Abstract: Disclosed is a digital twin tethered balloon system; key running state data of a tethered balloon is collected through an Internet of Things of a tethered balloon system; the key running state data of the tethered balloon is transmitted to a twin data service center; the twin data service center receives, analyzes and stores the data and forwards the data to a tethered balloon digital twin system; the tethered balloon digital twin system simulates a pose of a tethered balloon body and the movement of a ground tethering facility; and the tethered balloon monitoring service provides running state monitoring, quality problem tracking, fault prediction and early warning, automatic control and other services.

Abstract: Disclosed a digital twin tethered balloon system key running state data of a tethered balloon is collected through an Internet of Things of a tethered balloon system; the key running state data of the tethered balloon is transmitted to a twin data service center; the twin data service center receives, analyzes and stores the data and forwards the data to a tethered balloon digital twin system; the tethered balloon digital twin system simulates a pose of a tethered balloon body and the movement of a ground tethering facility; and the tethered balloon monitoring service provides running state monitoring, quality problem tracking, fault prediction and early warning, automatic control and other services. The present invention realizes the deep integration of a physical space and a digital space of the tethered balloon system, which can monitor the tethered balloon system, and is high in visualization degree and good in interaction means.

Abstract: A method for automatically generating hierarchical exploded views based on assembly constraints and collision detection, in which parts to be exploded are layered in explosion sequence according to a design result of the 3D assembly process planning, and the parts to be exploded in each layer are grouped based on the type and the disassembly direction; a feasible explosion direction of the parts in each layer is determined according to assembly constraints and collision detection; the explosion sequence and explosion direction of the parts in each layer are determined; and then the layered explosion is performed at a certain distance. Ball markers and a part-list are generated after all the parts are exploded.

Abstract: A method for automatically generating hierarchical exploded views based on assembly constraints and collision detection, in which parts to be exploded are layered in explosion sequence according to a design result of the 3D assembly process planning, and the parts to be exploded in each layer are grouped based on the type and the disassembly direction; a feasible explosion direction of the parts in each layer is determined according to assembly constraints and collision detection; the explosion sequence and explosion direction of the parts in each layer are determined; and then the layered explosion is performed at a certain distance. Ball markers and a part-list are generated after all the parts are exploded.