SU579856A3 - Contact apparatus packing - Google Patents

Description

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This invention relates to a power system, in particular, to the construction of a nozzle of a tower contact apparatus.

A nozzle of a contact apparatus is known, comprising an open: from the ends a tubular element, preferably of circular cross section with a diameter greater than its height and with radial ribs installed inside 1. The tower of the contact apparatus contains one or more layers of such an attachment. The contacting surfaces are passed through these layers according to the principle of countercurrent or fine current.

The disadvantage of the NK is well known; the device is the low productivity of the apparatus and the high hydraulic resistance of the packing layer when filling it into the apparatus in bulk.

The goal of aaaaaaaa is to increase productivity and reduce resistance.

To achieve this goal, the tubular element is made in the form of a truncated cone with a ratio of large diameter to width from 1.5 to 1O. The angle of the cone solution, defined by the diameters of the ends of the element,

no more than 30, and the width of the ribs is less than the width of the element. The ribs can be placed in groups in height, shifted relative to each other in pitch, and inside the element annular partitions intersecting with the ribs can be installed. The walls of the element can be made perforated.

This embodiment of the nozzle provides its self-orientation when filling in bulk in a contact device, which significantly improves performance and reduces the hydraulic resistance of the nozzle layer.

On (} ig. 1 shows the nozzle of the contact apparatus, view in plan; Fig. 2 - the same, transverse section; g. 3 - variant of the nozzle with convex walls of the tubular element, flooded section; Fig. 4; partitions and perforated walls of the tubular element, view in plan; on 4 sg. 5 - the same, cross section.

The nozzle contains open from the ends of the tubular element 1 in the shape of a truncated cone. The ratio of the larger diameter of the cone to

element width is 1.5-10. The raster angle of a cone, defined by the diameters of the ends of the element, is no more than 30 °. The walls of the tubular element can be straight (4ig. 2), convex (Fig. 3) or concave (Fig. 5).

Element 1 is provided with internal radial ribs 2 to prevent the trapping of one element into another. The width of the ribs 2 is less than the width of element 1, which ensures self-orientation of the nozzle in the layer. The number of edges can be four, six and 6onei depending on the diameter of the tubular element. The edges can fejTb combined in groups, shifted one relative to another in height (Fig. 4 and 5). In this case, the edges of the group located above are placed between the edges of the lower group. the tubular element 1 is installed annular partitions intersecting with the ribs 2, increasing the rigidity of the nozzles and intended to turbulize the fluid flow,

In the walls of the tubular element 1 there are holes 4, which, depending on the diameter of the element, can be located in one or. more than a few On the outer surface of the tubular element 1 can be made ribs 5 stiffness (fkg, 5),

The machines of the tubular element 1 can be made out of a plurality of flat elements, forming a polygon at the base. The nozzle works as follows. One of the contacting liquids, which is, for example, in the liquid phase, passes through the SG1ON nozzle downwards, for example, in a gas phase, for example, passes through the earthquake upwards. The shape of the nozzle contributes to the lateral mixing of the liquid, which improves its distribution over the entire surface of the liquid, which is wetted with liquid. The thin continuous film of the latter is in reliable contact with the turbulent gas flow.

The configuration of the nozzle ensures its optimal placement in the layer at which there is both maximum turbulization and lateral mixing of the flows of the contacting liquids, as well as their high speed, minimal pressure losses and the absence of stagnant zones. As a result, heat and mass transfer is intensified, which determines the efficiency of the contact apparatus.

The proposed nozzle has a higher throughput compared to traditionally used nozzles such as Raschig rings, ceramic saddles, Pall rings and others with the same mass transfer coefficients and has a higher mass transfer coefficient with the same capacity.

Claims (6)

1. The nozzle of the contact apparatus, containing an open from the ends. A tubular element is preferably of a circular cross section with a diameter greater than its height and with radial ribs installed inside, characterized in that, in order to increase productivity and reduce resistance, the tubular element truncated cozus with the ratio of large diameter to width of 1.5 to 1O. 2. The nozzle according to claim 1, characterized in that the angle of the solution of the cochus ,. determined by the diameters of the ends of the element, is not more than. 3. Attachment on PP. 1, 2, characterized in that, the width of the ribs is less than the width of the element. 4. Attachment on PP. 1-3, that is, with the fact that the ribs are arranged in groups in height, shifted relative to each other in a step. 5. Attachment on PP. 1-4, characterized in that inside the element of the mouth, the ridges intersecting with the ribs are new. 6 ... Nasafs on PP. 1-5, that is, with the fact that the walls of the element are perforated. Sources of information taken into account in the examination: 1. Kasatkin A.G. Basic processes and apparatuses of chemical technology. M.L. Goskhmizdat, 1971, p. 563-564,