Deformation and Flexibility Equations for Aris Umbilicals Idealized as Planar Elastica

The International Space Station relies on the active rack isolation system (ARIS) as the central component of an integrated, stationwide strategy to isolate microgravity space-science experiments. ARIS uses electromechanical actuators to isolate an international standard payload rack from disturbances due to the motion of the Space Station. Disturbances to microgravity experiments on ARIS isolated racks are transmitted primarily via the ARIS power and vacuum umbilicals. Experimental tests indicate that these umbilicals resonate at frequencies outside the ARIS controller s bandwidth at levels of potential concern for certain microgravity experiments. Reduction in the umbilical resonant frequencies could help to address this issue. This work documents the development and verification of equations for the in-plane deflections and flexibilities of an idealized umbilical (thin, flexible, inextensible, cantilever beam) under end-point, in-plane loading (inclined-force and moment). The effect of gravity is neglected due to the on-orbit application. The analysis assumes an initially curved (not necessarily circular), cantilevered umbilical with uniform cross-section, which undergoes large deflections with no plastic deformation, such that the umbilical slope changes monotonically. The treatment is applicable to the ARIS power and vacuum umbilicals under the indicated assumptions.Hampton, R. David and Leamy, Michael J. and Bryant, Paul J. and Quraishi, NaveedJohnson Space CenterFLEXIBILITY; INTERNATIONAL SPACE STATION; MICROGRAVITY; UMBILICAL CONNECTORS; ELASTIC DEFORMATION; PLANAR STRUCTURES; ELECTROMECHANICAL DEVICES; LOADS (FORCES); PAYLOADS; RESONANT FREQUENCIES; ACTUATORS; CANTILEVER BEAMS; GRAVITATIONAL EFFECTS