Screen handling system

What is claimed is: 1 . A screen handling system is provided for a rock drilling device including a feed assembly, at least one rail system supporting the feed assembly for translational movement relative to a boom along a first axis, and an actuator for advancing a bit or bolt into a rock face parallel to the first axis, the screen handling system comprising: a pad disposed proximate the bit or bolt; a block having a bore that defines a second axis parallel to the first axis; a gripper at least partially disposed within and axially moveable relative to the bore in a direction along the second axis; and a drive mechanism coupled to the block that is capable of continuously rotating the pad about the second axis to a desired orientation. 2 . The screen handling system of claim 1 , wherein the gripper includes a main body that is driven axially by a hydraulic actuator, a head spaced away from the main body, and a neck that connects the head to the main body. 3 . The screen handling system of claim 2 , wherein the neck has a reduced-diameter relative to both the main body and the head. 4 . The screen handling system of claim 2 , wherein the head is conically-shaped and includes a shoulder with a plurality of hooks that extend away from the head in a direction parallel to the second axis for hooking a mesh screen. 5 . The screen handling system of claim 4 , wherein the gripper is moveable between a retracted position, in which the head of the gripper does not extend beyond a front face of the pad, and an extended position, in which the head of the gripper extends beyond the front face of the pad. 6 . The screen handling system of claim 5 , wherein the gripper is retracted from the extended position toward the retracted position once the hooks grasp a portion of the mesh screen, at which point the mesh screen is forcibly held between the head of the gripper and the front face of the pad. 7 . The screen handling system of claim 1 , wherein the drive mechanism includes a hydraulic motor, a worm gear having helical teeth and driven by the hydraulic motor along a motor axis, and a worm wheel having corresponding helical teeth that mesh with the helical teeth of the worm gear. 8 . The screen handling system of claim 7 , wherein the worm wheel is driven by the worm gear about the second axis that is perpendicular to the motor axis. 9 . The screen handling system of claim 7 , wherein the pad is driven to rotate with the worm wheel. 10 . The screen handling system of claim 7 , wherein the pad is rotatably affixed to the worm wheel. 11 . The screen handling system of claim 7 , wherein the worm wheel and the pad are capable of being rotated together an infinite number of rotations about the second axis in a first direction and in a second direction. 12 . The screen handling system of claim 7 , wherein the pad is driven by the hydraulic motor based on a fixed gear ratio between the worm gear and the worm wheel, the hydraulic motor driving the rotation of the pad when the motor is activated and stopping the rotation of the pad when the motor is deactivated. 13 . The screen handling system of claim 1 , wherein the feed assembly is actuatable along the first axis toward the mine face to engage the head of the gripper against the rock face and stabilize the boom of the mining machine against the rock face. 14 . The screen handling system of claim 1 , wherein the actuator drives the bit or bolt through a mesh screen and into the rock face once the gripper is engaged with the mesh screen and stabilized against the rock face to inhibit inadvertent movement of the feed assembly while driving the workpiece into the rock face. 15 . A rock drilling device for use on a boom of a mining machine, the rock drilling device comprising: a feed assembly; a first frame at least partially supported by the feed assembly for translational movement relative to the boom along a first axis and a second frame supported for translational movement relative to the first frame; a drill feed coupled to the second frame for rotating and advancing a bit or bolt into a rock face along a second axis that is parallel to the first axis; and a screen handler coupled to the first rail system and configured to connect to and maneuver a screen relative to the rock face by rotating the screen through an infinite number of rotations. 16 . The rock drilling device of claim 15 , wherein the screen handling system includes a pad disposed proximate the bit or bolt, a block having a bore that defines a second axis parallel to the first axis, a gripper at least partially disposed within and axially moveable relative to the bore in a direction along the second axis, and a drive mechanism coupled to the block that is capable of continuously rotating the pad about the second axis to a desired orientation. 17 . The rock drilling device of claim 16 , wherein the drive mechanism includes a hydraulic motor, a worm gear having helical teeth and driven by the hydraulic motor along a motor axis, and a worm wheel having corresponding helical teeth that mesh with the helical teeth of the worm gear, wherein the pad is driven to rotate with the worm wheel. 18 . The rock drilling device of claim 15 , wherein the feed assembly is actuatable along the first axis toward the mine face to engage the head of the gripper against the rock face and stabilize the boom of the mining machine against the rock face. 19 . A method of installing a screen on a rock face, the method comprising: grasping the screen with a stinger assembly by securing a portion of the screen between a pad and a gripper; actuating a feed assembly that supports the stinger assembly to extend toward the rock face until the screen is adjacent the rock face; continuously rotating the pad and the screen via a slew drive mechanism to precisely position the screen in a desired orientation relative to the mine face; engaging the gripper against the rock face to stabilize the feed assembly relative to the rock face; and driving a bit or bolt through the screen and into the rock face to hold the screen against the rock face. 20 . The method of claim 19 , further comprising stopping rotation of the pad and the screen by deactivating a hydraulic motor of the slew drive mechanism. 21 . The method of claim 19 , wherein grasping the screen with the stinger assembly includes advancing a head of the gripper through the screen and holding the screen with a neck of the gripper that has a reduced-diameter compared to the head to inhibit the screen from inadvertently disengaging the gripper. 22 . The method of claim 19 , further comprising continuously counter-rotating the pad and the screen via the slew drive mechanism to precisely position the screen in a desired orientation relative to the mine face. 23 . The method of claim 21 , wherein rotating and counter-rotating the pad and the screen is performed about a stinger axis along which the gripper is actuatable, and wherein driving the bit or bolt is performed along a drill axis that is parallel to the stinger axis.