RU2659048C2 - Stareeva adsorbent - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to equipment for conducting adsorption processes in a gas (vapor) – adsorbent system. Adsorbent for the vertical adsorber contains a cylindrical body with a lid and a bottom. In the cover, a loading hatch is installed, a connection for supplying the original mixture with a distribution grid, a nozzle for evacuation of the vapors during desorption, and a connection for the safety valve. A ring of rigidity is provided at the junction of the cover and the body. In the middle of the hull on the supporting ring there are beams with supports supporting the grate, where a layer of gravel is laid. Layer of adsorbent is arranged between gravel layer and screen whereon weights are arranged to prevent adsorbent loss in desorption. Waste adsorbent is discharged through a discharge hatch installed in the housing. Bubbler is mounted in bottom as well as inspection port with union to discharge condensate and to feed water. Bubbler is made of toroidal form and fixed on the conical surface of the bottom by means of spacers. According to the variants, the adsorbent is formed in the form of a cylindrical ring with two hemispherical surfaces opposite each other in such a way that the diametral planes of the hemispheres coincide respectively with the upper and lower bases of the cylindrical ring. Tops of the semi-spherical surfaces lie on the axis of the ring and are directed towards each other. Packing element is made with perforation on side surface, and semi-spherical surfaces. Between the peaks of semi-spherical surfaces of packing element there is a perforated surface of the n order, for example, spherical, elliptic, hyperbolic. Adsorbent is made in the form of hemispherical surfaces, inside of which there are at least two hemispherical surfaces concentric and with a gap. Adsorbent is made in the form of a hollow spherical shape, on the outer surface of which there are additional elements in the form of spherical, conical surfaces, or any surface of bodies of revolution, for example a paraboloid, an ellipsoid. Inner spherical surface of nozzle is connected to external one by means of at least three channels.

EFFECT: invention provides an increase in 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.

1 cl, 11 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 an adsorber containing a housing with a lid and a bottom and an adsorbent layer located between them according to RF patent No. 2471536, B01D 53/02 (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.

The technical result is an increase in the degree of purification of the gas stream from the target component by increasing the contact area of the adsorbent with the target component.

This is achieved by the fact that the adsorbent, for example, for a vertical adsorber containing a cylindrical body with a lid and a bottom, is equipped with a loading hatch in the lid, a fitting for supplying the initial mixture with a distribution grid, a fitting for venting vapors during desorption, and a fitting for a safety valve, and in place a stiffening ring is provided at the junction of the lid and the housing, and in the middle part of the housing on the support ring there are beams with supports supporting the grate, on which a layer of gravel is laid, and the adsorbent layer p located between the gravel layer and the grid on which the goods are located to prevent adsorbent entrainment during desorption, and the spent adsorbent is unloaded through the discharge hatch installed in the housing, and a bubbler and inspection hatch with a fitting for condensate drainage and water supply are mounted in the bottom, the bubbler is made toroidal shape and mounted on the conical surface of the bottom by means of spacers, made in the form of a cylindrical ring, to the side surface of which two floors are oppositely attached to each other spherical surfaces in such a way that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, respectively, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other.

In FIG. 1 shows a frontal section of the adsorber; FIG. 2 is a variant of the adsorbent made in the form of a cylindrical ring with hemispheres, in FIG. 3 is an embodiment of an adsorbent made in the form of a cylindrical ring with mutually perpendicular plates inside, FIG. 4 is an embodiment of an adsorbent made of a lattice structure inscribed in a circle; FIG. 5 is an adsorbent made of a lattice structure (Fig. 4), in axonometric projection, in Fig. 6 - adsorbent made in the form of a cylindrical ring on the side, inner and outer, the surfaces of which are made by screw cutting, in FIG. 7 - an adsorbent made in the form of a ball, on the surface of which non-through holes are made hemispherical in shape, in FIG. 8 is an adsorbent made in the form of a ring, on the outer surface of which a helical surface is made like a plate auger, in FIG. 9 is an adsorbent made in the form of at least a three-blade propeller; FIG. 10, 11 illustrate adsorbent variants.

The adsorbent, for example, for a vertical adsorber, is made in the form of a cylindrical ring with hemispheres, designed for vertical or any other adsorber (Fig. 1, 2). The adsorber (Fig. 1) contains a cylindrical body 12 with a conical cover 9 and a bottom 21. In the cover 9, a loading hatch 4, a fitting 5 for supplying the initial mixture, drying and cooling air through a distribution grid 6, a fitting 7 for removing vapors during desorption are mounted and union 8 for the safety valve. A stiffening ring 11 is provided at the junction of the cover 9 and the housing 12. In the middle part of the housing 12, beams 17 with supports 22 are mounted on the support ring 14, supporting the grate 15, on which a layer of gravel 1 is laid. The adsorbent layer 13 is located between the gravel layer 1 and mesh 3, on which the goods 10 are located to prevent the entrainment of the adsorbent during desorption. The discharge of the spent adsorbent 13 is carried out through the discharge hatch 2, mounted in the housing. In the bottom 21 there is a viewing hatch 18 with a fitting 19 for condensate drainage and water supply, as well as a bubbler 20 with a fitting 23 for supplying water vapor through a bubbler. The bubbler is made of a toroidal shape and mounted on the conical surface of the bottom 21 by means of spacers. The fitting 16 for the removal of purified gas is located on the conical surface of the bottom 21.

The process of adsorption and desorption occurs at the following optimal ratios of the components making up the apparatus: the ratio of the height H of the cylindrical part of the body to its diameter D is in the optimal ratio of values: H / D = 0.73 ... 1.1; the ratio of the height H of the cylindrical part of the body to the thickness S of its wall is in the optimal ratio of values: H / S = 220 ... 275; the ratio of the height of the adsorbent layer H ₁ to the height H of the cylindrical part of the housing is in the optimal ratio of values: H ₁ / H = 0.22 ... 0.55; the ratio of the height of the adsorbent layer H ₁ to the height H _{2 of the} gravel layer is in the optimal ratio of values: H ₁ / H ₂ = 5.0 ... 12.0.

The adsorbent 13 can be made of porous polymeric materials, glass, porous rubber, composite materials, wood, stainless steel, titanium alloys, noble metals.

In order to increase the degree of purification of the gas stream from dust or the target component by increasing the contact area of the dusty stream with the adsorbent 13 (Fig. 2), it is made in the form of a cylindrical ring, on the side surface 30 of which two hemispherical surfaces 31 and 32 are attached opposite to each other so so that the diametrical planes of the hemispheres coincide respectively with the upper 33 and lower 34 bases of the cylindrical ring, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other. It is possible to perform adsorbent with perforation 35 both on the side surface 30 and on the hemispherical surfaces 31 and 32.

It is possible to make the adsorbent 13 (Fig. 3) in the form of a cylindrical ring, to the lateral inner surface 36 of which two plates 37 and 38 are mutually perpendicularly attached so that they do not protrude beyond the height of the ring.

It is possible to perform an adsorbent 13 (Fig. 4 and 5) of a lattice structure inscribed in a circle and consisting of at least two supporting (base) plates 39 and 40 located along the chords of the circle, close to its diameter, which are perpendicular to at least twelve additional parallel to each other plates 41, made in the parallel direction of the chords of a circle, with a uniform distribution along its diameter. It is possible to perform an adsorbent in the form of a cylindrical ring (Fig. 3) and an adsorbent of a lattice structure (Figs. 4 and 5) with perforation on the surfaces that form them.

It is possible to perform the adsorbent 13 (Fig. 6) in the form of a cylindrical ring, on the lateral, inner and outer surfaces of which a screw thread is made (not shown in the drawing) in opposite directions.

It is possible to perform adsorbent 13 (Fig. 7) in the form of a ball, on the surface of which non-through holes are made hemispherical in shape (not shown in the drawing).

A variant is possible (Fig. 8) when the adsorbent is made in the form of a cylindrical ring, to which two hemispherical surfaces are attached opposite to each other so that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, and the vertices of the hemispherical surfaces are on axis of the ring and directed towards each other. It is possible to perform nozzles with perforation both on the side surface and on hemispherical surfaces.

It is possible that the nozzle element is made in the form of a cylindrical ring, on which two hemispherical surfaces are attached opposite to each other so that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards to each other, and between them is a perforated surface of the nth order, for example spherical, elliptical, hyperbolic.

It is possible that the adsorbent is made (Fig. 9) in the form of a cylindrical ring, to which two hemispherical surfaces are attached opposite to each other so that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, the vertices of the hemispherical surfaces are on the axis rings and are directed towards each other, and inside hemispherical surfaces, at least two hemispherical surfaces are concentrically and with a gap.

A variant is possible when the adsorbent is made (Fig. 10) of balls with recesses, i.e. spherical shape, with non-through radial recesses, and the recesses are in the form of cylindrical, conical, spherical surfaces or any surface of bodies of revolution, for example a paraboloid, an ellipsoid.

It is possible that the adsorbent is hollow spherical in shape (Fig. 11), on the outer surface of which there are additional elements in the form of spherical, conical surfaces or any surface of revolution bodies, for example, a paraboloid, an ellipsoid, and the inner spherical surface of the nozzle is connected to the outer by at least at least three channels.

The adsorbent, for example for a vertical adsorber, operates as follows.

The gas (steam) stream for cleaning is fed to the upper part of the apparatus through the nozzle 5 for supplying the initial mixture through the distribution grid 6. The purified gas stream is discharged from the adsorber through the nozzle 16. The adsorbent is loaded through the loading hatch 4, and the spent adsorbent is removed through the unloading hatch 2. Desorption is carried out by supplying water vapor through the nozzle 23 to a bubbler 20 having a perforated toroidal surface for a more uniform course of the desorption process. The fitting 7 is provided for venting during desorption, and a relief valve is installed in the fitting 8.

Claims (1)

 The adsorbent for a vertical adsorber containing a cylindrical body with a conical cover and a bottom, a loading hatch, a fitting for supplying the initial mixture with a distribution grid, a fitting for venting vapors during desorption and a fitting for a safety valve are mounted in the cover, and a ring is provided at the junction of the cover and the housing stiffness, and in the middle part of the body on the support ring there are beams with supports supporting a grate, on which a layer of gravel is laid, and the adsorbent layer is located between the layer gravel and a grid on which goods are located to prevent adsorbent entrainment during desorption, and the spent adsorbent is unloaded through a discharge hatch installed in the housing, and a bubbler and inspection hatch with a fitting for condensate drainage and water supply are mounted in the bottom, and the bubbler is made in a toroidal shape and mounted on a conical surface of the bottom by means of spacers, characterized in that the adsorbent is made in the form of a cylindrical ring, to the side surface of which is opposite to each other two hemispherical surfaces are attached in such a way that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, respectively, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other, while the nozzle element is made with perforation both on the side surface and on hemispherical surfaces, and between the vertices of the hemispherical surfaces of the nozzle element there is an n-th perforated surface, for example a spherical, elliptical hyperbolic, or in the form of hemispherical surfaces, inside of which at least two hemispherical surfaces are concentrically and with a gap, or in the form of a hollow spherical shape, on the outer surface of which there are additional elements in the form of spherical, conical surfaces or any surface of bodies of revolution, for example, a paraboloid, an ellipsoid, and the inner spherical surface of the nozzle is connected to the outer via at least three channels.

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