A load securement device may comprise an extendable pole and a plurality of attachments. The device may be operable to manipulate a tie down of a cargo trailer. As non-limiting examples, the tie down may be a cargo strap, a cargo chain, or an elastic cord used to secure a cargo or to secure a tarp over the cargo. The extendable pole may be lengthened to reach the top of the cargo. The extendable pole may be shortened to take up less space for storage. The plurality of attachments may alter a distal end of the extendable pole to enable the extendable pole to perform multiple tasks necessary for securing the cargo. As non-limiting examples, the plurality of attachments may enable the extendable pole to toss the cargo strap, to pull the cargo strap, or lift a hard corner.

In one embodiment, a robotic system comprises: a robot comprising a robotic actuator and at least one robotic arm mechanically coupled to the robotic actuator; a suction gripper mechanism that comprises: a linear shaft element; an internal airflow passage within the linear shaft configured to communicate an airflow between an airflow application port at a first end of the linear shaft and a gripping port positioned at an opposing second end of the linear shaft; a suction cup assembly comprising a suction cup element coupled to the gripping port; and an actuator configured to rotate the linear shaft in order to articulate an orientation of the suction cup assembly.

The horizontal articulated robot includes a platform, a first arm which is coupled to the platform, which moves along a first linear-motion axis with respect to the platform, and which rotates around a first rotational axis parallel to the first linear-motion axis, a second arm which is coupled to the first arm, which moves along a second linear-motion axis different in direction from the first linear-motion axis with respect to the first arm, and which rotates around a second rotational axis parallel to the first rotational axis, a third arm which is coupled to the second arm, and which rotates around a third rotational axis perpendicular to the first linear-motion axis, and a fourth arm which is coupled to the third arm, and which rotates around a fourth rotational axis perpendicular to the third rotational axis.

A door opening device comprising a multi-directional head and a telescoping pole is provided. The multi-directional head allows the operator to choose the angle when opening the door and the telescoping pole allows the operator to remain at a distance away from the doorway while operating the doorknob. By allowing an operator to remain around a corner when opening a door, an armed and cornered individual is less able to harm the operator by shooting through the door.

An unmanned aerial vehicle includes a body with an arm mounted to a side of the body. The unmanned aerial vehicle also includes an actuator coupled to the arm. The actuator is configured to move the arm between a retracted position and an extended position. The actuator moves within a single degree of freedom to move the arm between the retracted position and the extended position.

A slag pusher apparatus having a boom with a plurality of telescopingly engaged boom segments. Rollers are positioned between each boom segment to provide support for the boom segments and facilitate extension and retraction of the boom.

A displaceable robot for performing operations using a tool near a high temperature furnace containing molten metal, wherein the robot is displaceable using a vehicle. The robot comprising: a frame having a ground interface for coming into contact with a ground surface while defining a clearance under a portion of the frame for engaging with the vehicle to displace the robot about the furnace when the ground interface is off the ground; an arm mounted to the frame, the arm comprising an end effector which is adapted for mounting the tool; a sensor for collecting at least one of exteroceptive data in a vicinity of the robot and proprioceptive data from the robot; and a controller receiving the collected data from the sensor and controlling a movement of at least the arm based on the collected data.

A mobile manipulation system configured to perform objective tasks within human environments is provided. The mobile manipulation system can include a mobile base assembly including a computing device, at least two drive wheels, and a sensor. The mobile manipulation system can include an actuation assembly including a chain cartridge and a drive chain including a plurality of inter-connected links conveying at least one cable within an interior space of each inter-connected link. The actuation assembly system can also include a telescopic structure including a plurality of segments configured to extend and retract telescopically and conveying the drive chain therein. The mobile manipulation system can include a mast attached to the mobile base assembly along which the actuation assembly translates vertically and a head assembly atop the mast including a first collection of sensors. The mobile manipulation system can also include a manipulation payload coupled to the telescopic structure.

A transportation apparatus (30), includes a bracket (31), a telescopic apparatus (32) and a manipulator (33), where the bracket is mounted to a storage shelf (20), the telescopic apparatus is mounted to the bracket, the manipulator is mounted to the telescopic apparatus, and the telescopic apparatus is used for driving the manipulator to move along a horizontal first reference line (S5) or a horizontal second reference line (S6). The manipulator is driven to move on the first reference line and second reference line that are disposed orthogonally, and thereby the manipulator is able to load or unload goods at any position on the first reference line or second reference line, so as to avoid time being wasted on adjusting an angle of a transportation robot (100). The transportation apparatus has a high transportation efficiency.

mechanical arm type measuring robot device and an application method, and relates to the technical field of intelligent coal mine mining. The mechanical arm type measuring robot device comprises an automatic leveling total station, a protection mechanism, a pitch adjusting mechanism, a yaw adjusting mechanism, a vertical rotating mechanism, a controller, a mounting base and a mobile terminal. Based on a preset pitch angle and a preset yaw angle, the measuring robot starts from an initial position, and performs extension and retraction actions in a plurality of degrees of freedom in the pitch adjusting mechanism and the yaw adjusting mechanism to move the total station to a preset working position.