Abstract: A cleaning system and a cleaning method configured for cleaning task of solar panels are provided. The cleaning system includes an operation region, cleaning robots, shuttle robots, and a data processing system. The cleaning method includes a first carrying step, a cleaning step, and a second carrying step.

Abstract: A device assembly system includes a control apparatus, a mobile apparatus, a lifting apparatus, and a plug in/out apparatus. The control apparatus is configured to control, based on an operation and maintenance instruction, the mobile apparatus, the lifting apparatus, and the plug in/out apparatus to complete an operation of the operation and maintenance instruction. The mobile apparatus is configured to move the device assembly system to a first location, and the first location identifies a rack in which a device is assembled. The lifting apparatus is configured to move the plug in/out apparatus to a target location in a first direction. The plug in/out apparatus is configured to place the device to be assembled at the target location, or obtain the device from the target location.

Abstract: A control method for a cleaning system, comprising the following steps: first control step—controlling a transfer robot to move a cleaning robot to a cleaning area; cleaning control step—controlling the cleaning robot to perform a cleaning operation on a upper surface of the cleaning area; second control step—controlling a transfer robot to move the cleaning robot away from the cleaning area.

Abstract: A data transmission method, including obtaining by a transmit end, at least two to-be-transmitted packets, determining a first interface used to transmit each of the packets in at least two interfaces of the transmit end, and determining an identifier of each of the packets that is related to the first interface, where the identifier represents an order of the first interface used to transmit each of the packets in the at least two interfaces used to send the at least two packets adding the identifier to a packet header of each of the packets and sending a packet added with the identifier to the receive end device through the first interface, so that the receive end device adjusts, based on the identifier, an order of the packet added with the identifier.

Abstract: Disclosed are a transfer robot (300) and a cleaning system. The transfer robot (300) comprises a vehicle body (310), a transfer device (320), and an angle adjusting device (330). The cleaning system comprises a cleaning area (500), a cleaning robot (200) and the transfer robot (300). The transfer robot (300) serves as a carrying tool for the cleaning robot (200), and transfers the cleaning robot (200) to a channel area (103) among a plurality of solar panel arrays (101), such that the cleaning robot (200) can complete cleaning work on the different solar panel arrays (101).

Abstract: A control method for a cleaning system, comprising the following steps: first control step—controlling a transfer robot to move a cleaning robot to a cleaning area; cleaning control step—controlling the cleaning robot to perform a cleaning operation on a upper surface of the cleaning area; second control step—controlling a transfer robot to move the cleaning robot away from the cleaning area.

Abstract: A docking method for docking a cleaning robot between a plurality of solar panels includes a docking area setting step, an approaching cleaning area step, a docking platform adjustment step, a cleaning robot first control step, and a leaving cleaning area step. The present invention uses a cleaning robot to complete cleaning on the solar panels or a solar panel array, a docking robot to transfer the cleaning robot between the solar panels or multiple solar panel arrays, and a data processing system to realize dispatching and controlling of the cleaning robot and the docking robot, so that a number of cleaning robots and docking robots can be dispatched properly according to a number of the solar panels needing to be cleaned, and a cleaning operation on all solar panels and panel arrays can be completed in a photovoltaic power station in a shortest time.

Abstract: A cleaning system and a cleaning method configured for cleaning task of solar panels are provided. The cleaning system includes an operation region, cleaning robots, shuttle robots, and a data processing system. The cleaning method includes a first carrying step, a cleaning step, and a second carrying step. The cleaning system and the cleaning method dispatch a suitable number of cleaning robots and shuttle robots according to workload of cleaning task to complete the cleaning task. The cleaning task of all solar panels and panel arrays can be completed in the shortest time.

Abstract: A robot scheduling method. A robot comprises a cleaning robot for performing cleaning operations in a cleaning area, and a conveying robot for transporting the cleaning robot in an aisle area. The robot scheduling method comprises a task generating step, a task issuing step, a route planning step, a travel controlling step, and a conveying controlling step.

Abstract: A memory allocation method and a server, wherein the method includes: identifying, by a server, a node topology table; generating fetch hop tables of the NUMA nodes based on the node topology table; calculating fetch priorities of the NUMA nodes based on the fetch hop tables of the NUMA nodes, and using an NC hop count as an important parameter for fetch priority calculation; and when a NUMA node applies for memory, allocating memory based on the fetch priority table, and for a higher priority, more preferentially allocating memory from a NUMA node corresponding to the priority.

Abstract: An edge positioning apparatus for a solar panel cleaning robot, and a positioning method thereof. The solar panel cleaning robot comprises a car body (10) and an edge positioning apparatus, and the car body travels or is resident on at least one solar panel (200). The edge positioning apparatus comprises an image acquisition unit (13) and an image recognition and processing unit. The image acquisition unit is arranged on the car body and is used for acquiring surface image information about the solar panel on a walking line of the car body. The image recognition and processing unit is used for processing image information, and in turn judging whether the car body is walking at an edge area of the solar panel.

Abstract: An objective of the present invention is to provide a method for determining and controlling a robot to move straightly on a sloping plane to solve a technical issue that a deviation of a conventional robot from a predetermined straight path is difficult to detect when the robot moves on a sloping plane and cannot be corrected, and moving on the straight path is difficult to guarantee.

Abstract: An edge positioning apparatus for a solar panel cleaning robot, and a positioning method thereof. The solar panel cleaning robot comprises a car body (10) and an edge positioning apparatus, and the car body travels or is resident on at least one solar panel (200). The edge positioning apparatus comprises an image acquisition unit (13) and an image recognition and processing unit. The image acquisition unit is arranged on the car body and is used for acquiring surface image information about the solar panel on a walking line of the car body. The image recognition and processing unit is used for processing image information, and in turn judging whether the car body is walking at an edge area of the solar panel.

Abstract: Provided are a positioning device for a solar panel cleaning robot (100) and a positioning method thereof. The positioning device is used to obtain a real-time position of a vehicle body (10) on a solar panel (200). The positioning device comprises an image acquisition unit (11), a border recognition unit (12), a latitude and longitude recognition unit (13), a vehicle body position calculation unit (14), an image acquisition unit position calculation unit (15), a vehicle body center point position calculation unit (16), a GPS unit (17), a panel determination unit (18), a wireless communication unit (19) and a memory (20).

Abstract: A data transmission method, including obtaining by a transmit end, at least two to-be-transmitted packets, determining a first interface used to transmit each of the packets in at least two interfaces of the transmit end, and determining an identifier of each of the packets that is related to the first interface, where the identifier represents an order of the first interface used to transmit each of the packets in the at least two interfaces used to send the at least two packets adding the identifier to a packet header of each of the packets and sending a packet added with the identifier to the receive end device through the first interface, so that the receive end device adjusts, based on the identifier, an order of the packet added with the identifier.

Abstract: A memory allocation method and a server, wherein the method includes: identifying, by a server, a node topology table; generating fetch hop tables of the NUMA nodes based on the node topology table; calculating fetch priorities of the NUMA nodes based on the fetch hop tables of the NUMA nodes, and using an NC hop count as an important parameter for fetch priority calculation; and when a NUMA node applies for memory, allocating memory based on the fetch priority table, and for a higher priority, more preferentially allocating memory from a NUMA node corresponding to the priority.

Abstract: An objective of the present invention is to provide a method for determining and controlling a robot to move straightly on a sloping plane to solve a technical issue that a deviation of a conventional robot from a predetermined straight path is difficult to detect when the robot moves on a sloping plane and cannot be corrected, and moving on the straight path is difficult to guarantee.

Abstract: A solar panel cleaning robot is provided and has a robot body. The robot body can move on at least one solar panel. A cleaning device, a power system, a control system and an electric power system are disposed on an internal or an external of the robot body.