SBIR-STTR Award

Current evaluations of stress in textile parachute structures rely heavily on analytical estimation without adequate data collection means to validate or improve simulations. Features of available data acquisition tools are too limited to facilitate “live” stress measurement of parachute textiles in operation. Advancements in microelectronics and electronics infused "E-textiles" can be employed in combination to create the critically needed data collection tools for use on parachutes in operation, with continued innovation required to expand capability to also include parachute deployment and inflation stages. The current concept for this proposal, hereinafter referred to as the Textile Strain Measurement System or TSMS, is anticipated to produce a data acquisition system that meets the Topic Z11.01: "... advanced sensors, sensor systems ... to perform inspections on large complex structures... for potential use on free-flying inspection platforms." The planned sensor system includes design of a directly measuring data recorder, with size and mass goals to remain non-influential to the parachute material's natural movement and dynamic characteristics. The latest advancements in microelectronics will be exploited to achieve the miniaturization goals. The proposed effort includes investigation and characterization of various strain sensitive materials suitable for stress measurement of multiple textile high and low elongation categories. The resulting TSMS innovation is a combined design of recorder with strain measurement materials specific to textile decelerator configurations that can be utilized in an efficient and non-invasive manner. Potential NASA Applications Wide range of mission applications that include textile structures or subsystems including: aerial decelerator systems, inflatable antennas, inflatable habitats, etc. Potential Non-NASA Applications All textile structure applications and investigations can use this innovation. For decelerator applications include: aircraft and UAV development, ejection seat and emergency parachutes, cargo aerial delivery, and munitions descent and guidance. Potential exists for applications in “smart textiles” and “wearable technology” markets.

The use of textile devices for spacecraft structures and deceleration provides significant stowed versus deployed volume and mass advantages. However, the long-standing problem with textile devices is the fact that measurement of physical and functional properties, especially during deployment and dynamic events, has been incredibly difficult if not impossible. Generally speaking, the sensors used to measure the textile behaviors have been of sufficient mass/stiffness/wiring/etc. as to alter the base behavior of the material being measured. Current evaluations of stress in textile structures such as parachutes, parafoils, inflatable shelters, etc. rely heavily on analytical estimation and empirical “go/no go” test results without adequate means of data collection to validate or improve simulations. The current concept for this proposal, hereinafter referred to as the Textile Strain Measurement System or TSMS, includes design of a direct measurement data recorder, with size and mass goals that do not influence the textile structure's natural movement and dynamic characteristics. Additionally, the proposed effort includes investigation and characterization of various strain sensitive materials suitable for non-invasive application to previously constructed textile assemblies, with initial focus on Aerodynamic Decelerator Systems (ADS), to allow dynamic stress measurement of flexible structures. Phase I resulted in the planned technology at TRL 3 and delivered a lab prototype of the data recorder with test samples of sensor-infused parachute material. Phase II, when selected, would progress TSMS to at least TRL 5 including fully functional hardware examples for use on free-flying inspection platforms during parachute operation including deployment and inflation. It is our intention to add an accelerometer as an additional sensor during Phase II. Potential NASA Applications (Limit 1500 characters, approximately 150 words) NASA JPL efforts associated with Mars 2020/ASPIRE and Fluid Structure Interaction (FSI) parachute modeling, NASA-wide efforts associated with balloon/inflatable development for Venus, starshade sunshields, deployable antennas, deployable solar arrays,deployable solar sails, NASA JSC efforts to characterize inflatable human habitats, Orion CPAS and commercial capsule recovery systems, NASA ARC/LaRC efforts to advance ADEPT and HIAD flexible heatshields. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) US Army efforts to characterize and improve soldier parafoil and ballistic deceleration systems, government-wide efforts to develop and characterize inflatable shelters and emergency facilities, and government-wide efforts to develop small satellite and sample return decelerator systems.