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This paper reviews the design and properties of the Water Supply System (WSS). It also discusses the water balance and its delivery amounts, as well as it presents diagrams and properties of water recovery system from humidity condensate WRS-CM and regeneration from urine WRS-UM which are the part of WSS. Some results of activities conducted for provision of water intake in a system of WRS-CM from different modules of station are shown and the problems of WSS interaction of Russian segment (RS) and American segment (USOS) of the International Space Station (ISS) are discussed.

A selection of a distillation subsystem with a rotary multistage vacuum distiller (RMVD) and a heat pump (HP) for the system for water reclamation from urine for the international space station is substantiated. The results of computational/experimental analysis of specific energy for distillation with RMVD and HP of different type used are presented. The test results of an experimental system mockup are given. It is shown that the subsystem of a given type is stable in operation, features high condensate processing rate and low specific energy demand.

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.

At the initial phase of the construction of the international space station (ISS) water supply will be provided by the systems located in the Russian segment. The paper reviews the systems for water recovery from humidity condensate and urine to be incorporated in the Russian segment of the ISS. The similar systems have been successfully operated on the Mir space station. The updates aim at enhancing system cost-effectiveness and reliability. The system for water recovery from humidity condensate (WRS-C) features an added assembly for the removal of organic contaminants to be catalytically oxidized in an air/liquid flow at ambient temperature and pressure. The system for water reclamation from urine (WRS-U) incorporates a new distillation subsystem based on vacuum distillation with a multistage rotary distiller and a vapor compression or thermoelectric heat pump. The updating of the WRS-C system will enable an increase in the multifiltration bed's life at least two fold.

A concept of LSS building for planetary stations is suggested on the basis of experience in the development, research and testing of physical/chemical regenerative LSS for long-duration ground-based bio-technical complexes of habitat support and for orbiting space stations. A gradual transition from integrated physical/chemical regenerative LSS to hybrid integrated physical/chemical and bio-technical LSS and finally to integrated bio-technical regenerative LSS, is suggested. It is shown that at all phases of integrated LSS development, the systems based on physical/chemical processes will be critical for correlating the interfaces between the biological components that process the products obtained in the bio-components, and enabling the vitality of integrated LSS under emergency situations. The interface of integrated LSS with base power supply system is outlined.

The paper reviews an integrated system for space station water supply based on a combination of water recovery systems and a water resupply system. The water balance data and system performance data in long-duration operation on the Mir space station are presented. A water supply concept for the Russian's segment (RS) of the International Space Station (ISS) is substantiated.

The report addresses the actions that are to be taken to assure complete safety of oxygen supply systems operation along with electrolysis units. The paper is based on over the 30-year experience gained in design, development, testing and flight operational use of the Russian space vehicles that currently made it possible to develop and successfully operate the long-duration service life oxygen supply systems.

The report is based on the activities conducted at S.P.Korolev RSC Energia supporting to the Mir space station. Mir has been flying since February 1986, with more than 8,5 years being in the manned mode of operation. The report addresses the gas composition requirements of the Gas Composition Support Aids (GCSA), operational data on the atmospheric composition and information about individual gas composition support aids.

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.