RU92492U1 - EJECTOR UNIT BLOCK - Google Patents

Abstract

1. The block of ejector installations containing a liquid-gas ejector, a pump with a drive, a pipe for supplying liquid to a liquid-gas ejector is connected to the outlet of the pump through a pipeline of high-pressure liquid, a pipe for supplying low-pressure gas to a liquid-gas ejector is connected to a gas pipeline of low-pressure gas, gas-liquid the mixture leaves the ejector through the nozzle into the mixture manifold, characterized in that the low-pressure gas pipeline is connected in parallel to the low-pressure gas supply pipe to the gas-gas ejector, the pipe a high-pressure gas supply to the gas-gas ejector is connected to a high-pressure gas pipeline, and the gas mixture exit nozzle from the gas-gas ejector is connected to the mixture manifold, combining the exits from the liquid-gas and gas-gas ejectors, the liquid-gas ejector being regulated by the flow rate low-pressure gas, for which the outlet from the pump is connected by a liquid recirculation line to the pump inlet through the recirculation pipeline and shut-off and control elements, one at the inlet to the inlet of the high-pressure liquid in the liquid Azov and the second ejector pump inlet. ! 2. The block of ejector installations according to claim 1, characterized in that at the outlet of the nozzle of the liquid-gas ejector to the gas mixture collector combining the exits from the liquid-gas and gas-gas ejectors, a separator is installed, a part of the liquid from the separator through the recirculation pipe and the locking-regulating element is directed to the pump inlet, the gas exits into the manifold of the gas mixture and the remainder of the liquid exits into the pipeline. ! 3. The block of ejector installations according to claim 1, characterized in that at

Description

The utility model relates to equipment for compression (compression) of gas and can be used in the oil, gas and other industries.

A known analogue of the claimed utility model: a method for the joint transport of oil and gas through a pipeline according to the invention, author. testimonial. No. 1071867, F17D 1/12, publ. 02/07/84, bull. No. 5, including mixing gas with a liquid and transporting them under pressure, the liquid is preliminarily accelerated in the narrowed section of the pipeline to the speed at which cavitation occurs, and gas is supplied to the cavitating liquid stream.

Common features of the analogue and the proposed device is

- joint transport of gas and liquid through the pipeline;

- mixing gas with liquid and transporting them under pressure.

The disadvantage of the prototype is the lack of a combination of a drive (liquid-gas) and non-drive (gas-gas) ejector, as a result of which there is no regulation of the performance of low-pressure gas and the simultaneous use of high-pressure gas energy.

A known prototype of the proposed utility model: pump-ejector installation according to the invention of the author testimonial. No. 1439292, F04F 5/54, publ. 11/23/88, Bull. No. 43, comprising a supply pipe, a first separator, a liquid-gas ejector with a pipe for supplying a gaseous passive medium, a pump, the output of which is connected via an hydraulic nozzle to the active nozzle of the ejector, and the input to the first separator, and a second separator connected by a bypass pipe with a regulating element to the first separator and connected by gas to the pipe for supplying a gaseous passive medium of the ejector, the ejector output being connected to the first separator, the hydraulic line is equipped with a heat exchanger, and indeed created a conduit connected with an overflow conduit.

Common to the prototype and the proposed device are signs:

- inlet pipe;

- liquid-gas ejector with a low-pressure gas supply pipe;

- a pump, the output of which is connected to the nozzle of a high-pressure liquid in a liquid-gas ejector.

The disadvantage of the prototype is the large energy loss on the pump drive, due to the lack of a non-drive (gas-gas) ejector for compressing low-pressure gas by high-pressure gas, the lack of temperature control of the liquid heated in the pump at the inlet of the liquid-gas ejector.

The technical task of the utility model is to increase and control the flow rate of a low-pressure gas without additional energy losses to the drive of the pump supplying liquid to the liquid-gas ejector, and to control the heating of the liquid after the pump at the inlet of the liquid-gas ejector.

The stated technical problem is solved in that the block of ejector installations contains a gas-gas ejector and a liquid-gas ejector, a pump with a drive. A pipe for supplying liquid to a liquid-gas ejector is connected to the outlet of the pump through a pipeline of high-pressure liquid, a pipe for supplying low-pressure gas to a liquid-gas ejector is connected to a low-pressure gas pipeline, a gas-liquid mixture leaves a liquid-gas ejector through a nozzle to a mixture manifold, a gas pipeline low-pressure gas in parallel is connected to the pipe for supplying low-pressure gas to the gas-gas ejector, the pipe for supplying high-pressure gas to the gas-gas ejector is connected to the gas pipeline pressure gas, and the nozzle for the outlet of the gas mixture from the gas-gas ejector is connected to the mixture collector combining the exits from the liquid-gas and gas-gas ejectors, the liquid-gas ejector being regulated by the flow rate of the low-pressure gas, for which the output of the high-pressure liquid from the pump is connected by a line liquid recirculation to the pump inlet through the recirculation pipeline and locking and regulating elements, one at the inlet to the nozzle for supplying high-pressure liquid to the liquid-gas ejector and the second at the pump inlet. At the outlet of the nozzle of the liquid-gas ejector, to the mixture manifold, a separator is installed, part of the liquid from the separator, through the recirculation pipe, the recirculation pipe and the shut-off and control element is directed to the pump inlet, the gas enters the manifold of the gas mixture and the remaining liquid enters the liquid pipe and / or combined with gas in the gas mixture manifold. At the outlet of the collector, a separator is installed, part of the liquid from the separator, through the recirculation pipe, the recirculation pipe and the shut-off and control element is directed to the pump inlet, the gas and the remaining part of the liquid exit separately from the separator and / or are combined into a gas-liquid stream.

Figure 1 shows the block of ejector installations according to claim 1 of the utility model formula, which consists of a gas-gas ejector 1, drive 2, pump 3 and a liquid-gas ejector 4.

Gas-gas ejector 1 is equipped with:

- pipe 5 for low-pressure gas inlet,

- pipe 6 for the entrance of high-pressure gas,

- nozzle 7 for the exit of the gas mixture.

The liquid gas ejector 4 is equipped with:

- pipe 8 for low-pressure gas inlet,

- pipe 9 for the entrance of high-pressure fluid,

- nozzle 10 for the exit of the gas-liquid mixture.

The gas-gas ejector 1 and the liquid-gas ejector 4 are connected in parallel through the nozzles 5 and 8 for the low-pressure gas inlet from the low-pressure gas line 11. A pipe 6 for entering the high-pressure gas into the gas ejector 1 is connected to the high-pressure gas line 12. The liquid through the pipe 13 enters the pump 3 then with a higher pressure enters the pipe 9 into the pipe 9 for the high-pressure liquid to enter the liquid-gas ejector 4. Nozzle 7 for the exit of the gas mixture from the gas-gas ejector 1 and the nozzle 10 for the exit of the gas-liquid mixture from a liquid-gas ejector 4 is connected to the manifold 15 of the mixture. In the pipeline 14, it is provided for controlling the flow rate of the liquid supplied to the liquid-gas ejector 4 with a locking-regulating element 16 installed on the pipeline 14 and a locking-regulating element 17 installed on the pipeline 18, supplying liquid from the outlet to the input of the pump 3.

At the outlet of the gas-liquid mixture from the nozzle 10 of the liquid-gas ejector 4, to the manifold 15 according to claim 2 of the utility model, a separator 19 is installed, in which there is a gas outlet pipe 20 to the manifold 15, the liquid from the separator 19 exits through the nozzles 21 and 22. From pipe 22, through the locking and regulating element 23 and the pipeline 24, a portion of the liquid is supplied for recirculation to the inlet of the pump 3. Compressed gas from the manifold 15 enters the gas pipeline 25 for transporting compressed gas. The rest of the liquid from the pipe 21 is fed into the pipe 26 for transporting liquid.

According to claim 3 of the utility model formula, FIG. 2, there is a block of ejector installations according to claim 1, a separator 19 is installed at the outlet of the gas-liquid mixture from the collector 15, in which the gas-liquid mixture with a higher gas content is separated than according to claim 2 of the useful formula model, the gas and liquid supply then occurs through the same pipelines and through the shut-off-regulating element 23, which according to claim 2 of the formula of the utility model.

The block of ejector installations works as follows.

In Fig. 1, low-pressure gas flows from the low-pressure gas line 11 to the pipe 5 of the gas-gas ejector 1 and to the pipe 8 of the liquid-gas ejector 4. High-pressure gas flows from the high-pressure gas line 12 to the pipe 6 of the gas-gas ejector 1. The liquid enters pump 3, from the pump 3 under the action of the drive 2, the high-pressure liquid enters through the pipe 14 into the pipe 9 into the liquid-gas ejector 4. The gas mixture of gases flows through the nozzle 7 of the gas-gas ejector 1 and the gas-liquid mixture through the nozzle 10 of the liquid-gas ejector 4. ABOUT nor enter the manifold 15 of the mixture. The amount of liquid and gas entering the liquid-gas ejector 4 is regulated by shut-off and regulating elements 16 and 17, partial closure of the passage section of element 16 and partial opening of the passage section of element 17. The fluid in the pump is heated as a result of increasing pressure. Recirculating through line 18, the heated liquid heats the gas when a gas-liquid mixture is formed in the ejector 4 and is cooled by gas, mixed and cooled by the mixture of gases flowing from the gas-gas ejector 1, in the manifold 15. From the liquid-gas ejector 4, the gas-liquid mixture through the nozzle 10, a separator 19 enters, where it is separated into liquid and gas, a part of the liquid is directed through a shut-off-regulating element 23 and a pipe 24 for recirculation to the inlet of the pump 3.

In Fig. 2, a separator 19 is installed after the gas-liquid mixture collector 15, a part of the heat of the gas-liquid mixture flowing from the liquid-gas ejector 4 is transferred to the gas mixture flowing from the gas-gas ejector 1. The cooling of the liquid recirculated from the separator 19 in this circuit is higher than in the previous one, due to the greater amount of gas in the gas-liquid mixture separated in the separator 19.

Thus, due to the combination of a gas-gas and a liquid-gas ejector in this block of ejectors, the flow rate of the low-pressure gas is increased and regulated without additional energy losses to the drive of the pump supplying liquid to the liquid-gas ejector. At the same time, the heating of the liquid after the pump at the inlet to the liquid-gas ejector is regulated.

Claims (3)

1. The block of ejector installations containing a liquid-gas ejector, a pump with a drive, a pipe for supplying liquid to a liquid-gas ejector is connected to the outlet of the pump through a pipeline of high-pressure liquid, a pipe for supplying low-pressure gas to a liquid-gas ejector is connected to a gas pipeline of low-pressure gas, gas-liquid the mixture leaves the ejector through the nozzle into the mixture manifold, characterized in that the low-pressure gas pipeline is connected in parallel to the low-pressure gas supply pipe to the gas-gas ejector, the pipe a high-pressure gas supply to the gas-gas ejector is connected to a high-pressure gas pipeline, and the gas mixture exit nozzle from the gas-gas ejector is connected to the mixture manifold, combining the exits from the liquid-gas and gas-gas ejectors, the liquid-gas ejector being regulated by the flow rate low-pressure gas, for which the outlet from the pump is connected by a liquid recirculation line to the pump inlet through the recirculation pipeline and shut-off and control elements, one at the inlet to the inlet of the high-pressure liquid in the liquid Azov and the second ejector pump inlet. 2. The block of ejector installations according to claim 1, characterized in that at the outlet of the nozzle of the liquid-gas ejector to the gas mixture collector combining the exits from the liquid-gas and gas-gas ejectors, a separator is installed, a part of the liquid from the separator through the recirculation pipe and the locking-regulating element is directed to the pump inlet, the gas exits into the manifold of the gas mixture and the remainder of the liquid exits into the pipeline. 3. The block of ejector installations according to claim 1, characterized in that at the outlet of the gas-liquid collector combining the exits from the liquid-gas and gas-gas ejectors, a separator is installed, part of the liquid from the separator through the recirculation pipe, the pipeline and the shut-off and control element are guided at the pump inlet, gas and the remainder of the liquid exit separately from the separator.