A robot arm with high productivity capable of preventing a decelerator from being damaged is provided. A robot arm according to an embodiment of the present disclosure is a robot arm in which a second member is rotationally coupled to a first member via a decelerator that accommodates lubricant therein, the robot arm including: a circulation path in which the lubricant is circulated via the decelerator; a storage part that is arranged in the circulation path and stores the lubricant; and an actuator configured to circulate the lubricant, in which the storage part is provided with a filter for capturing impurities in the lubricant in such a way that the filter covers an outlet of the lubricant in the storage part.

A cleaning robot includes a cover, a fixed body provided in the cover, a traveling part connected to the fixed body, a movement frame fastened to the cover to move in correspondence with movement of the cover, an inner body configured to support the movement frame relative to the fixed body, and a rotator provided on a bottom of the inner body to rotate in correspondence with movement of the cover.

Provided is a life evaluating device that evaluates the life of a lubricant in a machine including a motor and a transmission mechanism that is lubricated by the lubricant and transmits power of the motor to a movable unit. The life evaluating device includes a motor-heat-value calculating unit that calculates a motor heat value on the basis of a current value of the motor, a frictional-heat-value calculating unit that calculates a frictional heat value in the transmission mechanism on the basis of rotating speed of the motor and a coefficient of friction of the transmission mechanism, a lubricant-temperature estimating unit that estimates temperature of the lubricant on the basis of the calculated frictional heat value and the calculated motor heat value, and a life estimating unit that estimates the life of the lubricant on the basis of the estimated temperature of the lubricant and information concerning impurities in the lubricant.

A robot is provided which has: a housing including a plurality of joints; a reduction gear placed in the joint, the reduction gear including a lubrication chamber where a gear mechanism for slowing down and transmitting an output of a motor and lubricant is sealed; and an air chamber placed inside the housing, the air chamber communicating with the lubrication chamber.

A gear device includes an internal gear, a flexible external gear, and a wave generator. The wave generator includes an elliptical cam and a bearing. Grease is applied to the inner circumferential surface of the external gear. A groove is provided along a rotation axis on at least one of the inner circumferential surface of the external gear and an outer circumferential surface of the bearing.

A joint structure of a robot includes a first member, a second member which is rotatably supported around a horizontal rotation axis line with respect to the first member, and an actuator which rotates the second member with respect to the first member, a through-holes, each of which allows a lubrication space in which a lubricant for the actuator is enclosed to connect with an outer space is provided in at least one of the first member and the second member, and more than three of the through-holes are provided at an interval in a circumferential direction centering around the horizontal rotation axis line.

A control unit has as agitation mode in which a command is executed for a first switching valve so that the oil supply/discharge direction is switched so as to supply oil to a first oil supply/discharge port located at a low position and discharge oil from a second oil supply/discharge port located at a high position, whereby oil in an oil bath is agitated via a circulation pump from a low position to a high position is the oil bath; and a filter mode in which, after the agitation mode is executed, a command is executed for the first switching valve so that the oil supply/discharge direction is switched so as to discharge oil from the first oil supply/discharge port located at a low position and supply oil to the second oil supply/discharge port located in a high position, whereby impurities in the oil sent to a filter mechanism are filtered.

A sensor relating to the present invention includes: a first electrode; a second electrode; a first attracting portion positioned between the first electrode and the second electrode and configured to receive conductive abrasion powder contained in a detection region and attracted onto the first attracting portion; a sensing unit for sensing a change in electrical resistance between the first electrode and the second electrode caused by the conductive abrasion powder; and at least one second attracting portion positioned within the detection region and configured to attract the conductive abrasion powder contained in the detection region.

The present disclosure relates to a grip jaw structure with characteristics as follows: a cam disk is driven by a rotary motor; two transmission shafts are driven through two slotted guideways in the cam disk; lubricants inside the slotted guideways adhere to a plurality of bearings in which the transmission shafts in the slotted guideways are inserted when the transmission shafts are shifted; sliders between which a workpiece is clamped are driven to be shifted by the transmission shafts along linear rails at the top of the framework for stresses sustained and dispersed by bearings.

A robot includes a lubricant chamber in which a fluid lubricant can be stored, wherein the lubricant chamber is provided with three or more through-holes that extend through wall surfaces of the lubricant chamber, and the through-holes are disposed such that, in a state in which any one of the through-holes is disposed at a lowest level of the lubricant chamber so as to allow a utilization thereof as an oil discharge hole in two or more orientations of the lubricant chamber, another one of the through-holes is disposed at a position corresponding to a liquid level of the lubricant when a required amount of the lubricant is stored in the lubricant chamber or above the liquid level so as to allow a utilization thereof as a vent hole, and a remaining through-hole is disposed at a position that allows a utilization thereof as an oil supply hole from which the lubricant is supplied into the lubricant chamber.