RU2678058C1 - Nozzle for contacting gas and liquid - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to heat and mass transfer equipment. Nozzle contains the package forming the cell. Cells have a frame, made in the form of a direct non-rectangular parallelepiped, and sides. Sides are curved so that one ends of opposite sides mentioned 4 are curved towards each other, and their other ends 5 are curved in opposite directions. Batch nozzle has high performance (throughput in the liquid and gas phases), low hydraulic resistance, high values of heat and mass transfer coefficients, high rates of uniformity of distribution of liquid and gaseous streams over the cross section of the apparatus, compactness and adaptability.EFFECT: increasing the turbulence of oncoming gas and liquid flows due to asymmetry of the flow area, increasing the speed of passing the phases, improving the ability of the nozzle to redistribute phases across the entire cross section of the apparatus in which the nozzle is installed.4 cl, 5 dwg

Description

FIELD OF THE INVENTION

The invention relates to means for providing heat and mass transfer, and more particularly to nozzles for contacting gas and liquid, intended for use in installations and technologies for absorption, distillation, desorption, rectification, extraction, drying and humidification of gases, wet dust collection. The invention can be used in the chemical, petrochemical, metallurgy, energy and other industries.

State of the art

The prior art knows a large number of funds for the same purpose.

As the closest analogue, a nozzle for contacting gas and liquid was selected, containing the cells forming the packet, which are made in the form of a rectangular parallelepiped, and the sides, made curved (RF patent 2416461 C1, IPC B01J 19/32, 04/20/2011). This well-known nozzle provides contacting gas and liquid in a vortex flow. The disadvantage of this known tool is the lack of turbulence in the interaction of gas and liquid, limiting the intensification of mass transfer processes.

Disclosure of the invention

The problem to which the present invention is directed, is to increase the intensification of mass transfer processes.

In the course of solving this problem, the following set of technical results is achieved: increasing the turbulence of the oncoming gas and liquid flows due to the asymmetry of the flow section, increasing the speed of the phases, improving the ability of the nozzle to redistribute the phases throughout the entire section of the apparatus in which the nozzle is installed.

These technical results are achieved by the fact that the nozzle for contacting gas and liquid contains the cells forming the package, said cells have a frame made in the form of a straight non-rectangular parallelepiped, and the sides are curved so that one end of the opposite said sides is curved towards each other, and their other ends are curved in opposite directions.

These technical results are also achieved by the fact that the base of the said frame is made in the form of a rhombus having an angle from 95 degrees to 120 degrees.

These technical results are also achieved by the fact that at least part of the surface of the said sides is roughened.

These technical results are also achieved by the fact that at least some of the mentioned sides are made with perforation.

A distinctive feature of the nozzle in accordance with the invention is the implementation of cells in the form of a non-rectangular parallelepiped, which provides an asymmetric section for the passage of phases and the formation of more intense turbulence when they are mixed.

Brief Description of the Drawings

In FIG. 1 shows the shape of the wireframe cell

In FIG. 2 shows two side views of a cell.

In FIG. 3 shows a bottom / top view of a cell of a medium selected as the closest analogue.

In FIG. 4 shows a bottom / top view of a cell.

In FIG. 5 shows a photograph of the nozzle top / bottom view.

The implementation of the invention

Great attention is paid to improving the efficiency of heat and mass transfer equipment (apparatuses, columns, plants, etc.) in various fields of technology. Modern heat and mass transfer equipment has high mass-dimensional, energy and operational requirements. Modern equipment must be technologically advanced, efficient, simple in design and use, and reliable.

One of the ways to achieve the necessary properties is the use of so-called contact nozzles in heat and mass transfer plants, which ensure intensive interaction of the contacted phases.

The nozzle in accordance with the present invention relates to the batch type and provides heat and mass transfer due to the strong turbulence (swirl) of the oncoming phase flows and an increase in their contact area over the entire internal volume of the apparatus.

The nozzle for contacting gas and liquid contains the cells collected in a package. As a rule, all cells have the same shape and design. However, depending on the design of the apparatus inside which the assembled package is installed, some cells may differ in shape, size and design. The cells have a frame 1 made in the form of a direct non-rectangular parallelepiped and the sides 2, as well as the base 3.

As you know, a straight parallelepiped refers to a parallelepiped in which all side faces are rectangles. A straight non-rectangular parallelepiped means that its bases are made in the form of parallelograms (not rectangles), and the sides are in the form of rectangles.

The lateral sides 2 of the cell contain two pairs of oppositely lying sides and are made curved so that some ends of the opposite lateral sides are curved towards each other, while the other ends are curved in opposite directions, as shown in FIG. 2. Thus, in a cell taken separately from the rest, one ends of each pair of opposite sides are bent into the cell, i.e. towards each other (position 4 in Fig. 2), and the other ends are outside the cell, i.e. in opposite directions (position 5), while if, for example, the upper ends of the sides of one pair of opposite sides diverge, then the upper ends of the other pair of sides converge and vice versa.

A top view of the cell (the bottom view is similar) is shown in FIG. 4 and FIG. 5. Here a pair of sides 4, bent inward and a pair of sides 5, bent outward of the cell are clearly shown.

Cells can be packaged in various ways. It is most effective to package so that the cells have common adjacent sides, as well as bases. Then, the lateral side, bent inward of one cell, will simultaneously be the lateral side, bent outward in relation to the neighboring cell.

The base 3 of said frame is expediently made in the form of a rhombus having an angle α from 95 degrees to 120 degrees, as shown in FIG. 4 and FIG. 5, or a parallelogram with a slight difference in the length of the sides.

At least a portion of the surface of the sides can be roughened or have irregularities to hold droplets of the liquid phase on the surface.

At least some of the sides can be made with perforations of various shapes to increase the speed of advancement of the phases and reduce hydraulic resistance.

To more clearly illustrate the differences of the present invention in FIG. 3 shows a bottom view (a top view is similar) of the nozzle structure selected as the closest analogue. The fact that the convergent pairs of ends of the sides (in the prototype terminology are swirlers) are perpendicular to each other suggests that the base of the cell is made in the form of a rectangle, for example, a square. The so-called swirls in the prototype are formed by pairs of converging ends 4 of opposite sides. Pairs of diverging ends of 5 opposite lateral sides are directed outside the cell. With this configuration, the flow area (shaded area in FIG. 3) is predominantly symmetrical.

The implementation of the base of the cell in the form of a parallelogram, for example, a rhombus, in accordance with the present invention is shown in FIG. 4. Here, positions 4 and 5 also correspond to converging and diverging pairs of ends of the sides. As can be seen from FIG. 4, in the case of the present invention, the cross section (shaded area) is not symmetrical and contains sections of various shapes and sizes. This creates the conditions for the formation of more frequent and intense foci of turbulence than in a simpler section of the prototype.

The batch nozzle in accordance with the present invention has high productivity (throughput in liquid and gas phases), low hydraulic resistance, high values of heat and mass transfer coefficients, high uniformity of distribution of liquid and gaseous flows over the apparatus cross section, compactness and manufacturability.

The novelty of the invention consists in the form of the base of the cell, preferably in the form of a rhombus or parallelogram with a slight difference in the length of the sides.

The nozzle works as follows.

The cells assembled in the bag are installed inside the apparatus, column, installation or other heat or mass transfer equipment used for the processes of absorption, desorption, separation of multicomponent mixtures (rectification), wet dust collection in the chemical, petrochemical, energy, metallurgical and other industries.

Gas is supplied through the lower bases of 3 cells, and a liquid phase is supplied through the upper bases, countercurrent to the gas. The gas rising from the bottom up carries the flowing liquid and, returning part of it to the surface of the cells, enters the direct-flow vortex flow due to the design of the sides 2 and the shape of the cells. As a result of this, a large and evenly distributed phase contact surface is formed over the apparatus, high heat and mass transfer coefficients are realized, and at the same time, the hydraulic resistance of each cell is reduced due to the faster formation and deposition of droplets on the cell walls due to the gas swirling or vapor-liquid flow is carried out simultaneously along three axes. In each cell, several foci of vortices are formed due to the complex shape of the base cross section, which allows you to quickly, efficiently and evenly distribute the gas-liquid system throughout the entire volume of the apparatus.

Studies have shown that in the present invention, the working speed in the gas phase reaches 8 m / s, the working density of irrigation reaches 160 m ³ / (m ² ⋅ h).

The hydraulic resistance of the first layer of a high-intensity batch vortex nozzle is less than 90 Pa.

The conducted experimental studies prove that the complex shape of the cross section of the cell base (see Fig. 4, 5) provides a decrease in hydraulic resistance and an increase in the intensity of heat and mass transfer.

High operational properties of the nozzle in accordance with the present invention provide an improvement in the mass-dimensional and energy performance of heat-mass transfer equipment up to 40-60%. The nozzle easily adapts to equipment of any standard size and is characterized by an increased redistributing ability of the liquid phase over the cross section of the apparatus even when the latter is fed to one point.

Claims (4)

1. A nozzle for contacting gas and liquid containing the cells forming the packet, said cells have a frame made in the form of a straight non-rectangular parallelepiped, and the sides are curved so that one ends of the opposite said sides are curved towards each other, and the other ends curved in opposite directions. 2. The nozzle according to claim 1, characterized in that the base of said frame is made in the form of a rhombus having an angle from 95 to 120 °. 3. The nozzle according to claim 1, characterized in that at least a portion of the surface of said sides is roughened. 4. The nozzle according to claim 1, characterized in that at least some of the said sides are perforated.

Images