A malfunction detection device compares detected data on a condition at a predetermined part of an apparatus with a threshold so as to determine a malfunction of the apparatus. The malfunction detection device varies the threshold in accordance with a type of a lubricant used for movable parts of the apparatus.

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 relief unit that is attached to an attachment hole penetrating through a wall of a housing accommodating a power transmission mechanism of a robot together with lubricating oil in a sealed state, which includes a body that is provided with an attachment section attachable to the attachment hole and that forms a communication passage disposed at a position where an internal space of the housing and an external space are connected when the attachment section is attached to the attachment hole. An opening and closing mechanism that is provided in the communication passage, closes the communication passage in a sealed state when the opening and closing mechanism is closed, and that opens the communication passage when the opening and closing mechanism is opened. a catching part is disposed at an intermediate position of the communication passage that catches the lubricating oil.

The oil content of at least two kinematic modules (1) in different axes of the industrial robot is connected by the oil line (2) to the closed circuit of the oil between interconnected kinematic modules (1). In preferred arrangement, the system includes the pump (3) engaged in pushing the oil in the upper-mounted kinematic module (1) and also the filtration device (4) for filtering the oil in the circulating circuit or in a separate circuit with the oil tank (9). The system may also include at least one diagnostic element (5), for example an oil temperature sensor or an oil pressure sensor or an oil pollution sensor connected to the evaluation unit (6). The evaluation unit (6) can be interconnected with the industrial robot control system, whereby the oil economy is controlled and planned depending on the actual load of the individual kinematic modules (1). By this arrangement, you can achieve the condition in which the oil from the kinematic module (1) circulates in shared circulation with the oil from another kinematic module (1), whereas the oil gets purified through the filter device (4) by using the pump (3).

A wrist structure of a robot capable of protecting an oil seal of a wrist structure from a high-pressure jet for cleaning or from external foreign matter or the like. A wrist structure of a robot includes a wrist body, a holder attached to the wrist body, a wrist flange rotatably supported by the holder, an oil storage provided between the wrist body and the holder, an oil seal disposed between the holder and the wrist flange and configured to prevent oil from leaking from the oil storage, and a cover that is formed integrally with the holder and that covers the oil seal from the outside between the holder and the wrist flange.

A robot includes: a first arm having a first body, a first housing fixed to the first body, and a first gear transmitting power to a rotary member supported by the first housing so as to be rotatable; a second arm supporting the first arm and having a second body, a second shaft having a second gear meshing with the first gear, and a second bearing supporting the second shaft so that the second shaft is rotatable relative to the second body; and a channel in the arms. An inlet of the channel is formed in an outer surface of the first body, an outlet of the channel opening into a space in which an outer peripheral surface of the second shaft and the second bearing are arranged inside the second arm, the channel extending from the inlet to the outlet through inside of the first body.

A robot including, a motor attached to one end surface of a casing of an arm, a reducer output shaft attached to the other end surface of the casing by bolts, a hole provided in the casing, and through which the output shaft of the motor is inserted, a first sealing member sealing a space between the hole and the output shaft, a second sealing member sealing a space between the other end surface and the end surface of the reducer output shaft, a recessed portion provided on a side of the other end surface of the casing and recessed in a direction along the central axial line of the reducer output shaft; and a lubricant agent supply hole provided in the casing and extending in a substantially radial direction or in a radial direction of the reducer output shaft, the lubricant agent supply hole communicating to the recessed portion.

The present application comprises a loading gantry with at least one carriage traversable on a horizontal guide rail, in particular for the transport of workpieces between stations of a production system. In accordance with the application the loading gantry includes a media station which in at least one position of the carriage releasably can be mechanically coupled with the same in order to produce at least one media connection between the media station and the carriage.

A lubricant injection system is provided, which includes a pedestal, a robotic arm including a plurality of arm bodies sequentially coupled from pedestal, lubricant injecting hand having a discharge part configured to be sequentially coupled to each of a plurality of filler ports of a target machine, robot control device configured to control operation of robotic arm, a lubricant pumping device in which pumping of lubricant is controlled, a lubricant pumping channel configured to lead lubricant from the lubricant pumping device to the discharge part, and a flow rate sensor provided to the lubricant pumping channel and configured to send the detected flow rate information to the robot control device. Robot control device calculates an injection quantity based on the flow rate information sent from flow rate sensor, and when calculated injection quantity reaches target injection quantity, robot control device controls to stop pumping of lubricant.

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.