Rotary valve assembly for sieve beds for pressure swing adsorption control

What is claimed is: 1. A rotary control valve comprising: a product end comprising a product housing containing a product rotor and a product stator therein, the product housing comprising a chamber therein for receipt of the product rotor and the product stator, the product rotor comprising a plurality of cavities configured for alignment with ports in the product stator; an air end comprising an air housing containing an air rotor and an air stator therein, the air housing comprising a chamber therein for receipt of the air rotor and the air stator, the air rotor comprising a plurality of cavities configured for alignment with ports in the air stator; a shaft operatively connected to the product rotor and the air rotor; and a motor configured to drive the shaft, wherein the motor is provided between the stators, wherein both of the chambers are configured to hold pressurized gas therein; wherein the product stator and the air stator enclose their respective rotors within the chambers of the housings; and wherein driving of the shaft is configured to rotate the product rotor and air rotor relative to their respective stators such that the cavities in each of the rotors selectively align with ports in their respective stators. 2. The valve according to claim 1 , wherein rotors are configured to be rotated to different positions relative to their respective stators by the shaft and the alignment of the cavities of the rotors with the ports in the stators is determined based on a step in a selected PSA balance process, wherein each position is associated with one step in the selected PSA balance process. 3. The valve according to claim 1 , further comprising a driver at each of the product end and the air end, the drivers being mounted to the shaft, each driver being operatively connected to the respective rotors within the product end and air ends and configured to rotate the respective rotors during driving of the shaft. 4. The valve according to claim 3 , wherein each rotor has a mating surface corresponding to connective mating surface of its driver. 5. The valve according to claim 1 , wherein the motor is a programmable stepping motor configured to drive the shaft through a plurality of steps throughout a 360 degree cycle, wherein the product rotor and air rotor are configured to be rotated to different positions relative to their respective stators about the 360 degree cycle. 6. A method for controlling a pressure swing adsorption (PSA) process using a rotary control valve, the rotary control valve comprising a product end and an air end, the product end comprising a product housing containing a product rotor and a product stator therein and an air end comprising an air housing containing an air rotor and an air stator therein, the product housing comprising a chamber therein for receipt of the product rotor and the air housing comprising a chamber therein for receipt of the air rotor, the product rotor comprising a plurality of cavities configured for alignment with ports in the product stator and the air rotor comprising a plurality of cavities configured for alignment with ports in the air stator, the rotary control valve further comprising a shaft operatively connected to the product rotor and the air rotor a motor configured to drive the shaft, a driver at each of the product end and the air end, the drivers being mounted to the shaft, each driver being operatively connected to the respective rotors within the product end and air end and configured to rotate the respective rotors during driving of the shaft, and biasing mechanisms provided between the drivers and the product and air rotors for biasing and sealingly engaging the product and air rotors towards their respective stators; wherein the method comprises: operating the motor; driving the shaft using the motor; and rotating the product rotor and the air rotor relative to their respective stators as a result of the driving of the shaft, wherein both of the chambers are configured to hold pressurized gas therein during use of the rotary control valve; wherein the product stator and the air stator enclose their respective rotors within the chambers of the housings; and wherein the rotating of the product rotor and air rotor selectively aligns cavities in the rotors with ports of their respective stators. 7. The method according to claim 6 , wherein the motor is a programmable stepping motor configured to drive the shaft through a plurality of steps throughout a 360 degree cycle, wherein the product rotor and air rotor are configured to be rotated to different positions relative to their respective stators about the 360 degree cycle, and wherein the method further comprises: driving the shaft through the plurality of steps throughout the 360 degree cycle; and rotating the product rotor and the air rotor to different positions relative to their respective stators about the 360 degree cycle. 8. A rotary control valve comprising: a product end comprising a product housing containing a product rotor and a product stator therein, the product housing comprising a chamber therein for receipt of the product rotor and the product stator, the product rotor comprising a plurality of cavities configured for alignment with ports in the product stator; an air end comprising an air housing containing an air rotor and an air stator therein, the air housing comprising a chamber therein for receipt of the air rotor and the air stator, the air rotor comprising a plurality of cavities configured for alignment with ports in the air stator; a shaft operatively connected to the product rotor and the air rotor; and a motor configured to drive the shaft; a driver at each of the product end and the air end, the drivers being mounted to the shaft, each driver being operatively connected to the respective rotors within the product end and air end and configured to rotate the respective rotors during driving of the shaft; and biasing mechanisms provided between the drivers and the product and air rotors for biasing and sealingly engaging the product and air rotors towards their respective stators, wherein both of the chambers are configured to hold pressurized gas therein; wherein the product stator and the air stator enclose their respective rotors within the chambers of the housings; and wherein driving of the shaft is configured to rotate the product rotor and air rotor relative to their respective stators such that the cavities in each of the product and air rotors selectively align with ports in their respective stators. 9. The valve according to claim 8 , wherein rotors are configured to be rotated to different positions relative to their respective stators by the shaft and the alignment of the cavities of the rotors with the ports in the stators is determined based on a step in a selected PSA balance process, wherein each position is associated with one step in the selected PSA balance process. 10. The valve according to claim 8 , wherein the motor is provided between the stators. 11. The valve according to claim 8 , wherein each rotor has a mating surface corresponding to connective mating surface of its driver. 12. The valve according to claim 8 , wherein the motor is a programmable stepping motor configured to drive the shaft through a plurality of steps throughout a 360 degree cycle, wherein the product rotor and air rotor are configured to be rotated to different positions relative to their respective stators about the 360 degree cycle. 13. A module assembly comprising: a rotary control valve according to claim 8 , and a sieve bed module configured to receive air from the rotary control val