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Research Containing: Spacecraft environment

Advanced ISS Air Monitoring — The ANITA and ANITA2 Missions

by on 9 June 2015in Technology Development & Demonstration No comment

After 11 months of successful operation onboard the ISS US laboratory Destiny, the air quality monitors ANITA (Analyzing Interferometer for Ambient Air) was brought back to Earth on STS126 (ULF2). ANITA is a technology demonstrator flight experiment for continuous air quality monitoring inside the crewed cabin of the ISS with low detection limits and high time resolution. For the first time, the dynamics of the detected trace gas concentrations could be directly resolved by ANITA and correlated to gas events in the cabin. The system is the result of a long term ESA technology development programme initiated more than seventeen years ago. The ANITA mission was a cooperative project between ESA and NASA. ESA's responsibilities were the provision of the H/W, the data acquisition and the data evaluation. NASA was responsible for the launch, accommodation and operation onboard ISS, data download and the transportation of ANITA back to the Earth. ANITA was calibrated to detect and quantify 30 trace gases simultaneously with down to sub-ppm (parts per million) detection limits in addition to the always present background gases carbon dioxide and water vapour. The results of the mission are summarised in [ 1 ]. Further, with a specially developed gas bag hand pump system also gas analyses were performed on air samples from Node 1 of the Space Station. ANITA is a precursor for a permanent continuous trace gas monitoring system ANITA2 for ISS and future space vehicles. At the time of the conference the follow-on study on ANITA2 will have been initiated. This paper describes the measurement system, the lessons learned during the mission on ISS, and the planned follow-on activities. The work described has been performed under contract of the European Space Agency.

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ANITA Air Monitoring on the International Space Station Part 1: The Mission

by on 9 June 2015in Technology Development & Demonstration No comment

After the launch to the International Space Station with The Space Shuttle flight STS 118 13A.1 on August 9th 2007 and the accommodation in the US lab Destiny, the air quality monitor ANITA (Analyzing Interferometer for Ambient Air) has been successfully put into operation. ANITA is a technology demonstrator flight experiment being able to continuously monitor with high time resolution the air conditions within the crewed cabins of the ISS (International Space Station). The system has its origin in a long term ESA (European Space Agency) technology development program. The ANITA mission itself is an ESA-NASA cooperative project. ESA is responsible for the provision of the HW (Hardware), the data acquisition and data evaluation. NASA's responsibilities are launch, accommodation in the US Lab Destiny, operation and data download. The ANITA air analyser is designed to detect and quantify online and with high time resolution 30 trace gases simultaneously with down to sub-ppm (parts per million) detection limits in addition to the always present background gases carbon dioxide and water vapour. The air analyser thus monitors the trace gas dynamics of the spacecraft's atmosphere in providing continuous air monitoring as well as crew warning capability in case of malfunctions. Beside continuous measurements in the vicinity of the gas monitor, air samples from remote places in the International Space Station can be analyzed using gas bags and a hand pump. However, considering the experimental character of ANITA, the measurements are not on-line visible to the Crew. ANITA is an on-orbit test experiment and a precursor for a permanent continuous trace gas monitoring system on the ISS – ANITA II. It further represents a precursor system for future air monitoring in crewed vehicles being developed for the Human Space Exploration program. This is the first paper of two describing the measurement principle, the HW and the mission on the ISS. Finally, an outlook into the future highlights the potential of the ANITA technology for the Exploration program. The work described has been performed under contract of the European Space Agency.

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Rapid Monitoring of Bacteria and Fungi Aboard the International Space Station (ISS)

by on 9 June 2015in Technology Development & Demonstration No comment

Microorganisms within spacecraft have traditionally been monitored with culture-based techniques. These techniques involve growth of environmental samples (cabin water, air or surfaces) on agar-type media for several days, followed by visualization of resulting colonies or return of samples to Earth for ground-based analysis. Data obtained over the past 4 decades have enhanced our understanding of the microbial ecology within space stations. However, the approach has been limited by the following factors: i) Many microorganisms (estimated > 95%) in the environment cannot grow on conventional growth media; ii) Significant time lags (3-5 days for incubation and up to several months to return samples to ground); iii) Condensation in contact slides hinders colony counting by crew; and iv) Growth of potentially harmful microorganisms, which must then be disposed of safely. This report describes the operation of a new culture-independent technique onboard the ISS for rapid analysis (within minutes) of endotoxin and beta-1, 3-glucan, found in the cell walls of gramnegative bacteria and fungi, respectively. The technique involves analysis of environmental samples with the Limulus Amebocyte Lysate (LAL) assay in a handheld device, known as the Lab-On-a-Chip Application Development Portable Test System (LOCAD-PTS). LOCADPTS was launched to the ISS in December 2006, and here we present data obtained from Mach 2007 until the present day. These data include a comparative study between LOCADPTS analysis and existing culture-based methods; and an exploratory survey of surface endotoxin and beta-1, 3-glucan throughout the ISS. While a general correlation between LOCAD-PTS and traditional culture-based methods should not be expected, we will suggest new requirements for microbial monitoring based upon culture-independent parameters measured by LOCAD-PTS.

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http://dx.doi.org/10.2514/6.2009-959

LOCAD-PTS: Operation of a new system for microbial monitoring aboard the International Space Station (ISS)

by on 9 June 2015in Technology Development & Demonstration No comment

Microorganisms within the space stations Salyut, Mir and the International Space Station (ISS), have traditionally been monitored with culture-based techniques. These techniques involve growing environmental samples (cabin water, air or surfaces) on agar-type media for several days, followed by visualization of resulting colonies; and return of samples to Earth for ground-based analysis. This approach has provided a wealth of useful data and enhanced our understanding of the microbial ecology within space stations. However, the approach is also limited by the following: i) More than 95% microorganisms in the environment cannot grow on conventional growth media; ii) Significant time lags occur between onboard sampling and colony visualization (3-5 days) and ground-based analysis (as long as several months); iii) Colonies are often difficult to visualize due to condensation within contact slide media plates; and iv) Techniques involve growth of potentially harmful microorganisms, which must then be disposed of safely. This report describes the operation of a new culture-independent technique onboard the ISS for rapid analysis (within minutes) of endotoxin and β-1, 3-glucan, found in the cell walls of gram-negative bacteria and fungi, respectively. This technique involves analysis of environmental samples with the Limulus Amebocyte Lysate (LAL) assay in a handheld device. This handheld device and sampling system is known as the Lab-On-a-Chip Application Development Portable Test System (LOCAD-PTS). A poster will be presented that describes a comparative study between LOCAD-PTS analysis and existing culture-based methods onboard the ISS; together with an exploratory survey of surface endotoxin throughout the ISS. It is concluded that while a general correlation between LOCAD-PTS and traditional culture-based methods should not necessarily be expected, a combinatorial approach can be adopted where both sets of data are used together to generate a more complete story of the microbial ecology on the ISS.

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http://dx.doi.org/10.2514/6.2008-7900

Analysis of Noise Exposure Measurements Acquired Onboard the International Space Station

by on 9 June 2015in Technology Development & Demonstration No comment

The International S pace Station (ISS) is a unique workplace environment for U.S. astronauts and Russian cosmonauts to conduct research and live for a period of six months or more. Noise has been an enduring environmental physical hazard that has been a challenge for the U.S. space program since before the Apollo era. Noise exposure in ISS poses significant risks to the crewmembers, such as; hearing loss (temporary or permanent), possible disruptions of crew sleep, interference with speech intelligibility and communication, possible interference with crew task performance, and possible reduction in alarm audibility. Acoustic measurements were made onboard ISS and compared to requirements in or der to assess the acoustic environment to which the crewmembers are exposed. The purpose of this paper is to describe in detail the noise exposure monitoring program as well as an assessment of the acoustic dosimeter data collected to date . The hardware currently being used for monitoring the noise exposure onboard ISS will be discussed. Acoustic data onboard ISS has been collected since the beginning of ISS (Increment 1, November 2001). Noise exposure data analysis will include acoustic dosimetry logged data from crew-worn dosimeters during work and sleep periods and also fixed-location measurements from Increment 1 to present day. Noise exposure levels (8-, 16-and 24-hr), LEQ, will also be provided and discussed in this paper. Future directions and recommendations for the noise exposure monitoring program will be highlighted. This acoustic data is used to ensure a safe and healthy working and living environment for the crewmembers onboard the ISS.

Related URLs:
http://dx.doi.org/10.2514/6.2011-5137

International Space Station Acoustics

by on 9 June 2015in Technology Development & Demonstration No comment

The International Space Station (ISS) presents a significant acoustics challenge considering all of the modules and equipment that make it an on-orbit laboratory workshop and home with long-term crew occupation. This challenge is further complicated by the fact that there are numerous suppliers of ISS hardware, including the international partners. This paper addresses how ISS acoustics are managed to ensure a safe and habitable environment by establishing requirements, providing oversight and design support, sharing lessons learned and information, testing for hardware compliance, predicting future acoustic levels, and performing on-orbit measurements and monitoring of actual acoustic levels. ISS acoustic requirements are classified in three categories by the type of hardware involved: modules; payloads, and Government Furnished Equipment. The current status of overall ISS acoustics for each of these hardware categories will be discussed. In addition, examples will be discussed where NASA design support was used to aid in obtaining compliance, where difficulties were encountered, and where areas of concern were addressed.

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ANITA Air Monitoring on the International Space Station Part 2: Air Analyses

by on 9 June 2015in Technology Development & Demonstration No comment

After the launch to the ISS (International Space Station) with The Space Shuttle flight STS 118 13A.1 on August 9th 2007 and the accommodation in the US lab Destiny, the air quality monitor ANITA (Analysing Interferometer for Ambient Air) has been successfully put into operation. ANITA is a technology demonstrator flight experiment being able to continuously monitor with high time resolution the air conditions within the crewed cabins of the ISS. The system has its origin in a long term ESA technology development programme. The ANITA mission itself is an ESA-NASA cooperative project. ESA is responsible for the provision of the HW, the data acquisition and data evaluation. NASA’s responsibilities are launch, accommodation in the US Lab Destiny, operation and data download.The ANITA air analyser is currently calibrated to detect and quantify online and with high time resolution 33 gases simultaneously with down to sub-ppm detection limits. In addition the system has automatic warning capabilities covering possible malfunctions, surprising gases, and gas concentrations above preset limits. – However, owing to the experimental character of this ANITA mission, no measurement results are on-line visible to the crew.ANITA’s standard, fully automatic mode of operation applies direct air sampling in front of the system. Whenever wanted, air samples for automatic analyses can be taken from any human-accessible position in the ISS or any connected spacecraft and fed to ANITA, applying gas bags and a hand pump.ANITA is an on-orbit test experiment and a precursor for a permanent continuous trace gas monitoring system on the ISS – ANITA II. It further represents a precursor system for future air monitoring in crewed vehicles being developed for the Human Space Exploration programme.This paper is part 2 in a series of two papers. The first paper describes the HW and the ANITA mission itself. This paper is dedicated to the data analysis, including the handling of special challenges and some measurement results.On the ISS, ANITA has measured several gases that, before now, have never properly been measured before, including one unexpected gas. And many gases have for the first time been measured with high time resolution. The observed gas dynamics clearly show effects from spacecraft visits to the ISS, crew activities, the number of crew present, and the functioning of the air revitalisation systems. ANITA gives detailed time-resolved information on very different gases such as carbon dioxide and monoxide, methane, ammonia, perfluoro propane, sulphur hexafluoride, siloxanes, and alcohols.It was also demonstrated how ANITA was used to detect and quantify an unexpected gas in the ISS air, and how the system calibration could be updated from ground.The work described has been performed under contract of the European Space Agency.

Related URLs:
http://saeaero.saejournals.org/content/1/1/178.abstract

Evaluation of ANITA Air Monitoring on the International Space Station

by on 9 June 2015in Technology Development & Demonstration No comment

ANITA (Analysing Interferometer for Ambient Air) is a flight experiment precursor for a permanent continuous air quality monitoring system on the ISS (International Space Station).For the safety of the crew, ANITA can detect and quantify quasi-online and simultaneously 33 gas compounds in the air with ppm or sub-ppm detection limits. The autonomous measurement system is based on FTIR (Fourier Transform Infra-Red spectroscopy). The system represents a versatile air quality monitor, allowing for the first time the detection and monitoring of trace gas dynamics, with high time resolution, in a spacecraft atmosphere.ANITA operated on the ISS from September 2007 to August 2008. This paper summarises the results of ANITA’s air analyses and compares results to other measurements acquired on ISS during the operational period. The main basis of comparison is NASA’s set of grab samples taken onboard the ISS and analysed on ground applying various GC-based (Gas Chromatography) and GC/MS (Mass Spectrometry) systems. Comparison with other real-time instruments aboard ISS included the Volatile Organic Analyzer (VOA), the Compound Specific Analyzer – Combustion Products (CSA-CP), the Carbon Dioxide Monitor (CDM), and the Major Constituent Analyzer (MCA).

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http://saeaero.saejournals.org/content/4/1/451.abstract

On-board TLD measurements on MIR and ISS

by on 9 June 2015in Technology Development & Demonstration No comment

This paper presents results from dosimetric measurements made aboard the Mir space station and the International Space Station (ISS) using the Pille portable thermoluminescent dosemeter (TLD) system. This paper includes the dosimetry mapping and automatic readout (trapped and untrapped components) results from Mir and ISS. The mean dose rate in 2001–2003 was 7 μGy h−1. Using the hourly measuring period in automatic mode, doses from both galactic (independent of South Atlantic Anomaly—SAA) and SAA components were determined during Euromir'95 experiment. The mean total dose rate was 12.5 μGy h−1, while the SAA contribution was 6.2 μGy h−1. A similar measurement was performed on ISS in 2001 and in 2003. Both the manual and automatic measurements show a significant decrease in dose rate in 2001 in comparison to 1995–1997 due to the change in solar activity. For determination of the high linear energy transfer contribution from the radiation field during the ISS mapping experiment, three CR-39 plastic nuclear track detectors (PNTDs) were co-located with each TL detector. Analysis of the combined TLD and PNTD measurements showed a typical mean TLD efficiency of 84%, a dose contribution <10 keV μm−1 of 17%, and an average quality factor of 1.95.

Related URLs:
http://rpd.oxfordjournals.org/content/120/1-4/438.abstract