RU2492920C2 - Mixer - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to mixers intended for homogenisation of major volumes of suspension and may be used at chemical and metallurgical plants. Proposed mixer comprises vertical shaft revolved by the drive. Blades enclosed in fixed ring arranged at said shaft upper section and inclined to vertical. Vertical vanes are secured at shaft bottom section. Ring features definite height-to-diameter ratio while vanes feature definite width-to-height ratio. Revolving blades forced the suspension downward while swirl it radially. This results in intensive mixing of the entire bulk of suspension without stagnant areas.

EFFECT: higher efficiency of mixing, power savings.

6 dwg

Description

The invention is intended for the homogenization of large volumes of suspension. The mixer can be used in chemical and metallurgical industries.

A wide variety of mixers are used in various fields of human activity. A significant proportion of them are mixers with a vertical rotating shaft, on which working bodies are fixed - blades, blades, combs, etc. [1]. The design of such mixers is largely determined by the nature of the mixed media. The main problem when mixing suspensions is the sedimentation of solid particles on the walls and bottom. To prevent this process, various methods of creating turbulence covering the entire mixed volume are used. However, this drastically increases energy consumption. In addition, it is known that paddle and especially propeller stirrers during rotation form mainly an axial fluid flow. It should be noted that part of the liquid flowing from the blades forms a radial fluid flow, which, moving towards the walls of the apparatus, interacts with the fluid flow rising from the bottom of the mixer and prevents its further advance up to the surface of the mixed fluid. The resulting two circuits of fluid circulation from the lower and upper working mixing elements of the mixer prevent complete homogenization of the liquid in the apparatus.

Known turbulent mixer [2], in which the main mixing function is performed by vertical blades mounted in the lower part of the vertical shaft. To create turbulence, the inclined blades located above are designed with transverse plates fixed at their ends, which should prevent the centrifugal movement of the jet, directing it down. However, this design is not effective enough, since the plates also rotate and, due to their small size, cannot block the external surface of the flow. As a result, the use of a known stirring device is too costly.

A device for mixing, containing a vertical cylindrical tank with a bottom, a mixer installed inside the tank, containing a vertical shaft and a turbine mounted on it. The turbine is made in the form of a disk to which flat blades are attached around the circumference with a gap. The ratio of the height and length of each turbine blade to the diameter of the latter is from 0.2 to 2.0 and from 0.01 to 0.2, respectively [3]. It is known [1] that turbine mixers are high-speed mixing devices, the rotation speed of which is from 100 to 500 rpm, and are used for local mixing of especially viscous liquids in small volume reactors up to 450 m ³ . To ensure the homogenization of liquids and suspensions in large-volume apparatuses (≈5000 m ³ ), the use of turbine mixers is impractical in view of the significant specific power consumption for mixing.

Closest to the claimed invention (prototype) is a device for mixing [4]. The device comprises a cylindrical body with technological nozzles, a drive and a central shaft with a mixing unit fixed to it, made with a turbine mixer and a propeller mixer, covered by a cylindrical diffuser (ring). The housing is equipped with a heating jacket connected with a thermostat and nozzles. The dimensions of the reactor elements, in particular the inner diameter of the vessel, the diameter of the turbine mixer, the diameter of the propeller mixer, the height of the turbine mixer above the bottom of the vessel, the height of the propeller mixer above the bottom of the vessel must be interconnected by certain ratios to achieve effective mixing of the entire reaction mass.

The installation of a diffuser (ring) around the paddle mixer limits the spread of the radial fluid flow to the walls of the apparatus. However, the above ratios of the parameters of the mixer do not allow to increase the mixing efficiency and reduce energy consumption.

The objective of the present invention is to significantly reduce energy consumption while increasing the mixing efficiency.

The technical result consists in developing a mixer design in which the radial fluid flow is completely converted to axial and the speed and general circulation of the fluid in the apparatus are increased, which leads to an increase in mixing efficiency.

The technical result is achieved by the fact that in the mixer having a vertical cylindrical body and a drive with the possibility of transmitting rotation to the central shaft, on top of which are attached the blades inclined to the vertical, surrounded by a stationary ring oriented coaxially to the shaft, and the blades, according to the claimed invention, on the bottom surrounded by a fixed ring with a height to diameter ratio of 0.25-0.30, and the blades have a width to height ratio of 0.2-0.4.

To assess the performance of various mixing devices, there is a dependence of the degree of liquid homogenization in the apparatus volume on the power consumption for mixing. Moreover, the hydrodynamic parameters of the apparatus, such as the distribution of the fluid velocity in the apparatus, the pump effect of the mixer, the circulation speed of the suspension, etc. are decisive in optimizing the mixing process.

In general, the mixing process is characterized by the concepts of circumferential and radial-axial fluid circulation. Moreover, the latter is of the greatest importance for the homogenization process, since in its absence there can be no talk of convective mixing of the liquid. In industrial practice, mixing in large-volume apparatuses, reflective partitions are used to increase the radial-axial component of speed. However, the latter lead to an increase in power consumption and a decrease in the mixing efficiency [1, p. 134].

In the proposed invention, the task of increasing the radial-axial component of the speed is solved by changing the conditions for the flow of blades around the fluid flow. In the general case, when the blades move in a liquid, they flow around the stream along the vertical and horizontal edges. In this case, a part of the oncoming flow moves along the surface of the blade in the radial direction under the action of centrifugal forces. It should be noted that it is the radially transported stream that ensures the circulation of liquid in the apparatus, and the stream flowing around the blade locally turbulizes the liquid.

The ratio of the fluid flow around the blade and transported along it directly depends on the ratio of the lengths of the horizontal and vertical edges of the blade. The flow of liquid on the blades due to centrifugal forces is carried to the peripheral vertical edge of the blade. As the fluid flows, part of it flows through the upper and lower horizontal edges. With the same perimeter of the blade, an increase in the length of the vertical edges and a decrease in horizontal leads to an increase in the proportion of the transported fluid flow and a decrease in the proportion of the flow around the blade along the horizontal edges. This increases the radial-axial component of the velocity and increases the degree of fluid circulation in the apparatus.

Moreover, as laboratory studies have shown on a model of a device with a flat bottom with a volume of 100 l, and a ratio of height to diameter of 2.5, a decrease in the ratio of the width of the blade to its height less than 0.2 leads to an increase in the power consumption for mixing to achieve the same the degree of homogenization of the suspension of aluminum hydroxide, because the fraction of the transported stream is insignificant and the blade is mainly surrounded by liquid. When this ratio increases above 0.4, the power consumption gradually begins to grow, since the proportion of the flow around the horizontal edges of the stream prevails over the transported one, only with a ratio of 0.2-0.4 the power consumption becomes minimal.

The execution of the ring with the claimed ratio of height to diameter provides a reduction in energy consumption with an increase in mixing efficiency. The claimed height of the ring fully ensures the conversion of the radial fluid flow into axial flow. With a height to diameter ratio of less than 0.25, i.e. with insufficient ring height, part of the radial fluid flow will bend around it, reducing the overall fluid circulation in the apparatus. The ratio of height to diameter is more than 0.30, i.e., excessive ring height will increase the metal consumption of the structure without affecting the mixing efficiency.

The inventive design is illustrated by drawings, in which Fig. 1 shows the location of the structural components of the mixer, Fig. 2 - circuits of the fluid from the lower and upper working mixing elements of the inventive device, Fig. 3 - contours of the fluid from the lower and upper working mixing elements in the prototype [3], in Fig. 4 - the contours of the fluid from the lower and upper working mixing elements according to the analogue of [2], in Fig. 5 - the dependence of power consumption on the ratio of the width of the blades L to the height H, in Fig. 6 - dependence l power costs from the ratio of height to diameter of the ring.

A drive 2 is mounted above the cylindrical tank 1, which rotates the central vertical shaft 3. There are two tiers of mixing elements. The upper tier contains a fixed ring 4, inside of which are located blades 5 attached to the shaft 3, the planes of which are inclined to the vertical direction. The lower tier of the mixing element is made in the form of blades 6, mounted on the shaft 3 using a traverse. The volume of the tank 1 is filled with a stirred pulp 7.

The mixer works as follows. When the shaft 3 rotates, the blades 5 drive the suspension flow down to the blades 6, which convert the vertical flow to radial. Having reached the walls of the tank 1, the suspension rises to the upper part of the volume, where it again falls on the blades of the upper tier. This ensures turbulence in the entire volume of the tank 1. Ring 4, made according to the claimed ratio prevents centrifugal removal of the suspension, significantly increasing the efficiency of the blades 5. As a result, intensive mixing of the entire mass of the suspension without the presence of stagnant zones.

To assess the effectiveness of the invention, the dependence of the stratification of the suspension in relative units on the cost of power for mixing (6) was investigated. It was experimentally found that the minimum energy consumption is observed when the ratio of the height of the ring to the diameter in the range of 0.25-0.30. When the ratio of the height of the ring to the diameter is less than 0.25, the required power increases by about 1.5 times.

The dependence of power costs on the ratio of blade width L to height H was also studied for the same pulp stratification (Fig. 5). The graph shows that the optimal value of this ratio falls on the range 0.2-0.4.

Thus, in comparison with the prototype there is an increase in mixing efficiency while reducing energy consumption.

Information sources

1. Z. Shterbachek, P. Tausk. Mixing in the chemical industry. Per. from Czech, ed. I.S. Pavlushenko, L .: GHI, 1963.

2. Copyright certificate of the Russian Federation No. 948684, cl. B28C 5/16, 07/07/1982.

3. RF patent No. 784795, cl. S12M 1/02, 11/30/1980.

4. RF patent No. 2128182, cl. B01F 7/16, 03/27/1999.

Claims (1)

An agitator having a vertical cylindrical body and a drive with the possibility of transmitting rotation to the central shaft, on top of which blades inclined to the vertical are mounted, surrounded by a stationary ring oriented coaxially to the shaft, and vertical blades, characterized in that the blades are surrounded by a fixed ring with a height to a diameter of 0.25-0.30, and the blades have a ratio of width to height of 0.2-0.4.

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