Pressure exchange noise reduction

What is claimed is: 1. An energy recovery apparatus comprising: a rotor including a duct and configured to move the duct and low pressure fluid in the duct to a first position, and to move the duct and high pressure fluid in the duct to a second position; a high pressure input port disposed in a first end cover, the high pressure input port configured to admit high pressure fluid for compressing low pressure fluid and displacing compressed fluid while the rotor is in the first position; a high pressure output port disposed in a second end cover, the high pressure output port configured to release compressed fluid while the rotor is in the first position; a low pressure output port disposed in the first end cover, the low pressure output port configured to release decompressed high pressure fluid from the duct at low pressure while the duct is at the second position; a low pressure input port disposed in the second end cover, the low pressure input port configured to admit low pressure fluid into the duct to displace decompressed fluid while the duct is at the second position; a first high pressure seal surface in the second end cover and adjacent the low pressure input port; and a first groove disposed on a first outer surface of the second end cover and between the first high pressure seal surface and the low pressure input port, the first groove configured to release pressure and decompress high pressure fluid in the duct as the rotor moves the duct over the first groove and into alignment with the low pressure input port, wherein the first groove extends through only a portion of the first outer surface of the second end cover such that an innermost surface of the first groove forms at least a portion of the first outer surface of the second end cover; and a second high pressure seal surface in the first end cover and adjacent the low pressure output port. 2. The apparatus of claim 1 , further comprising a second groove disposed on a second outer surface of the first end cover and between the second high pressure seal surface and the low pressure output port, the second groove configured to release pressure and decompress high pressure fluid in the duct as the rotor moves the duct into alignment with the low pressure output port. 3. The apparatus of claim 1 , further comprising: a first low pressure seal surface in the first end cover and adjacent the high pressure input port; a third groove disposed on a second outer surface of the first end cover and between the first low pressure seal surface and the high pressure input port, the third groove configured to increase pressure and compress low pressure fluid in the duct as the rotor moves the duct over the third groove and into alignment with the high pressure input port; a second low pressure seal surface in the second end cover and adjacent the high pressure output port; and a fourth groove disposed on the first outer surface of the second end cover and between the second low pressure seal surface and the high pressure output port, the fourth groove configured to increase pressure and compress low pressure fluid in the duct as the rotor moves the duct into alignment with the high pressure output port. 4. The apparatus of claim 1 , further comprising a membrane separation device configured to extract a concentrate from high pressure feed-water. 5. The apparatus of claim 4 , wherein: the high pressure input port is configured to admit high pressure concentrate from the membrane separation device, the low pressure output port is configured to release concentrate at low pressure, the low pressure input port is configured to admit feed-water at low pressure from a low pressure pump, and the high pressure output port is configured to release feed-water at high pressure for communication to the membrane separation device. 6. The apparatus of claim 1 , wherein the first groove has parallel sides. 7. The apparatus of claim 1 , wherein the first groove has tapered sides. 8. The apparatus of claim 1 , wherein the first groove has a constant depth over a more than half the length of the groove. 9. The apparatus of claim 1 , wherein the depth of the first groove increases approaching the low pressure output port. 10. An energy recovery apparatus comprising: a rotor configured to move a duct containing low pressure fluid into alignment with a high pressure fluid source port for replacement of low pressure fluid in the duct with high pressure fluid, the rotor further configured to move the duct while containing high pressure fluid into alignment with a low pressure release port for release of the high pressure fluid within the duct to low pressure; a high pressure seal surface adjacent to the low pressure release port, the high pressure seal surface for maintaining high pressure on fluid in the duct during movement of the duct into alignment with the low pressure release port; and a first groove disposed on an outer surface of an end cover and extending through only a portion of the outer surface of the end cover such that an innermost surface of the first groove forms at least a portion of the outer surface, wherein the first groove is configured to be coupled to the rotor, wherein the groove forms a transition between the high pressure seal surface and the low pressure release port, the first groove configured to bleed off pressure from fluid in the duct as the rotor moves the duct over the first groove into alignment with the low pressure release port, and wherein the outer surface is at an interface between the end cover and the rotor. 11. The apparatus of claim 10 , further comprising: a low pressure seal surface adjacent the high pressure fluid source port, the low pressure seal surface for maintaining low pressure on fluid in the duct during movement of the duct into alignment with the high pressure fluid source port; and a second groove disposed on the outer surface of the end cover and forming a transition between the low pressure seal surface and the high pressure fluid source port, the second groove configured to bleed high pressure fluid into the duct from the high pressure fluid source port as the rotor moves the duct over the second groove into alignment with the high pressure fluid source port. 12. The apparatus of claim 10 , further comprising a shell enclosing the rotor and including an aperture for admitting high pressure fluid into a space between the shell and the rotor for suspending the rotor during rotation within the shell. 13. The apparatus of claim 10 , further comprising an impeller disposed in the low pressure port and configured to impart a rotation to the rotor. 14. The apparatus of claim 10 , wherein the first groove forms an impeller surface configured to impart rotational force to the rotor. 15. The apparatus of claim 10 , wherein the first groove includes a radius. 16. The pressure recovery device comprising: a feed-water end cover; a low pressure feed-water source port disposed in the feed-water end cover; a concentrate end cover; a high pressure concentrate source port disposed in the concentrate end cover; a duct configured to receive low pressure feed-water from the low pressure feed-water source port and high pressure concentrate from the high pressure concentrate source port; a rotor configured to position the duct in alignment with the low pressure feed-water source port, and to position the duct in alignment with the high pressure concentrate source port; a high pressure sealing surface in a first face of the feed-water end cover and adjacent the low pressure feed-water source port, the