RU82580U1 - MIXING DEVICE FOR GAS SYSTEMS - LIQUID - Google Patents

Abstract

A mixing device for gas-liquid systems containing a housing, an injection chamber, a liquid atomizer, a vertical tubular mixer, a dispersant located perpendicular to the axis of the mixer, characterized in that the mixer is made in the form of pipes coaxially mounted under each other, followed by a dispersant, and the diameter of the apparatus either changes in height or is constant.

Description

The utility model relates to devices that are used for carrying out technological processes in gas-liquid systems to create intensive mixing of phases for the purpose of mass or heat transfer, to obtain thin gas dispersions, high gas content of the liquid phase, as well as chemical interaction. It can be used in oil refining, petrochemical, chemical and other industries.

The most promising methods of intensification of gas-liquid processes: phase inversion, the use of input and terminal effects, collision, swirl, mutual ejection of flows, superposition of pulsations, and others.

A device is known in which many of these methods of intensification are used [autosvid. USSR No. 1263330 (MKP B01F 5/04)]. In this device for the intensification of the mass transfer process by increasing the contact surface of the phases and the speed of its renewal, four additional mixers are installed in the horizontal plane. The disadvantage of this device is the design complexity, a significant increase in pressure and flow rate, which is fed to five mixers.

The closest structural analogue is an aerating device [autosvid. USSR No. 593723 (M. Cl. B01F 5/04)], which is adopted as a prototype. The aerating device comprises a housing, an injection chamber, a liquid atomizer, a vertical tubular mixer, a dispersant located perpendicular to the axis of the mixer. Liquid under pressure is supplied to the atomizer and sprayed, creating a high-speed flow. The high-speed flow of atomized liquid creates a vacuum in the injection chamber, allowing suction

gas phase inside the mixer. Directly at the outlet of the atomizer in the injection chamber, the first stage of liquid-gas contact occurs. In the mixer, the second stage of liquid-gas contact proceeds, due to the developed surface of the atomized liquid, which causes phase inversion. At the outlet of the mixer, the gas-liquid mixture disperses upon impact, forming a fine dispersion, causing the third phase contact phase. The fourth stage of the developed contact of liquid and gas is carried out in the entire volume of the apparatus.

The disadvantage of the prototype is that the intensity of mixing, and consequently the mass transfer process, in the working volume of the reactor is much lower than in the mixer (vertical pipe), although the residence time of the liquid and gas in the working volume is much longer (hundreds of times) than in the mixer.

The objective of the proposed utility model: the intensification of the process of mass transfer by increasing the contact surface of the phases and the speed of its renewal. The problem is solved by introducing into the design of the apparatus n dispersants (where n is the number of dispersants, n> 1) that divide the reaction volume into n parts (n> 1). The number of collisions of a two-phase system with dispersants increases. The figure 1 shows the proposed three-stage mixing device for the gas-liquid system. The mixing device comprises a conical or cylindrical body 3, an injection chamber 2, a liquid atomizer 1, coaxially mounted mixers 4 of the first, second and third stages, made in the form of vertical pipes of varying height or a constant diameter, inserted into each other and dividing the gas-liquid flow into two parts and dispersants 5 of the first, second and third stages, located perpendicular to the axis of the mixers.

The device operates as follows. Liquid under pressure is supplied to the atomizer 1, atomized and sucks in the gas entering the injection chamber 2. Directly at the outlet of the atomizer into

Injection chamber is the first stage of contact of liquid and gas. The resulting gas-liquid mixture passes through the mixer 4 of the first stage. In the mixer, the second stage of liquid-gas contact proceeds, due to the developed surface of the atomized liquid, which causes phase inversion. Depending on the operating mode of the mixer, its geometrical parameters and the pressure drop across the atomizer, a gas-liquid two-phase flow with a different ratio of liquid to gas can form in the mixer. The two-phase flow can be with a dispersed liquid or gas phase. Under certain conditions, phase inversion can occur in the mixer itself and the gas phase becomes dispersed. This mode of operation is most effective due to the fact that at the moment of inversion the highest value of the mass transfer coefficient is observed. Upon exiting the mixer of the first stage, the gas-liquid flow is separated. Part of the flow at high speed hits the dispersant 5 of the first stage. When a gas-liquid stream hits a dispersant, gas bubbles are crushed. The third stage of gas-liquid contact occurs. Then the resulting mixture is distributed with vortexes over the reaction volume of apparatus 3. In the reaction volume, the fourth stage of gas-liquid contact is carried out.

The second part of the gas-liquid flow from the mixer of the first stage is directed to the mixer of the second stage, in which the hydrodynamic pattern is repeated. After each stage, the liquid saturated with gas flows down a cylindrical or conical wall down to the next stage of mass transfer and is partially mixed with the reaction volume due to vortices. The number of stages of mass transfer and their volume can be different (more than 1). For an n-step (where n is the number of dispersants, n> 1) apparatus, 3 · (n-1) +4 stages of developed contact of gas and liquid are characteristic, each of which is described by its mass transfer coefficient.

Claims (1)

A mixing device for gas-liquid systems containing a housing, an injection chamber, a liquid atomizer, a vertical tubular mixer, a dispersant located perpendicular to the axis of the mixer, characterized in that the mixer is made in the form of pipes coaxially mounted under each other, followed by a dispersant, and the diameter of the apparatus either changes in height or is constant.