Double piston effect lip seal seating assemblies

The invention claimed is: 1. A valve comprising: a hollow valve body; a ball disposed in a cavity of the hollow valve body, wherein the ball includes a flow port and is rotatable for controlling flow through the valve; and a seat assembly including a seat in contact with the ball, a ring positioned on an opposite side of the seat from the ball, and unidirectional lip seals, wherein the seat assembly is a double piston effect seat assembly and the seat, the ring, and the unidirectional lip seals are positioned with respect to one another for providing the double piston effect, and wherein the ring includes an axial flange, and the unidirectional lip seals include a first unidirectional lip seal that seals against an inner surface of the axial flange and a second unidirectional lip seal that seals against an outer surface of the axial flange. 2. The valve of claim 1 , comprising two connectors coupled to the hollow valve body, wherein the two connectors each include a conduit for routing flow through the valve and the seat assembly is positioned in a recess of a first connector of the two connectors. 3. The valve of claim 2 , wherein the seat assembly and the recess of the first connector are configured to allow fluid from a first side of a sealing interface between the seat and the ball to enter a first region of the recess behind the seat to push the seat against the ball, and to allow fluid from a second side of the sealing interface between the seat and the ball to enter a second region of the recess behind the seat to push the seat against the ball. 4. The valve of claim 3 , wherein the fluid from the first side of the sealing interface is fluid from the cavity of the hollow valve body, and the fluid from the second side of the sealing interface is fluid from the conduit of the first connector. 5. The valve of claim 2 , wherein the unidirectional lip seals are positioned such that, during operation, the ring acts as a piston that drives the seat against the ball in response to fluid entering behind the ring from the conduit of the first connector. 6. The valve of claim 2 , comprising an additional seat assembly positioned in a recess of a second connector of the two connectors. 7. The valve of claim 6 , wherein the additional seat assembly positioned in the recess of the second connector also includes a seat in contact with the ball, a ring positioned on an opposite side of the seat from the ball, and unidirectional lip seals; the additional seat assembly is also a double piston effect seat assembly; and the seat, the ring, and the unidirectional lip seals of the additional seat assembly are positioned with respect to one another for providing the double piston effect. 8. The valve of claim 1 , wherein the first unidirectional lip seal also seals against the seat. 9. The valve of claim 8 , wherein the unidirectional lip seals include a third unidirectional lip seal that seals against the seat in an opposite directional orientation than that of the first unidirectional lip seal. 10. The valve of claim 1 , comprising at least one spring that biases the seat toward the ball. 11. A method comprising: receiving fluid in a ball valve disposed between first and second sections of a fluid conduit, the ball valve including a ball disposed in a valve body and a seat that seals against the ball; and maintaining sealing of the seat against the ball during operation of the ball valve using a double piston effect seat assembly installed in a recess of a valve component, the double piston effect seat assembly including the seat, a piston ring, first and second lip seals oriented in opposite directions, and a third lip seal oriented in the same direction as the first lip seal, wherein the piston ring includes an axial flange, the first lip seal seals against an inner surface of the axial flange, and the third lip seal seals against an outer surface of the axial flange. 12. The method of claim 11 , wherein maintaining sealing of the seat against the ball during operation of the ball valve using the double piston effect seat assembly includes allowing fluid pressure in a portion of the recess between the valve component and the first lip seal to drive the first lip seal into the piston ring such that the piston ring is driven into the seat so as to increase sealing contact pressure of the seat against the ball. 13. The method of claim 11 , wherein maintaining sealing of the seat against the ball during operation of the ball valve using the double piston effect seat assembly includes allowing fluid pressure in a portion of the recess between the seat and the second lip seal to increase sealing contact pressure of the seat against the ball. 14. A valve comprising: a hollow valve body; a ball disposed in a cavity of the hollow valve body, wherein the ball includes a flow port and is rotatable for controlling flow through the valve; and a seat assembly including a seat in contact with the ball, a ring positioned on an opposite side of the seat from the ball, and unidirectional lip seals, wherein the seat assembly is a double piston effect seat assembly and the seat, the ring, and the unidirectional lip seals are positioned with respect to one another for providing the double piston effect, and wherein the unidirectional lip seals include a first unidirectional lip seal that is positioned along and seals against a radially inward surface of the ring and a second unidirectional lip seal that is positioned along and seals against a radially outward surface of the ring.