Minimizing mixing in a pressure exchanger

What is claimed is: 1 . A pressure exchanger comprising: a rotor configured to rotate to exchange pressure between a first fluid at a first pressure and a second fluid at a second pressure, wherein the rotor forms ducts that are routed from a first distal end of the rotor to a second distal end of the rotor; a first end cover disposed at the first distal end of the rotor, wherein the first end cover forms a high pressure in (HPIN) port configured to provide the first fluid at the first pressure in a substantially axial direction into the ducts, and wherein the first end cover forms a low pressure out (LPOUT) port configured to receive the first fluid from the ducts at a third pressure that is lower than the first pressure; and a second end cover disposed at the second distal end of the rotor, wherein the second end cover forms a low pressure in (LPIN) port configured to provide the second fluid at the second pressure into the ducts and forms a high pressure out (HPOUT) port configured to receive the second fluid from the ducts at a fourth pressure that is higher than the second pressure. 2 . The pressure exchanger of claim 1 , wherein: the first end cover comprises first radial sidewalls, a first inner sidewall, and a first outer sidewall that form the HPIN port, the first radial sidewalls being disposed between a first center of the first end cover and a first perimeter of the first end cover, the first inner sidewall being proximate the first center of the first end cover, and the first outer sidewall being proximate the first perimeter of the first end cover; the second end cover comprises second radial sidewalls, a second inner sidewall, and a second outer sidewall that form the HPOUT port, the second radial sidewalls being disposed between a second center of the second end cover and a second perimeter of the second end cover, the second inner sidewall being proximate the second center of the second end cover, and the second outer sidewall being proximate the second perimeter of the second end cover; and the first radial sidewalls of the HPIN port are at least two degrees closer to each other than the second radial sidewalls of the HPOUT port are to each other. 3 . The pressure exchanger of claim 1 , wherein leading radial sidewall of the HPIN port is configured to open relative to a corresponding duct of the rotor at least two degrees after a corresponding leading radial sidewall of HPOUT port opens relative to the corresponding duct of the rotor. 4 . The pressure exchanger of claim 1 , wherein trailing radial sidewall of the HPIN port closes relative to a corresponding duct of the rotor at least two degrees before a corresponding trailing radial sidewall of the HPOUT port closes relative to the corresponding duct of the rotor to reduce mixing of corresponding fluid between HPIN and HPOUT. 5 . The pressure exchanger of claim 1 , wherein one or more radial sidewalls of the LPOUT port are biased to reduce mixing at the LPOUT port. 6 . The pressure exchanger of claim 1 , wherein trailing radial sidewall of the LPIN port closes relative to a corresponding duct of the rotor at least two degrees before a corresponding radial sidewall of the LPOUT port closes relative to the corresponding duct of the rotor to reduce mixing of corresponding fluid between the LPIN port and the LPOUT port. 7 . The pressure exchanger of claim 1 , wherein leading radial sidewall of the LPIN port closes relative to a corresponding duct of the rotor at least two degrees before a corresponding radial sidewall of the LPOUT port closes relative to the corresponding duct of the rotor to reduce mixing of corresponding fluid between the LPIN port and the LPOUT port. 8 . The pressure exchanger of claim 2 , wherein: the first end cover forms a fillet between at least one of the first radial sidewalls and the first inner sidewall; and the fillet of the first end cover is configured to close the HPIN port relative to a duct of the rotor prior to the HPOUT port of the second end cover closes relative to the duct. 9 . The pressure exchanger of claim 2 , wherein: the first radial sidewalls of the first end cover each form a ramp; and the second radial sidewalls of the second end cover form the HPIN port without forming ramps. 10 . The pressure exchanger of claim 2 , wherein: the first radial sidewalls of the first end cover each form a ramp in a direction of rotation; and the second radial sidewalls of the second end cover form the HPIN port with a ramp in the direction of rotation, the first radial sidewalls comprising a leading sidewall and a trailing sidewall on the HPIN port that each have a corresponding ramp angle varying from about 30 degrees to about 70 degrees measured with respect to a face of the rotor. 11 . The pressure exchanger of claim 2 , wherein leading radial sidewall and trailing radial sidewall on the LPIN port form a ramp in direction of rotation, wherein the ramp has a ramp angle varying from about 30 degrees to about 70 degrees measured with respect to a face of the rotor. 12 . The pressure exchanger of claim 2 , wherein the first radial sidewalls form non-planar three-dimensional ramps defined by at least two helix at an innermost radius and outermost radius of the port. 13 . The pressure exchanger of claim 12 , wherein a corresponding ramp of the non-planar three-dimensional ramps is defined by a spiral that has a pitch that is proportional to a radius at which the corresponding ramp is located to reduce incidence. 14 . The pressure exchanger of claim 1 further comprising an insert disposed in the HPIN port, wherein the insert is configured to guide flow and to reduce flow incidence at the rotor. 15 . The pressure exchanger of claim 1 further comprising an insert disposed in the LPIN port, wherein the insert is configured to guide flow and to reduce flow incidence at the rotor. 16 . The pressure exchanger of claim 1 , wherein the first end cover forms a first spot face proximate the HPOUT port without forming a spot face at the HPIN port to reduce mixing of corresponding fluid between the HPIN port and the HPOUT port. 17 . The pressure exchanger of claim 1 , wherein the first end cover forms a second spot face proximate the LPOUT port without forming a spot face at the LPIN port to reduce mixing of corresponding fluid between the LPIN port and the LPOUT port. 18 . The pressure exchanger of claim 1 , wherein the pressure exchanger is configured to use the second fluid provided via the HPOUT port as bearing fluid and center bore fluid. 19 . A pressure exchanger comprising: a rotor configured to rotate to exchange pressure between a first fluid at a first pressure and a second fluid at a second pressure, wherein the rotor forms ducts that are routed from a first distal end of the rotor to a second distal end of the rotor; and inserts disposed in the ducts to provide a length to diameter ratio of about 5 to about 10. 20 . The pressure exchanger of claim 19 , wherein the inserts are honeycomb-shaped flow straighteners that are press-fit, shrunk-fit, or glued adhesively into the ducts.