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DSTI Plays Role in Astrophysics Research from South Pole
Published on June 29, 2016Most people are unaware that less than a quarter mile from the South Pole lie some of the world's most powerful radio telescopes.
MINNEAPOLIS, Minn. - June 29, 2016 - Most people are unaware that less than a quarter mile from the South Pole lie some of the world's most powerful radio telescopes.
Running year-round, they scan the sky observing very faint light from the Cosmic Microwave Background (CMB). The CMB is the oldest light visible in the Universe, a remnant glow from the very early times when the Universe was much hotter and much denser than it is today.
BICEP3, the 3rd generation in this series of instruments measuring the polarization of the CMB, requires rotary union technology to pass ultra-high purity helium gas from a compressor on the ground to a pulse-tube cryogenic cooler located above the telescope's rotating mount. Although the South Pole is bitterly cold, BICEP3 still needs to cool its detectors to a fraction of a degree above absolute zero (-273° C / -460° F) to operate properly.
During the first season of BICEP3 operation at the Amundsen-Scott South Pole station, BICEP3 was using a basic 2-channel DSTI rotary union. Unfortunately, that particular rotary union was not quite adequate for the very demanding application of passing high pressure helium, a gas notoriously hard to keep leak-tight, through the continuously rotating union.
As a result, the rotary union displayed a high leak rate requiring constant bleeding of helium back into the system for replenishment. Despite being 99.999% pure, enough contamination accumulated in the pulse-tube cooler to cause performance degradation requiring additional processes to get the system back up and running resulting in a month of downtime.
Research Scientist Denis Barkats from Harvard University partnered with DSTI to solve this problem with an upgraded 4-channel DSTI rotary union. The 4-channel union significantly outperformed the 2-channel union by effectively using the outer two channels as buffers for the two inner working channels.
"DSTI was incredibly responsive when we communicated these problems with them and were able to deliver new rotary unions with spare units without delay which is critical when working in the short austral summer season at the South Pole station," says Denis Barkats.
Dynamic Sealing Technologies (DSTI) specializes in the design and manufacturing of application-specific fluid solutions worldwide. DSTI's engineered fluid sealing products transfer hydraulic oil, chemicals, water, air, and a variety of other liquids and gases for rotating applications. The company offers custom integrated solutions to meet the unique design, manufacturing, testing, and qualification requirements of each project. DSTI has a full line of in-stock, standard fluid and electrical products including fluid rotary unions and electrical slip rings designed to meet a wide range of industrial applications.