The present disclosure generally relates to apparatus, systems, and kits of parts for knock-down heavy-duty transportable torque tool assemblies capable of onsite field-servicing of high-pressure heavy-duty hydraulic cylinders used in heavy-duty construction equipment and industrial machinery. The embodiments disclosed herein pertain to assemblies comprising modular knock-down components that may be mounted onto the bed of a field service truck and configured as needed to provide loosening and retorquing of piston-retaining nuts.

The invention relates to a system and method for the robotic and automated, coordinated, collaborative changing of mill liners, the configuration thereof allowing the full robotic and automated manipulation of the method, by means of a remote command entered by an operator by means of a processor of a control system. The system of the invention comprises: at least one robotic manipulator (2) located outside of the mill; at least one robotic manipulator (3) located inside the mill; a control system; and a series of tools that are taken and manipulated automatically by the robotic manipulators (2, 3), such that the control system sends a command to operate the at least one external manipulator (2) and the at least one internal manipulator (3) to carry out the steps of changing at least one liner of the mill in a coordinated manner with collaboration between at least the two robotic manipulators.

A control apparatus causes a robot device to move a suction head to a predetermined position at which a workpiece is fed and attempt to pick up the workpiece with the suction head at the predetermined position. Upon determining that the suction head has yet to pick up the workpiece, the control apparatus causes the robot device to rotationally move the suction head spirally in a horizontal direction while causing the suction head to perform a suction operation for the workpiece, and estimates a direction in which the workpiece is located with respect to the predetermined direction based on a change in compressed air pressure during the rotational movement of the suction head.

A control apparatus causes a robot device to move a suction head to a predetermined position at which a workpiece is fed and attempt to pick up the workpiece with the suction head at the predetermined position. Upon determining that the suction head has yet to pick up the workpiece, the control apparatus causes the robot device to rotationally move the suction head spirally in a horizontal direction while causing the suction head to perform a suction operation for the workpiece, and estimates a direction in which the workpiece is located with respect to the predetermined direction based on a change in compressed air pressure during the rotational movement of the suction head.

The invention relates to a fastening element for fastening to a workpiece, said fastening element comprising at least a first workpiece element having a first opening and a second workpiece element having a second opening aligned with the first opening, wherein the fastening element has a first contact section having a first contact surface for contact with a region of the first workpiece element surrounding the first opening and a second contact section having a second contact surface for contact with a region of the second workpiece element surrounding the second opening, with the first contact section and the second contact section being connected to one another by means of a reshaping section, and with a rivet section extending from the second contact section in a direction facing away from the reshaping section. The invention further relates to a corresponding component assembly and to a method of manufacturing such a component assembly.

The invention relates to a device or tool (1) for gripping a liner in order to carry out a method of removing same from, and installing same in, the shell of a mill, which comprises a rigid structure or frame (2) forming a support for containing the components needed for the operation thereof, a coupling element (6) that allows the device to be secured or disposed on at least one end of a manipulation device, such as a robotic manipulator, comprises at least one claw or pincer (7) for holding at least one bolt by the head, the tool being designed to allow the adjustment of the relative position thereof in order to align the pincers to the positions of the holes of each liner, the at least one pincer (7) having a configuration allowing said claws to open and close so as to adjust the size thereof to the size of the bolt being gripped, wherein the at least one pincer or claw (7) has at least one sensor, thereby enabling mill liners to be installed and removed, the tool being based on the fastening elements that hold the liners in position.

The invention relates to a device or tool (1) for gripping a liner in order to carry out a method of removing same from, and installing same in, the shell of a mill, which comprises a rigid structure or frame (2) forming a support for containing the components needed for the operation thereof, a coupling element (6) that allows the device to be secured or disposed on at least one end of a manipulation device, such as a robotic manipulator, comprises at least one claw or pincer (7) for holding at least one bolt by the head, the tool being designed to allow the adjustment of the relative position thereof in order to align the pincers to the positions of the holes of each liner, the at least one pincer (7) having a configuration allowing said claws to open and close so as to adjust the size thereof to the size of the bolt being gripped, wherein the at least one pincer or claw (7) has at least one sensor, thereby enabling mill liners to be installed and removed, the tool being based on the fastening elements that hold the liners in position.

The present invention relates to an operation parameter regulation unit (50) for use with a bolting system having a plurality of networked electrically powered torque tools (10, 11) and/or drive portions of torque tools (10, 11) for simultaneous tightening of industrial threaded fasteners (40), the operation parameter regulation unit (50) including: a processing unit (53); an output unit (51) connected and/or integrated with the processing unit (53); an input unit (52) connected and/or integrated with the processing unit (53); an activation unit (55) connected and/or integrated with the processing unit (53) for activating operation units of the plurality of networked electrically powered torque tools (10, 11) and/or drive portions of torque tools (10, 11); and a control unit (54) for controlling operation parameters (41) of each of the plurality of networked electrically powered torque tools (10, 11) and/or drive portions of torque tools (10, 11) to maintain a difference between the operation parameters (41) within a predetermined value.

A fastening device for fastening a bolt to a fastening target object, wherein the bolt has a bolt head female screw section in an inner circumferential surface of a recess provided in an upper surface of a bolt head section. The fastening device includes a tension rod having a rod male screw section engaging the bolt head female screw section; a drive socket circumferentially surrounding the tension rod and having a lower end section with a grasper for laterally grasping the bolt head section; a supporter circumferentially surrounding the drive socket and having a lower end section protruding downward beyond a lower end section of the drive socket; a sensor for sensing compression force acting on the supporter in the upward/downward direction; a first motor for rotating the tension rod around an axis extending in the upward/downward direction; and a second motor for rotating the drive socket around the axis.

A fastening device for fastening a bolt to a fastening target object, wherein the bolt has a bolt head female screw section in an inner circumferential surface of a recess provided in an upper surface of a bolt head section. The fastening device includes a tension rod having a rod male screw section engaging the bolt head female screw section; a drive socket circumferentially surrounding the tension rod and having a lower end section with a grasper for laterally grasping the bolt head section; a supporter circumferentially surrounding the drive socket and having a lower end section protruding downward beyond a lower end section of the drive socket; a sensor for sensing compression force acting on the supporter in the upward/downward direction; a first motor for rotating the tension rod around an axis extending in the upward/downward direction; and a second motor for rotating the drive socket around the axis.