Variable capacity screw compressor and method

What is claimed is: 1. A variable capacity screw compressor comprising: a rotor housing comprising: a suction port, a working chamber, a discharge port, and at least two screw rotors that include a female screw rotor and a male screw rotor being positioned within the working chamber for cooperatively compressing a fluid; one or more first bearings positioned close to the discharge port, wherein the one or more first bearings are configured to withstand radial forces in operation; one or more second bearings positioned close to the discharge port and abutting the one or more first bearings, wherein the one or more second bearings are configured to withstand axial forces in operation; a bearing housing, wherein of the one or more first bearings and the one or more second bearings, the bearing housing is configured to directly support only the one or more first bearings; a bearing cover, wherein of the one or more first bearings and the one or more second bearings, the bearing cover is configured to directly support only the one or more second bearings, the bearing housing being disposed physically between the rotor housing and the bearing cover; wherein the suction port, the at least two screw rotors, and the discharge port are sized in relation to a selected rotational speed, the selected rotational speed having an optimum peripheral velocity that is independent of a peripheral velocity of the at least one screw rotor at a synchronous motor rotational speed for a rated screw compressor capacity, the optimum peripheral velocity is a constant product including the selected rotational speed and a radius of the at least one screw rotor of the at least two screw rotors; a permanent magnet motor configured to drive the at least one screw rotor at the selected rotational speed when the compressor is operated at a full-load capacity, the selected rotational speed being greater than the synchronous motor rotational speed at the rated screw compressor capacity; and a variable speed drive configured to receive a command signal from a controller and to generate a control signal that drives the motor at the selected rotational speed, wherein the suction port is sized and located to provide a reduced approach velocity and reduce turbulence for the fluid entering the working chamber, the discharge port is sized larger than theoretically necessary to provide a thermodynamic optimum size, and the suction port and the discharge port are configured to reduce a flow loss. 2. A screw compressor comprising: a chamber including: a suction port and a discharge port; at least two screw rotors positioned in the chamber, the at least two screw rotors configured to compress a fluid between the suction port and the discharge port; wherein the suction port, the at least two screw rotors, and the discharge port are sized in relation to a selected rotational speed, the selected rotational speed having an optimum peripheral velocity that is independent of a peripheral velocity of the at least one screw rotor at a synchronous motor rotational speed for a rated screw compressor capacity, the optimum peripheral velocity is a constant product including the selected rotational speed and a radius of the at least one screw rotor of the at least two screw rotors; wherein the suction port is sized and located to provide a reduced approach velocity and reduce turbulence for the fluid entering the chamber, the discharge port is sized larger than theoretically necessary to provide a thermodynamic optimum size, and the suction port and the discharge port are configured to reduce a flow loss; one or more first bearings positioned close to the discharge port, wherein the one or more first bearings are configured to withstand radial forces in operation; one or more second bearings positioned close to the discharge port and abutting the one or more first bearings, wherein the one or more second bearings are configured to withstand axial forces in operation; a bearing housing, wherein of the one or more first bearings and the one or more second bearings, the bearing housing is configured to directly support only the one or more first bearings; a bearing cover, wherein of the one or more first bearings and the one or more second bearings, the bearing cover is configured to directly support only the one or more second bearings, the bearing housing being disposed physically between the chamber and the bearing cover, and a muffler, wherein the bearing cover being disposed within the muffler. 3. A screw compressor comprising: a chamber including: a suction port and a discharge port; at least two screw rotors positioned in the chamber, the at least two screw rotors configured to compress a fluid between the suction port and the discharge port; wherein the suction port, the at least two screw rotors, and the discharge port are sized in relation to a selected rotational speed, the selected rotational speed having an optimum peripheral velocity that is independent of a peripheral velocity of the at least one screw rotor at a synchronous motor rotational speed for a rated screw compressor capacity, the optimum peripheral velocity is a constant product including the selected rotational speed and a radius of the at least one screw rotor of the at least two screw rotors; wherein the suction port is sized and located to provide a reduced approach velocity and reduce turbulence for the fluid entering the chamber, the discharge port is sized larger than theoretically necessary to provide a thermodynamic optimum size, and the suction port and the discharge port are configured to reduce a flow loss; a plurality of bearings positioned close to the discharge port, the plurality of bearings configured to withstand forces of the one or more screw rotors in operation; a bearing housing configured to directly support only a first bearing of the plurality of bearings, wherein the first bearing of the plurality of bearings is disposed physically between the chamber and a second bearing of the plurality of bearings and abuts the second bearing of the plurality of bearings, wherein the first of the plurality of bearings is configured to withstand radial forces in operation and the second of the plurality of bearings is configured to withstand axial forces in operation; and a muffler, wherein the bearing housing is disposed physically between the muffler and the chamber. 4. The screw compressor of claim 2 , wherein the one or more first bearings are disposed physically between the chamber and the one or more second bearings. 5. The screw compressor of claim 3 , further comprising a bearing cover configured to directly support the second bearing of the plurality of bearings, wherein the bearing housing is disposed physically between the chamber and the bearing cover in an axial direction. 6. The variable capacity screw compressor of claim 1 , wherein the optimum peripheral velocity is in a range between 131 feet per second to 164 feet per second. 7. The variable capacity screw compressor of claim 1 , wherein the optimum peripheral velocity is between 137 feet per second to 147 feet per second. 8. The variable capacity screw compressor of claim 1 , wherein the at least two screw rotors each have a length that is in a range of 20% to 30% smaller than screw rotors of a conventionally sized screw compressor having a rated capacity same as the rated screw compressor capacity.