Space missions and projects can only be successful if the materials and components used are first tested on Earth under space conditions. Leybold delivers the technology as an integrated supplier - up to the ultra-high vacuum.
Leybold UNIVEX Testing Chamber.
Space missions are among mankind's most expensive research projects and can quickly cost several billion Euros. In order to ensure that the corresponding components also function in the vacuum conditions prevailing in space, they are technically simulated on Earth using suitable pumps and systems. Leybold offers a wide range of standardized and specific system solutions with integrated fore vacuum and high vacuum pumps - individually tailored to the respective requirements.
A major application is, for example, the simulation and testing of electrical space propulsion systems for spacecrafts. For this purpose, ionized gas particles are accelerated by an electric field. Modern ion engines generate a gas flow of 0.1 to 10 mg/s. In order to maintain a good high vacuum at this considerable flow rate in the test chambers, a very high suction capacity is required - often in the range of 10,000 to 100,000 l/s.
The experimental chamber systems required for this to produce the space conditions exist in all sizes: from a few liters for the testing of small objects such as printed circuit boards to several thousand cubic meters for proving the suitability of entire spaceships for space travel. The noble gas Xenon is the heaviest stable noble gas and is used in most cases for ion engines due to the high resulting thrust. However, the advantage of a large drive mass is a great challenge for vacuum pumps. One of the reasons is the poor thermal conductivity of Xenon gas, which leads to critical temperature increases in gas transfer vacuum pumps such as turbomolecular pumps. In addition, many large turbomolecular pumps would be required to achieve the required high pumping speeds.
Leybold has developed an optimized and simple cryogenic solution for Xenon pumping. The strong single-stage cold heads of the Gifford-McMahon type carry metal discs that condense the Xenon gas with a pumping speed at the edge of the theoretical limit.
Since it is necessary to reach a final pressure in the range of 10-5 Pa - far below the process pressure - before operating an ion engine, these applications also require a correspondingly powerful system of pre- and high-vacuum pumps in order to remove residual gases such as nitrogen, oxygen, etc. The pressure must be controlled by proper instruments throughout the testing process. Leybold provides all the necessary technology as well as technical consultancy, calculation, and design of the systems from a single source.
The demand for such vacuum test chambers increases as the number of Xenon ion engines for different space missions rises. Flexibility and time-to-market is the key factor for the success of these missions.
Leybold is a part of the Atlas Copco’s Vacuum Technique business area and offers a broad range of advanced vacuum solutions for use in manufacturing and analytical processes, as well as for research purposes. The core capabilities center on the development of application- and customer-specific systems for the creation of vacuums and extraction of processing gases. Fields of application are secondary metallurgy, heat treatment, automotive industry, coating technologies, solar and thin films such as displays, research & development, analytical instruments, food & packaging, as well as a multitude of other classic industrial processes.
About Atlas Copco
Subscription users only!
Subscribers are able to view the whole article. Please register/subscribe (it's free and easy) to read all articles.