Bypass directional control valve

The invention claimed is: 1. A bypass directional control valve comprising: a valve sleeve received in a housing, said housing having an input opening to receive a source of fluid, and said input opening communicating with two sets of inlet ports formed through said valve sleeve, and into an interior bore of said valve sleeve, two sets of outlet ports, with one on each of two axial sides of said sets of inlet ports, and extending through said valve sleeve, with said outlet and said inlet ports all being cylindrical holes, and a diameter of said sets of inlet ports being greater than a diameter of said sets of outlet ports, said outlet ports communicating to outlet openings in said housing; a valve spool movable along an axis within said bore of said valve sleeve, said valve spool having a land associated with each of said sets of said inlet ports, and a spring biasing said valve spool in a first direction such that a first land blocks a first of said sets of outlet ports, and a second land is spaced from a second of said sets of outlet ports, with a pressure tap to receive a pressure control signal to cause said valve spool to selectively move against the force of said spring such that said second land may block said second set of outlet ports and said first land opens said first set of outlet ports; said valve sleeve extends for a first axial distance between opposed ends, and a first of said sets of said inlet ports is spaced from said end by a second distance, and a ratio of said first distance to said second distance is between 3.600 and 3.615; said outlet ports in said two sets of outlet ports are circumferentially aligned, and said inlet ports in said two sets of inlet ports are circumferentially staggered between the two sets; and said valve spool extends for a first length, and a second length defined between an end of said valve spool which receives said spring, and an end of said first land which is closest to said spring, with a ratio of said first length to said second length being between 3.818 and 3.864; said first and second lands have edge breaks at an edge, and said lands have a nominal outer diameter, with an edge break outer diameter defined to a beginning of the edge break on said lands, and a ratio of said edge break outer diameter to said nominal outer diameter being between 0.995 and 1.000. 2. The control valve as set forth in claim 1 , wherein a ratio of the diameter of said inlet ports to the diameter of said outlet ports is between 1.269 and 1.348. 3. A valve sleeve comprising: a valve sleeve to be received in a housing, with two sets of inlet ports formed through said valve sleeve, and into an interior bore of said valve sleeve, and two sets of outlet ports, with one on each of two axial sides of said sets of inlet ports, and extending through said valve sleeve, with said outlet and said inlet ports all being cylindrical holes, and a diameter of said sets of inlet ports being be greater than a diameter of said outlet ports; a ratio of the diameter of said inlet ports to the diameter of said outlet ports is between 1.269 and 1.348; said valve sleeve extends for a first axial distance between opposed ends, and a first of said sets of said inlet ports is spaced from said end by a second distance, and a ratio of said first distance to said second distance is between 3.600 and 3.615; and said outlet ports in said two sets of outlet ports are circumferentially aligned, and said inlet ports in said two sets of inlet ports are circumferentially staggered between the two sets. 4. A fluid flow system comprising: a pump for delivering fluid to a downstream use, said pump delivering fluid through a pressure regulating valve, said pressure regulating valve being operable to bypass a portion of fluid to a bidirectional control valve; the bidirectional control valve including a valve sleeve received in a housing, said housing having an input opening to receive a source of fluid, and said input opening communicating with two sets of inlet ports formed through said valve sleeve, and into an interior bore of said valve sleeve, two sets of outlet ports, with one on each of two axial sides of said sets of inlet ports, and extending through said valve sleeve, with said outlet and said inlet ports all being cylindrical holes, and a diameter of said sets of inlet ports being greater than a diameter of said sets of outlet ports, said outlet ports communicating to outlet openings in said housing, and a valve spool movable along an axis within said bore of said valve sleeve, said valve spool having a land associated with each of said sets of said outlet ports, and a spring biasing said valve spool in a first direction such that a first land blocks a first of said sets of outlet ports, and a second land is spaced from a second of said sets of outlet ports, with a pressure tap to receive a pressure control signal to cause said valve spool to selectively move against the force of said spring such that said second land may block said second set of outlet ports and said first land opens said first set of outlet ports; said valve sleeve extends for a first axial distance between opposed ends, and a first of said sets of said inlet ports is spaced from said end by a second distance, and a ratio of said first distance to said second distance is between 3.600 and 3.615; said outlet ports in said two sets of outlet ports are circumferentially aligned, and said inlet ports in said two sets of inlet ports are circumferentially staggered between the two sets; said valve spool extends for a first length, and a second length defined between an end of said valve spool which receives said spring, and an end of said first land which is closest to said spring, with a ratio of said first length to said second length being between 3.818 and 3.864; and said first and second lands have edge breaks at an edge, and said lands have a nominal outer diameter, with an edge break outer diameter defined to a beginning of the edge break on said lands, and a ratio of said edge break outer diameter to said nominal outer diameter being between 0.995 and 1.000. 5. A fluid flow system as set forth in claim 4 , wherein said second set of outlet ports communicate with an outlet opening for delivering the fluid through a heat exchanger and back to a pump, and the first set of outlet ports communicate with an outlet opening for delivering fluid back to the pump without passing through the heat exchanger. 6. The fluid flow system as set forth in claim 5 , wherein a metering valve sends a control pressure to valve spool to move the valve spool to control the flow of fluid between the outlet openings. 7. The fluid flow system as set forth in claim 6 , wherein the heat exchanger is a fuel oil cooler on a gas turbine engine. 8. The fluid flow system as set forth in claim 5 , wherein the pump is a gear pump. 9. The fluid flow system as set forth in claim 4 , wherein a ratio of the diameter of said inlet ports to the diameter of said outlet ports is between 1.269 and 1.348. 10. A method of replacing a valve sleeve in a bypass directional control valve, including the steps of: removing a valve sleeve from a bypass directional control valve, and replacing said valve sleeve with a replacement valve sleeve; and wherein the replacement valve sleeve is received in a housing, said housing includes an input opening to receive a source of fluid, and said input opening communicating with two sets of inlet ports formed through said replacement valve sleeve, and into an interior bore of said replacement valve sleeve, and two sets of outlet ports with one set on each of two axial sides from said inlet ports, and extending through said replacement valve sleeve, with said out