RU2804503C1 - Water recovery system from atmospheric moisture condensate - Google Patents

Abstract

FIELD: spacecraft.

SUBSTANCE: invention relates to regeneration life support systems of a closed type, mainly for the crew of a spacecraft. The system comprises a fan, a refrigeration and drying unit, gas and liquid phase separators, pumps, columns with a sorbent for condensate treatment, a conductometric sensor, a regenerated water mineral composition conditioning unit, drinking water containers, and a water distribution and heating unit. After the first pump and before the second specified phase separator, a microwave device is introduced to sterilize the incoming condensate. After the specified conditioning unit and in front of the drinking water containers, a device for treating water with a high-frequency current with simultaneous saturation with silver is connected. A hydrophobic coating, for example, based on fluoroplast, is applied to the inner surfaces of pipelines, assemblies and units of the system.

EFFECT: increasing the service life of columns with a sorbent for cleaning the condensate of atmospheric moisture by ensuring the sterilization of this condensate at the inlet to the system of its regeneration and at the outlet of it.

1 cl, 1 dwg

Description

The proposed invention relates to the field of creating regenerative physico-chemical maximally closed life support systems for the crew of a long-term operating spacecraft.

The invention can also be used in special hermetic objects for various purposes.

There is a known general approach to the development of a life support system for a manned spacecraft, based on the circulation (regeneration) of basic substances - oxygen and water (Gusenberg A.S. Regeneration and air conditioning. // Space biology and medicine / O.G. Gazenko, A. I. Grigoriev (Russia); A.E. Nikogosyan, S.R. Mohler (USA), editor M., 1994. T. 2. P.252-312; Sinyak Yu.E., Gaidadymov V.B., Skuratov V.M., Sauer R.L., Murray R.U. Water supply for crews. // Space biology and medicine / O.G. Gazenko, A.I. Grigoriev (Russia); A.E. Nikogosyan, S.R. Mohler (USA), ed. M., 1994. T. 2. P.337-374).

As for water, various water-containing wastes in the spacecraft are regenerated in subsystems individual for each water source.

Each water regeneration subsystem is combined with one or more devices in which water-containing waste is collected. Thus, the subsystem for regenerating water from atmospheric moisture condensate is combined with a refrigeration and drying unit, which regulates the temperature and humidity of the apparatus atmosphere and collects atmospheric moisture condensate. The subsystem for regenerating water from sanitary waste is connected to shower and washbasin devices, and the subsystem for regenerating water from urine is connected to a sewage disposal device (Sinyak Yu.E., Gaidadymov V.B., Skuratov V.M., Sauer R.L., Murray R.U. Water supply for crews // Space biology and medicine / O.G. Gazenko, A.I. Grigoriev (Russia), A.E. Nikogosyan, S.R. Mohler (USA), editors M., 1994. T. 2. P 361).

The closest in technical essence to the claimed invention is a system for regenerating water from atmospheric moisture condensate, which includes the following main processes: separation of the gas-liquid mixture, purification of the condensate from harmful impurities, enrichment with mineral components, preservation with silver ions and heating. The technological process of regeneration is based on the principle of sorption purification using ion exchange resins (cationites and anionites) and activated carbons. The former are designed to remove ionized compounds, the latter - organic substances - non-electrolytes. The water regeneration system from atmospheric moisture condensate contains a fan, a refrigeration-drying unit, gas and liquid phase separators, pumps, columns with sorbent for condensate purification, a conductometric sensor, a conditioning unit for the mineral composition of regenerated water, drinking water containers, a water distribution and heating unit. (Sinyak Yu.E., Gaidadymov V.B., Skuratov V.M., Sauer R.L., Murray R.U. Water supply for crews. // Space biology and medicine / O.G. Gazenko, A.I. Grigoriev (Russia); A.E. Nikogosyan, S.R. Mohler (USA), editor M., 1994. T. 2. P. 367-368).

Together with atmospheric moisture condensate, microorganisms enter the regeneration system, further contaminating the block of purification columns and multiplying in the regeneration system as a whole.

To prevent the growth of microflora on sorbents, “a small amount of bactericidal sorbents containing silver or iodine is sometimes placed in the input and final layers of the block of condensate purification columns,” which is clearly not enough. Therefore, the problem of sterilization of atmospheric moisture condensate is associated with increasing the service life of sorbents included in the block of purification columns due to the complete destruction of microflora (Sinyak Yu.E., Gaidadymov V.B., Skuratov V.M., Sauer R.L., Murray R.U. Water supply for crews // Space biology and medicine / O.G. Gazenko, A.I. Grigoriev (Russia), A.E. Nikogosyan, S.R. Mohler (USA), ed. M, 1994. T. 2. P. 362).

The disadvantages of such a system are:

- lack of sterilization of atmospheric moisture condensate at the entrance to and exit from the regeneration system;

- reduction in the service life of columns with sorbent for condensate purification due to the presence of microflora.

The objective of the invention is to prevent the growth of microflora on sorbents.

The technical result of the claimed invention is to ensure sterilization of atmospheric moisture condensate at the entrance to its regeneration system and at the exit from it; increasing the service life of columns with sorbent for condensate purification.

The technical result is achieved by incorporating a water regeneration system from atmospheric moisture condensate containing a fan, a refrigeration-drying unit, gas and liquid phase separators, pumps, columns with sorbent for condensate purification, a conductometric sensor, a conditioning unit for the mineral composition of reclaimed water, drinking containers water, water distribution and heating unit, after the first pump and before the second gas-liquid phase separator, a microwave device is introduced to sterilize the incoming condensate; after the block for conditioning the mineral composition of regenerated water and in front of the drinking water containers, a device is additionally connected for treating water with high-frequency current while simultaneously saturating it with silver, and a hydrophobic coating, for example based on fluoroplastic, is applied to the internal surfaces of pipelines, components and blocks of the system.

The use of microwave heating to sterilize atmospheric moisture condensate at the entrance to its regeneration system is used for the first time and is an unknown technical solution.

During microwave heating, heat release occurs directly in the volume of the heated condensate and practically without the participation of the thermal conduction mechanism. This heating is fast and easily controlled.

The combination of microwave heating of atmospheric moisture condensate at the entrance to the system and the presence of bactericidal sorbents containing silver or iodine in the inlet and final layers of the purification column block ensures the sterilization of condensate contaminated with vegetative forms of microorganisms.

The use of a device for supplying high frequency current to regenerated water after its mineralization is an unknown technical solution and is being used for the first time.

In this case, the high-frequency current is supplied directly to the water through electrodes located coaxially in relation to each other, and can be made of silver or coated with silver, saturating the water with silver ions formed under the influence of the high-frequency current, while destroying any remaining residual microflora . The optimal dose of silver in water is determined experimentally by changing the strength of the high-frequency current.

The use of hydrophobic material for application to various surfaces is known in the art. However, the use of such a coating on the internal surfaces of pipelines, components and blocks of a water regeneration system is unknown and is being used for the first time. The use of such a coating complicates the deposition of microorganisms in the system as a whole and ensures optimal functioning of the process of regeneration of atmospheric moisture condensate.

The use of high-frequency current at the entrance to the water regeneration system from atmospheric moisture condensate is difficult due to the low specific electrical conductivity of the condensate (GOST R50804-95. Habitat for an astronaut in a manned spacecraft. General medical and technical requirements, pp. 107-108).

Brief description of the drawing

The proposed technical solution is illustrated in Figure 1, which shows a diagram of a system for regenerating water from atmospheric moisture condensate.

The system consists of: 1 - fan; 2 - refrigeration and drying unit; 3 - gas and liquid phase separators; 4 - pumps; 5 - columns with sorbent for condensate purification; 6 - conductometric sensor; 7 - conditioning unit for the mineral composition of regenerated water; 8, 9 - containers of drinking water; 10 - water distribution and heating unit; 11 - Microwave devices for sterilization of condensate; 12 - devices for treating water with high frequency current.

The inventive system includes a pipeline connected to the fan 1, to which, in the direction of travel, is connected the input of the refrigeration-drying unit 2, the output of which is connected to the input of the first gas-liquid phase separator 3, the input of the first pump 4 is connected to the output of it, the output of it is connected to input of microwave device 11 for sterilization of condensate; The input of the second gas-liquid phase separator 3 is connected to the output of the microwave device, and the output from it is connected to the input of the second pump 4. Next, the output of the second pump 4 is connected to the input of the columns with sorbent for purifying the condensate 5, the output from the purification columns is connected to the input of the conductometric sensor 6, the output from it is connected to the input of the conditioning unit for the mineral composition of regenerated water 7, the output from which is connected to the input of the device 12 for treating water with high frequency current, the output from it is connected to the input of drinking water containers 8 and 9, and the output from them is with the input of the water distribution and heating unit 10.

The water regeneration system from atmospheric moisture condensate operates cyclically as follows (see Fig. 1): fan 1 supplies air from the apparatus cabin to the input of the refrigeration-drying unit 2 and then to the first gas-liquid phase separator 3; the condensate formed in the refrigeration-drying unit 2 when regulating the humidity of the atmosphere in the cabin of the apparatus is sucked off by the first pump 4 and supplied to the first gas-liquid phase separator 3, where it is separated from the gaseous phase. The volume of a portion of condensate is limited by the volume of the cavity of pump 4. After pump 4, the separated condensate is collected in the cavity of microwave device 11, which is equal in volume, in which it is heated to the sterilization temperature; after this, the second pump 4 sucks the condensate into the second separator of gas and liquid phases 3 in order to separate the dissolved gas phase released from the condensate during microwave heating; Then, by the second pump 4, the separated condensate is supplied to the block of purification columns 5, which contains successive layers of ion exchangers and activated carbon. Demineralized water enters the cavity of the conductometric sensor 6, where its salt content is assessed, and is sent to the regenerated water conditioning unit 7. Water conditioning is carried out by introducing calcium, magnesium, potassium, sodium, bicarbonates and trace elements into demineralized water: fluorine and iodine. Regenerated drinking water is supplied through a device 12 for water treatment with high frequency current into drinking water containers 8, 9, from where it is consumed as needed by the crew through the distribution and heating unit 10.

Microwave device 11 for sterilizing condensate at the entrance to the system and device 12 for treating water with high-frequency current at the exit from the system operate asynchronously. After microwave heating of a portion of condensate in static conditions to the sterilization temperature, the power supply to the microwave device 11 is turned off. In this case, at the moment the heated condensate is sucked out by the second pump 4, the power supply to the device 12 is turned on for treating water with a high-frequency current at the outlet of the system. Device 12 provides processing of a portion of water in a flow limited by the volume of the cavity of the pump 4. Upon completion of processing of this portion of water, the power supply to device 12 is turned off until the start of the next cycle. The movement of liquid in the system is carried out in portions as it accumulates in the refrigeration-drying unit 2.

Thus, the inclusion in the system of water regeneration from atmospheric moisture condensate of a microwave device for sterilizing the condensate at the entrance to the system and a device for processing the regenerated water and saturating it with silver at the exit of the system leads to an increase in the service life of the condensate purification column unit due to the destruction of vegetative microflora , contaminating the condensate purification column block and the system as a whole. The increase in the service life of the condensate purification column unit is determined experimentally.

In the water regeneration system from atmospheric moisture condensate, condensate from the atmospheric purification system, as well as water generated during the processing of carbon dioxide and hydrogen, can also be further purified.

The proposed system for regenerating water from atmospheric moisture condensate can be used in a promising new generation life support system.

Claims (1)

A water regeneration system from atmospheric moisture condensate, containing a fan, a refrigeration-drying unit, gas and liquid phase separators, pumps, columns with sorbent for condensate purification, a conductometric sensor, a conditioning unit for the mineral composition of reclaimed water, drinking water containers, a water distribution and heating unit , characterized in that after the first pump and before the second gas-liquid phase separator, a microwave device is introduced to sterilize the incoming condensate; after the block for conditioning the mineral composition of regenerated water and in front of the drinking water containers, a device for treating water with high-frequency current while simultaneously saturating it is additionally connected silver, and a hydrophobic coating, for example, based on fluoroplastic, is applied to the internal surfaces of pipelines, components and blocks of the system.