SU1118383A1 - Jet tray for mass-transfer apparatus - Google Patents

Abstract

JET BOILER FOR MASS-EXCHANGE DEVICES, including perforated base with directional notched elements, overflow devices and partitioning partitions, each of which is made of a plate, vertically installed on the axis and connected to the base an account of the differentiated change in the proportion of transverse sectioning along the height of the contact zone, each partitioning partition is provided with an additional. body plate mounted horizontally above the vertical plate and connected to it pivotally. eo co 00 co

Description

The invention relates to mass transfer apparatus and can be used in distillation and absorption columns.

A well-known jet plate containing a perforated base with vertical transverse partitions dividing it into sections.

Such trays have a narrower range of stable operation than conventional jets, as well as a higher hydraulic resistance due to a significant proportion of the flow sectioning of the LIQUID;

A known jet plate for mass transfer apparatus, including perforated base with petals, overflow devices. And partitioning partitions, each of which is made of a plate vertically mounted on an axis connected to the base 2.

The disadvantage of the device is the lack of differentiated sectioning along the height of the contact zone, as a result, the plate has an insufficient range of effective operation and an increased resistance to the theoretical contact level.

The purpose of the invention. - intensification of the process of heat and mass transfer due to the differentiated change in the fraction of transverse sectioning along the height of the contact zone.

This goal is achieved by the fact that in the jet tray for mass transfer apparatus, including. perforated base with directional cutting elements, overflow devices and partitioning partitions, each of which is made of a plate vertically mounted on an axis and connected to the base, each sectional partition is provided with an additional plate mounted horizontally above the vertical plate and connected to it pivotally.

Figure 1 shows the plate, a General view in figure 2 - the same, top view.

The plate consists of a perforated base 1, on which holes 2 are provided, equipped with bent directional cutting elements 3, an overflow device 4, an overflow partition 5 and partitioning b, each partitioning partition 6 is made of a vertically mounted plate 7 and a horizontally mounted plate 8, vertically mounted plate 7 is connected by an axis 9 with a base 1, and with a horizontal plate 8 by means of a hinge 10.

Jet plate works as follows.

The gas, the passage through the holes 2 under the directional cut-off elements 3, interacts with the fluid coming from the overlying plate, and transports it to overflow 5 to the device 4. The gas-liquid flow when moving along the plate repeatedly encounters partitioning partitions in its path. At relatively low gas loads

The bubbling layer interacts with the vertical plates 7 of the partitioning partitions 6, which prevent the liquid from being blown off from the contact device. Plates 7, deployed in

5 adjacent rows of holes 2 in opposite directions cause a zigzag movement of the bubbling layer along the base, which increases the residence time of the liquid on the plate, not

Q creates a lot of resistance to fluid movement. At high gas loads beyond the phase inversion, when the liquid is dispersed, particles and liquid jets enter the

. Separation space (where they interact with the horizontal plates 8. When they hit the surface of the plates 8, the fluid particles lose speed and are crushed, which leads to an increase in the relative velocity and growth of the contact surface of the phases. The fluid particles by the horizontal plates 8 are reflected to the base 1 plate, which leads to JC separation of the massaging phases.

5 p generally, at high gas velocities, the gas-liquid stream, interacting with the plates 7 and 8, makes zigzag movements in the vertical. and horizontal directions. By measuring the rotation angles of the partitioned partition plates, it is possible to differentiate the fraction of the transverse sectioning along the height of the contact zone. This allows you to create

5 optimal conditions for contacting the phases and to ensure optimal hydrodynamic and mass transfer characteristics of the tray.

0 The proposed contact device; the device has a wider range of effective work compared to the prototype and allows to achieve greater efficiency while simultaneously creating optimal hydrodynamic conditions for the dish, which in turn allows the resistance of the theoretical degree of contact to be varied within wide limits. A single jet disc plate has greater versatility than the prototype and can be used in high-performance refineries and the petrochemical industry.

Claims (1)

JET PLATE FOR MASS TRANSFER APPARATUS, including a perforated base with directional perforated elements, overflow devices and sectional partitions, each of which is made of a plate vertically mounted on an axis and connected to the base, characterized in that, in order to intensify the heat and mass transfer process due to differentiated changes the proportion of transverse sectioning along the height of the contact zone, each sectional partition is provided with an additional. body plastic, installed horizontally above the vertical plastic § § and articulated with it, ι and * 00 CO 00 co> figure 1 Gas passing through the holes 2 under the directional slotted elements 3 interacts with the liquid coming from the overlying plate and transports it to the overflow device 4. The gas-liquid stream, when moving along the plate, repeatedly encounters sectional partitions on its way. With relatively small gas loads | the bubble layer interacts with the vertical plates 7 of the partition walls 6, preventing the blowing of fluid from the contact device. The plates 7, deployed in adjacent rows of holes 2 in opposite directions, cause a zigzag movement of the bubble layer along the base, which increases the residence time of the liquid on the plate, without creating much resistance to the movement of the liquid. At high gas loads beyond the phase inversion, when the liquid is dispersed, the particles and jets of liquid enter the separation space, where they interact with the horizontal plates 8. When they hit the surface: plates 8, the liquid particles lose speed and break up, which leads to an increase relative. velocity and the growth of the contact surface of the phases. Particles of liquid horizontal plates 8 are reflected to the base 1 of the plate, which leads to the separation of the masloobmena phases. . In general, at high gas velocities, the gas-liquid Flow interacting with plates 7 and 8 makes zigzag movements in the vertical and horizontal directions, Izme1 I