Hydraulic brake actuator piston adjuster assembly

What is claimed is: 1. A brake actuator assembly, comprising: a housing; a piston disposed in the housing and slidably engaged therewith; a resilient member disposed within the housing and coupled to the piston; and a deformable member disposed within the housing and coupled to the piston, wherein the deformable member comprises a porous metallic material having a porous structure, and wherein each of the deformable member and the resilient member are disposed radially between a piston rod of the piston and the housing, wherein the deformable member and the resilient member are located axially between a gland of the housing and a piston head of the piston, wherein the resilient member directly contacts the gland of the housing and the deformable member directly contacts the piston head of the piston, wherein the porous metallic material undergoes a permanent deformation characterized by a localized collapsing of the porous structure of the porous metallic material proximate a loaded face of the deformable member in response to contact between the loaded face and at least one of the piston head or the resilient member. 2. The brake actuator assembly of claim 1 , wherein the resilient member and the deformable member are coupled via a thrust washer. 3. The brake actuator assembly of claim 2 , wherein the thrust washer is slidably engaged to the piston rod. 4. The brake actuator assembly of claim 1 , wherein the deformable member comprises one of a steel, a stainless steel, a tungsten carbide, a titanium, a titanium alloy, a nickel, nickel alloy, a nickel steel, a silicate, an aluminum alloy, or a ceramic. 5. The brake actuator assembly of claim 1 , wherein the deformable member comprises a tubular structure. 6. The brake actuator assembly of claim 1 , wherein the deformable member is configured to undergo the permanent deformation in response to applying a brake pressure to the piston. 7. The brake actuator assembly of claim 1 , wherein the deformable member comprises a corrugated structure. 8. The brake actuator assembly of claim 1 , wherein the resilient member comprises a Bellville spring. 9. A wheel and brake assembly for mounting on an axle, comprising: a friction stack; a wheel comprising a hub coupled to the axle; a torque bar configured to engage with the wheel and rotate a brake rotor of the friction stack; and an actuator assembly configured to apply a brake pressure to the friction stack, the actuator assembly comprising: a housing; a piston disposed in the housing and slidably engaged therewith; a resilient member disposed within the housing and coupled to the piston; and a deformable member disposed within the housing and coupled to the piston, wherein the deformable member comprises a porous metallic material having a porous structure, and wherein each of the deformable member and the resilient member are disposed radially between a piston rod of the piston and the housing, wherein the deformable member and the resilient member are located axially between a gland of the housing and a piston head of the piston, wherein the resilient member contacts the gland and the deformable member contacts the piston head, wherein the porous metallic material undergoes a permanent deformation characterized by a localized collapsing of the porous structure of the porous metallic material proximate a loaded face of the deformable member in response to contact between the loaded face and at least one of the piston head or the resilient member. 10. The wheel and brake assembly of claim 9 , wherein the resilient member and the deformable member are coupled via a thrust washer. 11. The wheel and brake assembly of claim 10 , wherein the thrust washer is slidably engaged to the piston rod. 12. The wheel and brake assembly of claim 9 , wherein the deformable member comprises one of a steel, a stainless steel, a tungsten carbide, a titanium, a titanium alloy, a nickel, nickel alloy, a nickel steel, a silicate, an aluminum alloy, or a ceramic. 13. The wheel and brake assembly of claim 9 , wherein the deformable member comprises a tubular structure. 14. The wheel and brake assembly of claim 9 , wherein the deformable member is configured to undergo the permanent deformation in response to applying the brake pressure to the piston. 15. The wheel and brake assembly of claim 14 , wherein the permanent deformation is configured to maintain an actuator piston clearance between the friction stack and the piston at a desired actuator piston clearance in response to applying the brake pressure. 16. A method of dynamically adjusting an actuator piston clearance, the method comprising: disposing a piston within a housing, the piston being slidably engaged with the housing; disposing a deformable member in the housing, wherein the deformable member comprises a porous metallic material having a porous structure, wherein the deformable member is located radially between a piston rod of the piston and the housing; disposing a resilient member within the housing; coupling the resilient member to the deformable member, wherein the resilient member is disposed radially between the piston rod and the housing; and permanently deforming the deformable member in response to applying a brake pressure to the piston, wherein the deformable member and the resilient member are located axially between a gland of the housing and a piston head of the piston, wherein the resilient member contacts the gland and the deformable member contacts the piston head of the piston, wherein the porous metallic material undergoes a permanent deformation characterized by a localized collapsing of the porous structure of the porous metallic material proximate a loaded face of the deformable member in response to contact between the loaded face and at least one of the piston head or the resilient member.