CH676331A5 - Countering eddies in stirred bulk fluid - by providing oppositely rotating stirrers at different levels - Google Patents

Abstract

When a body of fluid in a container is stirred by a rotary mixer, whether axial or not, and given that the tangential sections of internal flow have minimum mixing effect, and that, esp. at high speeds an eddy is formed whose various negative aspects include unwantedm absorption of air/gas into the eddy surface, eddy formation is countered by one or more additional stirrers rotating in opposite directions. The stirrers may be of counter-rotating propellor type, with separate drive means via an inner shaft within a hollow outer shaft, or with a single drive with part of its power converted for reversed drive of the second stirrer. Stirrers pref. operate at different levels. Apart from the rotary stirrer(s), the container has no inserts which could affect fluid flow. USE - Esp. for wide range of prodn. processes.

Description

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description

The present invention relates to a method for mixing a fluid as well as an agitator and a reaction kettle according to the preambles of claims 1, 2 and 7.

A fluid is understood to mean a single-phase or multi-phase flowable material to be stirred, e.g. a pure liquid, a suspension, an emulsion or a gas-liquid mixture.

In process engineering, a large number of mixing processes, also known as stirring or mixing processes, are still carried out in containers. An agitator, on whose agitator shaft one or more agitators working in the same direction of rotation are attached, is immersed in the fluid. These stirrers produce a complex flow field in the container, which essentially causes the fluid to be mixed. The intensity of the mixing can be influenced within a wide range by optimal stirrer geometry and special operating conditions. Studies have shown that with all these possible variations, the tangential component of the resulting flow field makes no or only a modest contribution to the mixing. In addition, this flow component is solely responsible for the formation of a trombone in the container, which has the following disadvantages:

- the available container volume cannot be used optimally and completely,

- the risk of flooding the stirrer increases with increasing depth of the drum,

- In the area of the drum, separation processes caused by centrifugal force can impair the desired mixing,

- Gas (air) bubbles are sucked into the material to be stirred due to the negative pressure associated with the formation of troughs.

For this reason, efforts have long been underway in stirring technology to solve the problem of the formation of drums. However, the previous proposals for solutions have not been satisfactory (compared to Ulimann's Encyklopadie der Technische Chemie, Volume 3 (process engineering and reaction apparatus), Verlag Chemie Weinheim, 4th edition, page 506).

In order to prevent the formation of trombones, baffles are usually arranged in the container today. These baffles redirect the tangential flow components in the axial direction. This measure significantly increases the power requirement of the agitator. The additional cleaning effort also has a disadvantageous effect.

The present invention is therefore based on the object of proposing a method for approximately fluid-free mixing of a fluid. In particular, it should be possible to dispense with the use of baffles in this process; furthermore, the process should also be able to be carried out using conventional stirrer designs.

Another object of the invention is to propose an agitator which is suitable for carrying out the method according to the invention. In a special embodiment, this agitator is to be designed in such a way that it can be used on existing reaction vessels instead of conventional agitators without conversion work.

Another object is to propose an economical reaction kettle with an agitator according to the invention.

These objects are achieved by the characterizing features of claims 1, 2 and 7. Particular embodiments are defined in the dependent claims.

The condition “approximately free of droplets” is understood to mean a fluid surface which has no or only one, compared to the same fluid and stirred with the same, but in the same direction rotating stirring, much smaller drum

The flow field generated in the fluid in the method according to the invention can be briefly described as follows:

The two counter-rotating stirrers each generate a tangential flow rotating in the same direction as the respective stirrer. These two tangential flows overlap in their contact area. This mutual influence can be controlled over a wide range by selecting the stirrer speeds and the stirrer designs and the stirrer spacing. In order to prevent the formation of troughs as far as possible, operating conditions are selected which compensate for the two tangential flows as completely as possible. In other words: there are practically an infinite number of possible combinations of parameters for containment of the trombone. The stirring method according to the invention can thus be completely subordinated to the stirring parameters specified by the actual mixing task. Conventional stirring processes can thus be replaced without restriction by the new method based on the previous knowledge.

It is also conceivable that a certain minimum rotation of the fluid in the container cannot be dispensed with for technical reasons, e.g. to prevent deposits on the inside of the container. This state can also be achieved by suitable selection of the described operating parameters. Inevitably, a drum is formed under such operating conditions, but its formation is reduced in comparison with the drum in stirring with the same, but rotating in the same direction.

The collision of the two tangential flows also has a positive effect on the

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Fluid mixing out. While in conventional stirring processes the energy dissipation that is relevant for local mixing mainly takes place in the area of the stirrer and / or the Sfrombebreaker, in the method according to the invention the flow energy additionally dissipates over the entire contact zone of the two tangent vortexes. A suitable choice of the geometric and operational characteristics can therefore be used to build up a homogeneous energy dissipation field that largely covers the entire contents of a reaction vessel. A stirring process comparable with the mixing characteristics of the method according to the invention, also with two stirrers, has already been described in the literature (for comparison, Brauer, “Development and Performance of a Ramjet Mixer”, inter alia in the journal Chemie-Ing.-Techn. 52, issue 12 ( 1980)). However, this stirring process is in no way intended to influence the drum.

The method according to the invention can of course also be used using more than the minimally required two stirrers. It is thus possible to provide several pairs of stirrers working in opposite directions at the same time. However, the number of stirrers operating in one direction of rotation can also differ from the number of stirrers rotating in the opposite direction. Instead of individual stirrers which differ in the direction of rotation, groups of stirrers of the same design or which differ in terms of design or dimensions can also be used. Depending on the configuration selected, concentric stirrer shafts or non-coaxial shafts can be used. A structurally complex drive train device is also conceivable, e.g. with internal direction reversers, for example in the form of sun gear-like idler gears.

The choice of the optimal stirrer configuration and the geometry of the individual stirrers essentially depends on the fluid to be mixed i.e. from its material data (viscosity, density, if necessary interfacial tension) and the desired degree of homogenization. Since mixing processes are conceivable in practice with a wide variety of fluids and with widely varying homogenization goals, a final listing of dimensioning criteria must be dispensed with here. However, it is within the discretion and ability of the person skilled in the art to determine the structural parameters and the stirring-specific operating data for a given fluid in such a way that the listed fluidic advantages of the method according to the invention can be used to reduce the vortex.

The method according to the invention is described in more detail below with the aid of a few examples and with reference to the figures.

Figures 1-4 show the most important geometric dimensions of a laboratory test facility and some stirrers used therein. The reaction vessel is a cylindrical vessel 1 with a so-called glass bottom. The internal flow can be observed and assessed through the transparent vessel wall.

The inner diameter of the vessel 1 is di = 400 mm and the height h = 480 mm.

The two stirrer shafts 6, 7 are individually driven by two independently controllable DC motors 4, 5.

In a series of tests, disc (Fig. 2), inclined blade (Fig. 3) and blade stirrers (Fig. 4) with the main dimensions and the following individual data given in the figures were used: disc stirrer: rs = 40mm, b = 30mm, blade shape square inclined blade stirrer: 1 = 50 mm, b = 30 mm blade stirrer: 1 = 60 mm, b = 50 mm, number of blades = 2

The investigations were carried out on the one hand with water and on the other hand with several weakly viscous liquids from hydroxyethyl cellulose solutions up to 0.2 Pa * s (200 cP). The degree of filling of the vessel was h / dj = 1 in each case. The stirrer spacing was 140 mm, the lower stirrer being 120 mm from the floor. The following results were obtained with regard to drum reduction:

a) Disk stirrer

A pronounced reduction in the drums occurs when the upper stirrer is operated at approx. O times the speed of the lower stirrer. Under these operating conditions, no tangential flow can be found on the liquid surface.

Numerical example:

lower stirrer upper stirrer

case 1

110 rpm

94 rpm

Case 2

170 rpm

145 rpm

Deviations from the speed ratios mentioned led to tangential flows on the surface of the liquid, which with increasing speed difference showed an increasing formation of troughs. A higher speed of the upper stirrer leads to a more pronounced pellet formation in comparison to the same experiment with a correspondingly higher speed of the lower stirrer.

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b) Inclined bite stirrer

Basically, the same effects can be seen as with the disc stirrer. However, a significantly larger speed difference is required before a drum is formed. For example, with a speed of the lower stirrer of 200 rpm and 130 rpm of the upper stirrer, one cannot yet speak of a trained drum. In the investigations, both the upper and the lower stirrer were used to promote both upwards and downwards. No significant differences could be found in this regard with regard to the reduction in the drums.

10 c) blade stirrer

Optimal drum reduction was achieved with this stirrer at a speed ratio of 0.9

Numerical example: lower stirrer upper stirrer 154 rpm 170 rpm

20 d) combination of the stirrers mentioned

Axial and radial conveying stirrers can be combined as desired. The speed ratios that lead to the elimination of the surface tangential flow and thus to the lifting of the thrust, as shown in the following table, vary within wide limits.

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Stirrer

Speed [rpm]

Ratio speed oui o-top

Blade stirrer

154

0.9

u = below

Blade stirrer

170

O

Blade stirrer

150

0.6

u

Inclined sheet convey down

263

0

Blade stirrer

150

0.8

u

Disc stirrer

190

0

Blade stirrer

100

0.8

u

Disc stirrer

130

0

Blade stirrer

130

0.8

u

Disc stirrer

166

O

Inclined sheet upwards

224

1.2

u

Disc stirrer

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O

Inclined sheet convey down

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2.4

u

Disc stirrer

100

50 Due to the large number of free geometry and operating parameters, the specific data listed above are only to be regarded as non-limiting examples of possible process applications. It is quite conceivable that completely different results can be achieved with other stirrer designs or other stirring media.

According to the experience to date, reaction vessels whose agitator shaft (s) are parallel or inclined, e.g. at an angle in the range 0 to 45 degrees to the longitudinal axis of the boiler. The desired drum suppression can be accomplished particularly efficiently if at least one of the stirrers is arranged above the middle of the boiler. There is also no need for a detailed explanation that a reaction vessel without additional internals (which are only intended to eliminate the drum) is inexpensive and therefore also requires minimal cleaning effort.

Claims (9)

Claims 1. Method for at least approximately vortex-free mixing of a fluid by means of an agitator with more than one agitator, characterized in that the fluid has at least two effects 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 CH 676 331 A5 it is exposed to the counter-rotating stirrer in such a way that the drum, which is formed when the one of the two stirrers is switched off or when the two stirrers are rotated in the same direction, is reduced in its design or completely disappears. 2. Agitator for performing the method according to claim 1, characterized in that it has at least two stirrers which can be driven in opposite directions. 3. Agitator according to claim 2, characterized in that a separate drive motor is provided for each stirrer, or in that a single drive motor is provided which drives the other stirrer directly and indirectly via a direction of rotation change member. 4. Agitator according to claim 2 or 3, characterized in that the two agitators are either axially conveying, e.g. in the form of ship propellers or radially conveying, e.g. in the form of disk stirrers, or that one of the stirrers is designed axially and the other radially to promote. 5. Agitator according to one of claims 2 to 4, characterized in that there are means for mounting on a connecting piece of a container, e.g. a reaction vessel. 6. Agitator according to one of claims 2 to 5, characterized in that one stirrer is fastened to a hollow shaft and the other stirrer is fastened to a shaft running through the hollow shaft. 7. Reaction vessel with an agitator according to one of claims 2 to 6, characterized in that the agitator shafts run parallel or obliquely to the vessel axis. 8. Reaction vessel according to claim 7, characterized in that there are no fixed internals or, with the exception of the stirrer, moving internals to influence the flow of the fluid. 9. Reaction kettle according to claim 7 or 8, characterized in that at least one of the stirrers is arranged above the center of the kettle height. 5