According to one embodiment, a wall detection device includes an acquirer and processing circuitry. The acquirer acquires a point cloud, which includes a series of coordinates of a plurality of points corresponding to a first wall and a second wall that oppose each other. The processing circuitry detects a first detected wall and a second detected wall based on a model and the acquired point cloud, the model representing a first plane which corresponds to the first detected wall and indicates a surface of the first wall and a second plane which corresponds to the second detected wall and indicates a surface of the second wall, and the model representing the first plane and the second plane being parallel to each other.

Disclosed is a lifting robot that includes a housing and a tray. The housing includes a side wall formed by a plurality of enclosing side panels, a projection of the side wall on a horizontal plane is a regular polygon, and at least one of the plurality of side panels is provided with a connection device for connecting to a side panel of another lifting robot. Further disclosed is a robot system including a plurality of the lifting robot described above.

The present invention discloses a lifting mechanism mounted on a lifting device, wherein the lifting device includes a carrying unit. The lifting mechanism is disposed under the carrying unit, and comprises a driving assembly and a lifting assembly. The driving assembly includes an axle fixing part, a drive wheel and a power source, and the lifting assembly includes a screw nut and a screw rod. An upper end of the screw rod is fixedly connected to the carrying unit. When the lifting mechanism is traveling, each drive wheel is in contact with a base surface and moves the lifting device on the base surface; and when lifting, each drive wheel rotates on the base surface to drive the screw nut to rotate about a vertical axis relative to the carrying unit, to drive the screw rod to lift the carrying unit along the vertical direction.

The present disclosure relates to a position detection apparatus and a position detection method of a distribution object, a robot, a distribution apparatus, and a controller, and relates to the field of robots. The apparatus includes: a plurality of ranging sensors arranged on an end surface of a protrusion member of a robot facing a placement region of the distribution object, wherein the protrusion member is located on a chassis of the robot and each of the plurality of ranging sensors is configured to detect a distance between the ranging sensor and an end surface of the distribution object facing the plurality of ranging sensors; and a controller configured to determine that the distribution object has been located at a predetermined position above the chassis in a case where the distance detected by each of the plurality of ranging sensors is not greater than a first distance threshold.

A delivery apparatus, a delivery system, a delivery method, an electronic device, and a computer readable storage medium are disclosed. The delivery apparatus includes a movable detachably and electrically connected with a cabin, where the movable chassis is configured to include: a first controller mounted inside the movable chassis, and a moving component mounted at a bottom of the movable chassis and connected with the first controller to drive the movable chassis and the cabin to move to a target position according to an instruction of the first controller; the cabin is configured to have one or more accommodation spaces for accommodating to-be-delivered objects. The technical solution greatly improves the delivery efficiency and reduces the delivery cost.

Provided are a container storage system, a warehousing system, a robot control method, and a robot; the container storage system comprises an inventory area, a control server, a robot, and a plurality of workstations; the control server communicates with the robot wirelessly; an inventory rack is placed in the inventory area; the inventory rack comprises at least one layer of layered panels; the at least one layer of layered panels divides the inventory rack into at least two layers; at least two storage containers are placed on the inventory rack in the direction of the depth of the layered panels, and the direction of width of the storage container on the inventory rack is consistent with the direction of the depth of the layered panels. The system increases the storage density of storage containers in the inventory area, and reduces the energy consumption of the robot picking the storage containers.

A safety system for an automated storage and picking system is described. The storage system includes load handling devices operating above a series of stacked containers located within a framework, the top of which includes tracks on which the load handling devices operate. The safety system includes a transmitter located in close proximity to the storage system and a receiver located on each of the load handling devices. The transmitter can continually transmit a signal that is detected by the receivers on the load handling devices. In the event of an emergency or a breach of the storage system, the transmission of the signal is cut. Once the receiver no longer receives the signal from the transmitter, power to each load handling device drive is cut to render the storage system safe.

A gas cylinder automation system may include: a transfer path automatically supply gas in a gas cylinder brought into the gas cylinder automation system to a semiconductor process line; and a cylinder-type sensor checking whether the transfer path is abnormal by moving along the transfer path, wherein the cylinder-type sensor includes: a cylinder head including an end cap fastening member and an end cap coupled to the end cap fastening member and having a first detecting sensor disposed on the end cap fastening member to detect one of a force or torque applied to the end cap and a cylinder body connected to the cylinder head and having a second detecting sensor including at least one of an acceleration sensor or an inclination sensor mounted thereon.

A carrier applying precision support and lifting by an Automated Guided Vehicle includes a frame, two supporting arms, and pressing components. Two supporting arms are located on either side of the frame and are movable in a receiving direction relative to the frame. The pressing components are located on the frame, the pressing components include first pressure balls, for pushing the supporting arms across the carrier, and second pressure balls for pushing the supporting arms along the receiving direction. The first and second balls improve the positioning accuracy of the supporting arms relative to the object or material to be transported and reduces friction between the supporting arms and the pressing components. An AGV cart and a loading system are also disclosed.

A vehicle (4) comprising a vehicle accessory arrangement (2), the vehicle accessory arrangement, including a working equipment (6), is mounted on the vehicle (4), The vehicle accessory arrangement (2) is configured to receive current position data, e.g. GPS data, and working assignment data including route data for a working assignment for said vehicle (4) provided with said working equipment (6). The accessory control unit (8) is provided with a vehicle data set comprising control characteristics of the vehicle (4) on which the accessory arrangement (2) is mounted, and is configured to determine: navigation and drive control commands adapted to control said vehicle (4) provided with said vehicle accessory arrangement (2) to work in an autonomous mode and to travel along a route of a working assignment, working control commands adapted to control said vehicle (4) such that working procedures performed by said working equipment (6) are supported. The navigation and drive control commands and said working control commands are determined based upon said control characteristics. The vehicle control unit (17) is configured to determine a mode of operation of said vehicle (4) among a set of mode of operations including an autonomous mode of operation, and if it is determined that said vehicle (4) is in an autonomous mode of operation said vehicle control unit (17) is configured to enable said accessory control unit (8) to control said vehicle (4), by said navigation and drive commands and said working control commands, to fulfil said working assignment.