A system for preventing debris buildup in vacuum sensor lines includes: a manifold, including a positive air pressure source and a controller; and one or more positive air pressure lines. Each positive air pressure line is in fluid communication with the manifold and can be placed in fluid communication with a vacuum sensor line. The controller is operably connected to and selectively activates the positive air pressure source to emit a positive flow of air, which can be directed into the one or more positive air pressure lines, and then into and through the associated vacuum sensor lines to evacuate debris. In some embodiments, a positive flow of air can also be directed through one or more vacuum lines of the end effector to promote the release of a parcel engaged with the end effector and/or clear the vacuum lines of debris.

Robot charging dock includes a charge connector configured to mate with a charging port of a mobile robot. There is a charge connector frame having a front surface on which the charge connector is mounted. The front surface has a first side edge and a second side edge. There is a front cover disposed over the charge connector frame which has an aperture through which the charge connector protrudes. At least a portion of the front cover is spaced from the front surface of the charge connector frame, defining an internal region. There is an opening to the internal region formed along at least a portion of a perimeter of the aperture and there is a light source disposed in the internal region. The light source is directed toward the opening to allow the light source to illuminate charge connector.

The oil content of at least two kinematic modules in different axes of the industrial robot is connected by the oil line to the closed circuit of the oil between interconnected kinematic modules. The system includes the pump engaged in pushing the oil in the upper-mounted kinematic module and the filtration device for filtering the oil in the circulating circuit or in a separate circuit with the oil tank. The system includes at least one diagnostic element, for example an oil temperature sensor or an oil pressure sensor or an oil pollution sensor connected to the evaluation unit. The evaluation unit is interconnected with the industrial robot control system, thus, the oil economy is controlled and planned depending on the actual load of the individual kinematic modules.

A mobile robot includes a driver configured to provide a traveling function, a body disposed at an upper side of the driver and configured to include a head coupling hole formed at an upper portion thereof, and a head configured to include a head bracket inserted into the head coupling hole of the body. The body includes a head fixing frame fastened to the head bracket, a first bolt configured to fix the head fixing frame and the head bracket, and a repair cover coupled to an opening formed in a backward direction. The head is separated from the body when the first bolt is released by opening the repair cover.

This device includes an acquired data storing unit for storing acquired data about a current command value of a servo motor configuring a robot drive system; a tendency diagnosis unit for diagnosing a future changing tendency of the current command value based on the data of the current command value stored in the acquired data storing unit; and a life determining unit for determining a term until the current command value reaches a previously set value based on the future changing tendency of the current command value acquired by the tendency diagnosis unit. Thus, a residual life of the robot drive system can be accurately predicted.

Disclosed is a system, including: a robot having a controller configured to perform a self-assessment by being configured to: instruct an external sensor that is spaced apart from the robot to obtain and transmit sensor data that is indicative a condition of an external surface of the robot; determine from the sensor data that the robot requires service; and transmit a service request or schedule service responsive to determining that the robot requires service.

A fixture assembly, for use in maintaining a piece of heavy equipment. The fixture assembly includes a first connecting component configured to be connected releasably to a first part of the heavy equipment, and a second connecting component configured to be connected releasably to a second part of the heavy equipment connected to the first part when the heavy equipment is assembled. The fixture assembly also includes a hinge arrangement connecting the first connecting component to the second connecting component. The technology further includes methods for maintaining the heavy equipment using the fixture assembly, such as by separating heavy equipment parts in order to replace a gearbox of the equipment.

A robot includes a first member having a first mounting surface facing upward and a second member having an opening at an upside of the first member and facing the first member and a second mounting surface at the upside, and a joint actuator coupling the first and second members. The joint actuator has a flange fixed to the second mounting surface, a motor placed at the upside with respect to the flange, and a reducer placed at a downside with respect to the flange, projecting downward from the opening, and fixed to the first mounting surface. The joint actuator is mounted on the second mounting surface from the upside and the reducer is projected downward from the opening, and the flange is fastened to the second member from the upside using first screws and the reducer is fastened to the first member from the downside using second screws.

A gas pressure detection device 10 detects a decrease in a pressure of gas of a gas balancer 8 of a robot 2. The gas pressure detection device 10 includes a calculating part configured to calculate a parameter Rt(θ) indicating a magnitude relation between a reference pressure Pa(θ) at a rotational angle θ of a rotary arm 14 and a measured pressure Pt(θ) measured at the rotational angle θ, calculate a plurality of parameters Rt(θ) based on a plurality of measured pressures Pt(θ) at different measurement times, and calculate a moving average Rtj(θ) of the parameter Rt(θ) at a measurement time tj that is a j-th measurement time of the measured pressure Pt(θ) (j representing a natural number of 2 or above), and a determining part configured to compare the moving average Rtj(θ) with a reference value R to detect the decrease in the pressure of the gas.

Surgical kit inspection systems and methods are provided for inspecting surgical kits having parts of different types. The surgical kit inspection system comprises a vision unit including a first camera unit and a second camera unit to capture images of parts of a first type and a second type in each kit and to capture images of loose parts from each kit that are placed on a light surface. A robot supports the vision unit to move the first and second camera units relative to the parts in each surgical kit. One or more controllers obtain unique inspection instructions for each of the surgical kits to control inspection of each of the surgical kits and control movement of the robot and the vision unit accordingly to provide output indicating inspection results for each of the surgical kits.