Abstract: A robotic tool has a longitudinal shaft, defining a longitudinal axis when the shaft is in a default, centered position. A lockout rod is moveable between first and second positions. In the first position, the lockout rod allows the longitudinal shaft to move with 360 radial degrees of compliance about the longitudinal axis. In the second position, the lockout rod limits compliance of the longitudinal shaft to only one radial angle from the longitudinal axis. In one embodiment the lockout rod is positioned adjacent (e.g., above or below) part of one ring of a 2-axis concentric ring gimbal. The lockout rod is shaped so as to not contact any part of the gimbal in the first position, allowing compliance in a full 360 radial degrees. In the second position, the lockout rod limits the motion of one ring of the gimbal, limiting compliance of the shaft to motion of the other ring, which is necessarily limited to only one radial angle.

Abstract: A compliance mechanism for holding a robotic finishing tool implements passive force control and compliance using one or more double-acting pneumatic pistons. A desired application force is set and maintained by controlling pneumatic pressure in chambers both fore and aft of the one or more double-acting pneumatic pistons. The pressures in the fore and aft chambers are dynamically controlled, e.g., in response to changes in spatial orientation of the robot arm and tool, to maintain a desired compliance force applied by the robotic finishing tool to a workpiece. An external regulator maintains the fore and aft chamber pressures, for a given spatial orientation, throughout the holder's range of compliance motion. The compliance mechanism includes a plurality of piston bores; the number of active pistons may be adjusted for a given operation, e.g., in response to the finishing tool weight.

Abstract: A linkage assembly to connect a tool to a robotic device. The linkage assembly includes a body and a first linkage pair with first and second links that are configured to be connected to a first section of the tool. The linkage assembly also includes a second linkage pair that includes first and second links that are configured to be connected to a second section of the tool. The first linkage pair are powered to provide a force to move the tool relative to the body. The second linkage pair supports the tool and moves with the first linkage pair. Each of the first and second linkage pairs are pivotally connected to the body and may maintain parallel positioning during the movement.

Abstract: A turbine motor configured to be connected to a tool. The turbine motor includes a receptacle that houses a turbine blade. A channel is configured to receive air to drive the turbine blade. The turbine motor is configured to provide for one or more features that provide enhanced functionality. One feature includes a modular design that can be tailored to adjust the torque of the turbine blade and thus the output of the turbine motor. Another feature includes a brake that stops rotation of the turbine blade.

Abstract: A tool changing system that includes a tool mount adapter and a tool holder. The tool mount adapter is configured to be attached to a tool and selectively engage and disengage a tool bit. The tool provides movement to the engaged tool bit to perform work on a workpiece. The tool holder is positioned in proximity to hold the tool bit when the tool bit is not engaged by the tool. The tool holder can also selectively engage and disengage the tool bit.

Abstract: A motor brush quick change assembly that includes brush units and electrical spring contacts. The brush units include a carrier with a housing and a brush. The electrical spring contacts are connected to an electrical device. Each of the brush units is configured to be removably attached to the electrical device to contact one of the electrical spring contacts. The brush unit thus provide for both a mechanical and electrical connection to the electrical device. The brush units are configured to prevent the need for separate electrical leads that require separate attachment and detachment to the electrical device. This design provides for straight-forward removal and replacement that can be performed by a robotic device or an operator.

Abstract: A linkage assembly to connect a tool to a robotic device. The linkage assembly includes a body and a first linkage pair with first and second links that are configured to be connected to a first section of the tool. The linkage assembly also includes a second linkage pair that includes first and second links that are configured to be connected to a second section of the tool. The first linkage pair are powered to provide a force to move the tool relative to the body. The second linkage pair supports the tool and moves with the first linkage pair. Each of the first and second linkage pairs are pivotally connected to the body and may maintain parallel positioning during the movement.

Abstract: A motor brush quick change assembly that includes brush units and electrical spring contacts. The brush units include a carrier with a housing and a brush. The electrical spring contacts are connected to an electrical device. Each of the brush units is configured to be removably attached to the electrical device to contact one of the electrical spring contacts. The brush unit thus provide for both a mechanical and electrical connection to the electrical device. The brush units are configured to prevent the need for separate electrical leads that require separate attachment and detachment to the electrical device. This design provides for straight-forward removal and replacement that can be performed by a robotic device or an operator.

Abstract: A tool changing system that includes a tool mount adapter and a tool holder. The tool mount adapter is configured to be attached to a tool and selectively engage and disengage a tool bit. The tool provides movement to the engaged tool bit to perform work on a workpiece. The tool holder is positioned in proximity to hold the tool bit when the tool bit is not engaged by the tool. The tool holder can also selectively engage and disengage the tool bit.

Abstract: A compliance mechanism for holding a robotic finishing tool implements passive force control and compliance using one or more double-acting pneumatic pistons. A desired application force is set and maintained by controlling pneumatic pressure in chambers both fore and aft of the one or more double-acting pneumatic pistons. The pressures in the fore and aft chambers are dynamically controlled, e.g., in response to changes in spatial orientation of the robot arm and tool, to maintain a desired compliance force applied by the robotic finishing tool to a workpiece. An external regulator maintains the fore and aft chamber pressures, for a given spatial orientation, throughout the holder's range of compliance motion. The compliance mechanism includes a plurality of piston bores; the number of active pistons may be adjusted for a given operation, e.g., in response to the finishing tool weight.

Abstract: A robotic tool has a longitudinal shaft, defining a longitudinal axis when the shaft is in a default, centered position. A lockout rod is moveable between first and second positions. In the first position, the lockout rod allows the longitudinal shaft to move with 360 radial degrees of compliance about the longitudinal axis. In the second position, the lockout rod limits compliance of the longitudinal shaft to only one radial angle from the longitudinal axis. In one embodiment the lockout rod is positioned adjacent (e.g., above or below) part of one ring of a 2-axis concentric ring gimbal. The lockout rod is shaped so as to not contact any part of the gimbal in the first position, allowing compliance in a full 360 radial degrees. In the second position, the lockout rod limits the motion of one ring of the gimbal, limiting compliance of the shaft to motion of the other ring, which is necessarily limited to only one radial angle.

Abstract: A robotic tool changer includes a locking feature, and may be made washable by sealing against fluid incursion. The tool changer comprises a master unit and one or more tool units, and it transitions between decoupled and coupled states by rotation of one part relative to another. The rotation displaces rolling members in the master unit, such as balls, from a retaining surface to a locking surface which is sized and positioned to force the rolling members against a coupling surface of the tool unit. A deformable pin interposed between the retaining and locking surfaces resists movement of the rolling members therebetween, requiring the application of force. The pin remains deformed, and continues to exert a force on the rolling members, when the robotic tool changer is in the coupled state, providing a locking feature which automatically and positively resists any inadvertent decoupling of the tool changer.