The present invention relates to the field of vehicle safety crash test dummies, and discloses an arm for a crash dummy, a control method, a device and a storage medium. The arm comprises: a first motor (1), a coupling (2), a capstan shaft (3), a first bevel gear (4), a second motor (5), a first capstan (6), a capstan bearing (7), an elbow joint base (8), a forearm (9), a first elbow joint bearing (11), drive lines (13), a second pulley (14), an elbow joint shaft (16), a first fixed sleeve (17), a second fixed sleeve (18), a second elbow joint bearing (20), an elbow joint connection block (22), a power source connection block (24), a second bevel gear (27), two sets of pulleys, a second capstan (28) and a power source bracket (29). The arm provided in this embodiment has an active function.

The present invention relates to the field of vehicle safety crash test dummies, and discloses an arm for a crash dummy, a control method, a device and a storage medium. The arm comprises: a first motor (1), a coupling (2), a capstan shaft (3), a first bevel gear (4), a second motor (5), a first capstan (6), a capstan bearing (7), an elbow joint base (8), a forearm (9), a first elbow joint bearing (11), drive lines (13), a second pulley (14), an elbow joint shaft (16), a first fixed sleeve (17), a second fixed sleeve (18), a second elbow joint bearing (20), an elbow joint connection block (22), a power source connection block (24), a second bevel gear (27), two sets of pulleys, a second capstan (28) and a power source bracket (29). The arm provided in this embodiment has an active function.

Disclosed in some embodiments is a chamber component (such as an end effector body) coated with an ultrathin electrically-dissipative material to provide a dissipative path from the coating to the ground. The coating may be deposited via a chemical precursor deposition to provide a uniform, conformal, and porosity free coating in a cost effective manner. In an embodiment wherein the chamber component comprises an end effector body, the end effector body may further comprise replaceable contact pads for supporting a substrate and the contact surface of the contact pads head may also be coated with an electrically-dissipative material.

A medical system includes a manipulator arm including a movable distal portion, a proximal portion coupled to a base, and joints between the distal portion and the base. A processor coupled to the manipulator arm performs operations including calculating a first movement of the joints in a null-space of a Jacobian of the manipulator arm, the first movement being calculated in accordance with a first objective for arm-to-patient collision avoidance. The operations further include calculating a second movement of the joints in the null-space, the second movement being calculated in accordance with a second objective for arm-to-arm collision avoidance, and combining at least the first and second movements into a combined movement in a manner allowing the first objective to overpower the second objective, and driving the joints to effect the combined movement.

A mortar applicator includes: a duct having a first end and a second end; a piston movably mounted within the duct, the piston dividing the duct into first and second variable volume chambers on opposite sides of the piston; a piston actuator operatively connected to the piston, the piston actuator being operable to move the piston within the duct; a nozzle assembly located at the first end of the duct, the nozzle assembly having a tip defining a nozzle opening in fluid communication with the first variable volume chamber to discharge mortar contained therein; and a cover member selectively movable between an open position and a closed position to respectively allow and prevent mortar to be discharged through the nozzle opening; a cover member actuator operatively connected to the cover member, the cover member actuator being operable to move the cover member between the open position and the closed position.

A mortar applicator includes: a duct having a first end and a second end; a piston movably mounted within the duct, the piston dividing the duct into first and second variable volume chambers on opposite sides of the piston; a piston actuator operatively connected to the piston, the piston actuator being operable to move the piston within the duct; a nozzle assembly located at the first end of the duct, the nozzle assembly having a tip defining a nozzle opening in fluid communication with the first variable volume chamber to discharge mortar contained therein; and a cover member selectively movable between an open position and a closed position to respectively allow and prevent mortar to be discharged through the nozzle opening; a cover member actuator operatively connected to the cover member, the cover member actuator being operable to move the cover member between the open position and the closed position.

A surgical system includes at least one input coupler, an end effector assembly having a pair of jaw members configured to grasp tissue, and an actuation assembly. The pair of jaw members are caused to transition from an open position to a closed position to apply a jaw force to tissue. The surgical system also includes an articulating section configured to transition the end effector assembly between an un-articulated position and at least one articulated position and a storage device storing setting information and adjustment information. The setting information enables determination of a first input to cause the pair of jaw members to apply the jaw force to the tissue. The adjustment information enables adjustment of the setting information based on the position of the end effector assembly, for determination of a second input to cause the pair of jaw members to apply the jaw force to the tissue.

A surgical system includes at least one input coupler, an end effector assembly having a pair of jaw members configured to grasp tissue, and an actuation assembly. The pair of jaw members are caused to transition from an open position to a closed position to apply a jaw force to tissue. The surgical system also includes an articulating section configured to transition the end effector assembly between an un-articulated position and at least one articulated position and a storage device storing setting information and adjustment information. The setting information enables determination of a first input to cause the pair of jaw members to apply the jaw force to the tissue. The adjustment information enables adjustment of the setting information based on the position of the end effector assembly, for determination of a second input to cause the pair of jaw members to apply the jaw force to the tissue.

A robot includes a robot arm including an arm to which an end effector is connected, in which the arm and the end effector are formed therein with an ingredient channel through which ingredients pass. The ingredient channel includes a first channel having an ingredient inlet into which the ingredients are introduced and extending from the ingredient inlet toward the end effector; and a second channel having an ingredient outlet provided in the end effector and positioned after the first channel in an ingredient transfer direction to guide the ingredients at a different speed from a speed of the first channel.

A robot includes a robot arm including an arm to which an end effector is connected, in which the arm and the end effector are formed therein with an ingredient channel through which ingredients pass. The ingredient channel includes a first channel having an ingredient inlet into which the ingredients are introduced and extending from the ingredient inlet toward the end effector; and a second channel having an ingredient outlet provided in the end effector and positioned after the first channel in an ingredient transfer direction to guide the ingredients at a different speed from a speed of the first channel.