HU177412B - Cellular feed of axial-tangential flow for blast-type material transport - Google Patents

Description

The present invention relates to an axial-tangential flow cellular dispenser for metering dusty and particulate materials, e.g. material feeding structure of bag filling machines for filling valve bags.

Cellular dispensers are known which are capable of feeding the materials to be conveyed into the air stream of the conveyor. Such is described in e.g. U.S. Patent Nos. 23,39,326 and 24,198,841. A common feature of these dispensers is that the material to be dispensed flows radially into and out of the horizontal axis rotating cell wheel. The material exiting the dispenser meets cross-flow with the conveying air flowing in the conveyor pipe.

The speed of these cell feeders is limited because, above a critical speed, the rotating cell wheel is driven by the thrust of the inlet material and is not transported. Because of their low rpm, these dispensers are large and therefore have a large outlet and connection pipe. Dispensers have the disadvantage that due to their relatively large dimensions they are not suitable in cases where the size of the conveyor pipes is limited for technological reasons, e.g. for bag filling machines with valve bags, where the conveying tube must pass through a relatively narrow valve opening for the bags to be filled.

It is an object of the present invention to provide a relatively small cell dispenser which does not have a critical upper speed limit and can thus be operated at a higher speed. The dispenser provides a solution 5 so that the material flowing out of the rotating cell wheel is in almost the same direction as the conveying air, and thus the material to be conveyed into the relatively small conveying pipe is easily and without collision.

The present invention relates to an axial-tangential flow cell dispenser for transporting material by airflow, defined by a cellular wheel having a vertical or slightly different axis and having a radially bifurcated open cell with a small play on the outer wheel casing, the inner wheel an axially connected inlet, an outlet duct tangentially connected to the outer rim, and an outlet duct separating the cells in connection with the outlet from the inlet, which fits the inner rim with small play. In a functionally advantageous embodiment, air is fed into the inlet ducts connected to the inlet passage through air filter plates disposed between the cell wheel face plates and the dosing housing lids and curved air distribution slots adjacent the outer wheel casing. In a further preferred embodiment, air is introduced into the inlet duct via an air filter disk mounted on the cell face side lower face plate.

The axial-tangential flow cellular dispenser according to the invention is illustrated in Fig. 1 in a sectional view, Fig. 2 in a section perpendicular to the axis.

The cellular wheel 2 is mounted on a vertical axis 1 mounted on the bearing, with radially open cells 5 between the lower face plate 3 and the upper face plate 4 in an annular manner.

The 2-cell wheel rotates in the dispenser housing 6 to which the outer wheel rim 7 of the wheel is fitted with a small play. The dosing housing 6 is closed from below by the lower lid 8 and from above by the upper lid 9.

Between the lower cover 8 and the lower face plate 3 of the cell wheel 2 is located the lower air filter plate 10, the upper cover 9 and the upper face plate 4 an upper air filter plate. The covers 8 and 9 are provided with air connection holes 12.

The dosing housing 6 has an outlet duct 13 tangentially connected to the outer rim 7 of the cell wheel 2, to which an air inlet hole 14 is connected. The air connector 15 is connected to the air inlet hole 14 via the air filter tube 16.

An inlet channel 18 is axially connected to the inner rim 17 of the cell wheel. The cells 5 which are connected to the outlet channel 13 during rotation are separated from the inlet channel 18 by a small toy separating arcuate 19 connected to the inner wheel rim 17.

During the rotation, the cells 5 in connection with the inlet channel 18 are connected by the lower rim 3 and lower air filter plate 3, the upper face plate 4 and the upper air filter 11 along the outer rim 7 in the feed housing 6 plate space.

On the lower face plate 3 of the cell wheel 2, on the side facing the cells 5, an air filter disk 22 is mounted and an air connection hole 23 is formed in the shaft 1.

The cellular dispenser according to the invention operates as follows:

Dust or particulate material flowing into the inlet passage 18 is applied to the rotating cell wheel 2 where it is applied to the cells 5 by a folding force. When the rotating cells 5 are in contact with the outlet duct 13, the frictional force delivers the material to the outlet duct 13 where it is conveyed by the conveying air introduced through the air inlet hole 14.

The air blown through the air inlet holes 12 passes through the lower and upper air filter plates 10 and through the lower and upper curved air distribution slots 20 into the rotating cells 5 and then into the inlet channel 18. This air cleans the spaces between the bottom and top face plates 3 of the cell wheel 2 and the bottom and top air filter plates 10, reducing friction of the material on the contact surface 6, releasing heat from friction, and keeping it loose the material in the cells 5.

The air introduced through the air connection bore 23 in the shaft 1 passes through the air filter disc 22 into the inlet duct 18, loosening the material therein and preventing its entrapment.

The separating diaphragm 19 separates the relaxing air supplied to the inlet duct 18 and the supply air flowing through the outlet duct 13 and ensures that the air supplied to the dispenser at various locations is used as intended.

The air filter plates 10 and 11, the air filter tube 6 and the air filter disc 22 are of small pore size e.g. powder metallurgy bronze filter elements. Their function is to separate the material to be fed from the feed air and to ensure an even distribution of air in the material.

An advantage of the cellular dispenser according to the invention is that it does not have a critical upper speed limit, because the material flowing from the inlet channel to the cellular wheel is forced by the rotating power of the rotating wheel into the cells. The height of the cells may be small and equal to the size of the outlet duct section. The material that enters the discharge channel from the cells, with good approximation, flies towards the axis of the discharge channel. Thus, the material is introduced into the outlet channel without any sudden cross-sectional change or refraction. A further advantage is that the inlet duct, where the material is gravitationally flowing, is large, and by introducing air it is easy to loosen the material in the inlet duct.

Claims (3)

Patent claims: Axial-tangential flow cell feeder for transporting material by airflow, characterized in that a cellular wheel (2) with a vertical or slightly different axis (1), arranged in the form of an annular radially open cell (5) on both sides, (7) a small toy-adapted dispenser housing (6), an inlet channel (18) axially connected to the inner wheel casing (17) and an outlet channel (13) tangentially connected to the outer wheel casing (7) with an air inlet (14); (13) has a curve (19) separating the adjacent cells (5) from the inlet channel (18), which is fitted with a small play to the inner wheel rim (17). An embodiment of a cellular dispenser as defined in claim 1, characterized in that the front plates (3, 4) of the cellular wheel (2) and the covers (8, 9) of the dispenser housing (6) are provided with an air connection bore (12). ) between the air filter plates (10, 11) and the face plates (3, 4) of the cell wheel (2) and the air filter plates (10, 11), connecting the outer wheel casing with the cells (5) connected to the inlet channel (18) (7) have curved air distribution slots (20, 21). The cellular dispenser as defined in claim 1 or 2, characterized in that the air filter disk (22) mounted on the lower face plate (3) of the cell wheel (2), on the side facing the inlet channel (18), and the air filter There is an air connection bore (23) in the shaft (1) under the pulley (22).