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Based on experience obtained in operation of the water and oxygen recovery systems installed onboard the Russian space stations Salut, Mir and the International Space Station ISS, data on the water and oxygen balance for a space station are presented as well as operational parameters and performance data of the systems. Using the data obtained design analysis of an integrated life support system for water and oxygen recovery based on physical/chemical means to be installed on a promising space station is carried out. Mandatory verification tests of new process (technologies) and recovery systems are to be conducted on ISS.

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 paper deals with the construction and performance data of the service module Zvezda water and oxygen supply systems of the International Space Station (ISS). The performance data at the first 14 months of manned station functioning are provided. The data of humidity condensate and recovered water compositions are reviewed. The water supply and demand balance are analyzed. The system of oxygen generation “Electron-VM” and its functioning results are reviewed. The effective cooperation of the international partners on part of life support is shown.

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.

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 reviews Air Revitalization System (ARS) for Russian Segment of International Space Station software simulation development and implementation by the example the Service Module (SM) ARS. This simulation is designed for the ARS ground test functional analysis and in-flight support Individual ARS complex systems formal description is based on each system description as a unit, using information received from experiments and detailed simulations. Failure can be introduced for contingency simulation.

The paper describes the design specifics of the system for oxygen generation by electrolysis Elektron and major results obtained in long-term operation of the system aboard space station Mir. Operational data analysis makes possible to draw a conclusion that the system is capable to attain life parameters for at least 2 years with maintaining serviceability for no less than 8 years without attendance and unit replacement. Based on flight operation the possibility of reducing power consumption by 10 per cent is proven. System design updates are realized in the water electrolysis system intended for the Russian segment of the international space station.