Disclosed are a ground test system and a test method for a space-oriented multi-arm spacecraft system. A spacecraft system simulator floats on an air-floating platform through four porous air feet, a test truss is placed around the air-floating platform, a simulation auxiliary docking device, a simulation crawling truss and a satellite model are arranged in a middle of a ceiling of the test truss, and an assembly test area and a silent air compressor are arranged on sides of the test truss. The application is used to solve the problems that the prior art cannot simulate the movement and crawling of the multi-arm spacecraft system in space, assembly of large space structures, and the prior art cannot simulate the influence of assembling, catching and other actions on a base in a weightless environment.

Disclosed are a ground test system and a test method for a space-oriented multi-arm spacecraft system. A spacecraft system simulator floats on an air-floating platform through four porous air feet, a test truss is placed around the air-floating platform, a simulation auxiliary docking device, a simulation crawling truss and a satellite model are arranged in a middle of a ceiling of the test truss, and an assembly test area and a silent air compressor are arranged on sides of the test truss. The application is used to solve the problems that the prior art cannot simulate the movement and crawling of the multi-arm spacecraft system in space, assembly of large space structures, and the prior art cannot simulate the influence of assembling, catching and other actions on a base in a weightless environment.

A space oven operates in microgravity environments by forcing convection towards the center through a unique heating element and airflow design. The space oven includes a tubular chamber, a heating rack, a heating system, a cooling system, a hatch, a user interface, a microcontroller, an enclosure, at least one first vent, at least one second vent and at least one temperature sensor. The tubular chamber is the cooking area. The heating rack holds consumables in place. The heating system heats up consumables. The cooling system prevents any overheating. The hatch closes off and allows access to the inside of the tubular chamber. The user interface allows a user to input commands. The microcontroller manages the electronic components. The enclosure protects the tubular chamber. The at least one first vent and the at least one second vent reduce pressure buildup. The at least one temperature sensor monitors the internal temperature.

A space oven operates in microgravity environments by forcing convection towards the center through a unique heating element and airflow design. The space oven includes a tubular chamber, a heating rack, a heating system, a cooling system, a hatch, a user interface, a microcontroller, an enclosure, at least one first vent, at least one second vent and at least one temperature sensor. The tubular chamber is the cooking area. The heating rack holds consumables in place. The heating system heats up consumables. The cooling system prevents any overheating. The hatch closes off and allows access to the inside of the tubular chamber. The user interface allows a user to input commands. The microcontroller manages the electronic components. The enclosure protects the tubular chamber. The at least one first vent and the at least one second vent reduce pressure buildup. The at least one temperature sensor monitors the internal temperature.

A payload suspension system is described herein. A payload suspension system may comprise a suspended payload container within an internal cavity defined by the payload suspension system. The suspended payload container may be suspended by one or more tensile members. The one or more tensile members may be coupled with respective tension adjustment mechanisms configured to adjust a tension of the tensile members. The tension may be adjusted based on a transition to and from a low- or micro-gravity state, in order to provide an increased or decreased movement/rotational ability for the payload container. The low- or micro-gravity state may be produced due to an aircraft performing a parabolic maneuver.

A payload suspension system is described herein. A payload suspension system may comprise a suspended payload container within an internal cavity defined by the payload suspension system. The suspended payload container may be suspended by one or more tensile members. The one or more tensile members may be coupled with respective tension adjustment mechanisms configured to adjust a tension of the tensile members. The tension may be adjusted based on a transition to and from a low- or micro-gravity state, in order to provide an increased or decreased movement/rotational ability for the payload container. The low- or micro-gravity state may be produced due to an aircraft performing a parabolic maneuver.

A suspending release device for observing a drop vibration attitude change of a lander and a test method are provided. The device includes a bench system, a lifting system fixed to the bench system, a horizontal frame system, an attitude control system, and a suspending release system hinged to the attitude control system. The horizontal frame system may slide vertically on the bench system and may drive the attitude control system to slide horizontally. A test lander is fixed to a release sliding block. The release sliding block is locked with a main load bearing block. An attitude of the test lander when releasing is adjusted. The horizontal frame system is lifted to a predetermined height. Guide rods are indirectly driven to release the sliding block by a motor. The whole lander falls freely and touches the ground to collide, and the process is recorded by a high-speed camera.

Ion booster for thrust generation. The invention pertains to electrical propulsion generated by the rapid acceleration of ions between asymmetrical electrodes. The invention is applicable for propulsion generation in atmospheric and space environments.

An improved debris generator that can be used as part of a space object modeling (SOM) system to turn any active spacecraft into a debris sensor for characterizing and cataloging space debris. The space debris generator includes an extractor which extracts satellite sensor data into a sensor store, an impact agent which estimates “on the fly” new debris field objects generated by the collision, and an injector which stores the enhanced object data on a central server for near-term mitigation of impact driven breakup events. The impact agent is an artificial neural network trained using a large number of simulations of impact events.

An improved debris generator that can be used as part of a space object modeling (SOM) system to turn any active spacecraft into a debris sensor for characterizing and cataloging space debris. The space debris generator includes an extractor which extracts satellite sensor data into a sensor store, an impact agent which estimates “on the fly” new debris field objects generated by the collision, and an injector which stores the enhanced object data on a central server for near-term mitigation of impact driven breakup events. The impact agent is an artificial neural network trained using a large number of simulations of impact events.