Search Results

The Regenerative Atmosphere Revitalization and Monitoring system (ARMS), been part of Integrated Life Support System (ILSS), is intended for maintenance in the manned modules of a necessary chemical composition of an artificial gas atmosphere (AGA) on base of the crew metabolism product transform to environment initial components. Generally, the ARMS structure includes the individual systems and units intended for: → oxygen generation; → carbon dioxide removal and it concentration; → trace contaminants removal; → carbon dioxide reduction with the goal to produce an additional quantity of water necessary to increase the degree of the oxygen loop clousure. The ARMS structure of the International Space Station (ISS) Russian Segment (RS) includes the Electron-VM Oxygen Generation System (OGS), Vozdukh Carbon Dioxide Removal System (CDRS) and SBMP Trace Contaminants Removal Means (TCRM) installed in the Service Module.

This paper describes the concept of Ecotechnical System (ETS) based on the analysis of mass, power and data flow exchange within a biocenosis and between a biocenosis and technical systems that support life and activity of any biological entity in isolated environment of space vehicle. A biocenosis is considered to be a gathering of live organisms (generally people, animals, plants and micro-organisms) in an artificial habitat of the isolated environment. An Ecotechnical System is defined and it is shown that the given concept brings together different life support systems based on physical-chemical and biological means of regeneration of crew metabolic products. The existing limitations to the ETS development are reviewed in the paper in respect to limited volumes of space vehicles based on the vehicle characteristics and particular space program tasks. Three step analysis approach proposed for ETS effectiveness evaluation.

This paper reviews the preliminary definition of integrated life support system configurations based on a single criterion decision-making task (SCDMT). Comparative analysis results are shown for currently used effectiveness models based on SCDMT. Possible areas of application for those models are determined. It is also proven that well-known effectiveness model, which uses an equivalent mass approach to determine system expenditures, can be used only in cases where useful effect from system operation is the same. The article proposes the use of a global thermodynamic effectiveness criterion based on the exergy method to account for ECLSS functional expenditures, i.e. functional costs. Exergy is a concept that fuses energy and material quality information in a measure that is both descriptive and physically significant. This method accounts for nonequivalence of different forms of energy and allows measuring technological flows in the system using same measuring units.

The research conducted at NIICHIMMASH for the past several years in the area of Integrated Life Support System (ILSS) strategy development for technology efficiency analysis and system structure synthesis is reviewed in this paper. This study proposes an generalized efficiency model for ILSS development, which includes global, thermodynamic and local quantitative and qualitative factors. The research resulted in a strategy for the synthesis of ILSS structure based on evolutionary and integral- hypothhetical approaches. This strategy allows development of new system configurations, evaluation of existing ILSS effectiveness and considers decision marker's (DM) preferences. Uncertainty in the initial information about properties of the system or technology has a big influence on DM making decisions about future system appearance. Fuzzy set theory is used to define the uncertainty in the initial information.

This paper reviews a Crew Simulation Model (CSM) for Space Vehicle Integrative Life Support System (ILSS) operation study. It is designed to simulate crew metabolic reaction mass and energy flows in accelerated time mode with each crew member specifics consideration. This CSM formally is based on human body general simulation, which includes main functional systems like: the cardiac-vascular, external respiration, thermal regulation and water/mineral balance. Work and rest time schedules are also considered as well as each crew member presence in a particular module. The CSM considers trace contaminants in metabolic products due to nutrition and environment temperature. This simulations' formal review is shown in the paper as well as formal implementation with computed experiment results. Some of the possible applications are also approached.

This paper deals with a man-made Gas Atmosphere (MMGA) Simulation Model developed and software presented for the Russian Segment of the International Space Station (ISS). The simulation Model (SM) is intended for analysis of the MMGA parameter nonstationary values in isothermal and non-isothermal conditions under a variable number of crew taking into account the intensities of the crew activity. The person's structure of the SM, basic assumptions, taken for modeling and formalized descriptions of SM separate modules. Formalized descriptions by the Segment's Pressurized Modules are based on using the nonlinear equations of mass/energy balance for the controlling volume, taking into account all main sources and sinks of the environment separate components, which are a crew, Integrated Regenerative Life Support System (IRLSS) separate subsystems, ISS on-board systems.

This paper considers one of the possible approaches to the synthesis of technologies for developing future Integrated Regenerative Life Support Systems (IRLSS) for space vehicle crews. The solution of technology synthesis task involves the following phases: (a) the efficiency model structuring for technical decision making process; (b) presentation of a discrete set of alternative technologies and their formal description; (c) the decision making task introduction. Modified efficiency model under consideration is based on use of local efficiency criteria set, reflecting designed system and its subsystems properties, space vehicle properties for which this system is intended. For the local criteria after verification of the independence terms quantitative and qualitative efficiency factors are applied. The qualitative efficiency factors were evaluated on the scale of order. The consideration of uncertainty in criteria values is based on a fuzzy set theory.

The paper is devoted to consideration of the possible approach to forecasting functioning physico/chemical Regenerative Life Support Systems (RLSS) in regular and off-normal conditions of operation on the basis of methods of mathematical simulation. Prediction of RLSS functioning under operating conditions represents the special interest for the analysis of off-normal situations, caused by development of a resource or presence that or that or of the other of failure of the equipment, or change of external conditions. In the given situations working mechanisms of transfer of mass and energy change not only characteristic and modes of operations of separate apparatus, but also, in a number of cases. The given peculiarities should be taken into account at formation of the formalized descriptions of the RLSS hardware.

Development of closed life support systems for water recovery, oxygen generation and food processing is achievable in the future. However, currently the possibility of partial reproduction of food components from metabolic products and biocomplex waste should be taken into account when advanced life support system development is under consideration. Studies on carbohydrate synthesis from products of life are of particular interest because carbohydrates hold the first place in terms of mass in the food. The paper discusses possible ways of carbohydrate synthesis by physical/chemical means. Separate stages of a carbohydrate synthesis process are considered.

This paper describes the results of research and tests of different patterns of distillation processes for water reclamation from urine accomplished by NIICHIMMASH in cooperation with other companies. Several typical patterns of evaporation to air flow from water-retentive porous bodies, from the surface confined by capillary/porous membranes and from free liquid surface in rotary units under atmospheric and reduced pressure are analyzed. Relevant condensation processes are reviewed. Performance data for distillation unit of SS MIR system for water reclamation from urine are outlined. The paper highlights the prospects of distillation hardware development.

A concept of developing a regenerative water management system (RWMS) for first lunar base missions is reviewed. The principal feature of the concept proposed is the maximum possible unification of RWMS for long-duration orbiting station and a lunar base with due regard to possible modification of the hardware for lunar gravity conditions. The paper is based on the expertise in research, development, testing and flight operation of RWMS in Russia. An upgraded RWMS of the International Space Station may be used for first lunar missions.

The paper deals with the problems of development of physico-chemical systems for water recovery and atmosphere revitalization for long-duration space stations. Schematics of regenerative life support systems featuring a high degree of closure and biotechnological components are presented. A year-long experiment has proved the possibility for Man to stay in a closed artificial environment for a long time by consuming substances regenerated by physico-chemical means from the end products of life. A complex of the life support systems (LSS) on Mir space station allowing for oxygen and 90% water recovery as well as its future updating is considered.

The paper deals with some aspects and results of research in major processes and hardware of a system for hygiene waste water recovery and its architecture concepts. A principal system schematic and its functions on Mir space station are presented. It is shown that physico-chemical means ensure cost-effective recovery with minimum energy demand and resupply which is particulary important for long-duration space missions.