RU2624701C1 - Packed gas drying absorber - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: packed gas drying absorber contains a housing with gas inlet branch pipes, a dry gas discharge, an inlet and an outlet of the absorbent, and an inlet separation section located in the housing, a mass exchange absorption packed section and an outlet filter section. The gas inlet branch pipe has the form of a tapering nozzle to a smaller hole, and a large hole of the converging nozzle is provided with a circular groove connected to the sump, with curvilinear grooves along the cycloid line as a brachistochrone on the inner surface of the nozzle, and the profile of the curvilinear groove has the form of a dovetail.

EFFECT: invention allows to prevent plugging of the branch pipe grooves with solid droplet forming particles.

4 dwg

Description

The invention relates to the drying and / or purification of gases in the chemical, metallurgical or other fields of the national economy.

A known gas drying absorber (see patent for utility model No. 37471 MPK V 01 D 53/26, publ. 04/27/2004), comprising a housing with pipes for supplying gas, drainage of dried gas, supply and removal of absorbent material and an inlet section located in the housing, mass transfer absorption nozzle section and output filter section, technologically interconnected.

The disadvantage is a decrease in the degree of gas purification during long-term operation, due to the presence in the cleaned stream of a high concentration of finely divided solid and droplet-like particles, which, in contact with the material of the packed sections, contribute to intensive pollution and, consequently, reduce the absorption capacity of the section, which leads to an increase in “slip” untreated gas for consumption or to the environment with subsequent pollution.

Known nozzle absorber gas dehydration (see RF patent for utility model No. 134818 IPC B01D 53/26, publ. 11/27/2013), containing a housing with pipes for supplying gas, drainage of dried gas, supply and removal of absorbent material and located in the inlet separation section , a mass transfer absorption nozzle section and an outlet filter section, technologically connected to each other, and the gas supply pipe has the form of a tapering nozzle to a smaller hole, and a circular groove is made at the large opening of the tapering nozzle, connected nennaya with a dirt collector.

The disadvantage is the additional energy costs associated with unscheduled dismantling work on replacing and / or cleaning the gas supply pipe made in the form of a tapering nozzle, due to clogging of the screw-shaped cavities of the grooves with contaminants that subsequently wander around the entire internal volume of the tapering nozzle and are carried by a moving gas stream into nozzle sections followed by sticking to the material, which leads, respectively, to a decrease in the absorption capacity of the section.

The technical task of the invention is to reduce energy consumption that increases during long-term operation of the packed gas drying absorber due to elimination of additional dismantling work on replacing or cleaning the gas supply pipe from dirt adhering to the inner surface, preventing curvilinear grooves from clogging with solid drop-forming particles by performing their curvature along the line of a cycloid as a brachistochron, and a profile in the form of a dovetail.

The technical result is achieved in that the packed gas dryer absorber comprises a housing with nozzles for supplying gas, draining dried gas, supplying and removing absorbent and an inlet separation section located in the housing, a mass transfer absorption nozzle section and an outlet filter section, which are technologically interconnected, and the inlet pipe gas has the form of a tapering nozzle to a smaller hole, and at the large hole of the tapering nozzle there is a circular groove connected to the dirt collector, while The curved grooves are made along the line of the cycloid as a brachistochron, and the profile of the curved groove has the form of a dovetail.

In FIG. 1 shows a packed gas dryer absorber; FIG. 2 - the inner surface of the gas supply pipe in the form of a tapering nozzle with a dirt collector, in FIG. 3 - curvature of the curved groove along the line of the cycloid as a brachistochron; FIG. 4 - profile of the curved groove in the form of a dovetail.

The nozzle for drying gas contains a housing 1 with a nozzle for supplying gas 2 and a nozzle for draining the dried gas 3, nozzle 4 for supplying absorbent and nozzle 5 for removing absorbent located in the housing 1. The inlet separation section 6, the mass transfer absorption nozzle section 7 and the outlet filter section 8, technologically interconnected. The gas supply pipe 2 has the form of a tapering nozzle, on the inner surface 9 of which there are curved grooves 10 longitudinally spaced from the large hole 11 of the tapering nozzle 2 to the smaller hole 12, and at the large hole 11 there is a circular groove 13 connected to the dirt collector 14. In this case the packing material 15 of the mass transfer absorption section 7 is made, for example, of ultrafine basalt fiber. The curvature of the curved groove 10 is made along the line of the cycloid as a brachistochron 16, and the profile 17 of the curved groove 10 has the form of a dovetail.

Packed absorber gas dehydration operates as follows. A cleaning gas saturated with fine particulate and droplet particles enters the gas supply pipe 2 and then into the inlet separation section 6, where it extends through the internal volume of the housing 1 and comes into contact with the packing material 15 of the mass transfer absorption section 7. Fine particulate and droplet particles stick on the packed fibrous material 15 and are practically not completely washed off and / or dissolved by the absorption liquid. As a result, the subsequent mass flow of gas is in contact with the smaller absorbing surface of the packed fibrous material 15, and this leads to the fact that gas untreated to normalized parameters is directed to the output filtering section 8, which especially during long-term operation sharply reduces the efficiency of absorption drying.

To eliminate this phenomenon, the gas supply pipe 2 is made in the form of a narrowing nozzle, in this case, as the gas moves from the larger hole 11 to the smaller hole 12, the gas to be purified, saturated with fine solid and droplet-like particles, moves along the longitudinally arranged curved grooves 10. As a result, a rotating vortex flow thermodynamically stratified into “hot” (temperature is higher than the gas temperature before entering the gas supply pipe 2 in the form of a tapering nozzle) the peripheral layer is saturated a fine, solid and droplet-like particles, and “cold” (temperature is lower than the gas temperature before entering the gas supply pipe 2) an axial layer purified from contaminants (see, for example, V. P. Merkulov. Vortex effect and its application in technology. Samara 1992 - 209 p.). The finely dispersed and droplet-shaped particles discarded by centrifugal force of the vortex flow toward the inner surface 9 in curved grooves 10 collide with each other, coagulate, enlarge and move from the smaller hole 12 toward the larger hole 11, accumulating in the circular groove 13 (see, for example Nashokin V.V. Technical Thermodynamics and Heat Transfer.M.: 1980 - 415 p.), From where the contaminants are moved to the dirt collector 14 for subsequent removal manually or automatically (not shown).

As the particles of dirt become larger, especially the attachment of solid and finely divided droplet particles, the speed of movement in the cavity 17 of the curved groove 10 decreases due to increasing friction, which leads to clogging of the cavity 17 and, as a result, the subsequent particles are forced out into the internal volume of the gas supply pipe 2 in the form of a tapering nozzle, i.e. its cleaning function from pollution is not carried out partially or even completely.

When curvilinear grooves 10 are curved along the line of a cycloid as a brachistochron 16, the contaminant particles are solid or droplet-like, as well as coarsening when combined and under conditions of the fastest descent (see page 802. Some remarkable curves. M.Ya. Vagodsky. Handbook of higher mathematics. M .: Nauka, 1965–872 pp.) Displacement, for example, from point A, located at the smaller opening 12 of the gas supply pipe 2 in the form of a tapering nozzle, to point B of the groove curve 13. As a result, an increase in the speed of movement of contaminant particles d about 25%, which eliminates the clogging of curved grooves 10.

In addition, the execution of the cavity 17 of curved grooves in the form of a dovetail not only prevents the displacement of colliding and enlarged particles of contaminants moving from the smaller hole 12 to the larger hole 11 into the inner volume of the nozzle 2, but also contributes to the process of throttling the gas exiting through the slot section 18 , creating a pressure drop over the cross section of the cavity 17, which additionally acts in the trench of the pushing force on the moving particles of pollution (see, for example, p. 136, Kovalenko L.M., Glushkov A.F. eploobmen particles with the intensification of heat transfer M .: Energoatomizdat 1986 -.. 240, yl)...

 A swirling gas stream purified from fine particulate and droplet particles, leaving the smaller hole 12 on the gas supply pipe 2 in the form of a tapering nozzle into the inlet separation section 6, suddenly expands, lowering its temperature (((Joule-Thomson effect) see, for example, 199 in the same place)), which leads to additional gas purification by condensation of moisture vapor and its subsequent coagulation on the packed material 15 in contact with absorbent wildness entering through the pipe 4 for supplying the absorbent to the mass transfer absorbent the packing nozzle section 7 and entering through the pipe 5 of the absorbent outlet. After the outlet filter section 8, gas with normalized parameters according to the degree of purification is discharged through the pipe 3 for draining the drained gas into the environment, maintaining the cleanliness of the ecological industrial zone or is sent to the consumer for technological processes.

The originality of the invention to maintain the specified quality during normalized energy consumption during the long-term operation of the packed absorber is that the contaminants associated with the drained gas are separated before entering the separating section by curving the curved grooves on the inner surface of the tapering nozzle along the line of the cycloid as a brachistochron with a profile in dovetail.

Claims (1)

A nozzle dryer for gas drying, comprising a housing with nozzles for supplying gas, drainage of dried gas, inlet and outlet of absorbent material and inlet separation section located in the housing, mass transfer absorption nozzle section and outlet filter section, which are technologically interconnected, and the nozzle of the gas supply has the form of a tapering nozzle to the smaller hole, and at the large hole of the tapering nozzle a circular groove is made connected to the dirt collector, characterized in that the curved grooves are filled along the line of the cycloid as a brachistochron, and the profile of the curved groove looks like a dovetail.

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