Port geometry for pressure exchanger

1 . A rotary isobaric pressure exchanger (IPX) for transferring pressure energy from a high pressure fluid to a low pressure fluid, comprising: a cylindrical rotor configured to rotate circumferentially about a rotational axis and having a first end face and a second end face disposed opposite each other with a plurality of channels extending axially therethrough between respective apertures located in the first and second end faces; a first end cover having a first surface that interfaces with and slidingly and sealingly engages the first end face, wherein the first end cover has at least one first fluid inlet and at least one first fluid outlet that during rotation of the cylindrical rotor about the rotational axis alternately fluidly communicate with at least one channel of the plurality of channels, and wherein the at least one first fluid inlet has a first aperture at the first surface and the at least one first fluid outlet has a second aperture at the first surface; and a second end cover having a second surface that interfaces with and slidingly and sealingly engages the second end face, wherein the second end cover has at least one second fluid inlet and at least one second fluid outlet that during rotation of the cylindrical rotor about the rotational axis alternately fluidly communicate with at least one channel of the plurality of channels, and wherein the at least one second fluid inlet has a third aperture at the second surface and the at least one second fluid outlet has a fourth aperture at the second surface; and wherein a leading edge of at least one of the first aperture, the second aperture, the third aperture, and the fourth aperture comprises a contour that corresponds to a respective contour of a respective aperture of at least one channel of the plurality of channels. 2 . The rotary IPX of claim 1 , wherein the contour of the leading edge and the respective contour of the respective aperture form a line contact along an entire length of the contour of the leading edge upon initial fluid communication between either the first fluid inlet, the first fluid outlet, the second fluid inlet, or the second fluid outlet and the at least one channel of the plurality of channels. 3 . The rotary IPX of claim 2 , wherein the contour of the leading edge comprises a concave shape. 4 . The rotary IPX of claim 3 , wherein the contour of the leading edge and the respective contour of the at least one channel both comprises a curved shape. 5 . The rotary IPX of claim 2 , wherein the line contact extends in a radial direction relative to the rotational axis. 6 . The rotary IPX of claim 1 , wherein the leading edge of the first aperture comprises the contour that corresponds to the respective contour of the respective aperture of at least one channel on the first end face. 7 . The rotary IPX of claim 6 , wherein the first end cover comprises a spotface formed in the first surface adjacent to the leading edge. 8 . The rotary IPX of claim 1 , wherein the leading edge of the second aperture comprises the contour that corresponds to the respective contour of the respective aperture of at least one channel on the first end face. 9 . The rotary IPX of claim 8 , wherein the first end cover comprises a spotface formed in the first surface adjacent to the leading edge. 10 . The rotary IPX of claim 1 , wherein the leading edge of the third aperture comprises the contour that corresponds to the respective contour of the respective aperture of at least one channel on the second end face. 11 . The rotary IPX of claim 10 , wherein the second end cover comprises a spotface formed in the second surface adjacent to the leading edge. 12 . The rotary IPX of claim 1 , wherein the leading edge of the fourth aperture comprises the contour that corresponds to the respective contour of the respective aperture of at least one channel on the second end face. 13 . The rotary IPX of claim 12 , wherein the second end cover comprises a spotface formed in the second surface adjacent to the leading edge. 14 . The rotary IPX of claim 1 , wherein a respective leading edge of each of the first aperture, the second aperture, the third aperture, and the fourth aperture comprises the contour that corresponds to the respective contour of the respective aperture of at least one channel. 15 . The rotary IPX of claim 1 , comprising a frac system having the rotary IPX, wherein the low pressure second fluid comprises a frac fluid having proppants and the high pressure second fluid comprises a proppant free fluid. 16 . A system, comprising: a hydraulic transfer system configured to transfer pressure energy from a high pressure fluid to a low pressure fluid, comprising: a rotary isobaric pressure exchanger (IPX) configured to exchange pressures between the high pressure fluid and the low pressure fluid, wherein the high pressure fluid has a pressure higher than the low pressure fluid; a sleeve; a cylindrical rotor configured to rotate circumferentially about a rotational axis and having a first end face and a second end face disposed opposite each other with a plurality of channels extending axially therethrough between respective apertures located in the first and second end faces; a first end cover having a first surface that interfaces with and slidingly and sealingly engages the first end face, wherein the first end cover has at least one first fluid inlet and at least one first fluid outlet that during rotation of the cylindrical rotor about the rotational axis alternately fluidly communicate with at least one channel of the plurality of channels, and wherein the at least one first fluid inlet has a first aperture at the first surface and the at least one first fluid outlet has a second aperture at the first surface; and a second end cover having a second surface that interfaces with and slidingly and sealingly engages the second end face, wherein the second end cover has at least one second fluid inlet and at least one second fluid outlet that during rotation of the cylindrical rotor about the rotational axis alternately fluidly communicate with at least one channel of the plurality of channels, and wherein the at least one second fluid inlet has a third aperture at the second surface and the at least one second fluid outlet has a fourth aperture at the second surface; and wherein a leading edge of at least one of the first aperture, the second aperture, the third aperture, and the fourth aperture comprises a contour that corresponds to a respective contour of a respective aperture of at least one channel of the plurality of channels. 17 . The system of claim 16 , wherein the contour of the leading edge and the respective contour of the respective aperture form a line contact along an entire length of the contour of the leading edge upon initial fluid communication between either the first fluid inlet, the first fluid outlet, the second fluid inlet, or the second fluid outlet and the at least one channel of the plurality of channels 18 . The system of claim 16 , wherein the contour of the leading edge and the respective contour of the at least one channel both comprises a curved shape. 19 . A method, comprising: rotating a cylindrical rotor of a rotary isobaric pressure exchanger about a rotational axis, wherein the cylindrical rotor comprises a plurality of channels extending between a first end face and a second end face disposed opposite each other; and forming a line contact between a contour of a leading edge of an aperture of a fluid inlet of a fir