Drill cuttings circular separator

We claim: 1. A vibratory separator comprising: a base; a separator housing movably connected with the base, the separator housing including an inlet chute, a discharge chute, a sidewall defining an axial centerline and having a discharge spout, and at least one screen mounted within the separator housing; a first circular force generator (CFG) disposed on or about the separator housing, the first CFG arranged in an annular ring outwardly adjacent the inlet chute; a second CFG disposed upon the bottom of the separator housing, the second CFG arranged in an annular ring outwardly adjacent the discharge chute; at least one sensor in communication with the separator housing; and a controller in communication with the at least one sensor and with at least one CFG selected from the first CFG and the second CFR, wherein each of the first CFG and the second CFG produces a rotating force vector, wherein the rotating force vector includes a magnitude, a phase, and a frequency, and wherein the first CFG and the second CFG create at least one vibration profile of the at least one screen mounted within the separator housing, wherein the controller is configured to operably control the rotating force vector based of an operating function, comprising the at least one vibration profile of the at least one screen, that is measured by the at least one sensor, wherein the magnitude, the phase and the frequency are independently controllable by the controller, and further wherein the controller is configured to change the rotating force vector. 2. The vibratory separator of claim 1 , wherein the controller enables forces and phase angles of the first CFG and the second CFG to adjust automatically and achieve a targeted motion of the vibratory separator. 3. The vibratory separator of claim 1 , wherein the first CFG and the second CFG each comprise a plurality of imbalanced masses rotatable in a plane parallel the axial centerline. 4. The vibratory separator of claim 1 , further comprising a vacuum system proximate said at least one screen. 5. The vibratory separator of claim 1 , wherein the first CFG and the second CFG each comprise at least two servo motors that include imbalanced masses at independent angular positions to provide infinite force and phase adjustments. 6. The vibratory separator of claim 1 , the sidewall having a semicircular slot extending therethrough in a plane perpendicular to an axial centerline of the sidewall, a seal extending fully about the inner circumference of the sidewall and adjacent the slot, a stop adjacent the slot and extending about the inner circumference of the sidewall, the stop being opposed to and displaced from the seal across the slot. 7. The vibratory separator of claim 6 , wherein the at least one screen is mounted in the separator housing between the seal and the stop, the at least one screen including a screen frame and tensioned screen cloth mounted to the screen frame, and the screen frame fitting closely within the separator housing. 8. The vibratory separator of claim 7 , wherein the screen frame is compressed between the seal and the stop when said seal is inflated. 9. The vibratory separator of claim 8 , further comprising a gasket positioned between the screen frame and the stop. 10. The vibratory separator of claim 1 , as used in a method of separating drill cuttings from drilling fluid at a drilling rig, the method comprising: providing a drilling rig; installing a plurality of the circular vibratory screen separator of claim 5 onto the drilling rig wherein at least two of the circular vibratory screen separators are movably connected to a manifold; producing a drilling fluid laden with drill cuttings from a wellbore in communication with the drilling rig; and, introducing the drilling fluid laden with drill cuttings into the inlet chute of each of the at least two circular vibratory screen separators through the manifold, and separating the drill cuttings from the drilling fluid. 11. A method comprising: providing a drilling rig; installing at least one circular vibratory screen separator onto the drilling rig, the at least one circular vibratory screen separator comprising: a base; a separator housing movably connected with the base, the separator housing including a top having an inlet chute, a bottom having a liquid discharge chute, a cylindrical sidewall defining an axial centerline and having a discharge spout, and at least one screen mounted within the separator housing; a first circular force generator (CFG) disposed upon the top of the separator housing, the first CFG arranged in an annular ring adjacent the inlet chute; a second CFG disposed upon the bottom of the separator housing, the second CFG arranged in an annular ring adjacent the discharge chute; and, wherein each of the first CFG and the second CFG produces a rotating force vector, wherein the rotating force vector includes a magnitude, a phase, and a frequency, and wherein the first CFG and the second CFG create at least one vibration profile of the at least one screen mounted within the separator housing; producing a drilling fluid laden with drill cuttings from a wellbore; introducing the drilling fluid laden with drill cuttings into the inlet chute of the at least one circular vibratory screen separator, and separating the drill cuttings from the drilling fluid; measuring an operating function, comprising the at least one vibration profile of the at least one screen, via at least one sensor; and, operably controlling and changing, via a controller, the rotating force vector based on the measured operating function wherein the magnitude, the phase and the frequency are independently controllable by the controller. 12. The method of claim 11 , wherein the controller enables forces and phase angles of each of the first CFG and second CFG to adjust automatically and achieve a targeted motion of the at least one circular vibratory screen separator. 13. The method of claim 11 wherein the first CFG and second CFG each comprise a plurality of imbalanced masses which rotate in a plane parallel the axial centerline. 14. The method of claim 11 wherein at least two circular vibratory screen separators are installed onto the drilling rig, wherein the at least two of the circular vibratory screen separators are movably connected to a manifold, introducing the drilling fluid laden with drill cuttings into the inlet chute of each of the at least two circular vibratory screen separators through the manifold, and separating the drill cuttings from the drilling fluid. 15. The method of claim 11 , wherein the at least one circular vibratory screen separator further comprising a vacuum system proximate the at least one screen.