29 research outputs found
Suitability Testing for PoSSUM Scientist-Astronaut Candidates using the Suborbital Space Flight Simulator with an IVA Spacesuit
This paper evaluates key functional data parameters that must be considered for suborbital spaceflight participants wearing pressurized suits for intravehicular activity (IVA). Data parameters of an analog spacesuit worn in an analog flight environment were obtained from 40 civilian participants using the Suborbital Space Flight Simulator (SSFS) at Embry-Riddle Aeronautical University (ERAU) while donning Final Frontier Design’s (FFD) fully pressurized third-generation spacesuit as part of their training for Project PoSSUM (the Polar Suborbital Science in the Upper Mesosphere Project). The physiological data collected included: blood pressure, electrocardiograms, heart rate, grip strength, and skin temperature. These parameters were measured using a blood pressure monitor, a Zephyr Bioharness, and a BioRadio respectively. Other data collected include participants’ motion sickness, discomfort and mobility, and stress and workload. These parameters were self-assessed using the Simulator Sickness Questionnaire (SSQ), the Modified Cooper Harper Rating Scale, and the NASA-Task Load Index (TLX) respectively. Preliminary results show that 29% of the participants experienced basic spacesuit donning discomfort, while 17% of the participants showed some doffing discomfort. Feet, shoulders, neck, arms, and ankles were the most sensitive parts in this process and throughout their use of the suit. Our results also indicate that the spacesuit limited participants by approximately 24% of their normal cross-body reach range of motion. Nevertheless, the operational capability of this suit is currently being evaluated as a viable option for supporting future suborbital, orbital, and exploration missions. This research will enhance the functionality of the suit, standardize suit testing procedures, aid in identifying key parameters for reducing physiological deconditioning in the use of emerging spacesuit technologies, and provide comparative analysis reference for future studies
Suitability Testing for PoSSUM Scientist-Astronaut Candidates Using the Suborbital Space Flight Simulator with an IVA Spacesuit
This paper evaluates key functional data parameters that must be considered for suborbital spaceflight participants wearing pressurized suits for intravehicular activity (IVA). Data parameters of an analog spacesuit worn in an analog flight environment were obtained from 40 civilian participants using the Suborbital Space Flight Simulator (SSFS) at Embry-Riddle Aeronautical University (ERAU) while donning Final Frontier Design’s (FFD) fully pressurized third-generation spacesuit as part of their training for Project PoSSUM (the Polar Suborbital Science in the Upper Mesosphere Project). The physiological data collected included: blood pressure, electrocardiograms, heart rate, grip strength, and skin temperature. These parameters were measured using a blood pressure monitor, a Zephyr Bioharness, and a BioRadio respectively. Other data collected include participants’ motion sickness, discomfort and mobility, and stress and workload. These parameters were self-assessed using the Simulator Sickness Questionnaire (SSQ), the Modified Cooper Harper Rating Scale, and the NASA-Task Load Index (TLX) respectively. Preliminary results show that 29% of the participants experienced basic spacesuit donning discomfort, while 17% of the participants showed some doffing discomfort. Feet, shoulders, neck, arms, and ankles were the most sensitive parts in this process and throughout their use of the suit. Our results also indicate that the spacesuit limited participants by approximately 24% of their normal cross-body reach range of motion. Nevertheless, the operational capability of this suit is currently being evaluated as a viable option for supporting future suborbital, orbital, and exploration missions. This research will enhance the functionality of the suit, standardize suit testing procedures, aid in identifying key parameters for reducing physiological deconditioning in the use of emerging spacesuit technologies, and provide comparative analysis reference for future studies
Human Factors for Small Net Habitable Volume: The Case for a Close-Quarter Space Habitat Analog
Increasing efforts in sending humans to Mars calls for greater considerations of the ways in which vehicle and habitat design can influence crew performance and behavioral health
Toxicity of lunar dust
The formation, composition and physical properties of lunar dust are
incompletely characterised with regard to human health. While the physical and
chemical determinants of dust toxicity for materials such as asbestos, quartz,
volcanic ashes and urban particulate matter have been the focus of substantial
research efforts, lunar dust properties, and therefore lunar dust toxicity may
differ substantially. In this contribution, past and ongoing work on dust
toxicity is reviewed, and major knowledge gaps that prevent an accurate
assessment of lunar dust toxicity are identified. Finally, a range of studies
using ground-based, low-gravity, and in situ measurements is recommended to
address the identified knowledge gaps. Because none of the curated lunar
samples exist in a pristine state that preserves the surface reactive chemical
aspects thought to be present on the lunar surface, studies using this material
carry with them considerable uncertainty in terms of fidelity. As a
consequence, in situ data on lunar dust properties will be required to provide
ground truth for ground-based studies quantifying the toxicity of dust exposure
and the associated health risks during future manned lunar missions.Comment: 62 pages, 9 figures, 2 tables, accepted for publication in Planetary
and Space Scienc
Suitability Testing for PoSSUM Scientist-Astronaut Candidates using the Suborbital Space Flight Simulator with an IVA Spacesuit
This paper evaluates key functional data parameters that must be considered for suborbital spaceflight participants wearing pressurized suits for intravehicular activity (IVA). Data parameters of an analog spacesuit worn in an analog flight environment were obtained from 40 civilian participants using the Suborbital Space Flight Simulator (SSFS) at Embry-Riddle Aeronautical University (ERAU) while donning Final Frontier Design’s (FFD) fully pressurized third-generation spacesuit as part of their training for Project PoSSUM (the Polar Suborbital Science in the Upper Mesosphere Project). The physiological data collected included: blood pressure, electrocardiograms, heart rate, grip strength, and skin temperature. These parameters were measured using a blood pressure monitor, a Zephyr Bioharness, and a BioRadio respectively. Other data collected include participants’ motion sickness, discomfort and mobility, and stress and workload. These parameters were self-assessed using the Simulator Sickness Questionnaire (SSQ), the Modified Cooper Harper Rating Scale, and the NASA-Task Load Index (TLX) respectively. Preliminary results show that 29% of the participants experienced basic spacesuit donning discomfort, while 17% of the participants showed some doffing discomfort. Feet, shoulders, neck, arms, and ankles were the most sensitive parts in this process and throughout their use of the suit. Our results also indicate that the spacesuit limited participants by approximately 24% of their normal cross-body reach range of motion. Nevertheless, the operational capability of this suit is currently being evaluated as a viable option for supporting future suborbital, orbital, and exploration missions. This research will enhance the functionality of the suit, standardize suit testing procedures, aid in identifying key parameters for reducing physiological deconditioning in the use of emerging spacesuit technologies, and provide comparative analysis reference for future studies
Suitability Testing for PoSSUM Scientist-Astronaut Candidates Using the Suborbital Space Flight Simulator with an IVA Spacesuit
This paper evaluates key functional data parameters that must be considered for suborbital spaceflight participants wearing pressurized suits for intravehicular activity (IVA). Data parameters of an analog spacesuit worn in an analog flight environment were obtained from 40 civilian participants using the Suborbital Space Flight Simulator (SSFS) at Embry-Riddle Aeronautical University (ERAU) while donning Final Frontier Design’s (FFD) fully pressurized third-generation spacesuit as part of their training for Project PoSSUM (the Polar Suborbital Science in the Upper Mesosphere Project). The physiological data collected included: blood pressure, electrocardiograms, heart rate, grip strength, and skin temperature. These parameters were measured using a blood pressure monitor, a Zephyr Bioharness, and a BioRadio respectively. Other data collected include participants’ motion sickness, discomfort and mobility, and stress and workload. These parameters were self-assessed using the Simulator Sickness Questionnaire (SSQ), the Modified Cooper Harper Rating Scale, and the NASA-Task Load Index (TLX) respectively. Preliminary results show that 29% of the participants experienced basic spacesuit donning discomfort, while 17% of the participants showed some doffing discomfort. Feet, shoulders, neck, arms, and ankles were the most sensitive parts in this process and throughout their use of the suit. Our results also indicate that the spacesuit limited participants by approximately 24% of their normal cross-body reach range of motion. Nevertheless, the operational capability of this suit is currently being evaluated as a viable option for supporting future suborbital, orbital, and exploration missions. This research will enhance the functionality of the suit, standardize suit testing procedures, aid in identifying key parameters for reducing physiological deconditioning in the use of emerging spacesuit technologies, and provide comparative analysis reference for future studies
Suitability Testing for PoSSUM Scientist-Astronaut Candidates Using the Suborbital Space Flight Simulator with an IVA Spacesuit
This paper evaluates key functional data parameters that must be considered for suborbital spaceflight participants wearing pressurized suits for intravehicular activity (IVA). Data parameters of an analog spacesuit worn in an analog flight environment were obtained from 40 civilian participants using the Suborbital Space Flight Simulator (SSFS) at Embry-Riddle Aeronautical University (ERAU) while donning Final Frontier Design’s (FFD) fully pressurized third-generation spacesuit as part of their training for Project PoSSUM (the Polar Suborbital Science in the Upper Mesosphere Project). The physiological data collected included: blood pressure, electrocardiograms, heart rate, grip strength, and skin temperature. These parameters were measured using a blood pressure monitor, a Zephyr Bioharness, and a BioRadio respectively. Other data collected include participants’ motion sickness, discomfort and mobility, and stress and workload. These parameters were self-assessed using the Simulator Sickness Questionnaire (SSQ), the Modified Cooper Harper Rating Scale, and the NASA-Task Load Index (TLX) respectively. Preliminary results show that 29% of the participants experienced basic spacesuit donning discomfort, while 17% of the participants showed some doffing discomfort. Feet, shoulders, neck, arms, and ankles were the most sensitive parts in this process and throughout their use of the suit. Our results also indicate that the spacesuit limited participants by approximately 24% of their normal cross-body reach range of motion. Nevertheless, the operational capability of this suit is currently being evaluated as a viable option for supporting future suborbital, orbital, and exploration missions. This research will enhance the functionality of the suit, standardize suit testing procedures, aid in identifying key parameters for reducing physiological deconditioning in the use of emerging spacesuit technologies, and provide comparative analysis reference for future studies