SU1313495A1 - Installation for adsorption desiccation of gases - Google Patents

Abstract

The invention relates to devices for the purification of gases from impurities by means of sorbents and allows to reduce energy consumption and increase the degree of gas drying. In the installation, the gas going for regeneration is expanded polytropically with the return of external work and simultaneous cooling in the expander 8, is fed to heat exchange with the desorption gas flow, and then compressed with the simultaneous temperature increase in the compressor 9 connected with the common shaft with the expander . 1 il. W with with 4; coke

Description

The invention relates to an adsorption technique and can be used for cleaning and drying gases, obtaining a fraction of extractable components and separating gas and vapor-gas mixtures in a stationary layer of the adsorbent.

The purpose of the invention is to reduce energy consumption and increase the degree of gas drying.

The drawing shows the installation diagram of the adsorption drying of gases.

The installation consists of adsorbers 1, 2, ejector 3, heater 4, heat exchangers 5, 6, separator 7, expander 8 mounted on a common shaft with compressor 9, three-way switching valves 10, 11 and check valves 12-15, lines 16 dried gas, desorption gas injection line 17, desorption gas drive line 18.

The installation works in the following way.

The gas to be purified at a pressure of 2.5 MPa and a temperature of 293 K is fed through an ejector 3, a three-way switching valve 10 to an adsorber 2, where it is cleaned and then removed from the installation through a check valve 15 and a heat exchanger 5. At the same time, the check valve 14 is closed by back pressure, and the purified gas takes part of the heat of desorption in the heat exchanger, reducing the temperature of the desorption gas to 25 ° C.

A portion of the gas used to regenerate the adsorber 1 is fed through valve 19 to expander 8, where it expands with the return of external work and simultaneously cooled to 233-223 K at a pressure of 0.1-0.1 MPa.

From the expander 8, the cold gas stream through line 17 enters the heat exchanger 6, where it is heated to 20 ° C, taking heat from the desorption gas and the latent condensation heat of the desorbed components.

After heat exchanger 6, the heated gas flow with a temperature of 293 K is directed to compressor 9, where it is compressed polytropically with a simultaneous increase in temperature to 373-393 K due to the energy obtained during expansion in expander 8, while the pressure rises to 0.3-0. , 6 MPa. From compressor 9, compressed gas is fed through line 17 to heater 4, where it is heated to

required temperature of 523-573 K and further

through a three-way switching valve

11 to desorber 1 for adsorbent regeneration.

The desorption gas from stripper 1 is passed through a check valve 12 sequentially to heat exchangers 5 and 6 to cool it to 263-268 K and condense the desorbed components. Then the cooled gas from the heat exchanger 6 is directed

Q to separator 7 for separating the condensed desorbed components and withdrawing them from the regeneration cycle.

The separated cold gas at 263-268 K from the separator 7 is directed to the ejector 3 to restore the pressure to

5 2.0 MPa due to the energy of the main gas stream, going to adsorption, while the temperature of the gas going to adsorption, reduced to 288-291 K.

The effect of using the device is due to an increase in the productivity of adsorption units by 15-22% due to an increase in the period of operation of the unit capacity of the adsorber due to the cooling of the desorption gas stream with the gas going to regeneration after polytropic expansion

5 in the expander.

In addition, supplying a cold stream of separating desorption gas after the separator to the ejector is restored: the pressure of the regeneration gas allows to reduce the temperature of the main stream of the treated gas, increasing the efficiency;: absorption block: -: a 3 - 5%, which is in favor of an increase in the productivity of adsorption OJIOKOES by 5-7%.

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Shape. Invention

Installation of adsorption drying of gases, including a compressor, two adsorbers, a wet gas line, equipped with an ejector, a dried gas line, a gas injection line

desorption, a heat exchanger connected to the separator, characterized in that, in order to reduce energy costs and increase the degree of gas drying, the desorption gas inlet line is equipped with an expander mounted on the same shaft with the compressor, the gas output from which is connected to the compressor through the heat exchanger.

Claims (1)

Claim Installation of adsorption gas drying, including a compressor, two adsorbers, a wet gas line equipped with an ejector, a dried gas line, a desorption gas inlet line, a heat exchanger connected to a separator, characterized in that. In order to reduce energy consumption and increase the degree of gas dehydration, the desorption gas inlet line is equipped with an expander installed on the same shaft as the compressor, the gas outlet from which is connected through the heat exchanger to the compressor.