RU2096655C1 - Gas-liquid machine - Google Patents

Abstract

FIELD: engine engineering. SUBSTANCE: machine has two tanks partially filled with liquid. To the first tank a hydraulic motor is connected. The outlet of the hydraulic motor is connected to the second tank. The pressure of liquid in the first tank is higher than that in the second tank. As a result a pressure drop is at the working member of the hydraulic motor that allows generation of mechanical energy. There is also a slide valve with a chamber. The slide valve reciprocates. The chamber of the slide valve is connected alternatively with the first and the second tanks. When the slide moves from the first tank to the second tank the chamber brings gas whereas moving back the chamber brings liquid. EFFECT: improved efficiency. 4 cl, 5 dwg

Description

 The invention relates to the field of hydraulics and for gas-liquid machines.

 A gas-liquid machine is known comprising a first container partially filled with liquid, and partially gas, a second container completely or partially filled with liquid, wherein the pressure of the liquid in the second container is less than the pressure of the liquid in the first container to that part of the first container which is filled with liquid a hydraulic motor or other consumer of a given fluid is connected, a spool installed in the housing, a spool made with the ability to make any periodically repeating movement, for example, a reciprocating post atelnoe inner surface or the outer surface of the slide surface of the spool and the inner surface of the housing, wherein the valve chamber is formed is installed.

 The disadvantage of this invention is that the spool chamber is used to connect two containers to each other, that is, the spool chamber is simultaneously in communication with both tanks and for continuous operation of the device, at least three tanks, one second and two first, are required.

 An object of the invention is to simplify the design, reducing the size and weight.

 The specified technical problem is achieved due to the fact that in the known gas-liquid machine having a first container, partially filled with liquid, and partially with gas, there is a second container, or completely or partially filled with liquid, while the pressure of the liquid in the second container is less than the pressure of the liquid in the first capacity, to that part of the first capacity that is filled with liquid, either a hydraulic motor or other consumer of this liquid is connected, there is a spool installed in the housing, the spool is made with the possibility make any periodically repeating movement, for example, reciprocating, either with the inner surface of the spool or the outer surface of the spool and the inner surface of the housing in which the spool is mounted; the chamber is made with the possibility of alternating communication as with that part of the first tank that is filled with gas, so with the part of the second container that is filled with liquid.

 In addition, the output of the hydraulic motor can be connected to a second tank.

 In addition, an external gas source may be connected to the first container.

 In addition, an outlet channel is connected to that part of the second container that is filled with gas.

 In FIG. 1-5 shows a gas-liquid machine during operation.

 The inventive solution in a variant of the engine is the following. There is a first container 1 / Fig. 1-5 /, partially filled with liquid 2. A pipe 3 is connected to the container 1, to its part that is filled with the liquid, the other end of which is connected to the outlet to the hydraulic motor 4. The output from the hydraulic motor 4 is connected to the second container 5 filled with the liquid 6 (fully or partially). There is a spool 7, consisting of two cylindrical parts of equal diameter, and interconnected using a rod 8, a constant cylindrical section and having a smaller diameter than both halves of the spool 7. The outer surface of the spool 7 and the rod 8, and the inner surface of the housing, in which the spool 7 is installed (i.e., the walls of the tank 1) form a chamber 9 of a well-defined volume. The spool 7 can make reciprocating movements, and its chamber 9 can alternately communicate with either the first tank 1 or the second tank 5. Moreover, when the camera 9 communicates with the tank 1, it is located in that part of the tank 1 that is filled with gas , and the chamber 9 communicates with the tank 5, then it communicates with the part of the tank that is filled with liquid. An input channel 10 is connected to a container 1, to that part of it which is filled with gas, which serves to supply gas to the container 1. An outlet channel 11 is connected to a container 5, to that part of it which is filled with gas, which serves to remove gas from the container 5 to the atmosphere.

 The inventive machine in an embodiment of the engine operates as follows. The liquid 2 (Fig. 1-5) in the tank 1 is affected by gas pressure. Under the influence of this pressure, the liquid 2 through the pipeline 3 enters the inlet of the hydraulic motor 4, acts on its working body, forcing it to generate mechanical energy, which can be transmitted to the consumer in this form, or converted using electric generator into electricity, and transmitted to the consumer in this form .

 After passing the hydraulic motor 4, the liquid enters the tank 5. The pressure of the liquid 6 in the tank 5 and the gas pressure on its surface and the pressure of the liquid 6 in the tank at the outlet of the hydraulic motor 4 is less than the pressure of the liquid 2 in the tank 1 and at the inlet of the hydraulic motor 4, due to which forms the pressure drop of the liquid on the working body of the hydraulic motor 4, which allows to generate mechanical energy. The gas pressure on the surface of the liquid 2 in the tank 1 is greater than the gas pressure on the surface of the liquid 6 in the tank 5.

 At the moment when the spool 7 communicates with the tank 1 with its chamber 9 (Fig. 1), it is located in that part of the tank 1 that is filled with gas, and therefore the chamber 9 is filled with gas. At this point, the camera 9 is isolated from the tank 5.

 When translating the spool 7 with the chamber 9 filled with gas from the tank 1 to the tank 5, at a certain moment the camera 9 is isolated from the tank 1 (Fig. 2). At this point, the camera 9 is also isolated from the tank 1 (Fig. 2). At this point, the camera 9 is also isolated from the tank 5.

 With further translational movement of the spool 7, its chamber 9 (Fig. 3) communicates with the capacity 5, with that part of it which is filled with liquid. At this moment, the chamber 9 is isolated from the tank 1. The gas from the chamber 9 rises to the surface of the liquid 6 in the tank 5, and then is released into the atmosphere through the outlet channel 11 (shown in the figure in the finish). At the same time, the chamber 9 is filled with liquid 6 entering it from the tank 5.

 After filling the chamber 9 with liquid 6, the spool 7 begins to move in the opposite direction / in the direction of the tank 1 /. At a certain moment, the chamber 9 (Fig. 4), filled with liquid, is isolated from the tank 5. At this moment, it is also isolated from the tank 1.

 With further movement of the spool 7 in the direction of the tank 1, its chamber 8, filled with liquid, communicates with the tank 1 (Fig. 5). The liquid under the influence of gravitational force (gravity) flows from the chamber 9 into the tank 1, and at the same time, the chamber 9 is filled with gas from the tank 1. This is possible because the chamber 9 communicates with the part of the tank 1 that is filled with gas. At this moment, the chamber 9 is isolated from the tank 5. In the future, the liquid that entered from the chamber 9 into the tank 1 is again fed through the pipeline 3 to the inlet of the hydraulic motor 4, and then everything is periodically repeated.

 After all the liquid has flowed out of the chamber 9, the chamber 9 is again filled with gas. The spool 7 with the chamber 9 filled with gas begins to move in the opposite direction in the direction of the tank 5 and then everything is periodically repeated.

 In place of the volume of gas removed by the chamber 9 of the container 1, a new portion of gas enters the container 1 through the inlet channel 10, and so everything is periodically repeated.

 Thus, the spool 7 with the chamber 9 makes reciprocating movements, alternately communicating the chamber 9, then with the capacity 1, then with the capacity 5. Moreover, when moving from the tank 1 to the tank 5, the spool 7 in the chamber 9 transfers gas, and when moving in the opposite direction carries fluid. The system is closed in the hydraulic sense, i.e. how much liquid goes out through the pipe 3 from the tank 1, the same amount of it flows through the chamber 9 into the tank 1. At the same time, the spool 7 and the camera 9 are shaped so that they are not affected by the gas pressure in the tank 1 and the liquid pressure in the tank 5 that is, these pressures do not interfere with the reciprocating movement of the spool 7. Only the force due to the inertial mass of the spool 7 and the gas or liquid in the chamber 9, as well as the friction forces arising in the contact zone of the spool 7 with case in which about n installed.

 As for the possibility of using the proposed solution in an engine variant in a gas liquefaction system (cryogenic systems), it can be used in the form shown in FIG. 1-5. The only difference will be that the liquefied gas, when supplied from the chamber 9 of the spool 7 into the container 5, turns into a liquid, because its pressure and temperature decreases. In this case, the density of the liquefied gas must be less (or greater) than the density of the fluid circulating through the pipe 3 and the hydraulic motor 4 (circulating fluid) so that it is possible to separate the liquefied gas and circulating fluid. The resulting liquid (liquefied gas) rises to the surface of the circulating liquid in the tank 5, and then collects in any way possible, for example, pumped out because a layer of liquefied gas will have a very definite thickness, and is sent to the consumer. At the same time, the chamber 9 of the spool 7 is filled with a circulation fluid. Otherwise, everything happens similarly to the case considered above. In this embodiment, the input channel 10 is connected to the outlet of the compressor of the cryogenic system.

 Thus, applying the claimed solution in a cryogenic system, we obtain mechanical energy using a hydraulic motor 4, while in existing cryogenic systems, the energy of compressed gas is lost irrevocably (without performing work) in a throttle valve.

 The inventive solution can be used in the version of the engine both under pressure and as an independent power plant.

 The inventive solution can be used as a pump, employee or fluid supply. In this embodiment, in the circuit shown in FIG. 1-5, there will be no hydraulic motor 4. In this case, the pipeline 3 and the tank 5 can be made both closed and open in hydraulic terms.

 An embodiment of the claimed solution is possible when, at the moment when the chamber 9, filled with gas and isolated from the tanks 1 and 5 (Fig. 2), is connected in any possible way (for example, by means of a valve) with a gas engine (piston, turbine, etc.) P.). Gas leaves the chamber 9 in a gas engine, thereby doing the job. In this case, the gas pressure in the chamber 9 decreases. At a certain point, the valve closes and the chamber 9 is isolated from the gas engine. In the future, everything happens similarly to the case considered above. In this embodiment, additional mechanical energy is obtained due to the work performed by the compressed gas in the gas engine.

 An embodiment of the claimed solution is possible, which differs from the one discussed above in that it exits from the chamber 9 into a volumetric gas engine, for example, a piston. At the moment when the piston of the gas engine is at bottom dead center (BDC), the chamber 9 is isolated from the gas engine. When the piston of the gas engine moves from the BDC to the top dead center / TDC / it compresses the gas coming from the chamber 9 to the pressure to which there is enough energy stored by the flywheel when the piston moves from the TDC to the BDC at the time of gas expansion in the gas engine. In this embodiment, the gas engine plays the role of a kind of battery, which allows to reduce the gas flow through the tank 5, and therefore, increase the efficiency of the engine since the fluid flow through the hydraulic motor 4 has not changed, and therefore, the mechanical energy generated by the HD 4 has not changed, while the gas flow has decreased. Of course, the pressure of the gas compressed by the gas engine will be less than the gas pressure in the tank 1 to the chamber 9 due to various kinds of losses - mechanical, thermal, hydraulic.

 The chamber 9 of the spool 7 can be formed as the outer surface of the spool 7 and the inner surface of the housing in which the spool 7 is installed, and only the inner surface of the spool, or in any other way.

 Spool 7 can make any periodically repeating movement: reciprocating, rotational, etc.

 A possible embodiment of the proposed solution (when it is used in a gas liquefaction system) is when the liquefied gas obtained in this liquefaction system is used as the liquid creating a pressure at the inlet to the hydraulic motor 4.

 In the claimed solution, the level of the liquid surface in the first tank can be either lower or higher, or at the same level, with the liquid surface level in the second tank (when the surface of the liquid is formed in the tanks both due to the action of gravitational force on the liquid, and under the action of a centrifugal force on the liquid, in the latter case, the entire gas-liquid machine is made rotating around a certain axis, and the containers with liquids are located at a certain distance from the axis of rotation).

 A variant of the work of the claimed solution is possible when the gas from the chamber formed by the outer surface of the spool and the inner surface of the housing in which the spool is installed does not all come from the first tank to the second tank. In this case, at the moment when the spool chamber, filled with gas and isolated both from the first tank and from the second tank, communicates in any possible way, for example, by means of a valve, with an external gas consumer. Gas from the chamber enters the consumer, and at a certain point the valve isolates the chamber from the consumer. Subsequently, the spool chamber with the gas remaining in it moves towards the second tank and communicates with it. In the future, everything happens similarly to the above-considered option of the claimed solution.

 The inventive solution, when used as an independent power plant, can receive gas under a certain pressure entering the first tank, which can be either products of fuel combustion or steam obtained by evaporating the liquid in a steam generator.

 A possible embodiment of the claimed solution is when the entire tank 1 and partially the chamber 9 of the spool 7 (shown in FIG. 1 in the initial application materials) are filled with liquid 2. In the space of the chamber 9 that is not filled with liquid 2 through the outlet channel 10, which can be located as in the place shown in FIG. 1, and in that place of the chamber 9, with unfilled liquid 2, in both cases, the inlet channel 10 is connected to the tank 1, a gas is supplied having a well-defined pressure greater than the gas pressure in the tank 5. At a certain point in time, the inlet channel 10 and part of the chamber 9, filled with gas, is isolated from each other (for example, using a valve). The gas in the chamber 9 begins to expand, displacing the liquid 2 from the chamber 9 into the tank 1, and then through the pipe 3 to the entrance to the hydraulic motor 4, and then to the tank 5. Thus, mechanical energy is generated by the hydraulic motor 4.

 At the time when the entire chamber 9 and part of the container 1 is freed from the liquid 2, the spool 7 with the chamber 9 filled with gas begins to move towards the tank 5. With the further movement of the spool 7, its chamber 9 communicates with the tank 5 and gas from the chamber 9 goes into the tank 5, at the same time the chamber 9 is filled with liquid 6 from the tank 5. In the tank 1 filled with gas, all this time the gas expands; the gas pressure at the time when the chamber 9 of the spool 7 was isolated from the tank 1 was even higher than the pressure gas in the tank 5, and therefore, all this time hydraulic motor 4 produces mechanical energy.

 The chamber 9 filled with liquid begins to move from the tank 5 to the tank 1, and at a certain moment it communicates with the tank 1 and the liquid from the chamber 9 flows out (due to the action of gravitational force on the liquid) into the tank 1. After that, into the chamber 9 space filled with gas , a new portion of gas is supplied through inlet channel 10, and then everything is periodically repeated.

 In this embodiment of the claimed solution, more mechanical energy is obtained than in the case discussed above due to a greater expansion of the gas in the tank 1. All the time when the spool 7 with the chamber 9 moves from tank 1 to tank 5 and vice versa, it goes to tank 1 the process of expansion of the gas, that is, the liquid continues to flow continuously at the inlet to the hydraulic motor 4 for the entire duration of the proposed solution, only the fluctuation (cyclic) of the fluid pressure at its inlet occurs.

Claims (4)

 1. The gas-liquid machine has a first tank, partially filled with liquid, and partially gas, there is a second tank, or completely or partially filled with liquid, while the pressure of the liquid in the second tank is less than the pressure of the liquid in the first tank, to that part of the first tank, which it is filled with liquid, either a hydraulic motor or other consumer of this liquid is connected, there is a spool installed in the housing, the spool is made with the ability to make any periodically repeating movement, for example a translational chamber, or the inner surface of the spool, or the outer surface of the spool and the inner surface of the housing in which the spool is installed, a chamber is formed, characterized in that the chamber is arranged to alternately communicate both with that part of the first container that is filled with gas, and with that part of the second container, which is filled with liquid.  2. The machine according to claim 1, characterized in that the output of the hydraulic motor is connected to a second tank.  3. The machine according to claims 1 and 2, characterized in that an external gas source is connected to the first tank.  4. The machine according to claims 1 to 3, characterized in that an output channel is connected to that part of the second tank that is filled with gas.

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