DE19952760A1 - Stirrer to mix and blend liquid has number of blades fitted to hubs at center shaft with asymmetric curve profile - Google Patents

Abstract

The stirring apparatus, for mixing a liquid, has a number of blades (B) fitted to a hub (N). The blades (B) have an asymmetric curvature profile resembling an aircraft wing and a unified thickness. The blade has two longitudinal edges, with a curvature radius which decreases from the first longitudinal edge to the second. The blade (B) has a Reynolds number of <= 60000 and a sliding count of no more than 0.09 (especially no more than 0.04), and preferably <= 0.04 at a Reynolds number of 40000-120000 and especially up to 180000. The second longitudinal blade edge runs into a point. Both longitudinal edges have different lengths. The blades (B) are held by connecting arms (V) at a gap from the hub (N). The profile axis (P) of the blade profile is at right angles to the hub (N) axis. The blades (B) are set at an angle of 0.5-30.0 deg to a plane at right angles or parallel to the hub (N) axis, or the blade profile axis (P) is parallel to the hub (N) axis. The blades (B) are mounted so that they are diametrically opposite each other on a plane at the hub (N), and the stirrer has blades (B) on a number of planes with their hubs (N) on the center shaft (W).

Description

The invention relates to a stirring element for mixing a Fluids according to the preamble of claim 1.

Such a stirring element is known from US 5,297,938. There the blades are attached to a hub via auxiliary blades brings. The leaves consist of a kinked plate. The radially outer plate section is essentially symmetrically curved.

From US 4,802,771 a stirring device is known from a stirring element is attached to a shaft. The blades of the stirring element are symme at their ends tric curved fins.

US 4,519,715 describes a propeller for generating a axial flow. The leaves extending from the shaft ter have a symmetrical curvature in cross section.

A mixing device is known from US Pat. No. 4,896,971 the multiple impellers are attached to a shaft. The The ends of the leaves are curved downwards. The leaves white have a symmetrical curvature at the ends. You are with narrow auxiliary blades attached to the shaft. In top view the blades partially overlap on the stirring element.

US 5,158,434 and 5,112,192 describe impellers for Mix in liquids. The blades of these impellers stretch radially from a shaft. You are convoluted and have a full profile in the manner of an airplane wing.  

In the Flü described in US 5,813,837 and 5,052,892 in turn, kinked blades are attached to the shaft brings.

In the known stirring devices is to achieve the ge desired stirring result a relatively high power input required. In addition, the stirring devices require the prior art, a high manufacturing cost.

The object of the invention is to provide a stirring element with a good through with as little energy expenditure as possible mixing of a fluid is possible. In addition, the stir bar ment be as simple and inexpensive to manufacture.

This object is solved by the features of claim 1. Appropriate developments of the invention result from the features of claims 2-14.

According to the invention it is provided that the profile is asymmetrically curved in the manner of an airplane wing. - The stirring element according to the invention surprisingly performs with a significantly lower energy input compared to mixing results. It's simple and inexpensive adjustable.

The plate also has a first and a second longitudinal edge and the radius of curvature decreases in profile from the first to the second longitudinal edge. The profile thus formed is characterized by a particularly high lift coefficient c _a and a low drag coefficient c _w .

The profile has a Reynolds number Re of less than 60,000 a sliding number ε of at most 0.09, preferably  at most 0.04. According to a particularly preferred embodiment The shape of the slide is ε in an area of the Reynolds Number from 40,000 to 120,000, preferably up to 180,000, small less than 0.04.

It is also of hydrodynamic advantage that the second Longitudinal edge of the plate tapered in profile is. Depending on the application, the first and the second Long edge can be of different lengths.

It is considered particularly advantageous that the leaves by means of a connector at a distance from the hub are held. The connector can be a Rod, a tube or a particularly aerodynamic professional acted element. With such an arrangement the Leaves form at a certain speed of movement speed on the first longitudinal edge or rear edge of the sheets two counter rotating pegs. The training sol cher swirl braids is beneficial; they contribute to the improved Mix the fluid. The vortex braids form surprisingly, even with profiles with a small one Sliding number off. The energy expenditure for their generation is ge ring.

A profile axis of the profile is advantageously vertical arranged to the axis of the hub. But it may also be that the profile axis at an angle to the axis of the hub or also is arranged parallel to the axis of the hub. Under profile axis is understood in this context an axis, which in the runs essentially parallel to the longitudinal edges and points connects the same curvature.  

According to another design feature, the leaves are with an angle of attack relative to one perpendicular to the axis attached to the hub. If the profile axis is arranged parallel to the axis of the hub, it can be advantageous be sticky that the blades with an angle of attack opposite attached to a plane parallel to the axis of the hub are. The angle of attack can be between 0.5 and 30 °, preferably be 10-15 °. This will further increase the mixing result improves. Of course, inclinations are also Leaves between the aforementioned vertical and parallel Arrangement possible.

It is advantageous that at least two of the leaves are in one the opposite arrangement in a first level on the Are attached. However, several, e.g. B. four, at opposite radially from the hub he Leaves attached to extending axes may be provided. It it is also possible for a plurality of levels to be provided and in each of the levels at least two leaves in each other opposite arrangement are provided.

Exemplary embodiments are described below with reference to the drawing the invention explained in more detail. Show it

Fig. 1 is a profile of a blade of the invention,

Fig. 2 shows the determination of the glide ratio of the sheet of FIG. 1 and a wing profile according to the prior art,

Fig. 3, the glide ratio of the sheet of FIG. 1 in comparison to a floating-wing profile according to the prior art as well as a flat plate,

Fig. 4 shows the formation of eddy braids in a sheet accelerator as Fig. 1,

Figure 5 nik. The power input of the sheet of FIG. 1 in comparison with agitating elements according to the prior Tech,

Fig. 6 shows a first stirring member,

Fig. 7 shows a second agitating member,

Fig. 8 shows a third agitating element,

Fig. 9 shows a fourth stirring member,

Fig. 10 shows a fifth stirring element and

Fig. 11 shows a sixth stirring member.

To characterize stirring elements, the Reynolds number is used primarily in stirring technology. It results from the following relationship:

Here d _{r is} the stirrer diameter, n the speed and ν the kinematic viscosity.

With regard to the geometric design of the profile of the blades of impellers, the equation for the driving force can be used:
F _A = C _a .Sq

where the reference surface S is defined by the product of the profile depth fe l with the span b:

S = b.l.

Similarly, can the resistance force F _W following define:

F _W = C _w .Sq

The factors c _a and c _w are the dimensionless lift or drag coefficient. With q the kinetic pressure is called.

The glide ratio ε is defined as follows:

The following relationship can be used to determine the stirring power:

P = M.2.π.n.

To determine the stirring power P, it is sufficient that Knowing torque M and the speed n of the stirrer. Both Sizes can easily be measured. After the investigation tion of these sizes, it is possible to use the dimensionless To determine Reynolds number Re. Likewise, the stirring performance  or the power input P compared to the mixing time be.

In Fig. 1, a profile of a sheet B according to the invention is shown ge. The sheet B is made from a plate with a first longitudinal edge L1 and a second longitudinal edge L2. The radius of curvature decreases in profile from the first L1 to the second longitudinal edge. The second longitudinal edge L2 is tapered in profile. With the exception of the tapered section in the region of the second longitudinal edge L2, the sheet B has an essentially uniform thickness d.

In FIG. 2, the lift coefficient c _{a of} the sheet B according to FIG. 1 is plotted against its drag coefficient c _w at a Reynolds number of 42,000. In comparison, the lift coefficient c _a above the drag coefficient c _w for a wing profile according to the prior art is also shown on the right. In contrast to the profile according to FIG. 1, this wing profile is flat on its underside.

From the comparative illustration in Fig. 2 it is clear that the sheet B according to the invention has higher lift coefficients c _a and lower drag coefficients c _w than the wing according to the prior art.

In Fig. 3, the sliding number ε is shown over the Reynolds number for the sheet B according to FIG. 1, a wing profile according to the prior art and a flat plate. Sheet B according to FIG. 1 is characterized by particularly low sliding numbers ε over the entire range of the Reynolds numbers Re considered here from approximately 20,000 to 180,000. The sliding numbers ε are always less than 0.04 over the entire range. In particular in the range between 20,000 and 60,000, the sliding numbers ε of the sheet B according to FIG. 1 are less than 0.04. According to the state of the art, the sliding numbers ε of the wing profile reach values of more than 0.2.

FIG. 4 shows the vortex formation caused in a fluid when using the sheet B according to FIG. 1. The spatial flow caused on the sheet B according to the invention arises from a pressure equalization between the underside and top of the sheet at the sheet ends. This pressure equalization deflects the streamlines at the top towards the center and at the bottom from the center. Towards the center of the sheet, the size of the streamline deflection decreases to zero on both sides. When the upper and lower stream lines behind the blade are reunited, they have lateral speed components depending on the size of the deflection. This initiates a rotary movement. Along the second edge L2, vortices are thus created which together form a vortex surface. The vortex bands, which start from the leaf ends, are particularly strong. These are commonly referred to as "swirl braids". The hydrodynamically profiled sheet B according to the invention is distinguished by particularly narrow peg braids. If you inject z. B. to carry out a che mixing reaction a 2nd component in the area of these vortex braids, the vortex braids ensure a Schlagar term mixing with a fluid in the first component. This makes it possible, in particular in the case of competing chemical reactions, to carry out a targeted reaction, ie to influence the selectivity and the conversion.

FIG. 5 shows the mixing time of the sheet B according to FIG. 1 over the power input P. Sheet B used here has an edge length of the first and second longitudinal edges of 50 mm and an edge length of the first and second transverse edges of 50 mm. The thickness of the curved plate is 1 mm. The angle of attack is 15 °. Compared to the stirring elements examined according to the prior art by Ruzkowski (Ruszkowski, S., 1994, A rational method for measuring blending perfor mance and comparison of different impeller types, Proc. Eight European Conference on Mixing, I. Chem. E. Symposium Series No. 136, 283-291) the mixing time is reduced by a multiple with comparable power input. The stirring element according to the invention is therefore particularly energy-saving.

In Fig. 6, a first embodiment of a Rührele element is shown. A hub N is attached to a shaft W. From the hub N extend rod-like connecting elements V, to which a sheet B is attached at each end. A profile axis P of the blades B is oriented parallel to the axis of the hub N here. In the second exemplary embodiment shown in FIG. 7, the profile axis P is arranged perpendicular to the axis of the hub N. The blades B are set here with an angle of attack of approximately 15 ° with respect to a plane defined in particular by rotation of the connecting elements V. The plane is therefore perpendicular to the axis of the hub N.

In the third and fourth embodiments shown in FIGS. 8 and 9, the connecting element V is made shorter than in the aforementioned exemplary embodiments.

Fig. 10 shows an embodiment in which two sheets B in an opposing arrangement are each fixed to a connecting element V. There are several levels here. Each level is occupied by an agitation element consisting of two sheets B in an opposite arrangement.

In Fig. 11, a stirring member is shown, are received on a connecting element V in which two sheets B.

Reference list

N hub
W wave
B sheet
P profile axis
V connecting element
L1 first longitudinal edge
L2 second longitudinal edge
d thickness

Claims (14)

1. A stirring element for mixing a fluid with a plurality of blades (B) attached to a hub (N) and formed from a plate with a curved profile, the plate having a substantially uniform thickness (d), characterized in that that the profile has an asymmetrical curvature in the manner of an aircraft wing. 2. Stirring element according to claim 1, wherein the plate is a first (L1) and a second longitudinal edge (L2) and the elbow radius in profile from the first (L1) to the second longitudinal edge (L2) decreases. 3. stirring element according to one of the preceding claims, where for sheet (B) with a Reynolds number of less than 60,000 a sliding number ε of at most 0.09, preferably at most 0.04. 4. stirring element according to one of the preceding claims, where at the sliding number ε of the sheet (B) in a range of Reynolds number from 40,000 to 120,000, preferably up to 180,000, less than 0.04. 5. Rührelememt according to any one of the preceding claims, where at the second longitudinal edge (L2) of the plate pointed in profile is continuously trained. 6. stirring element according to one of the preceding claims, where at the first (L1) and the second longitudinal edge (L2) below are of different lengths.   7. stirring element according to one of the preceding claims, where with the leaves (B) by means of a connecting piece (V) are kept at a distance from the hub (N). 8. stirring element according to one of the preceding claims, where with a profile axis (P) of the profile perpendicular to the axis of the Hub (N) is arranged. 9. stirring element according to claim 8, wherein the blades (B) with an angle of attack relative to a perpendicular to the axis of the Hub (N) brought level are attached. 10. stirring element according to one of the preceding claims, where at the profile axis (P) parallel to the axis of the hub (N) is arranged. 11. stirring element according to claim 10, wherein the blades (B) with an angle of attack relative to a parallel to the axis of the Hub (N) imaginary level are attached. 12. stirring element according to one of the preceding claims, where at the angle of attack between 0.5 and 30 °, preferably 10-15 °. 13. stirring element according to one of the preceding claims, where at least two of the leaves (B) face each other Gender arrangement in a first level on the hub (N) are brought. 14. Stirring element according to one of the preceding claims, where is provided at a plurality of levels and in each of the Planes at least two of the sheets (B) facing each other lying arrangement are provided.