DE3718191A1 - Aeration device for agitators - Google Patents

Abstract

An aeration device for agitators for aeration of liquid is described. Downstream, in the direction of flow, of a motor-driven propeller beneath the liquid surface is arranged an element roughly taking the form of an open impeller, in the outer region of which the gas sucked in by injector action is mixed into the turbulent agitator jet produced by the propeller. Various designs of the element roughly corresponding to an open impeller are possible; it is arranged in the pressure region of the propeller.

Description

The invention relates to a ventilation device for Agitators to handle liquids simultaneously with the Vermi also ventilate. In the direction of flow behind the Propeller is rotationally symmetrical to the propeller axis a similar to one known from fluid engineering arranged open impeller model, the air bubbles into the propeller interferes.

Mixers that mix air at the same time into the liquid are known (e.g. DE-P 24 61 032). Here, e.g. over the on the suction side of the Propellers generated negative pressure via a supply line Air drawn in from the atmosphere or even larger ones Deep into the rivers with an additional fan liquid pressed. Now the flow impulse from the propeller is transferred to an air-liquid mixture it explains that with a larger amount of air sucked in the stirring effect drops sharply. You try to counter that to act by using the mixer with the nominal power designed for the largest possible air interference. Disadvantageous but here is that even with minor disturbances the increase in performance in the air supply line Values far exceeds and the desirable Dosing of the air volume via a control valve in the Air supply becomes practically impossible.

Another disadvantage of these known devices is that low diving depth achievable without additional blower.

In contrast, the embodiment of the invention Advantage that by introducing the air on the pressure side of the propeller the stirring effect in no way is changed.

In parallel, there is also only a minor performance change with different air intake, e.g. by Changing the inlet cross-section of a control valve in the air supply line.

Another advantage of the embodiment according to the invention is the high negative pressure when starting the device. The Suction line and the element similar to an open impeller are completely filled with liquid at standstill. At The liquid begins to rotate by pumping action at high speed from the air supply line and out sucked the impeller and it becomes a cleaning effect achieved, even with problematic media, such as Slurry, reliably prevent the suction line from overgrowing different.

Economic ventilation also requires lots of small air bubbles with a big one overall Phase interface and mixing with a lot of liquid. According to the invention this is solved in that the door bulging jet of fluid from behind the propeller Flow core through the rotating disc or hood is accelerated radially outwards and in the disc Outside on the impeller edges with the injector effect sucked air mixed.

In the shear field between the turbulent stirring jet and which the air preferably approximately at right angles to this Rotating blades entering the stirring jet larger air bubbles finely divided, as well as through the door bulent impulse exchange of the fast stirring jet with mixed with a lot of liquid in the slower environment and kept at a distance.

In the following, the invention will be described with reference to the drawings are explained:

Fig. 1 mixer with ventilation device according to the invention, with drive outside of the medium, in side view and partly in section.

Fig. 2 to 4 representation of details of the invention, on an enlarged scale.

Fig. 6 mixer with ventilation device according to the invention, designed as a diving unit, in side view.

In Fig. 1, a basic construction possibility is illustrated a mixing machine with an inventive ventilation device. The propeller ( 1 ) with the wing disc ( 2 ) is motorized via the shaft ( 16 ). This wing disc forms an element similar to an open impeller with the stationary disc that can be adjusted. The stationary disc ( 4 ) is attached to the bearing housing ( 6 ) of the propeller shaft ( 16 ) by means of a holder ( 27 ).

The center of the stationary disk is connected to the atmosphere, for example, via a feed line ( 5 ).

At the beginning of the rotation of the propeller with the superior one The entire suction line is up to Mirror under liquid. By pumping the with adjustable gap to the stationary disc rotating Wing disc is the space between the discs and the suction line emptied. The flow in below de Air is introduced into the turbulent stirring jet.  

In an embodiment according to the invention according to FIG. 2, the rotating wing disk and the stationary disk are designed as conical hoods. A more aerodynamic shape on the side facing the propeller improves the efficiency of the agitator.

Fig. 3 shows a further embodiment according to the invention. The blades become wedge-shaped in radial section due to different angles of inclination of the rotating hood and the stationary hood. The resulting large difference in the flow cross-sections on the outer diameter and on the inner diameter creates a high vacuum.

Fig. 4 shows an embodiment in particular according to claim 9. Due to the aerodynamic conical design of the rotating hood, a good We efficiency is achieved when the agitator jet is discharged, by the approximately perpendicular to the propeller-facing boundary surface of the rotating hood, which causes the air to be preferably vertical is mixed into the stirring jet. This achieves the greatest possible hydraulic shear forces and thus fine bubbles in the liquid.

Fig. 5 shows an embodiment according to claim 10 again. The two-part rotating hood consists of the propeller-facing conical hood ( 17 ), the form-fitting, for example, via cams ( 18 ) with this verbun those wing disc ( 19 ) and a screw connection ( 20 ) of both elements.

The conical hood and wing disc are sealed on the inside and outside diameter via elastomer seals ( 21 ). This prevents liquid from entering the cavity ( 22 ).

In the embodiment of Fig. 6, the stirrer is designed as a submersible agitator (23).

The submersible mixer is attached to a carriage ( 24 ) which can be raised and lowered by means of a lifting device via a square rail ( 25 ) mounted vertically in the storage container. The suction line ( 5 ) to the center of the stationary disc ( 8 ) is fixed in the agitator area on the wire rope ( 26 ) and on the holder ( 27 ). The holder ( 27 ) is firmly connected to the agitator, the distance between the stationary and rotating disc can be adjusted during assembly. The submersible agitator can be pivoted about the pivot point ( 28 ) when the bolt is moved from the lower bracket ( 29 ) to the upper bracket ( 30 ). This enables the device to be used in an inclined position of up to 45 °. In the case of strongly foaming liquids, the agitator can be operated just below the liquid level and the foam can be torn into the liquid by the propeller and broken up.

All in the description, the claims and the drawing Features and embodiments described can both individually and in any combination other essential to the invention.

Claims (10)

1. Aeration device for stirrers for additional ventilation of liquids with a motor-driven propeller under the liquid level ( 1 ), characterized in that in the direction of flow behind the propeller rotationally symmetrically to the propeller axis, an approximately the shape of an open impeller known from fluid technology, taking element is arranged, the sen radial blades ( 3 ) on the side facing away from the propeller of a rotating disc ( 2 ) are attached and in the center of the stationary wall ( 4 ) the air supply ( 5 ) is provided. 2. Ventilation device according to claim 1, characterized in that the stationary disc ( 4 ) with the holder ( 27 ) on the bearing housing ( 6 ) of the propeller axis is attached. 3. Ventilation device according to claim 1, characterized in that the distance A of the stationary disc ( 4 ) to the blades ( 2 ) of the rotating disc ( 3 ) is adjustable. 4. Ventilation device according to claim 1, characterized in that the stationary disc ( 4 ) and the rotating wing disc ( 3 ) are designed approximately with the same outer diameter. 5. Ventilation device according to claim 1, characterized in that the diameter of the rotating wing disc ( 3 ) and the stationary disc ( 4 ) with about 2/3 of the outer diameter of the propeller ( 1 ) are executed. 6. Ventilation device according to claim 1, characterized in that the rotating and the stationary disc are designed as conical hoods ( 7 , 8 ) and the imaginary cone tips of both hoods ( 9 ) lie approximately on the propeller axis ( 10 ) and are turned towards the propeller . 7. Ventilation device according to claims 1 and 6, characterized in that the angle of inclination ( α 1 ) of the stationary hood ( 11 ) is smaller than the angle of inclination ( α 2 ) of the co-rotating the wing hood and thus the blades in the radial cut are approximately wedge-shaped ( 13 ). 8. Ventilation device according to claim 1, characterized characterized that propeller and with rotating wing disc are made in several parts, so that e.g. is possible to economize the propeller Lich as a welded construction and the rotating hood to be manufactured as a cast construction. 9. Ventilation device according to claims 1 and 6, characterized in that the propeller-facing boundary surface of the wall ( 14 ) of the rotating conical hood is not parallel to the propeller-facing boundary surface ( 15 ) and the generatrix of the propeller-facing surface a smaller angle ( β 1 ) to the axis includes, as the generatrix of the surface facing away from the propeller equipped with radial blades. 10. Ventilation device according to claims 1, 6 and 9 characterized in that the rotating hood to achieve a low weight and thus a lower rotating mass in two parts is led.