RU173673U1 - THREE-SADBORNE EJECTOR MEMBRANE-SORPTION INSTALLATION - Google Patents

Abstract

The utility model relates to membrane-adsorption units for separating gas mixtures and can be used to enrich individual components of gas mixtures in order to obtain enriched components. A three-adsorption hybrid membrane-sorption unit for air enrichment with oxygen consists of two successive blocks of oxygen enrichment for air: sorption and membrane . Gas is supplied by the compressor and enters through one of the adsorbers through the mixing ejector, displacing part of the oxygen-enriched gas into the next adsorber, filling it to operating pressure, and the other part of the stream is taken through the valve to the receiver, from where the gas enters the membrane module. At the same moment, the third, idle adsorber, discharges the existing exhaust gas in it into the atmosphere. In the membrane module, part of the flow passes through the membrane, thereby being further enriched with oxygen, and collected in the receiver for further supply to the consumer, and the other part, thanks to the mixing ejector, is returned to the installation. The technical result achieved by the implementation of the claimed utility model is to obtain the final product high pressure with a constant concentration of components of the gas mixture and a constant installation capacity.

Description

The utility model relates to membrane adsorption devices for separating gas mixtures and can be used to isolate weakly sorbed components from gas mixtures.

The prior art adsorption-membrane installation for the separation of gas mixtures described in patent No. 122907, comprising a compressor, the output of which is connected to two adsorbers and a membrane filter connected through distribution valves to the adsorbers. The adsorbers in this scheme work alternately, with the transfer of a small part of the gas from one adsorber to another to restore the sorption properties of the sorbent, which does not allow to achieve high oxygen concentrations in the product stream of the installation, in addition, when organizing the installation in this way, a steady-state supply stream is not provided required for membrane filter.

The prior art also known installation for producing oxygen from atmospheric air, described in the patent of the Russian Federation No. 101646, consisting of two parallel adsorbers, the inlet pipes of which are connected to the compressor, and the output provide the enriched gas in the adsorbers with the target component to the membrane module, and not passed through the membrane, the gas is directed to purge the adsorber. The main disadvantages of such an installation are, firstly, the impossibility of organizing a stationary in magnitude and pressure feed stream of the membrane module, and secondly, the loss of the stream enriched in the target component that did not pass through the membrane during purging of the adsorbers, which helps to reduce the extraction coefficient.

The closest in design and adopted for the prototype is an ejector membrane-sorption device for separating gas mixtures described in patent No. 139877. This device contains at least two adsorbers filled with a solid adsorbent, a compressor, the outlet pipe of which is connected to the adsorbers through adjustable valves and with the inlet to the ejector mixer, the outlet of which is connected through the first control valve to the inlet pipes of the adsorbers, and the outputs of the adsorbers are equipped with control valves for venting gas from the adsorbers to the discharge pipe, equipped with an additional ejection mixer with receiver, and connected via a second distribution valve to the meme brane filter, one of the branch pipes of the outlet which is connected to the consumer, and the second with an ejection mixer. However, this scheme does not allow to obtain a flow with a constant concentration due to the non-stationary desorption front during the displacement of the product gas stream from the adsorber. In addition, such an installation does not provide a membrane filter power supply that is stationary in magnitude, due to the complex organization of the flow, the discharged gas first enters the receiver, and then the gas from the receiver through the ejector should entrain gas from the adsorber.

The technical task of the proposed utility model is to provide a stationary flow and simplify the scheme of a hybrid membrane-sorption installation while maintaining the parameters of the resulting product.

The technical result achieved by the implementation of the claimed utility model is to obtain a final high-pressure product with a constant concentration of gas mixture components and a constant installation capacity due to simplified flow organization.

The specified technical result is achieved by creating an installation containing a compressor, three adsorbers filled with a solid adsorbent, the first three of the inlet pipes of which are connected to the compressor output through a mixing ejector, three passage valves, for switching the flow of compressed gas from the compressor between the adsorbers equipped with valves for gas removal, characterized by a larger amount of adsorption in the discharge pipe, the outlet pipes are connected through controlled valves between themselves and the inlet of the throttle, and the output is oscel through the valve is connected to the second three of the inlet portions of the adsorbers, while part of the gas transferred from one adsorber to the other is taken and fed to the receiver designed to mix the product flow of the adsorption unit of the system in front of the membrane filter, the amount of gas taken through the nozzle to the receiver is regulated by a throttle, taken in the receiver receives gas through the receiver’s outlet pipe to the membrane filter inlet pipe, part of the gas flow passes through the membrane and sweat is removed from the unit to the faucet through an additional receiver, the pressure of which is limited by an adjustable valve, the stream that has not passed through the membrane is fed through a non-return valve to the ejection mixer and mixed with the compressed air stream from the compressor.

In particular, the installation can be equipped with at least three additional adsorbers for absorbing moisture, carbon dioxide and carbon monoxide, hydrocarbons, each of which is installed immediately before entering the adsorber.

The installation can also be equipped with a vacuum or ejection pump mounted on the discharge pipe.

The installation can be additionally equipped with an adjustable blower to maintain a stable pressure at the compressor inlet, for example, when used in mountainous conditions or on board an aircraft.

The claimed utility model is illustrated by the drawing (Fig. 1), which shows a schematic diagram of a three-adsorption hybrid membrane-sorption installation for air enrichment with oxygen. The scheme is made in the form of graphical symbols for elements connected functionally with the lines of movement of air, nitrogen and oxygen flows.

The installation includes a compressor 1, the outlet pipe of which is connected to the first inlet pipe of the ejection mixer 2, through a dryer 25, which recirculates the gas that has not passed through the membrane and mixes it through the second inlet pipe of the ejector mixer to the filling flow of adsorbers 3, 4, 5 connected to the outlet pipe of the ejector mixer through checkpoints 9, 10, 11, the gas depleted in the adsorbers for the target gas component is discharged through valves 12, 13, 14. The second three of the outlet pipes a sorbers 3, 4, 5, filled with a solid adsorbent, for example, granular zeolite (or a carbon molecular sieve), is connected through check valves 18, 19, 20 to the inlet of the restriction orifice 22, restricting the gas bypass flow between the adsorbers, the output of the orifice 22 is connected to the adsorbers through the valve 15, 16, 17, while in front of the throttle 22, gas is discharged through the throttle 23 to the averaging receiver 6, the outlet pipe of which is connected to the input of the membrane filter 8, which provides fine tertiary treatment of the product mixture including removing the products of abrasion of sorbents and increasing the concentration of the target component, the membrane filter product stream through the receiver 7 and the throttle 24, which serves to regulate the pressure of the product stream, is discharged to the consumer, and the stream that has not passed through the membrane is returned and mixed with an ejector 2 equipped with inlet check valve 21, to the power supply flow of the installation.

Three adsorption hybrid membrane-sorption installation for air enrichment with oxygen works as follows. The gas is supplied by compressor 1 and enters through the mixing ejector 2 and desiccant 25 into the adsorber 3, displacing the oxygen-enriched gas in it, which through the throttle 22 enters the adsorber 4, filling it to the working pressure. At the same time, the adsorber 5 through the discharge pipe discharges its existing exhaust gas into the atmosphere. The figure 2 presents the cyclogram of the operation of a single adsorber (Fig. 2A) and the entire CCA block (Fig. 26). When the working pressure in the filled adsorber reaches the adsorbers, they change functions: in the adsorber in which the displacement stage has passed, the discharge stage begins, the filling stage is replaced by the displacement stage, and the discharge - filling stage. During the displacement of the adsorber, a part of the displacement flow in front of the throttle 22 is taken to the receiver 6 through the throttle 23, from where it enters the membrane module 8. Since one of the adsorbers is always in the displacement stage, a stationary largest flow at constant pressure is supplied to the membrane module of the installation. In the membrane module, part of the flow passes through the membrane, thereby being further enriched with oxygen, and is collected in the receiver 7 for further supply to the consumer, and the other part, thanks to the mixing ejector, is returned to the installation.

Implementation examples.

Example 1

Both in the prototype and in the present utility model, common devices are used:

- adsorption columns filled with solid zeolite;

- discharge compressor;

- receiver;

- ejectors.

The goal is to obtain air enriched in oxygen to a given volume concentration of not less than 50%.

In the prototype, it is assumed to achieve the task the use of a zeolite with a selectivity of 7 for nitrogen-oxygen pair of separated components.

The proposed utility model is able, while maintaining the degree of extraction of the prototype, but with lower selectivity of the sorbent for a nitrogen-oxygen pair (selectivity 1.7), to ensure equal plant performance.

Example 2

When using the proposed installation according to claim 2, when introducing additional filtration adsorbers into the installation, it is possible to obtain a product stream with an increased degree of product recovery, which is achieved by preliminary removal of a mixture of carbon dioxide and carbon monoxide, water vapor, and hydrocarbons from the mixture that is separated in the sorption block.

Example 3

Using the proposed installation according to claim 3, when an additional pump is introduced into the installation to organize desorption of the sorbent under reduced pressure to 0.1 atm, a product stream can be obtained with an increased degree of product recovery. So, with a single act of separation in the adsorber, the oxygen concentration in the product stream increases from atmospheric to 35-40%, and when using a vacuum pump and desorption at 0.1 atm, the oxygen concentration in the product stream with a single act of division in the adsorber increases to 65-70 %

Example 4

When using the proposed installation according to claim 4, when introducing an adjustable blower into the installation, the possibilities of using the installation expand at reduced ambient pressures, for example, in an airplane cabin or in mountainous areas, since the blower will increase the pressure at the compressor inlet, which will allow it to work under normal atmospheric conditions.

In examples based on experimental studies, an Air Product Prism membrane module was used as a membrane filter. Zeolite HF-512 O was used as a sorbent. As a compressor, a compressor of the DurrTechnik model A-100 was used.

Claims (4)

1. Three-adsorber ejector membrane-sorption gas separation unit containing adsorbers filled with a solid adsorbent, a compressor, the outlet pipe of which is connected to the adsorbers through adjustable valves and with the inlet to the ejector mixer, the outlet of which is connected through the first distribution valve to the inlet pipes of the adsorbers, and the outputs of the adsorbers equipped with control valves for venting gas from the adsorbers to the discharge pipe, equipped with an additional ejection mixer with receiver, and through the second distribution valve to the membrane filter, one of the outlet pipes of which is connected to the consumer, and the second to the ejection mixer, characterized in that it is equipped with three adsorbers filled with a solid adsorbent, the first three inlets of which are connected to the outlet of the ejector mixer, in addition the outlet nozzles of the adsorbers are connected both to the second triple of the inlet nozzles of the adsorbers and to the entrance to the membrane filter, a pipeline connecting the outputs of the adsorbers to the entrance of the membrane filter It is connected through the throttle and the averaging receiver, and the pipeline connecting the outputs of the adsorbers to the inputs of the adsorbers is connected through the throttle and the valve line, the output pipe of the membrane filter is connected to the input pipe of the receiver connected to the limiting choke. 2. Installation according to claim 1, characterized in that it is equipped with three additional filter adsorbers installed in front of the main adsorbers. 3. Installation according to claim 1, characterized in that it is equipped with an additional pump (vacuum, ejection) installed on the discharge pipe. 4. Installation according to claim 1, characterized in that it is equipped with an adjustable blower installed in front of the compressor.

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