RU2165871C1 - Device for separation of liquid and gas under weightlessness conditions - Google Patents

Abstract

FIELD: space engineering; cleaning liquids from gaseous inclusions under conditions of weightlessness and microgravitation. SUBSTANCE: device has housing made in form of two truncated cones interconnected by means of circular insert by their large bases. Partitions mounted inside housing form taper circular passages widening towards central axis of housing. Capillary intake unit with outlet branch pipe is fitted between edges of partitions and circular insert. Inlet branch pipe of housing is parallel to axis of housing; holes made in its surface are perpendicular to plane passing through axes of branch pipe and housing. One or more holes are provided between partitions and between end partition and housing. Drain branch pipe and its inlet are found in central portion of housing. This branch pipe is provided with throttle valve, outlet valve and taper shield. LIQUID-GAS indicator is fitted in central portion of housing. Similar indicator is also provided between partitions or between partition and housing. Small base of one of cones may be provided with transparent portlight. EFFECT: reduced mass and overall dimensions. 2 cl, 1 dwg

Description

 The invention relates to space technology and is intended for the purification of liquids from gas inclusions in zero gravity and microgravity conditions in space objects systems.

 An analogue of the proposed device is a centrifugal separator, presented in Fig. 2.21 p. 47 of the book "Capillary system for the selection of liquid from tanks of spacecraft" edited by a professor, Doctor of Technical Sciences V. M. Polyaeva, M., Educational and Scientific Production Center "Energomash", 1997

 The centrifugal separator includes a cylindrical container, an annular diffuser for incoming fluid, a nozzle inlet apparatus, a pipe for exhausting gas, and a tangential nozzle for removing fluid. The location of the nozzle apparatus and the tangential nozzle for draining the liquid create a swirling rotational movement of the liquid in the cylindrical body of the separator, as a result of which the gas inclusions contained in the liquid are separated to the axis of the body under the action of centrifugal forces and form a cylindrical gas cushion around the axis of the separator. Gas from the cushion is removed through a pipe located on the axis of the separator. Liquid without gas inclusions is supplied through an annular diffuser for the outgoing liquid.

 The disadvantage of the centrifugal separator considered is that it is operable only at a fluid flow rate and provided that the overloads acting on it cannot substantially change and displace the cylindrical shape of the gas cushion supported by the centrifugal forces of the rotating fluid.

 Therefore, the removal of gas from such a separator, without supplying liquid or at low flow rates, is impossible even in zero gravity conditions, since the gas cushion in this case will take an equilibrium shape and move away from the drainage pipe. In addition, the flow of fluid without small bubbles cannot be guaranteed without special capillary intake devices (KZU).

 The prototype of the proposed device is a capillary fluid sampling system (CSF), shown in Fig. 4.15, p. 94 of the book "Capillary system for the selection of liquid from tanks of spacecraft" edited by a professor, Doctor of Technical Sciences V.M. Polyaeva, M., Energomash Educational Scientific Research Center, 1997. This system includes a fuel tank compartment, a capillary intake device (KZU), and a nozzle for fluid outlet. The tank compartment has a cylindrical shell with an elliptical bottom, which in itself does not provide localization of the liquid and gas cushion in certain places of the compartment and therefore the KZU has a complex system of branched channels that allows fluid to be taken from anywhere in the tank compartment.

 The disadvantage of the considered CSF is that it does not allow gas to accumulate in a certain place of the tank compartment and, therefore, to periodically remove it. Therefore, a separator of this type must have large dimensions and a volume for accommodating all the gas to be separated inside it, i.e. essentially a one-shot system.

 The objective of the invention is to provide a small-sized and lightweight device for cleaning liquids from gas inclusions and removing gas from a gas contaminated liquid under zero gravity conditions, and thus providing clean liquid through a short-circuit breaker, as well as localizing the gas cushion and draining it from the central part of the separator without ejection of fluid.

 This problem is solved in that the proposed device for separating liquid and gas in zero gravity conditions comprises a housing with an inlet pipe, a capillary intake device with an output pipe; the housing is made in the form of two identical truncated cones, interconnected by large bases using an annular insert, which is a body of revolution; inside the case there are partitions, the axis of symmetry of which coincide with the central axis of the case, while the partitions are located from each other and the extreme of them from the case with the same angular pitch and form conical annular channels expanding to the central axis of the case; between the peripheral edges of the partitions and the inner surface of the annular insert with a gap placed a capillary intake device with an outlet pipe; the inlet pipe of the device is made in the form of a pipe whose axis is parallel to the axis of the housing; at the same time, holes are made on the surface of the pipe, the axes of which are perpendicular to the plane passing through the axis of the pipe and the body and are directed in the same direction, at least one hole is located between the adjacent partitions, and also between the extreme partitions and the inner surface of the body; a drainage pipe is installed in the central part of the housing, the inlet of which is located in the center of the housing and is equipped with a throttle, and a valve is installed at its outlet; while on the drainage pipe there is a conical screen with the top of the cone facing the inlet of the pipe; a central liquid-gas detector is installed in the central part of the housing, and at least one liquid-gas detector is installed between partitions or partitions and the inner surface of the housing. A transparent porthole is made in the small base of the body cone.

The drawing shows a diagram of a device where
1 - housing
2 - ring insert
3 - partitions,
4 - capillary intake device (KZU),
5 - drainage pipe,
6 - throttle,
7 - conical screen,
8 - inlet pipe
9 - holes of the inlet pipe,
10 - porthole
11 - signaling device "liquid - gas",
12 - signaling device "liquid - gas",
13 - output pipe
14 - valve.

 The device for separating liquid and gas has a housing 1 in the form of two truncated cones folded with large bases, inside of which are placed partitions 3, uniformly converging with the same angle to the periphery of the housing 1 and forming conical annular channels. At the equator itself, behind the partitions inside the separating device, there is a short circuit 4. An internal cavity of the short circuit 4 is connected to the outlet pipe 13. In the center of the body there is a drain pipe 5 with a throttle 6, a conical screen 7 and a valve 14.

 In the middle part of the housing 1, an inlet pipe 8 is installed with openings 9 for supplying gassed liquid to the device. The inlet pipe 8 of the device is made in the form of a pipe whose axis is parallel to the axis of the housing 1; while on the surface of the pipe between adjacent partitions 3 holes 9 are made, the axes of which are perpendicular to the plane passing through the axis of the pipe and the body and are directed in one direction, the same holes are made between the end walls 3 and the inner surface of the body. The specified holes 9 must be at least one.

 The truncated cones of the housing 1 with large bases are interconnected using an annular insert 2, which is a body of revolution.

 Near the entrance to the drainage pipe 5, a central liquid-gas signaling device 11 is installed. At least one liquid-gas peripheral signaling device 12 is installed between the partitions 3 or the partitions and the inner surface of the housing.

 A transparent porthole 10 is placed on the small base of the body cone.

To increase the reliability of the device when exposed to alternating overloads, at least three peripheral signaling devices 12 can be introduced. In this case, 3 peripheral signaling devices 12 must be located relative to the housing axis at an angle of 120 ^o in a plane perpendicular to the housing axis, which ensures the presence of gas with a minimum volume liquids.

 The design of KZU 4 may, for example, consist of a set of tube blocks welded together, perforated along the surface with holes. On the outside of the blocks, a fine mesh is fixed.

 The proposed device operates as follows.

 Before work, the entire internal volume of the device and KZU 4 are filled with clean liquid without gas inclusions.

 The inlet pipe of the fluid supply 8 is connected through a pump to a removable reservoir of gas-polluted liquid, the outlet pipe 13 is connected to a consumer of clean liquid.

 In the process of operation of the device, clean liquid is drawn through the outlet pipe 13, and liquid and gas are supplied in its place through the inlet pipe 8. The tangential fluid inlet through the openings 9 of the inlet pipe 8 creates a fluid swirl in the inner cavity of the housing 1, which contributes to centrifugal forces the movement of bubbles in the liquid to the center of the body and the formation of a single gas cushion in the region of its axis. Conical annular channels formed by partitions 3 or partitions 3 and the inner surface of the housing 1 prevent the displacement of the gas cushion in the radial direction under the influence of random overloads.

 Gas bubbles at the exit of the inlet pipe 8, having a size greater than the width of the conical channels between the partitions 3 or partitions 3 and the inner surface of the housing 1, are pushed toward the center of the housing 1 by capillary forces and combined with the gas cushion. At the periphery of the device, the system of partitions 3 provides a constant contact of liquid with KZU 4, from which the liquid purified from gas inclusions flows through the outlet pipe 13 to the consumer.

 When the gas cushion occupies the entire central zone of the device’s body, while maintaining alignment, it will begin to move into the zone of the conical partitions 3 and gradually reach the peripheral liquid-gas signaling device 12. When the central 11 and peripheral signaling devices 12 simultaneously show the presence of gas, gas drainage opens drainage pipe 5 and valve 14. Drainage continues until the gas cushion is almost completely removed, into which gas-polluted liquid enters.

 When the indicator 11 indicates the presence of liquid, the valve 14 closes and the gas drain stops. The number of gas drainage cycles is thus not limited, which allows the same device to clean any volume of gas contaminated.

 To increase the reliability and the ability to visually monitor the operation of the device, a porthole 10 is installed on the front wall of the housing 1.

 Based on the task, a form of the device is chosen that, in conditions of practical zero gravity, facilitates the accumulation and retention of a sufficiently large volume of gas by capillary forces only in the central part of the device around the throttle of the drainage pipe 5. This ensures the possibility of gas drainage in zero gravity conditions. At the same time, the selected design of KZU 4 allows it to work under conditions of variable overloads of any direction available at the orbital station.

 The proposed device can be used, for example, in the life support systems of the orbital stations MIR, ISS. It can ensure trouble-free operation of centrifugal liquid transfer pumps, which eliminates the time spent on the crew of the stations to restore the operability of the systems.

 The proposed device was manufactured and tested both in ground conditions and in zero gravity conditions at the Mir orbital station as part of the Volna-2A space hydraulic stand. The test results confirmed the device’s operability in the modes corresponding to the standard conditions for liquid supply on board the orbital stations in the Electron-V system.

 A device for separating liquid and gas is simple to manufacture, does not require expensive and scarce materials, and its implementation in space technology is economically justified and expedient.

Claims (2)

 1. A device for separating liquid and gas in zero gravity, comprising a housing with an inlet pipe and a capillary intake device with an outlet pipe, characterized in that the housing is made in the form of two identical truncated cones, interconnected by large bases using an annular insert in the form of a body rotation, inside the case there are partitions, the axis of symmetry of which coincide with the central axis of the case, while the partitions are located relative to each other and the outermost ones relative to the case - with one the angular pitch, forming conical annular channels expanding to the central axis of the housing, between the peripheral edges of the partitions and the inner surface of the annular insert with a gap is placed the specified capillary intake device with an outlet pipe, while the specified inlet pipe is made in the form of a pipe whose axis is parallel to the axis of the housing , holes are made on the surface of the pipe, the axes of which are perpendicular to the plane passing through the axis of the pipe and the body, and are directed in one direction, and between adjacent partitions at least one hole is located between the extreme partitions and the inner surface of the housing, and a drainage pipe is installed in the central part of the housing, the inlet of which is located in the same part of the housing and is equipped with a throttle, and a valve is installed at the outlet of the pipe, while the drainage pipe is placed a conical screen with the apex of the cone facing the inlet of the nozzle, a central liquid-gas detector is installed in the central part of the housing, and between the partitions or between the partitions and the inner surface At least one liquid-gas peripheral alarm is installed by the housing.  2. The device according to claim 1, characterized in that in the small base of one of the cones of the casing a transparent porthole is made.