outer surfaces of the seal. 9. The vibration-resistant, flexible metallic seal of claim 8 , wherein the non-porous metal comprises a first Ni—Co alloy. 10. The vibration-resistant, flexible metallic seal of claim 9 , wherein the porous metal comprises a partially-etched, second Ni—Co alloy, the second Ni—Co alloy having a different phase composition as compared to the first Ni—Co alloy. 11. The vibration-resistant, flexible metallic seal of claim 8 , wherein the elastomeric material is infiltrated into the plurality of pores of the second fraction. 12. The vibration-resistant, flexible metallic seal of claim 8 , wherein the first end has a smaller diameter as compared to a diameter of the second end. 13. A torque motor, comprising: the armature support comprising the base, an armature-flapper support, and a plurality of springs, the base having the first opening, the armature-flapper support having a second opening, the base and armature-flapper support spaced apart from each other, the springs coupled between the base and the armature-flapper support; the armature coupled to the armature-flapper support and having a third opening; the flapper coupled to the flapper support and to the armature, the flapper extending through the first and third openings, and extending at least partially into the second opening; and the vibration-resistant, flexible metallic seal of claim 8 . 14. An electrohydraulic valve, comprising: a nozzle housing including a first housing inlet, a second housing inlet, and a housing outlet; a first nozzle mounted within the nozzle housing, the first nozzle having a first nozzle inlet and a first nozzle outlet, the first nozzle inlet in fluid communication with the first housing inlet; a second nozzle mounted within the nozzle housings, the second nozzle having a second nozzle inlet and a second nozzle outlet, the second nozzle inlet in fluid communication with the second housing inlet; and the torque motor of claim 13 .