Flow restricting slip joint clamps and methods for use in a nuclear reactor jet pump

What is claimed is: 1. A clamp for a slip joint formed by a juncture of a diffuser and an inlet mixer in a nuclear reactor, the clamp comprising: at least two opposite clamp arms shaped to fit inside of the diffuser and against the inlet mixer in the slip joint; a leaf spring in a first arm of the two opposite clamp arms, wherein the leaf spring is configured to bias the inlet mixer in a transverse direction against a second arm of the two opposite clamp arms with the clamp closed around the inlet mixer and without significantly transversely loading the diffuser; and an O-ring seated in a perimeter of the two opposite clamp arms, wherein the O-ring fills the slip joint, and wherein the O-ring is configured to bias against the inlet mixer separately from the spring biasing the inlet mixer. 2. The clamp of claim 1 , further comprising: a joint moveably connecting the two opposite clamp arms to permit movement of the two clamp arms around the inlet mixer, wherein the O-ring is adjustable to move in a transverse direction and directly contact the inlet mixer so as to limit fluid flow past the inlet mixer and out of the slip joint. 3. The clamp of claim 2 , wherein the two opposite clamp arms are two annular halves that join to form a continuous annulus around an entire upper and inner perimeter of the diffuser, and wherein the O-ring is seated in and moves with an inner surface of only one of the two annular halves. 4. The clamp of claim 3 , wherein the joint is a pin allowing rotation of the two annular halves with respect to each other about a single axis with no other relative movement. 5. The clamp of claim 2 , further comprising: a biasing drive connected to and moving the O-ring and open to an outside surface of the clamp. 6. The clamp of claim 5 , wherein the biasing drive is captured in an outer bore of the outside surface, wherein the outer bore connects to an inner groove housing the O-ring in the inner surface. 7. The clamp of claim 6 , wherein the biasing drive includes a threaded cap, an internal spring, and a plunger that drive the O-ring. 8. The clamp of claim 7 wherein the plunger extends from the outer bore to the inner groove to contact and drive the O-ring. 9. The clamp of claim 2 , wherein the O-ring is fabricated entirely of at least one of a stainless steel alloy, a zirconium alloy, and an aluminum alloy. 10. The clamp of claim 2 , further comprising: an axial mount on one of the clamp arms, wherein the axial mount is configured to secure to only an exterior of the diffuser so as to prevent relative movement between the one clamp arm and the diffuser. 11. The clamp of claim 2 , wherein the spring is a leaf spring captured in one of the two opposite clamp arms, and wherein the O-ring is axially below the leaf spring. 12. The clamp of claim 1 , wherein the two opposite clamp arms are semi-circular and join to create a continuous annulus, and wherein the O-ring extends around an entire inner surface of the annulus. 13. The clamp of claim 1 , further comprising: a biasing drive connected to and moving the O-ring and open to an outside surface of the clamp. 14. The clamp of claim 13 , wherein the biasing drive is captured in an outer bore of the outside surface, wherein the outer bore connects to an inner groove housing the O-ring in an inner surface of the clamp arms. 15. The clamp of claim 14 , wherein the biasing drive includes a threaded cap, an internal spring, and a plunger that drive the O-ring. 16. The clamp of claim 1 , wherein the O-ring is fabricated entirely of at least one of a stainless steel alloy, a zirconium alloy, and an aluminum alloy.