DE1169370B - Pneumatic feeding device for loose bulk goods - Google Patents

Description

Pneumatic feeding device for loose bulk material The invention relates to a pneumatic feeding device for loose bulk material with a feed screw, a conveying gas into a mixing chamber through its hollow, overhung screw shaft for conveying the material in a conveying line connected to the mixing chamber is blown in.

Such feeding devices are used, for example, for transport used by conveyed goods through a closed pipeline to the point of use.

It has now been shown that it is very difficult to find a sufficient one To generate or maintain negative pressure at the flying end of the worm shaft, as he does for a perfect introduction of the goods into the conveying gas flow necessary is. The reason for this is that when it emerges from the worm shaft conically widening gas jet due to the high exit velocity has a very hard surface. The conveyed material must be in this gas cone with a great effort to be pressed, which inevitably leads to the formation of turbulent Currents in the mixing chamber occur and thus destroy the negative pressure the screw outlet.

The kinetic energy of the exiting gas jet, which the is intended to counteract the back pressure that builds up in the delivery line is destroyed here, so there is also a pressure increase within the mixing chamber. The feed screw the material to be conveyed must therefore be pressed into the mixing chamber against the internal overpressure. In order to prevent the conveying gas from flowing back through the metering screw or through the air gap To prevent between the screw and the screw housing, the feed screw must also operated at very high speeds. This is what is in the screw The conveyed material is thrown outwards by centrifugal force and thus serves as a seal of the annular gap between the screw and the screw sleeve.

The disadvantages of these known designs are very high Force required to feed the conveyed material into the pressurized mixing chamber and in the resulting high wear of the screw, the housing and the mixing chamber walls, especially when pumping aggressive, e.g. mineral materials.

These disadvantages are exacerbated by the fact that one at such high speeds only achieve a low degree of filling of the screw can, so this must be greatly oversized for a relatively high performance.

To counter these difficulties, a pneumatic one is already available Feeding device with feeding of the goods by means of a screw became known, in which the conveying air circulates around the end of the screw feed pipe and the Receives well. However, with this feed device, the conveying gas does not get through the worm shaft, but through an annular gap around the worm housing introduced around.

According to a also known pneumatic feed device is provided that the conveyed material in the conveying line by means of conveying air emerging from nozzles is washed around by this, each nozzle is directed so that the outflow direction of the air one component oriented in the conveying direction of the goods and one peripherally oriented component contains. This device also does not have a feed screw, the conveying gas is fed through their hollow shaft.

But these two pneumatic feeding devices also vouch for this no proper introduction of the conveyed material into the conveying gas flow, because it is on A mixture of the conveyed material and conveying gas flow with as little resistance as possible is missing. Because in the first-mentioned device, the conveyed material is only on its periphery flows around, and the back pressure from the delivery line can unhindered on the metering screw and affect the conveyed goods supplied by it, all the more so than the central one Gas flow supplied from the hollow screw shaft to brake the backflow completely is missing. With the other device, the conveyed material only reaches its own weight in the area of the conveying gas flow emerging from the nozzles, and this is also absent the centrally supplied conveying gas flow.

The object of the invention is to make the conveyed material as resistant as possible to be introduced into the conveying gas flow in order to remove the Negative pressure zone to maintain and the back pressure building up in the delivery line to counteract the utilization of the kinetic energy of the conveying gas flow.

For this purpose, the inventive training is to be seen in the fact that the Generating the inner wall of the outlet opening in the worm shaft from the Axis of the mixing chamber are at different distances, so that during rotation the feed screw the gas enters the mixing chamber in a helical manner. This will the conical surface of the gas jet in relation to its respective diameter in the cycle of the number of revolutions of the worm shaft constantly changed and thereby a intimate mixing of the material and gas flow and thus easier introduction of the material to be conveyed into the gas flow.

According to a preferred embodiment of the invention, the cross section the outlet opening of the worm shaft have a flattened shape.

If with such an outlet nozzle the gas outlet velocity is correctly matched to the number of revolutions of the screw, one achieves - how already executed - a helical surface of the conical gas jet. The conveyed material emerging from the screw is fed into the depressions of the screw threads smuggled in.

A similar effect is achieved if you use a nozzle of z. B. circular cross-section eccentric to the worm shaft axis.

In the drawing, two exemplary embodiments of the training are shown of the invention shown. It shows: Fig. 1 the pneumatic feeding device in side view, F i g. 2 shows an end view of the nozzle outlet according to FIG G. 1 on an enlarged scale, FIG. 2a shows a section along the line A-B according to FIG Fig. 2, Fig. 2b shows a section along the line C-D according to FIG. 2, FIG. 3 another Exemplary embodiment in side view.

In the F i g. 1 and 3 is the end part of the feed screw 1 with the hollow worm shaft 1 'shown. The metering screw 1 is of a screw sleeve 2 and the latter at its end facing the conveying line by an annular nozzle 3 surrounded, which is provided with a number of nozzle openings 4 in the conveying direction. That through the snail Conveying gas fed to shaft 1 'passes through an outlet opening 5 into the mixing chamber 6. In the F i g. 2, 2 a and 2 b is the nozzle-shaped outlet opening 5 shown for the conveying gas. In Figs. 2, 2 a and 2 b, the outlet opening a flattened shape.

Since the outlet opening 5 is the rotational movement of the worm shaft 1 ' participates, the conveying gas is given one in FIG. 1 indicated helical movement given up.

A similar inevitable movement of the conveying gas can thereby be achieved that the opening 5 designed as a nozzle to the axis of the worm shaft 1 ' is arranged eccentrically, as shown in FIG. 3 can be found.

To increase the targeted delivery rate, the contributes to the metering auger 1 arranged around annular nozzle 3, the channels or nozzle openings 4 tangential are arranged to the screw circumference and at an obtuse angle to the conveying direction.

Claims (3)

Claims: 1. Pneumatic feeding device for loose bulk material with a metering screw through its hollow, overhung screw shaft Conveying gas in a mixing chamber for conveying the goods in one to the mixing chamber subsequent delivery line is blown in, d a d u r c h marked that the generatrix of the inner wall of the outlet opening (5) in the worm shaft (1 ') are at different distances from the axis of the mixing chamber (6), so that during When the metering screw (1) is rotated, the gas enters the mixing chamber in a helical manner. 2. Conveyor device according to claim 1, characterized in that the cross section of the outlet opening (5) of the screw shaft (1 ') is a flattened one Has shape. 3. Conveyor according to claim 1, characterized in that the outlet opening (5) of the worm shaft (1 ') is arranged eccentrically to its axis is. Considered publications: German Patent Specifications No. 484 424, 482 401, 471 2971 Austrian patent specification No. 118 338; Swiss U.S. Patent No. 345,844: U.S. Patent No. 2,614,892.