RU2607809C1 - Continuous-operation adsorber - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: invention relates to equipment for adsorption in a gas (steam) - adsorbent. Adsorber comprises cylindrical housing (1), screen plates (2) with adsorbent weighed layers and overflow devices (3). Housing (1) upper part is made in form of conical-cylindrical chamber (4). In chamber (4) bin (5) is mounted in form of downwards turned cone with perforated side surface (6). In bin (5) funnel is additionally installed, consisting of large and small diameter (11 and 13) cylindrical surfaces, between which conical surface (12) is arranged. Adsorbent is made in form of cylindrical ring, on lateral, inner and outer surfaces of which screw thread in opposite directions is made, or in form of ball, on surface of which semi-spherical shaped blind bores are made, or in form of ring, on outer surface of which screw surface is made according to plated screw type, or in form of, at least, three-bladed propeller.

EFFECT: enabling increased degree of gas flow cleaning of target component and dust due to increasing in adsorbent with target component contact area.

1 cl, 6 dwg

Description

The invention relates to equipment for carrying out adsorption processes in a gas (steam) - adsorbent system.

The closest technical solution to the claimed object is a continuous adsorber, including a cylindrical body, the upper part of which is made in the form of a conical-cylindrical chamber, in which a hopper is mounted in the form of a cone tilted downward with a perforated side surface, sieve plates with suspended adsorbent layers and overflow devices according to the patent of the Russian Federation No. 2268771 (prototype).

A disadvantage of the known adsorber is that it does not provide a high degree of purification of the gas stream from the target component and dust.

The purpose of the invention is to increase the degree of purification of the gas stream from the target component and dust by increasing the contact area of the adsorbent with the target component.

This is achieved by the fact that in a continuous adsorber, which includes a cylindrical body, the upper part of which is made in the form of a conical-cylindrical chamber, in which a hopper is mounted in the form of a cone with a perforated side surface tilted downward, sieve plates with suspended adsorbent layers and transfer devices, in the hopper mounted in a conical-cylindrical chamber, with a gap relative to its side surfaces, an additional funnel consisting of a cylindrical surface is additionally installed large and small diameters, between which a perforated conical surface is located, and the funnel is fastened with at least three restrictive elements connecting the conical surfaces of the hopper and funnel, and at least three restrictive elements connecting the conical surfaces of the hopper and the cylindrical surface of the small diameter of the funnel, and the adsorbent is spherical in shape, in which through radial recesses are made, the recesses being in the form of a cylindrical, conical Coy, spherical surfaces or any surface of bodies of revolution, such a paraboloid, an ellipsoid.

In FIG. 1 shows an adsorber, a longitudinal section, in FIG. 2-5 - embodiments of the form of the adsorbent.

The continuous adsorber comprises a cylindrical body 1, the upper part of which is made in the form of a conical-cylindrical chamber 4, in which the hopper 5 is mounted in the form of a cone with a perforated side surface 6 tilted downward, screen plates 2 with suspended adsorbent layers and transfer devices 3. B a hopper 5 mounted in a conical-cylindrical chamber 4, with a gap S relative to its side surfaces 6, an additional funnel is installed, consisting of cylindrical surfaces 11 and 13 of large and m diameter of the diameter, between which the perforated conical surface 12 is located, and the funnel is fastened with at least three restrictive elements 15, connecting the conical surfaces of the hopper 6 and the funnel 12, and at least three restrictive elements 14, connecting the conical surfaces of the hopper 6 and the cylindrical surface 13 small diameter funnels. The gap between the conical side surfaces of the hopper 6 and funnel 12 is in the optimal range of values

S = (10 ... 20) D / d cm,

where D is the diameter of the cylindrical part of the conical-cylindrical chamber,

d is the diameter of the cylindrical body of the adsorber.

The lateral perforated surface 12 of the funnel is made in the form of stepwise truncated truncated cones, the lower end of the overlying cone with a gap δ entering the upper end of the underlying cone, and the gap δ is in the optimal range of values

δ = (1,0 ... 2,0) D ₁ / d ₁ cm,

where D ₁ - the diameter of the cylindrical surface of the large diameter of the funnel,

d ₁ - the diameter of the cylindrical surface of the small diameter of the funnel.

The shape of the sieve plates 2 can be made in the form of a concave curvilinear surface of the second order (for example, part of an ellipsoid of revolution), which will significantly increase the contact area of the sorbent and the target component.

In order to prevent the perforation of the side surface of the hopper from becoming clogged with a small part of the adsorbent (crumb) or its dust, it is made in the form of stepwise located truncated cones, the lower end of the overlying cone entering with a gap into the upper end of the underlying cone. The annular slots formed in this way serve to pass a gas stream into the hopper, the lower part of which goes into a cylindrical overflow 7. A nozzle 8 is installed along the axis in the conical-cylindrical part of the housing, through which adsorbent is fed into the hopper. The bottom end of the nozzle determines the height of the adsorbent layer in the hopper. By lowering or raising the end face of the nozzle, it is possible to create adsorbent layers of various heights in the intermediate hopper. The adsorber is equipped with fittings 9-11, respectively, for supplying gas, withdrawing purified gas and removing the adsorbent.

In order to increase the degree of purification of the gas stream from the target component by increasing the contact area of the adsorbent with the target component, the adsorbent is made spherical in shape 16, in which through radial recesses are made, the recesses being in the form of cylindrical 18, conical 17, spherical 19 surfaces or any surface of bodies of revolution e.g. paraboloid, ellipsoid.

The adsorber works as follows.

The gas (steam) stream for cleaning is supplied to the lower part of the apparatus through the nozzle 9 and passes through all plates located at its height, at which it contacts the adsorbent, bringing it into suspension. From the upper plate, the gas flow is directed into the conical-cylindrical chamber 4 of the housing and through the perforated side surface 5 of the hopper enters the conical space formed by the gap S relative to the side surfaces 6 of the hopper and the perforated conical surface 12 of the additionally installed funnel. In this zone of a moving dense layer of adsorbent, the gas stream is further purified from the target component and at the same time it is cleaned of small particles (dust) formed as a result of abrasion of the adsorbent under the operating conditions of the apparatus.

The purified gas stream is discharged from the adsorber through the nozzle 10. The adsorbent from the nozzle 8 enters the hopper, which creates a moving dense layer of adsorbent. The movement of the gas stream and adsorbent is countercurrent. Through the cylindrical overflow 7 of the hopper 5, the adsorbent enters the upper plate 2, where it contacts the gas stream, and then moves to the underlying plates 2 through the transfer devices 3. The spent adsorbent is discharged from the bottom of the column through the nozzle 11.

The proposed device can significantly increase the degree of purification of the gas stream from the target component and dust by increasing the contact areas of the moving adsorbent with the target component with the same overall dimensions of the column.

It is possible to fulfill the shape of the adsorbent (Fig. 3) in the form of a cylindrical ring, on the lateral, internal and external surfaces of which a screw thread (not shown) is made in opposite directions.

It is possible to fulfill the shape of the adsorbent (Fig. 4) in the form of a ball, on the surface of which non-through holes of a hemispherical shape are made (not shown in the drawing).

It is possible to fulfill the shape of the adsorbent (Fig. 5) in the form of a ring, on the outer surface of which a helical surface is made like a plate screw.

It is possible to fulfill the form of the adsorbent (Fig. 6) in the form of at least a three-blade propeller.

Claims (9)

Continuous adsorber, including a cylindrical body, the upper part of which is made in the form of a conical-cylindrical chamber, in which a hopper is mounted in the form of a cone with a perforated side surface overturned down, screen plates with suspended adsorbent layers and transfer devices, and in a hopper mounted in conical-cylindrical chamber, with a gap relative to its side surfaces, an additional funnel is installed, consisting of cylindrical surfaces of large and small diameters ra, between which there is a perforated conical surface, and the funnel is fastened with at least three restrictive elements connecting the conical surfaces of the hopper and funnel, and at least three restrictive elements connecting the conical surfaces of the hopper and the cylindrical surface of the small diameter of the funnel, and the gap between the conical the side surfaces of the hopper and funnel are in the optimal range of values S = (10 ... 20) D / d cm, where D is the diameter of the cylindrical part of the conical-cylindrical chamber, d is the diameter of the cylindrical housing of the adsorber, and the lateral perforated surface of the funnel is made in the form of stepped truncated cones, the lower end of the overlying cone entering with a gap δ into the upper end of the underlying cone, and the gap δ is in the optimal range of values δ = (1,0 ... 2,0) D ₁ / d ₁ cm, where D ₁ - the diameter of the cylindrical surface of the large diameter of the funnel, d ₁ - the diameter of the cylindrical surface of the small diameter of the funnel, the shape of the sieve plates is a concave curvilinear surface of the second order, characterized in that the adsorbent is made in the form of a cylindrical ring, on the lateral, inner and outer surfaces of which there is a screw thread in opposite directions, or in the form of a ball on the surface of which through holes are made hemispherical shape, or in the form of a ring on the outer surface of which a helical surface is made like a plate auger, or in the form of at least a three-blade propeller but.

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