SU1162461A1 - Mass exchange apparatus packing for heterogeneous system - Google Patents

Abstract

1. MASS-EXCHANGE UNITS FOR HETEROGENEOUS SYSTEMS, made in the form of inclined plates installed rigidly fixed in a cell of a rectangular section formed by vertical partitions, characterized in that, in order to intensify the process of mass exchange by increasing the surface of phase contact and their interaction time it is provided with convex plates, the lower ends of which are connected to the side wall of the cell, and their upper edges - with the lower edges of the inclined plates. 2. The nozzle of claim 1, wherein the partitions are solid, and the lower end of each inclined partition is located at a distance from the side wall of the cell. (L O5 to 4 O5

Description

The invention relates to instrumentation of packed columns for carrying out mass exchange processes of chemical technology, which can be used in chemical, petrochemical, pharmaceutical, food and other industries as contact elements of reaction and mass transfer equipment. The known regular packing consists of flat and corrugated perforated sheets with bent edges along corrugation 1. However, the packing of this design is intended for gas systems and implies a downward film movement of the fluid during upward countercurrent movement of the gas flow. Known nozzle mass transfer apparatus for heterogeneous systems, made in the form of inclined plates installed rigidly fixed in the cell of rectangular cross section formed by vertical partitions 2. Disadvantages of the known nozzle - relatively low mass transfer rate and short time of contact of the solid phase with gases and liquid, caused by a small time contacting the gas-liquid system with the solid phase. The purpose of the invention is to intensify the process of mass exchange by increasing the contact surface of the phases and the time of their interaction. This goal is achieved by the fact that the mass transfer apparatus attachment for heterogeneous systems, made in the form of inclined plates, rigidly fixed in a rectangular cell formed by vertical partitions, is equipped with upwardly convex plates, the lower ends of which are connected to the side wall of the cell, and their upper edges - with lower edges of inclined plates. In addition, the partitions are solid, and the lower end of each inclined partition is located at a distance from the side wall of the cell. FIG. 1 shows an apparatus with a nozzle in a perspective view; in fig. 2 - the same, longitudinal section. The nozzle for mass exchangers contains plates 1 with their ends 2 fixed in a cell 3 of rectangular cross section. The flat inclined plates 1 are arranged with respect to the horizontal plane at an angle, greater than the angle of inclination of the solid phase, and are rigidly connected to the side wall 4 of the cells. A gap 6 is formed between the lower edges 5 of the inclined plates and the opposite side wall 4 of the cells. Above the flat inclined plates 1, upwardly convex plates 7 are coaxially arranged, which are also rigidly fixed in the cell 3 of rectangular cross section. The lower edges of the 9 convex plates are rigidly connected to the side wall of the 4 cells, and the upper edges to the lower edges of 6 flat inclined plates. 1. A nasal / mass transfer apparatus for heterogeneous liquid-gas-solid systems operates as follows. A gas (vapor) stream is fed into the lower part of the nozzle into the labyrinth channel formed by flat inclined plates 1 and convex plates 7. Liquid or liquid-solid phase is fed into the upper part of the nozzle into the labyrinth channel. Thus, in the labyrinth nozzle channel, a countercurrent movement of the downward liquid phase and the ascending gas (vapor) stream is organized. Due to the design features of the nozzle in each section of its labyrinth channel, an effective mass exchange between the liquid-solid-gas phases is ensured. The gas flow into the section comes from the nozzle below through the bottom gap 6 between the edges of the plates 5 and the side wall 4 of the cell. The gas flow hits the inner surface of the convex plate 7, changes the direction of movement and mixes the liquid and solid phases in the section. A uniform distribution of the solid phase in the stream is also achieved. The liquid and solid phase enter the same section from the overlying section of the nozzle through the upper gap between the edges of the plates and the cell wall. The gas (vapor) phase moves through the upper gap of the section to the overlying section of the nozzle, and the liquid and solid phase through the lower gap of the section enters the lower section. Due to the reduced cross section of the gap in comparison with the cross section between the plates, the velocity of the liquid in the overflow gaps is higher than it provides in each passage gap an additional zone of particularly efficient mass transfer. The design of the proposed nozzle provides the possibility of other phase motion schemes. Thus, if necessary, the downward movement of the solid phase in relation to the upward flow of liquid and gas in the lower part of the apparatus with the proposed nozzle is supplied gas and liquid, and in the upper part of it - the solid phase. In the case of a counter-current movement of the liquid and solid phase with respect to the upward movement of the gas flow, the supply of the liquid and solid phases is organized in the upper part of the apparatus, and the gas flow in the lower part. Intensification of mass transfer on the proposed nozzle is explained as follows. The nozzle in the form of inclined flat plates and convex coaxial to them

Claims (2)

1. NOZZLE MASS TRANSFER- NEW DEVICES FOR HETEROGENEOUS SYSTEM, made in the form of obliquely mounted plates, rigidly fixed in a rectangular cell formed by vertical partitions, characterized in that, in order to intensify the mass transfer process by increasing the contact surface of the phases and the time of their interaction, it is equipped with convex plates, the lower ends of which are connected to the side wall of the cell, and their upper edges with the lower edges of the inclined plates. 2. Nozzle according to π. 1, characterized in that the partitions are solid, and the lower end of each inclined partition is located at a distance from the side wall of the cell.