Gripping system with clamp device and method of using the same

What is claimed is: 1. A gripping system for securing a work piece, the gripping system comprising: a clamp device including a body and a ball screw mechanism, the body defining a central axis, the body including a jaw portion that has multiple grip fingers, the ball screw mechanism including a shaft and a holder assembly, the holder assembly secured in a fixed position to the body, the shaft extending through the holder assembly and configured for displacement along the central axis of the body, a distal tip of the shaft engaging the grip fingers of the jaw portion; a rotary actuator connected to the shaft of the ball screw mechanism; and a control circuit communicatively connected to the rotary actuator, wherein the control circuit is configured to control the rotary actuator to drive rotation of the shaft relative to the holder assembly causing displacement of the shaft relative to the body along the central axis, wherein the displacement of the shaft causes the distal tip of the shaft to force the grip fingers to move in a radial direction away from the central axis to provide a clamp force on the work piece. 2. The gripping system of claim 1 , wherein the jaw portion of the body is cylindrical and is configured to be inserted into a hole of the work piece, and wherein the control circuit is configured to control the rotary actuator to drive rotation of the shaft while the jaw portion is within the hole of the work piece to force the grip fingers of the jaw portion to move in the radial direction away from the central axis until respective engagement surfaces of the grip fingers engage an inner surface that defines the hole to secure the work piece to the clamp device. 3. The gripping system of claim 1 , wherein the rotary actuator has a set number of steps per revolution, and the control circuit is configured to control the rotary actuator to rotate a predetermined number of the steps to force the grip fingers of the jaw portion to move in the radial direction away from the central axis until respective engagement surfaces of the grip fingers define a designated outer diameter for engaging the work piece. 4. The gripping system of claim 1 , wherein the control circuit is configured to control the rotary actuator to drive rotation of the shaft independent of feedback from a sensor. 5. The gripping system of claim 1 , wherein the grip fingers of the jaw portion are arranged circumferentially around the central axis and adjacent grip fingers are separated by slits, the grip fingers configured to radially deflect relative to the central axis. 6. The gripping system of claim 1 , wherein the jaw portion of the body includes a first clamping region and a second clamping region, the second clamping region disposed between the first clamping region and a base portion of the body along the central axis, the first clamping region defined by a first set of engagement surfaces of the grip fingers and having a first configurable range of diameters, the second clamping region defined by a second set of engagement surfaces of the grip fingers and having a second configurable range of diameters that has greater diameter sizes than the first configurable range of diameters. 7. The gripping system of claim 1 , wherein the holder assembly of the ball screw mechanism is mounted to a base portion of the body, the base portion connected to the jaw portion. 8. The gripping system of claim 1 , wherein the holder assembly of the ball screw mechanism includes a housing and ball bearings held within the housing, wherein the shaft of the ball screw mechanism defines helical raceways that receive the ball bearings therein to mechanically connect the shaft to the holder assembly. 9. The gripping system of claim 1 , wherein the shaft of the ball screw mechanism extends into an interior channel of the body and is coaxial with the central axis, the distal tip of the shaft engaging interior surfaces of the grip fingers that face towards the central axis. 10. The gripping system of claim 1 , wherein the clamp device is mounted on a robotic arm. 11. A method for gripping a work piece, the method comprising: inserting a jaw portion of a clamp device into a hole of the work piece, the clamp device including the jaw portion and a ball screw mechanism, the jaw portion having multiple grip fingers and defining a central axis, the ball screw mechanism including a shaft and a holder assembly, the holder assembly secured in a fixed position relative to the jaw portion, the shaft connected to a rotary actuator and extending through the holder assembly, the shaft configured for displacement along the central axis, a distal tip of the shaft engaging the grip fingers; and controlling the rotary actuator, via one or more processors, to drive rotation of the shaft relative to the holder assembly while the jaw portion is within the hole of the work piece, wherein the rotation of the shaft causes displacement of the shaft relative to the jaw portion and the distal tip of the shaft forces the grip fingers to move in a radial direction away from the central axis to provide a clamp force on an inner surface that defines the hole of the work piece for securing the work piece to the clamp device. 12. The method of claim 11 , wherein the rotary actuator has a set number of steps per revolution, and the rotary actuator is controlled to rotate a predetermined number of the steps to force the grip fingers of the jaw portion to move in the radial direction away from the central axis until respective engagement surfaces of the grip fingers define a designated outer diameter for engaging the inner surface of the work piece that defines the hole. 13. The method of claim 11 , wherein the rotary actuator is controlled to drive rotation of the shaft independent of feedback from a sensor. 14. The method of claim 11 , wherein the clamp device is mounted on a robotic arm, and the method further comprises controlling the robotic arm to change positions of the clamp device while the work piece is secured to the clamp device via the clamp force provided by the grip fingers of the jaw portion on the inner surface of the work piece to move the work piece. 15. The method of claim 11 , wherein the rotary actuator is controlled to drive rotation of the shaft in a first direction relative to the holder assembly to cause the grip fingers to provide the clamp force on the inner surface of the work piece, and the method further comprises controlling the rotary actuator to drive rotation of the shaft in an opposite, second direction relative to the holder assembly to cause the grip fingers to inwardly move towards the central axis and release the clamp force on the inner surface of the work piece. 16. A clamp device comprising: a body defining a central axis, the body including a base portion and a jaw portion, the jaw portion having multiple grip fingers; and a ball screw mechanism including a shaft and a holder assembly, the holder assembly mounted in a fixed position to the base portion of the body, the shaft extending through the holder assembly and configured for linear displacement relative to the holder assembly, wherein the shaft extends into the body and is coaxial with the central axis, a distal tip of the shaft engaging interior surfaces of the grip fingers, wherein forced rotation of the shaft relative to the holder assembly causes linear displacement of the shaft relative to the body along the central axis, and the distal tip forces the grip fingers to move in a radial direction away from the central axis for engaging a work piece. 17. The clamp device of